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ATSAML11D14A-MUT

ATSAML11D14A-MUT

  • 厂商:

    ACTEL(微芯科技)

  • 封装:

    VFQFN24

  • 描述:

    IC MCU 32BIT 16KB FLASH 24VQFN

  • 数据手册
  • 价格&库存
ATSAML11D14A-MUT 数据手册
SAM L10/L11 Family Ultra Low-Power, 32-bit Cortex-M23 MCUs with TrustZone, Crypto, and Enhanced PTC Features • Operating Conditions: 1.62V to 3.63V, -40ºC to +125ºC, DC to 32 MHz • Core: 32 MHz (2.64 CoreMark/MHz and up to 31 DMIPS) Arm® Cortex®-M23 with: – Single-cycle hardware multiplier – Hardware divider – Nested Vector Interrupt Controller (NVIC) – Memory Protection Unit (MPU) – Stack Limit Checking – TrustZone® for ARMv8-M (optional) • System – Power-on Reset (POR) and programmable Brown-out Detection (BOD) – 8-channel Direct Memory Access Controller (DMAC) – 8-channel event system for Inter-peripheral Core-independent Operation – CRC-32 generator • Memory – 16/32/64-KB Flash – 4/8/16-KB SRAM – 2-KB Data Flash Write-While-Read (WWR) section for non-volatile data storage – 256 bytes TrustRAM with physical protection features • Clock Management – Flexible clock distribution optimized for low power – 32.768 kHz crystal oscillator – 32.768 kHz ultra low-power internal RC oscillator – 0.4 to 32 MHz crystal oscillator – 16/12/8/4 MHz low-power internal RC oscillator – Ultra low-power digital Frequency-Locked Loop (DFLLULP) – 32-96 MHz fractional digital Phase-Locked Loop (FDPLL96M) – One frequency meter • Low-Power and Power Management – Active, Idle, Standby with partial or full SRAM retention and off sleep modes: • Active mode (< 25 μA/MHz) • Idle mode (< 10 μA/MHz) with 1.5 μs wake-up time • Standby with Full SRAM Retention (0.5 μA) with 5.3 μs wake-up time • Off mode (< 100 nA) – Static and dynamic power gating architecture – Sleepwalking peripherals – Two performance levels © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1 SAM L10/L11 Family – Embedded Buck/LDO regulator with on-the-fly selection • Security – Up to four tamper pins for static and dynamic intrusion detections – Data Flash • Optimized for secure storage • Address and data scrambling with user-defined key (optional) • Rapid tamper erase on scrambling key and on one user-defined row • Silent access for data read noise reduction – TrustRAM • Address and data scrambling with user-defined key • Chip-level tamper detection on physical RAM to resist microprobing attacks • Rapid tamper erase on scrambling key and RAM data • Silent access for data read noise reduction • Data remanence prevention – Peripherals • One True Random Generator (TRNG) • AES-128, SHA-256, and GCM cryptography accelerators (optional) • Secure pin multiplexing to isolate on dedicated I/O pins a secured communication with external devices from the non-secure application (optional) – TrustZone for flexible hardware isolation of memories and peripherals (optional) • Up to six regions for the Flash • Up to two regions for the Data Flash • Up to two regions for the SRAM • Individual security attribution for each peripheral, I/O, external interrupt line, and Event System Channel – Secure Boot with SHA-based authentication (optional) – Up to three debug access levels – Up to three Chip Erase commands to erase part of or the entire embedded memories – Unique 128-bit serial number – SAM L11 Securely Key Provisioned (KPH) (optional) • Key Provisioning using Root of Trust flow • Security Software Framework using Kinibi-M™ Software Development Kit (SDK) • Advanced Analog and Touch – One 12-bit 1 Msps Analog-to-Digital Converter (ADC) with up to 10 channels – Two Analog Comparators (AC) with window compare function – One 10-bit 350 kSPS Digital-to-Analog Converter (DAC) with external and internal outputs – Three Operational Amplifiers (OPAMP) – One enhanced Peripheral Touch Controller (PTC): • Up to 20 self-capacitance channels • Up to 100 (10x10) mutual-capacitance channels • Low-power, high-sensitivity, environmentally robust capacitive touch buttons, sliders, and wheels • Hardware noise filtering and noise signal desynchronization for high conducted immunity • Driven Shield Plus for better noise immunity and moisture tolerance • Parallel Acquisition through Polarity control • Supports wake-up on touch from Standby Sleep mode • Communication Interfaces – Up to three Serial Communication Interfaces (SERCOM) that can operate as: • USART with full-duplex and single-wire half-duplex configuration © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 2 SAM L10/L11 Family • • • • • I2C up to 3.4 Mbit/s (High-Speed mode) on one instance and up to 1 Mbit/s (Fast-mode Plus) on the second instance Serial Peripheral Interface (SPI) ISO7816 on one instance (Available on 32-pin packages only) RS-485 on one instance (Available on 32-pin packages only) LIN Slave on one instance (Available on 32-pin packages only) • Timers/Output Compare/Input Capture – Three 16-bit Timers/Counters (TC), each configurable as: • One 16-bit TC with two compare/capture channels • One 8-bit TC with two compare/capture channels • One 32-bit TC with two compare/capture channels, by using two TCs – 32-bit Real-Time Counter (RTC) with clock/calendar functions – Watchdog Timer (WDT) with Window mode • Input/Output (I/O) – Up to 25 programmable I/O lines – Eight external interrupts (EIC) – One non-maskable interrupt (NMI) – One Configurable Custom Logic (CCL) that supports: • Combinatorial logic functions, such as AND, NAND, OR, and NOR • Sequential logic functions, such as Flip-Flop and Latches • Qualification and Class-B Support – AEC-Q100 Grade 1 (-40ºC to +125ºC) – Class-B safety library, IEC 60730 (future) • Debugger Development Support – Two-pin Serial Wire Debug (SWD) programming and debugging interface Packages (1) • VQFN Type TQFP SSOP WLCSP Pin Count 24 32 32 24 32 I/O Pins (up to) 17 25 25 17 25 0.5 mm 0.5 mm 0.8 mm 0.65 mm 0.4 mm 4x4x0.9 mm 5x5x1 mm 7x7x1 mm 8.2x5.3x2.0 mm 2.79x2.79x0.482 mm Contact/Lead Pitch Dimensions 5x5x0.9 mm(2) Notes:  1. AEC-Q100 Grade 1 Qualification is only offered for VQFN (with wettable flanks) and TQFP devices. 2. VQFN with wettable flanks. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 3 SAM L10/L11 Family Table of Contents Features......................................................................................................................................................... 1 1. Configuration Summary........................................................................................................................ 14 2. Ordering Information............................................................................................................................. 16 3. Block Diagram.......................................................................................................................................17 4. Pinouts.................................................................................................................................................. 18 4.1. 4.2. 4.3. 4.4. Multiplexed Signals.................................................................................................................... 19 Oscillators Pinout....................................................................................................................... 20 Serial Wire Debug Interface Pinout............................................................................................ 21 General Purpose I/O (GPIO) Clusters........................................................................................21 5. Signal Descriptions List ........................................................................................................................22 6. Power Considerations........................................................................................................................... 24 6.1. 6.2. 6.3. 6.4. 6.5. 7. Analog Peripherals Considerations.......................................................................................................27 7.1. 7.2. 8. Reference Voltages.................................................................................................................... 28 Analog On Demand Feature...................................................................................................... 28 Device Startup.......................................................................................................................................29 8.1. 8.2. 8.3. 8.4. 9. Power Supplies.......................................................................................................................... 24 Power Supply Constraints.......................................................................................................... 24 Power-On Reset and Brown-Out Detectors............................................................................... 25 Voltage Regulators..................................................................................................................... 25 Typical Powering Schematic...................................................................................................... 25 Clocks Startup............................................................................................................................ 29 Initial Instructions Fetching.........................................................................................................29 I/O Pins.......................................................................................................................................29 Performance Level Overview..................................................................................................... 29 Product Mapping................................................................................................................................... 30 10. Memories.............................................................................................................................................. 32 10.1. Embedded Memories................................................................................................................. 32 10.2. NVM Rows................................................................................................................................. 34 10.3. Serial Number............................................................................................................................ 40 11. Processor and Architecture...................................................................................................................41 11.1. 11.2. 11.3. 11.4. Cortex-M23 Processor............................................................................................................... 41 Nested Vector Interrupt Controller..............................................................................................43 High-Speed Bus System............................................................................................................ 46 SRAM Quality of Service............................................................................................................48 12. Peripherals Configuration Summary..................................................................................................... 50 13. SAM L11 Specific Security Features..................................................................................................... 53 13.1. Features..................................................................................................................................... 53 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 4 SAM L10/L11 Family 13.2. 13.3. 13.4. 13.5. 13.6. Arm TrustZone Technology for Armv8-M....................................................................................53 Crypto Acceleration.................................................................................................................... 63 Secure Boot................................................................................................................................66 Secure Pin Multiplexing on SERCOM........................................................................................ 66 Data Flash Scrambling............................................................................................................... 66 14. Boot ROM............................................................................................................................................. 67 14.1. 14.2. 14.3. 14.4. Features..................................................................................................................................... 67 Block Diagram............................................................................................................................ 67 Product Dependencies............................................................................................................... 68 Functional Description................................................................................................................68 15. PAC - Peripheral Access Controller...................................................................................................... 89 15.1. 15.2. 15.3. 15.4. 15.5. 15.6. 15.7. Overview.................................................................................................................................... 89 Features..................................................................................................................................... 89 Block Diagram............................................................................................................................ 89 Product Dependencies............................................................................................................... 89 Functional Description................................................................................................................90 Register Summary......................................................................................................................94 Register Description................................................................................................................... 95 16. Device Service Unit (DSU).................................................................................................................. 115 16.1. Overview...................................................................................................................................115 16.2. Features................................................................................................................................... 115 16.3. Block Diagram.......................................................................................................................... 116 16.4. Signal Description.....................................................................................................................116 16.5. Product Dependencies............................................................................................................. 116 16.6. Debug Operation...................................................................................................................... 117 16.7. Programming............................................................................................................................ 119 16.8. Security Enforcement............................................................................................................... 120 16.9. Device Identification................................................................................................................. 122 16.10. Functional Description..............................................................................................................123 16.11. Register Summary....................................................................................................................128 16.12. Register Description.................................................................................................................129 17. Clock System...................................................................................................................................... 156 17.1. 17.2. 17.3. 17.4. 17.5. 17.6. 17.7. Clock Distribution..................................................................................................................... 156 Synchronous and Asynchronous Clocks..................................................................................157 Register Synchronization......................................................................................................... 157 Enabling a Peripheral............................................................................................................... 160 On Demand Clock Requests....................................................................................................160 Power Consumption vs. Speed................................................................................................ 160 Clocks after Reset.................................................................................................................... 161 18. GCLK - Generic Clock Controller........................................................................................................ 162 18.1. 18.2. 18.3. 18.4. Overview.................................................................................................................................. 162 Features................................................................................................................................... 162 Block Diagram.......................................................................................................................... 162 Signal Description.................................................................................................................... 163 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 5 SAM L10/L11 Family 18.5. 18.6. 18.7. 18.8. Product Dependencies............................................................................................................. 163 Functional Description..............................................................................................................164 Register Summary....................................................................................................................169 Register Description................................................................................................................. 169 19. MCLK – Main Clock............................................................................................................................ 178 19.1. 19.2. 19.3. 19.4. 19.5. 19.6. 19.7. 19.8. Overview.................................................................................................................................. 178 Features................................................................................................................................... 178 Block Diagram.......................................................................................................................... 178 Signal Description.................................................................................................................... 178 Product Dependencies............................................................................................................. 178 Functional Description..............................................................................................................180 Register Summary....................................................................................................................184 Register Description................................................................................................................. 184 20. FREQM – Frequency Meter................................................................................................................ 197 20.1. 20.2. 20.3. 20.4. 20.5. 20.6. 20.7. 20.8. Overview.................................................................................................................................. 197 Features................................................................................................................................... 197 Block Diagram.......................................................................................................................... 197 Signal Description.................................................................................................................... 197 Product Dependencies............................................................................................................. 197 Functional Description..............................................................................................................199 Register Summary....................................................................................................................202 Register Description................................................................................................................. 202 21. RSTC – Reset Controller.................................................................................................................... 212 21.1. 21.2. 21.3. 21.4. 21.5. 21.6. 21.7. 21.8. Overview.................................................................................................................................. 212 Features................................................................................................................................... 212 Block Diagram.......................................................................................................................... 212 Signal Description.................................................................................................................... 212 Product Dependencies............................................................................................................. 212 Functional Description..............................................................................................................213 Register Summary....................................................................................................................215 Register Description................................................................................................................. 215 22. PM – Power Manager......................................................................................................................... 217 22.1. 22.2. 22.3. 22.4. 22.5. 22.6. 22.7. 22.8. Overview.................................................................................................................................. 217 Features................................................................................................................................... 217 Block Diagram.......................................................................................................................... 217 Signal Description.................................................................................................................... 218 Product Dependencies............................................................................................................. 218 Functional Description..............................................................................................................219 Register Summary....................................................................................................................234 Register Description................................................................................................................. 234 23. OSCCTRL – Oscillators Controller......................................................................................................242 23.1. Overview.................................................................................................................................. 242 23.2. Features................................................................................................................................... 242 23.3. Block Diagram.......................................................................................................................... 242 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 6 SAM L10/L11 Family 23.4. 23.5. 23.6. 23.7. 23.8. Signal Description.................................................................................................................... 243 Product Dependencies............................................................................................................. 243 Functional Description..............................................................................................................244 Register Summary....................................................................................................................254 Register Description................................................................................................................. 255 24. OSC32KCTRL – 32KHz Oscillators Controller................................................................................... 283 24.1. 24.2. 24.3. 24.4. 24.5. 24.6. 24.7. 24.8. Overview.................................................................................................................................. 283 Features................................................................................................................................... 283 Block Diagram.......................................................................................................................... 283 Signal Description.................................................................................................................... 284 Product Dependencies............................................................................................................. 284 Functional Description..............................................................................................................285 Register Summary....................................................................................................................290 Register Description................................................................................................................. 290 25. SUPC – Supply Controller...................................................................................................................302 25.1. 25.2. 25.3. 25.4. 25.5. 25.6. 25.7. 25.8. Overview.................................................................................................................................. 302 Features................................................................................................................................... 302 Block Diagram.......................................................................................................................... 303 Signal Description.................................................................................................................... 303 Product Dependencies............................................................................................................. 303 Functional Description..............................................................................................................304 Register Summary....................................................................................................................310 Register Description................................................................................................................. 310 26. WDT – Watchdog Timer...................................................................................................................... 327 26.1. 26.2. 26.3. 26.4. 26.5. 26.6. 26.7. 26.8. Overview.................................................................................................................................. 327 Features................................................................................................................................... 327 Block Diagram.......................................................................................................................... 327 Signal Description.................................................................................................................... 328 Product Dependencies............................................................................................................. 328 Functional Description..............................................................................................................329 Register Summary....................................................................................................................334 Register Description................................................................................................................. 334 27. RTC – Real-Time Counter...................................................................................................................343 27.1. 27.2. 27.3. 27.4. 27.5. 27.6. 27.7. Overview.................................................................................................................................. 343 Features................................................................................................................................... 343 Block Diagram.......................................................................................................................... 343 Signal Description.................................................................................................................... 345 Product Dependencies............................................................................................................. 345 Functional Description..............................................................................................................346 Register Description ................................................................................................................ 355 28. DMAC – Direct Memory Access Controller......................................................................................... 425 28.1. Overview.................................................................................................................................. 425 28.2. Features................................................................................................................................... 425 28.3. Block Diagram.......................................................................................................................... 426 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 7 SAM L10/L11 Family 28.4. Signal Description.................................................................................................................... 427 28.5. Product Dependencies............................................................................................................. 427 28.6. Functional Description..............................................................................................................428 28.7. Register Summary....................................................................................................................446 28.8. Register Description................................................................................................................. 447 28.9. Register Summary - SRAM...................................................................................................... 474 28.10. Register Description - SRAM................................................................................................... 474 29. EIC – External Interrupt Controller...................................................................................................... 481 29.1. 29.2. 29.3. 29.4. 29.5. 29.6. 29.7. 29.8. Overview.................................................................................................................................. 481 Features................................................................................................................................... 481 Block Diagram.......................................................................................................................... 481 Signal Description.................................................................................................................... 482 Product Dependencies............................................................................................................. 482 Functional Description..............................................................................................................483 Register Summary....................................................................................................................489 Register Description................................................................................................................. 490 30. NVMCTRL – Nonvolatile Memory Controller...................................................................................... 506 30.1. 30.2. 30.3. 30.4. 30.5. 30.6. 30.7. 30.8. Overview.................................................................................................................................. 506 Features................................................................................................................................... 506 Block Diagram.......................................................................................................................... 506 Signal Description.................................................................................................................... 507 Product Dependencies............................................................................................................. 507 Functional Description..............................................................................................................508 Register Summary....................................................................................................................518 Register Description................................................................................................................. 519 31. TrustRAM (TRAM)...............................................................................................................................542 31.1. 31.2. 31.3. 31.4. 31.5. 31.6. 31.7. 31.8. Overview.................................................................................................................................. 542 Features................................................................................................................................... 542 Block Diagram.......................................................................................................................... 542 Signal Description.................................................................................................................... 542 Product Dependencies............................................................................................................. 542 Functional Description..............................................................................................................543 Register Summary....................................................................................................................548 Register Description................................................................................................................. 548 32. PORT - I/O Pin Controller....................................................................................................................559 32.1. 32.2. 32.3. 32.4. 32.5. 32.6. 32.7. 32.8. Overview.................................................................................................................................. 559 Features................................................................................................................................... 559 Block Diagram.......................................................................................................................... 560 Signal Description.................................................................................................................... 560 Product Dependencies............................................................................................................. 560 Functional Description..............................................................................................................562 Register Summary....................................................................................................................568 Register Description................................................................................................................. 569 33. EVSYS – Event System...................................................................................................................... 593 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 8 SAM L10/L11 Family 33.1. 33.2. 33.3. 33.4. 33.5. 33.6. 33.7. Overview.................................................................................................................................. 593 Features................................................................................................................................... 593 Block Diagram.......................................................................................................................... 593 Product Dependencies............................................................................................................. 594 Functional Description..............................................................................................................595 Register Summary....................................................................................................................601 Register Description................................................................................................................. 603 34. SERCOM – Serial Communication Interface...................................................................................... 625 34.1. 34.2. 34.3. 34.4. 34.5. 34.6. Overview.................................................................................................................................. 625 Features................................................................................................................................... 625 Block Diagram.......................................................................................................................... 626 Signal Description.................................................................................................................... 626 Product Dependencies............................................................................................................. 626 Functional Description..............................................................................................................628 35. SERCOM USART - SERCOM Synchronous and Asynchronous Receiver and Transmitter.............. 633 35.1. 35.2. 35.3. 35.4. 35.5. 35.6. 35.7. 35.8. Overview.................................................................................................................................. 633 USART Features...................................................................................................................... 633 Block Diagram.......................................................................................................................... 634 Signal Description.................................................................................................................... 634 Product Dependencies............................................................................................................. 634 Functional Description..............................................................................................................636 Register Summary....................................................................................................................649 Register Description................................................................................................................. 649 36. SERCOM SPI – SERCOM Serial Peripheral Interface....................................................................... 671 36.1. 36.2. 36.3. 36.4. 36.5. 36.6. 36.7. 36.8. Overview.................................................................................................................................. 671 Features................................................................................................................................... 671 Block Diagram.......................................................................................................................... 671 Signal Description.................................................................................................................... 672 Product Dependencies............................................................................................................. 672 Functional Description..............................................................................................................673 Register Summary....................................................................................................................682 Register Description................................................................................................................. 682 37. SERCOM I2C – SERCOM Inter-Integrated Circuit..............................................................................698 37.1. Overview.................................................................................................................................. 698 37.2. Features................................................................................................................................... 698 37.3. Block Diagram.......................................................................................................................... 699 37.4. Signal Description.................................................................................................................... 699 37.5. Product Dependencies............................................................................................................. 699 37.6. Functional Description..............................................................................................................701 37.7. Register Summary - I2C Slave.................................................................................................718 37.8. Register Description - I2C Slave...............................................................................................718 37.9. Register Summary - I2C Master...............................................................................................732 37.10. Register Description - I2C Master............................................................................................ 732 38. TC – Timer/Counter.............................................................................................................................750 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 9 SAM L10/L11 Family 38.1. 38.2. 38.3. 38.4. 38.5. 38.6. 38.7. Overview.................................................................................................................................. 750 Features................................................................................................................................... 750 Block Diagram.......................................................................................................................... 751 Signal Description.................................................................................................................... 751 Product Dependencies............................................................................................................. 752 Functional Description..............................................................................................................753 Register Description................................................................................................................. 766 39. TRNG – True Random Number Generator......................................................................................... 831 39.1. 39.2. 39.3. 39.4. 39.5. 39.6. 39.7. 39.8. Overview.................................................................................................................................. 831 Features................................................................................................................................... 831 Block Diagram.......................................................................................................................... 831 Signal Description.................................................................................................................... 831 Product Dependencies............................................................................................................. 831 Functional Description..............................................................................................................833 Register Summary....................................................................................................................835 Register Description................................................................................................................. 835 40. CCL – Configurable Custom Logic......................................................................................................842 40.1. 40.2. 40.3. 40.4. 40.5. 40.6. 40.7. 40.8. Overview.................................................................................................................................. 842 Features................................................................................................................................... 842 Block Diagram.......................................................................................................................... 843 Signal Description.................................................................................................................... 843 Product Dependencies............................................................................................................. 843 Functional Description..............................................................................................................845 Register Summary....................................................................................................................854 Register Description................................................................................................................. 854 41. ADC – Analog-to-Digital Converter..................................................................................................... 859 41.1. 41.2. 41.3. 41.4. 41.5. 41.6. 41.7. 41.8. Overview.................................................................................................................................. 859 Features................................................................................................................................... 859 Block Diagram.......................................................................................................................... 860 Signal Description.................................................................................................................... 860 Product Dependencies............................................................................................................. 860 Functional Description..............................................................................................................862 Register Summary....................................................................................................................873 Register Description................................................................................................................. 873 42. AC – Analog Comparators.................................................................................................................. 900 42.1. 42.2. 42.3. 42.4. 42.5. 42.6. 42.7. 42.8. Overview.................................................................................................................................. 900 Features................................................................................................................................... 900 Block Diagram.......................................................................................................................... 901 Signal Description.................................................................................................................... 901 Product Dependencies............................................................................................................. 901 Functional Description..............................................................................................................903 Register Summary....................................................................................................................911 Register Description................................................................................................................. 911 43. DAC – Digital-to-Analog Converter..................................................................................................... 928 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 10 SAM L10/L11 Family 43.1. 43.2. 43.3. 43.4. 43.5. 43.6. 43.7. 43.8. Overview.................................................................................................................................. 928 Features................................................................................................................................... 928 Block Diagram.......................................................................................................................... 928 Signal Description.................................................................................................................... 928 Product Dependencies............................................................................................................. 928 Functional Description..............................................................................................................930 Register Summary....................................................................................................................934 Register Description................................................................................................................. 934 44. OPAMP – Operational Amplifier Controller......................................................................................... 946 44.1. 44.2. 44.3. 44.4. 44.5. 44.6. 44.7. 44.8. Overview.................................................................................................................................. 946 Features................................................................................................................................... 946 Block Diagram.......................................................................................................................... 947 Signal Description.................................................................................................................... 947 Product Dependencies............................................................................................................. 948 Functional Description..............................................................................................................949 Register Summary....................................................................................................................962 Register Description................................................................................................................. 962 45. PTC - Peripheral Touch Controller...................................................................................................... 969 45.1. 45.2. 45.3. 45.4. 45.5. 45.6. Overview.................................................................................................................................. 969 Features................................................................................................................................... 969 Block Diagram.......................................................................................................................... 970 Signal Description.................................................................................................................... 971 System Dependencies............................................................................................................. 971 Functional Description..............................................................................................................972 46. Electrical Characteristics ....................................................................................................................973 46.1. Disclaimer.................................................................................................................................973 46.2. Thermal Considerations........................................................................................................... 973 46.3. Absolute Maximum Ratings......................................................................................................973 46.4. General Operating Ratings.......................................................................................................974 46.5. Supply Characteristics..............................................................................................................974 46.6. Maximum Clock Frequencies................................................................................................... 975 46.7. Power Consumption................................................................................................................. 976 46.8. Wake-Up Time..........................................................................................................................980 46.9. I/O Pin Characteristics..............................................................................................................981 46.10. Injection Current.......................................................................................................................982 46.11. Analog Characteristics............................................................................................................. 983 46.12. NVM Characteristics................................................................................................................ 998 46.13. Oscillators Characteristics........................................................................................................999 46.14. Timing Characteristics............................................................................................................1006 47. 125°C Electrical Characteristics........................................................................................................1013 47.1. 47.2. 47.3. 47.4. 47.5. Disclaimer...............................................................................................................................1013 General Operating Ratings.....................................................................................................1013 Power Consumption............................................................................................................... 1013 Analog Characteristics........................................................................................................... 1018 Oscillators Characteristics......................................................................................................1028 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 11 SAM L10/L11 Family 47.6. Timing Characteristics............................................................................................................ 1031 48. AEC-Q100 Grade (-40°C to 125°C) Electrical Characteristics..........................................................1037 48.1. 48.2. 48.3. 48.4. 48.5. 48.6. 48.7. 48.8. 48.9. Disclaimer...............................................................................................................................1037 General Operating Ratings.....................................................................................................1037 Supply Characteristics............................................................................................................1037 Power Consumption............................................................................................................... 1037 I/O Pin Characteristics............................................................................................................1041 Analog Characteristics........................................................................................................... 1042 NVM Characteristics...............................................................................................................1052 Oscillators Characteristics......................................................................................................1053 Timing Characteristics............................................................................................................ 1056 49. AC and DC Characteristics Graphs.................................................................................................. 1063 49.1. Typical Power Consumption over Temperature in Sleep Modes - 85°C.................................1063 49.2. Typical Power Consumption over Temperature in Sleep Modes - 125°C...............................1065 50. Packaging Information...................................................................................................................... 1067 50.1. Package Marking Information.................................................................................................1067 50.2. Package Drawings................................................................................................................. 1067 50.3. Soldering Profile..................................................................................................................... 1081 51. Schematic Checklist..........................................................................................................................1082 51.1. 51.2. 51.3. 51.4. 51.5. 51.6. 51.7. 51.8. Introduction.............................................................................................................................1082 Power Supply......................................................................................................................... 1082 External Analog Reference Connections............................................................................... 1084 External Reset Circuit.............................................................................................................1086 Unused or Unconnected Pins.................................................................................................1087 Clocks and Crystal Oscillators................................................................................................1087 Programming and Debug Ports..............................................................................................1090 Peripherals Considerations.................................................................................................... 1092 52. Conventions...................................................................................................................................... 1093 52.1. 52.2. 52.3. 52.4. Numerical Notation.................................................................................................................1093 Memory Size and Type...........................................................................................................1093 Frequency and Time...............................................................................................................1093 Registers and Bits.................................................................................................................. 1094 53. Acronyms and Abbreviations............................................................................................................ 1095 54. Appendix A: Migrating From SAM L21 to SAM L10/L11 (32-pin Package)....................................... 1098 54.1. Pinout Differences.................................................................................................................. 1098 54.2. Pinout Multiplexing Differences.............................................................................................. 1099 55. Appendix B: Migrating From SAM D20/D21 to SAM L10/L11 (32-pin Package) .............................. 1101 55.1. Pinout Differences.................................................................................................................. 1101 55.2. Pinout Multiplexing Differences.............................................................................................. 1102 56. Data Sheet Revision History..............................................................................................................1106 56.1. Revision F - 06/2020.............................................................................................................. 1106 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 12 SAM L10/L11 Family 56.2. 56.3. 56.4. 56.5. 56.6. Revision E - 08/2019.............................................................................................................. 1108 Rev D - 04/2019..................................................................................................................... 1108 Rev C - 02/2019......................................................................................................................1112 Rev B - 06/2018......................................................................................................................1114 Rev A - 09/2017......................................................................................................................1114 The Microchip Web Site............................................................................................................................1115 Customer Change Notification Service..................................................................................................... 1115 Customer Support.....................................................................................................................................1115 Product Identification System................................................................................................................... 1116 Microchip Devices Code Protection Feature.............................................................................................1116 Legal Notice.............................................................................................................................................. 1116 Trademarks...............................................................................................................................................1117 Quality Management System Certified by DNV........................................................................................ 1117 Worldwide Sales and Service................................................................................................................... 1118 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 13 SAM L10/L11 Family Configuration Summary 1. Configuration Summary Table 1-1. SAM L10/L11 Device-Specific Features Device Flash + Data Flash Memory (KB) SRAM (KB) SAML10D14 16+2 4 SAML10D15 32+2 8 SAML10D16 64+2 16 SAML10E14 16+2 4 SAML10E15 32+2 8 SAML10E16 64+2 16 SAML11D14 16+2 8 SAML11D15 32+2 8 SAML11D16 64+2 16 SAML11E14 16+2 8 SAML11E15 32+2 8 SAML11E16 64+2 16 Analog Comparators Inputs CCL Inputs GCLK I/Os PTC Selfcapacitance/ Mutualcapacitance Channels I/O Pins Tamper Pins Packages Pins SERCOM(1) ADC Channels 24 2 5 2 4 4 16/64 17 3 VQFN, SSOP 32 3 10 4 6 5 20/100 25 4 VQFN, TQFP, WLCSP 24 2 5 2 4 4 16/64 17 3 VQFN, SSOP 32 3 10 4 6 5 20/100 25 4 VQFN, TQFP, WLCSP Note:  1. ISO7816, RS-485 and LIN slave are only supported on 32-pin packages. Table 1-2. SAM L10/L11 Family Features Feature SAM L10 Family SAM L11 Family 1 2 TrustZone for ARMv8-M No Yes Secure Boot No Yes TrustRAM (Bytes) 256 256 8 8 TrustRAM TrustRAM, Data Flash 8 8 8/1 8/1 VDDIO and VDDCORE VDDIO and VDDCORE MPU DMA Channels Address and Data Scrambling Event System Channels External Interrupt Lines/NMI Brown-out Detection Secure Pin Multiplexing (on SERCOM) No Yes TC/Compare 3 3 RTC 1 1 Watchdog 1 1 DAC Channels 1 1 OPAMP 3 3 CCL Look-up Tables 2 2 Frequency Meter 1 1 No Yes Crypto Accelerators © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 14 SAM L10/L11 Family Configuration Summary ...........continued Feature SAM L10 Family SAM L11 Family TRNG Yes Yes CRC Yes Yes 2 3 Debug Access Levels (DAL) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 15 SAM L10/L11 Family Ordering Information 2. Ordering Information ATSAML 11 D 14 A M U T KPH Securely Key Provisioned SAML = Ultra Low Power Microcontroller No character = Tray or Tube 10 = Cortex-M23 CPU 11 = Cortex-M23 CPU with TrustZone Enabled U = -40 - +85°C Matte Sn Plating F = -40 - +125°C Matte Sn Plating Z = -40 - +125°C Matte Sn Plating (AEC-Q100 Qualified) D = 24 Pins E = 32 Pins (Flash) 16 = 64 KB 15 = 32 KB 14 = 16 KB A = TQFP M = VQFN Y = SSOP U = WLCSP Notes:  1. Devices in the WLCSP package include a factory programmed Bootloader. Contact your local Microchip sales office for more information. 2. Devices can be factory programmed with securely key provisioned software. Contact your local Microchip sales office for more information. 3. Optional KPH suffix indicates SAM L11 MCUs that are securely key provisioned with RoT (Root of Trust) flow and are supported with Kinibi-M™ Software Development Kit. KPH solution is only offered for TQFP and VQFN packages. 4. The AEC-Q100 Grade 1 qualified version is only offered for TQFP and VQFN packages. VQFN packages have wettable flanks, and both TQFP and VQFN packages are assembled with gold bond wires. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 16 SAM L10/L11 Family Block Diagram Block Diagram Figure 3-1. SAM L10/L11 Block Diagram SAM L11 Added Features 64/32/16 KB Flash with Cache Crypto Accelerators (AES128, SHA256, GCM) IOBUS SWCLK SERIAL WIRE SWDIO MPU 2KB Data Flash Cortex-M23 PROCESSOR Fmax 32 MHz Scrambling 16/8/8 KB RAM (SAM L11) 16/8/4 KB RAM (SAM L10) 128-bit Unique ID NVM EVENT CONTROLLER TrustZone for ARMv8-M DEVICE SERVICE UNIT SRAM CONTROLLER IDAU M M M S S CRC-32 M High-Speed Bus Matrix 8 KB ROM Secure Boot DMA EVENT S S S AHB-APB BRIDGE B (APBB) S AHB-APB BRIDGE A (APBA) AHB-APB BRIDGE C (APBC) EVENT PERIPHERAL ACCESS CONTROLLER EVENT MAIN CLOCKS CONTROLLER DMA OSCILLATORS CONTROLLER OSC16M DFLLULP XOSC FDPLL96M XIN XOUT 3x6SERCOM x SERCOM PAD[0] PAD[1] PAD[2] PAD[3] EVENT DMA 3x TIMER / COUNTER 8 x Timer Counter GENERIC CLOCK CONTROLLER GCLK_IO[4..0] EVENT WATCHDOG TIMER EVENT SYSTEM OA[0..2]NEG FREQUENCY METER 3x OPAMP 2x ANALOG COMPARATORS 10-CHANNEL 12-bit ADC 1MSPS DMA EVENT EXTERNAL INTERRUPT CONTROLLER EXTINT[7..0] NMI PERIPHERAL TOUCH CONTROLLER VREFA VREFB XY[19..0] EVENT EVENT DMA POWER MANAGER OA[0..2]POS OA0OUT / OA2OUT AIN[9..0] DMA EVENT AIN[3..0] CMP[1..0] WO[0] WO[1] PORT PORT 3. 10-bit DAC 350kSPS VOUT VREFA EVENT OSC32K CONTROLLER XIN32 XOUT32 XOSC32K TRNG OSCULP32K EVENT EVENT IN[5..0] SUPPLY CONTROLLER VREF BOD12 BOD33 EVENT RESET IN[3:0] OUT[3:0] CCL Voltage Regulators 256 Bytes TrustRAM RESET CONTROLLER REAL-TIME COUNTER OUT[1..0] EVENT EVENT Note:  Number of SERCOM instances, PTC/ADC channels, Tamper input pins, and Analog Compare inputs differ on the packages pinout. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 17 SAM L10/L11 Family Pinouts 4. Pinouts Figure 4-1. SAM L10/L11 24-pin VQFN Pinout 24 23 22 21 20 19 1 18 2 17 3 16 4 15 5 14 6 13 7 8 9 10 11 12 Figure 4-2. SAM L10/L11 24-pin SSOP Pinout 1 24 2 23 3 22 4 21 5 20 6 19 7 18 8 17 9 16 10 15 11 14 12 13 Figure 4-3. SAM L10/L11 32-pin VQFN and TQFP Pinout 32 31 30 29 28 27 26 25 1 24 2 23 3 22 4 21 5 20 6 19 7 18 17 8 9 © 2020 Microchip Technology Inc. 10 11 12 13 14 15 16 Datasheet DS60001513F-page 18 SAM L10/L11 Family Pinouts Figure 4-4. SAM L10/L11 32-pin WLCSP Pinout 4.1 Multiplexed Signals Each pin is controlled by the I/O Pin Controller (PORT) as a general purpose I/O and alternatively can be assigned to one of the peripheral functions: A, B, C, D, E, G, H, or I. The following table describes the peripheral signals multiplexed to the PORT I/O pins. The column “Reset State” indicates the reset state of the line with mnemonics: • "I/O" or "Function" indicates whether the I/O pin resets in I/O mode or in peripheral function mode. • “I” / ”O” / "Hi-Z" indicates whether the I/O is configured as an input, output or is tri-stated. • “PU” / “PD” indicates whether pullup, pulldown or nothing is enabled. Table 4-1. Pinout Multiplexing Pin Pin Name Supply B(1) A ADC AC PTC DAC G H I SERCOM SERCOM ALTERN ATIVE TC RTC/ Debug AC/ GCLK CCL Reset State WLCSP3 2 TQFP32/ VQFN32 5 2 A2 1 PA00 / XIN32 VDDANA EXTINT[0 ] XY[0] OA1NEG SERCOM 1/PAD[0] TC2/ WO[0] I/O, Hi-Z 6 3 A3 2 PA01 / XOUT32 VDDANA EXTINT[1 ] XY[1] OA1POS SERCOM 1/PAD[1] TC2/ WO[1] I/O, Hi-Z 7 4 A4 3 PA02 VDDANA EXTINT[2 ] OA0NEG SERCOM 0/PAD[2] I/O, Hi-Z 8 5 B3 4 PA03 VDDANA EXTINT[3 ] OA2NEG SERCOM 0/PAD[3] I/O, Hi-Z 9 6 B4 5 PA04 VDDANA EXTINT[4 ] OA2OUT SERCOM 0/PAD[0] TC0/ WO[0] IN[0] I/O, Hi-Z 10 7 A5 6 PA05 VDDANA C4 7 PA06 B5 8 PA07 B6 9 VDDANA AIN[0] XY[2] VREFA AIN[1] XY[3] VREFB AIN[2] AIN[0] EXTINT[5 ] AIN[3] AIN[1] XY[4] OA2POS SERCOM 0/PAD[1] TC0/ WO[1] IN[1] I/O, Hi-Z VDDANA EXTINT[6 ] AIN[4] AIN[2] XY[5] OA0POS SERCOM 0/PAD[2] TC1/ WO[0] IN[2] I/O, Hi-Z VDDANA EXTINT[7 ] AIN[5] AIN[3] OA0OUT SERCOM 0/PAD[3] TC1/ WO[1] OUT[0] I/O, Hi-Z © 2020 Microchip Technology Inc. VOUT OPAMP E VQFN24 8 REF D(2)(3) SSOP24 11 EIC C(2)(3) - Datasheet DS60001513F-page 19 SAM L10/L11 Family Pinouts ...........continued Pin SSOP24 Pin Name Supply B(1) A EIC REF ADC AC PTC DAC OPAMP C(2)(3) D(2)(3) E G H I SERCOM SERCOM ALTERN ATIVE TC RTC/ Debug AC/ GCLK CCL Reset State VQFN24 WLCSP3 2 TQFP32/ VQFN32 12 9 C6 10 GNDANA 13 10 D4 11 PA08 VDDIO NMI AIN[6] XY[6] SERCOM 1/PAD[0] SERCOM 2/PAD[0] RTC/IN[0] IN[3] I/O, Hi-Z D6 12 PA09 VDDIO EXTINT[0 ] AIN[7] XY[7] SERCOM 1/PAD[1] SERCOM 2/PAD[1] RTC/IN[1] IN[4] I/O, Hi-Z C5 13 PA10 VDDIO EXTINT[1 ] AIN[8] XY[8] SERCOM 1/PAD[2] SERCOM 2/PAD[2] GCLK_I O[4] IN[5] I/O, Hi-Z D5 14 PA11 VDDIO EXTINT[2 ] AIN[9] XY[9] SERCOM 1/PAD[3] SERCOM 2/PAD[3] GCLK_I O[3] OUT[1] I/O, Hi-Z - 14 11 E6 15 PA14 / XOSC VDDIO EXTINT[3 ] XY[10] SERCOM 2/PAD[2] SERCOM 0/PAD[2] TC0/ WO[0] GCLK_I O[0] I/O, Hi-Z 15 12 E5 16 PA15 / XOUT VDDIO EXTINT[4 ] XY[11] SERCOM 2/PAD[3] SERCOM 0/PAD[3] TC0/ WO[1] GCLK_I O[1] I/O, Hi-Z 16 13 D3 17 PA16(4) VDDIO EXTINT[5 ] XY[12] SERCOM 1/PAD[0] SERCOM 0/PAD[0] RTC/IN[2] GCLK_I O[2] IN[0] I/O, Hi-Z 17 14 F5 18 PA17(4) VDDIO EXTINT[6 ] XY[13] SERCOM 1/PAD[1] SERCOM 0/PAD[1] RTC/IN[3] GCLK_I O[3] IN[1] I/O, Hi-Z 18 15 E4 19 PA18 VDDIO EXTINT[7 ] XY[14] SERCOM 1/PAD[2] SERCOM 0/PAD[2] TC2/ WO[0] RTC/ OUT[0] AC/ CMP[0] IN[2] I/O, Hi-Z 19 16 E3 20 PA19 VDDIO EXTINT[0 ] XY[15] SERCOM 1/PAD[3] SERCOM 0/PAD[3] TC2/ WO[1] RTC/ OUT[1] AC/ CMP[1] OUT[0] I/O, Hi-Z 20 17 F4 21 PA22(4) VDDIO EXTINT[1 ] XY[16] SERCOM 0/PAD[0] SERCOM 2/PAD[0] TC0/ WO[0] RTC/ OUT[2] GCLK_I O[2] I/O, Hi-Z 21 18 F3 22 PA23(4) VDDIO EXTINT[2 ] XY[17] SERCOM 0/PAD[1] SERCOM 2/PAD[1] TC0/ WO[1] RTC/ OUT[3] GCLK_I O[1] I/O, Hi-Z F2 23 PA24 VDDIO EXTINT[3 ] SERCOM 0/PAD[2] SERCOM 2/PAD[2] TC1/ WO[0] I/O, Hi-Z E2 24 PA25 VDDIO EXTINT[4 ] SERCOM 0/PAD[3] SERCOM 2/PAD[3] TC1/ WO[1] I/O, Hi-Z D2 25 PA27 VDDIO EXTINT[5 ] VDDIO GCLK_I O[0] I/O, Hi-Z 22 19 C2 26 RESET 23 20 E1 27 VDDCOR E - 24 21 D1 28 GND - 1 22 C1 29 VDDOUT - 2 23 B1 30 VDDIO 3 24 B2 31 PA30 / SWCLK VDDIO EXTINT[6 ] XY[18] SERCOM 1/PAD[2] TC1/ WO[0] 4 1 C3 32 PA31 / SWDIO(4 ) VDDIO EXTINT[7 ] XY[19] SERCOM 1/PAD[3] TC1/ WO[1] 1. 2. 3. 4. 4.2 I, PU SWCLK GCLK_I O[0] IN[3] SWCLK, I, PU OUT[1] I/O, Hi-Z All analog pin functions are on the peripheral function B. The peripheral function B must be selected to disable the digital control of the pin. Refer to SERCOM Features to get the list of the supported features for each SERCOM instance. 24-pin packages only have two SERCOM instances: SERCOM0 and SERCOM1. The following pins are High Sink pins and have different properties than standard pins: PA16, PA17, PA22, PA23 and PA31. Oscillators Pinout The oscillators are not mapped to the I/O Pin Controller (PORT) functions and their multiplexing is controlled by the Oscillators Controller (OSCCTRL) and 32 kHz Oscillators Controller (OSC32KCTRL) registers. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 20 SAM L10/L11 Family Pinouts Table 4-2. Oscillator Pinout Oscillator Supply Signal I/O pin XOSC VDDIO XIN PA14 XOUT PA15 XIN32 PA00 XOUT32 PA01 XOSC32K VDDANA The transition time of the following pins must be greater than 50us in order to not affect the XOSC32 cycle to cycle jitter: Table 4-3. XOSC32 Jitter Minimization 4.3 Package Pin Name TQFP32 / VQFN32 / VQFN24 / SSOP24 PA02, PA31 WLCSP32 PA30 Serial Wire Debug Interface Pinout The SWCLK pin is by default assigned to the SWCLK peripheral function G to allow debugger probe detection. A debugger probe detection (cold-plugging or hot-plugging) will automatically switch the SWDIO I/O pin to the SWDIO function, as long as the SWLCK peripheral function is selected. Table 4-4. Serial Wire Debug Interface Pinout 4.4 Signal Supply I/O pin SWCLK VDDIO PA30 SWDIO VDDIO PA31 General Purpose I/O (GPIO) Clusters Table 4-5. GPIO Clusters Package 32-pin 24-pin Cluster GPIO Supply Pins Connected to the Cluster 1 PA00 PA01 PA02 PA03 PA04 PA05 PA06 PA07 VDDANA/GNDANA 2 PA08 PA09 PA10 PA11 PA14 PA15 PA16 PA17 PA18 PA19 PA22 PA23 PA24 PA25 PA27 PA30 PA31 VDDIO/GND 1 PA00 PA01 PA02 PA03 PA04 PA05 VDDANA/GND 2 PA08 PA14 PA15 PA16 PA17 PA18 PA19 PA22 PA23 PA30 PA31 VDDIO/GND © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 21 SAM L10/L11 Family Signal Descriptions List 5. Signal Descriptions List The following table provides details on signal names classified by peripherals. Table 5-1. Signal Descriptions List Signal Name Function Type Generators Clock Source (Input) or Generic Clock Signal (Output) Digital I/O XIN Crystal Oscillator or External Clock Input Analog Input (Crystal Oscillator)/Digital Input (External Clock) XOUT Crystal Oscillator Output Analog Output XIN32 32.768 kHz Crystal Oscillator or External Clock Input Analog Input (Crystal Oscillator)/Digital Input (External Clock) XOUT32 32.768 kHz Crystal Oscillator Output Analog Output General SERCOM Pins Digital I/O Capture Inputs or Waveform Outputs Digital I/O IN[3:0] Tamper Detection Inputs Digital Input OUT[3:0] Tamper Detection Outputs Digital Output AIN[3:0] AC Comparator Inputs Analog Input CMP[1:0] AC Comparator Outputs Digital Output Generic Clock Generator - GCLK GCLK_IO[4:0] Oscillators Control - OSCCTRL 32 kHz Oscillators Control - OSC32KCTRL Serial Communication Interface - SERCOMx PAD[3:0] Timer Counter - TCx WO[1:0] Real Timer Clock - RTC Analog Comparators - AC Analog Digital Converter - ADC AIN[9:0] ADC Input Channels Analog Input VREFA(1) ADC External Reference Voltage A Analog Input VREFB ADC External Reference Voltage B Analog Input VOUT DAC Voltage Output Analog Output VREFA(1) DAC External Reference Voltage A Analog Input OA[2:0]NEG OPAMP Negative Inputs Analog Input OA[2:0]POS OPAMP Positive Inputs Analog Input OA0OUT / OA2OUT OPAMP Outputs Analog Output X-lines and Y-lines Digital Output (X-line) /Analog I/O (Y-line) IN[5:0] Inputs to lookup table Digital Input OUT[1:0] Outputs from lookup table Digital Output Digital Analog Converter - DAC Operational Amplifier - OPAMP Peripheral Touch Controller - PTC XY[19:0] Custom Control Logic - CCL © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 22 SAM L10/L11 Family Signal Descriptions List ...........continued Signal Name Function Type EXTINT[7:0] External Interrupts Pins Digital Input NMI Non-Maskable Interrupt Pin Digital Input General Purpose I/O Pin in Port A Digital I/O External Reset Pin (Active Level: LOW) Digital Input SWCLK Serial Wire Clock Digital Input SWDIO Serial Wire Bidirectional Data Pin Digital I/O External Interrupt Controller - EIC General Purpose I/O - PORT PA11-PA00 / PA19-PA14 / PA25-PA22 / PA27 / PA31-PA30 Reset Controller - RSTC RESET Debug Service Unit - DSU 1. VREFA is shared between the ADC and DAC peripherals. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 23 SAM L10/L11 Family Power Considerations 6. Power Considerations 6.1 Power Supplies The SAM L10/L11 have three different power supply pins: Table 6-1. SAM L10/L11 Power Supplies Name Associated Ground Powers VDDIO GND OSC16M, XOSC, the internal voltage regulator and BOD12 I/O lines: PA[11:08], PA[19:14], PA[25:22], PA[27] and PA[31:30] Voltage range, nominal: 1.62V - 3.63V, 3.3V VDDANA GNDANA OSCULP32K, XOSC32K, the POR/BOD33, the analog peripherals (ADC, AC, DAC, PTC, OPAMP) I/O lines: PA[07:00] Voltage range, nominal: 1.62V - 3.63V, 3.3V VDDCORE GND Core, embedded memories, peripherals, the FDPLL96M and the DFLLULP Voltage range: 0.9V - 1.2V ADC PA[31:30] PA[27] VDDIO VDDANA PA[07:00] PA[25:22] PA[19:14] PA[11:08] GND VDDIO VDDOUT VDDCORE GNDANA VDDANA Figure 6-1. Power Domain Overview OSC16M BUCK BOD12 LDO XOSC AC DAC VDDCORE Digital Logic PTC POR OSCULP32K CPU, Peripherals, Memories BOD33 XOSC32K FDPLL96M OPAMP DFLLULP 6.2 Power Supply Constraints The same voltage source must be applied to both VDDIO and VDDANA. Note:  This common voltage is referred to as VDD in the Data Sheet. The maximum supply falling and rising rates of the different power supplies must not exceed the values described in the Supply Characteristics section of the Electrical Characteristics chapters. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 24 SAM L10/L11 Family Power Considerations 6.3 Power-On Reset and Brown-Out Detectors The SAM L10/L11 embed three features to monitor, warn and reset the device: • A Power-on Reset (POR) on VDD (VDDANA and VDDIO): – Monitoring is always activated, including during device startup or during any sleep modes. – Having VDD below a fixed threshold voltage will reset the whole device. • • 6.4 Note:  Refer to 46.11.2 Power-On Reset (POR) Characteristics for the rising and falling threshold voltages. A Brown-out Detector (BOD33) on VDD (VDDANA and VDDIO): – The BOD33 can monitor VDD continuously (continuous mode) or periodically (sampled mode) with a programmable sample frequency in active mode as in any sleep modes. – A programmable threshold loaded from the NVM User Row is used to trigger an interrupt and/or reset the whole device. A Brown-out Detector (BOD12) on VDDCORE. Note:  BOD12 is calibrated in production and its calibration parameters are stored in the NVM User Row. This data must not be changed to ensure correct device behavior. Voltage Regulators Two embedded voltage regulators are used to provide VDDCORE to the device: • The Main voltage regulator (MAINVREG) • The Low-Power voltage regulator (LPVREG) used when the device is in Standby Sleep mode The SAM L10/L11 Main Voltage Regulator has two modes: • • 6.5 Linear (LDO) mode: The default mode after reset. Switching (BUCK) mode: The most power efficient mode when the CPU and peripherals are running (Active mode). Note:  In Active mode, the voltage regulator can be selected on the fly between LDO (low-dropout) type regulator and Buck converter using the Supply Controller (SUPC) Typical Powering Schematic The SAM L10/L11 requires a single supply from 1.62V to 3.63V. The following figures show the recommended power supply connections for two voltage regulators use cases: • LDO mode only • LDO/BUCK modes Note:  By default the LDO voltage regulator is enabled after any reset. Switching to BUCK mode is then required to benefit from its power efficiency. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 25 SAM L10/L11 Family Power Considerations Figure 6-2. Power Supply Connections for Linear (LDO) Mode Only Main Supply VDDANA (1.62V — 3.63V) VDDIO VDDOUT VDDCORE GND GNDANA Note:  Refer to "Schematic Checklist" chapter for additional information. Figure 6-3. Power Supply Connections for Switching (BUCK) / Linear (LDO) Modes Main Supply VDDANA (1.62V — 3.63V) VDDIO VDDOUT VDDCORE GND GNDANA Note:  Refer to "Schematic Checklist" chapter for additional information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 26 SAM L10/L11 Family Analog Peripherals Considerations 7. Analog Peripherals Considerations This chapter provides a global view of the analog system, which is composed of the following analog peripherals: AC, ADC, DAC, OPAMP. The analog peripherals can be connected to each other as illustrated in the following block diagram. Important:  When an analog peripheral is enabled, each analog output of the peripheral will be prevented from using the alternative functions of the output pads. This is also true even when the peripheral is used for internal purposes. Analog inputs do not interfere with alternate pad functions. Figure 7-1. Analog Signal Components Interconnections GND DAC/REFBUF OA0TAP + OA0POS ADC VDDANA OPAMP0 OA0NEG shared with DAC Output - OA0OUT GND UG DAC/REFBUF AIN0 + VDDANA - VDD SCALER R2 HYSTERESIS ENABLE OA0TAP OA0POS DAC Internal Input. DAC R1 COMPCTRLn OA0NEG DAC VOUT output buffer DAC/REFBUF GND Rg_CONN INTREF VDDANA ENABLE BANDGAP HYSTERESIS + AIN2 VREFA CMP0 COMP0 AIN1 CMP1 COMP1 GND AIN3 OA0OUT OA1TAP OA1POS + ADC VDDANA DAC/REFBUF OA1OUT OPAMP1 - OA1NEG DAC/REFBUF - OPAMP2 GND UG AIN0 AIN2 AIN5 ... AIN9 1/4 VDDIO 1/4 VDDCORE 1/4 VDDANA INTREF Temp Sensor OPAMP01 OPAMP2 DAC VDDANA R2 OA1TAP R1 MUXPOS ADC OA1POS POST PROCESSING OA1NEG GND AIN0 ... Rg_CONN AIN7 OA0OUT GND MUXNEG INTREF VREFA OA0POS VREFB OA1POS GND 1/1.6 VDDANA 1/2 VDDANA OA1OUT OA0TAP OA2POS + ADC/ AC VDDANA PRESCALER VDDANA OA2TAP DAC/REFBUF OA2OUT OPAMP2 RES3TAP - OA0NEG GND UG OA1NEG OA2NEG OA0OUT DAC/REFBUF VDDANA R2 RES3TAP R2 R1 OA2TAP DAC/REFBUF DAC Output REFBUF R1 OA2POS OA2NEG OA1OUT GND Note:  Some OPAMP Outputs (OAxOUT) can be connected directly to specific Analog Comparator or ADC Inputs (AINx) if they share the same pad: as an example, OA0OUT can be connected to the Analog Comparator AIN3 or ADC AIN5 input (PA07 pin). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 27 SAM L10/L11 Family Analog Peripherals Considerations 7.1 Reference Voltages Some analog peripherals require a reference voltage for proper operation. Apart from external voltages (that is, VDDANA or VREFx), the device has a DETREF module that provides two different internal voltage references: • BANDGAP: A stable voltage reference, fixed at 1.1V. • INTREF: A variable voltage reference, configured by the Voltage References System Control register in the Supply Controller (SUPC.VREF). The respective reference voltage source must be selected within each dedicated analog peripheral register: • ADC: Reference Control register (ADC.REFCTRL) • DAC: Reference Selection bits in the Control B register (DAC.CTRLB.REFSEL) Note:  AC has a fixed reference voltage to BANDGAP value. 7.2 Analog On Demand Feature The Analog On Demand feature allows the ADC and the AC analog peripherals to automatically enable the OPAMPx only when it is needed, thereby allowing a reduction in power consumption. It also allows the ADC analog block to be powered-off when a conversion is completed. Note:  The Analog On Demand is independent from the On Demand Clock request feature, which is used by peripherals to automatically request a source clock which was previously stopped. OPAMP case The Analog On Demand feature of the OPAMPx is activated by writing a '1' to the OPAMP.OPAMPCTRLx.ONDEMAND bit. In that case, the OPAMPx is automatically enabled when the ADC or the AC requests it (as an input) and is automatically disabled when no more requests are coming from these peripherals. CAUTION The Analog On Demand feature is not fully supported on cascaded OPAMPs. If several OPAMPs are cascaded together, only the OPAMPx that is connected to the ADC or AC can be enabled/disabled automatically. Upstream OPAMPs will not benefit from this feature. In Standby Sleep mode, the Analog On Demand feature is still supported if OPAMP.OPAMPCTRLx.RUNSTDBY=1. If OPAMP.OPAMPCTRLx.RUNSTDBY=0, the OPAMPx will be disabled entering this Sleep mode. ADC case For the ADC peripheral, Analog On Demand feature is enabled by writing the ADC.CTRLA.ONDEMAND bit to '1'. When this feature is activated, the analog block is powered-off when the conversion is complete. In Sleep mode, when an ADC start request is detected, the analog block is powered-on again and the ADC starts a new conversion after the start-up time delay. Note:  If the OPAMPx is set to accept Analog On Demand requests but the ADC is not, the ADC will send continuous requests to the OPAMPx keeping it enabled until the ADC is switching on another input. AC case For the AC peripheral,there is no explicit ONDEMAND bit. Analog On Demand requests are issued either when the AC is used in Single-Shot mode, or when comparisons are triggered by events from the Event System. Related Links 44. OPAMP – Operational Amplifier Controller 41. ADC – Analog-to-Digital Converter 42. AC – Analog Comparators © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 28 SAM L10/L11 Family Device Startup 8. Device Startup This section summarizes the SAM L10/L11 device startup sequence which starts after device power-up. After power-up, the device is kept in reset until the power has stabilized throughout the device. Once VDDIO/VDDANA and VDDCORE voltages reach a stable value, the internal reset is released. 8.1 Clocks Startup The device selects the OSC16M oscillator which is enabled by default after reset and configured at 4MHz. This 4MHz clock is also the default time base for the Generic Clock Generator 0 which provides the main clock (CLK_MAIN) to the system through the GLCK_MAIN clock. Note:  Other generic clocks are disabled to optimize power consumption. Some synchronous clocks require also to be active after startup. Note:  These active synchronous clocks also receive the 4MHz clock from Generic Clock Generator 0. Refer to the Clock Mask Register section in the Main Clock (MCLK) chapter to obtain the list of clocks that are running by default. 8.2 Initial Instructions Fetching After reset is released, the CPU starts fetching from the Boot ROM. Unless a debugger is connected and places the Boot ROM in a specific mode called Boot Interactive mode, the CPU will jump to the Flash memory loading the Program Counter (PC) and Stack Pointer (SP) values and start fetching flash user code. Before jumping to the Flash, the Boot ROM resets the first 2kB of SRAM. The Clocks remain unchanged. Note:  SAM L10/L11 Boot Interactive mode allows a debugger to perform several actions on the device such as NVM areas integrity check, chip erase, etc. Refer to 14. Boot ROM for more information. In addition, the SAM L11 Boot ROM has extra security features, such as device integrity checks, memories and peripherals security attributions, and Secure Boot that can be executed before jumping to the Flash in Secure state. 8.3 I/O Pins After reset, the I/O pins are tri-stated except PA30 pin (configured as an input with pull-up enabled) which is by default assigned to the SWCLK peripheral function to allow debugger probe detection. 8.4 Performance Level Overview The SAM L10/L11 support two different performance levels: PL0 and PL2. The default performance level after reset is PL0. This performance level is aiming for the lowest power consumption by limiting logic speeds and CPU frequency. As a consequence, some peripherals and clock sources will work with limited capabilities. Full device functionality and performance will be ensured with PL2 mode. Please refer to the Electrical Characteristics sections for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 29 SAM L10/L11 Family Product Mapping 9. Product Mapping Figure 9-1. SAM L10 Product Mapping Code Global Memory Space 0x00000000 0x00000000 Flash Code 0x00400000 0x00010000 0x02000000 Reserved NVM Rows Reserved 0x00400000 0x00804000 0x00806020 0x00806038 Boot ROM PAC 0x0080C000 Temperature Log row 0x02002000 Reserved 0x20000000 SRAM 0x20004000 Reserved 0x40001400 0x41000000 0x40001800 APBC Peripherals 0x40001C00 0x60000800 Reserved 0x60000000 IOBUS PORT TC1 Reserved 0x41FFFFFF 0x42001800 TC2 0x42001C00 WDT DAC 0x42002400 RTC Reserved 0x40002800 PTC 0x42002800 EIC Undefined 0x40002C00 Cortex-M23 Private Peripheral Bus (PPB) 0xFFFFFFFF ADC 0x42002000 0x40002400 0x60000400 0x80000000 0xE0000000 0x42001400 0x41010000 0x40002000 IOBUS TC0 HMATRIXHS GCLK Peripherals 0x60000000 0x42001000 SUPC 0x42000000 0x40000000 SERCOM2 DMAC OSC32KCTRL APBB Peripherals 0x42000C00 0x41008000 OSCCTRL APBA Peripherals SERCOM1 NVMCTRL RSTC 0x40000000 0x42000800 0x41006000 0x40001000 SERCOM0 DSU MCLK Boot Configuration row 0x42000400 0x41004000 0x40000C00 EVSYS Reserved PM User row APBC Peripherals 0x42000000 0x41002000 0x40000800 Software Calibration row APBB Peripherals 0x41000000 0x40000400 Reserved Data Flash 0x00400800 APBA Peripherals 0x40000000 TRNG 0x42002C00 FREQM 0x40003000 CCL 0x42003000 PORT 0x40003400 OPAMP 0x42003400 AC 0x40003800 TRAM 0x42003800 Reserved 0x40FFFFFF © 2020 Microchip Technology Inc. Reserved 0x42FFFFFF Datasheet DS60001513F-page 30 SAM L10/L11 Family Product Mapping Figure 9-2. SAM L11 Product Mapping Code Global Memory Space 0x00000000 0x00000000 Flash Code 0x00400000 0x00010000 0x02000000 Reserved NVM Rows Reserved 0x00804000 0x00806020 0x0080C000 Temperature Log row 0x40000C00 Reserved SRAM 0x40001400 APBB Peripherals 0x40001800 APBC Peripherals 0x40001C00 0x41000000 0x20004000 Reserved APBA Peripherals 0x60000800 Reserved TC0 HMATRIXHS 0x42001400 0x41010000 TC1 Reserved 0x41FFFFFF 0x42001800 TC2 0x42001C00 GCLK 0x40002000 IOBUS SERCOM2 0x42001000 SUPC Peripherals 0x60000000 SERCOM1 0x42000C00 DMAC OSC32KCTRL 0x42000000 0x40000000 NVMCTRL 0x41008000 OSCCTRL 0x40000000 SERCOM0 0x42000800 NVMCTRL Secure(1) 0x41006000 0x40001000 0x20000000 0x41005000 RSTC Boot Configuration row EVSYS Secure(1) DSU 0x41004000 0x60000000 IOBUS PORT WDT Undefined 0x40002A00 EIC Cortex-M23 Private Peripheral Bus (PPB) PTC 0x42002800 TRNG EIC Secure(1) 0x40002C00 0xFFFFFFFF DAC 0x42002400 RTC Reserved 0x40002800 0x80000000 ADC 0x42002000 0x40002400 0x60000400 0x42002C00 FREQM 0x40003000 0x40003200 0x40003400 EVSYS 0x42000200 0x42000400 0x41002000 MCLK APBC Peripherals 0x42000000 Reserved PM User row Software Calibration row APBB Peripherals 0x41000000 PAC Secure(1) 0x40000800 0x02002000 0xE0000000 PAC 0x40000400 0x00400000 0x00806038 Boot ROM 0x40000200 Reserved Data Flash 0x00400800 APBA Peripherals 0x40000000 PORT CCL 0x42003000 OPAMP PORT Secure(1) 0x42003400 AC 0x40003800 TRAM 0x42003800 Reserved 0x40FFFFFF Reserved 0x42FFFFFF Note:  1. This peripheral secure memory region will only appear if the peripheral is secured using PAC. Refer to MixSecure Peripherals for details. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 31 SAM L10/L11 Family Memories 10. Memories 10.1 Embedded Memories The 32-bit physical memory address space is mapped as follows: Table 10-1. Memory Sizes Memory Base Address Size [KB] SAM L11x16(1) SAM L11x15(1) SAM L10x16(1) SAM L10x15(1) SAM L11x14 (1) SAM L10x14 (1) Flash 0x00000000 64 32 16 16 Data Flash 0x00400000 2 2 2 2 SRAM 0x20000000 16 8 8 4 Boot ROM 0x02000000 8 8 8 8 Note:  1. x = E or D. 10.1.1 Flash SAM L10/L11 devices embed 16 KB, 32 KB or 64 KB of internal Flash mapped at address 0x0000 0000. The Flash has a 512-byte (64 lines of 8 bytes) direct-mapped cache which is disabled by default after power up. The Flash is organized into rows, where each row contains four pages. The Flash has a row-erase and a page-write granularity. Table 10-2. Flash Memory Parameters Device Memory Size [KB] Number of Rows Row size [Bytes] Number of Pages Page size [Bytes] SAM L11x16 / SAM L10x16 (1) 64 256 256 1024 64 SAM L11x15 / SAM L10x15 (1) 32 128 256 512 64 SAM L11x14 / SAM L10x14 (1) 16 64 256 256 64 Note:  1. x = E or D. The Flash is divided in different regions. Each region has a dedicated lock bit preventing from writing and erasing pages on it. Refer to the NVM Memory Organization figures in the NVMCTRL chapter to get the different regions definition. Note:  The regions size is configured by the Boot ROM at device startup by reading the NVM Boot Configuration Row (BOCOR). Please refer to the 14. Boot ROM chapter for more information. Table 10-3. Flash Lock Regions Parameters Device Number of Flash Lock Regions Regions Name 10.1.2 SAM L10 SAM L11 2 4 Flash (BOOT region) Secure Flash (BOOT region) / Non-Secure Flash (BOOT region) / Flash (APPLICATION region) Secure Flash (APPLICATION region) / Non-Secure Flash (APPLICATION region) Data Flash SAM L10/L11 devices embed 2 KB of internal Data Flash with Write-While-Read (WWR) capability mapped at address 0x0040 0000. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 32 SAM L10/L11 Family Memories The Data Flash can be programmed or erased while reading the Flash memory. It is not possible to read the Data Flash while writing or erasing the Flash. Note:  The Data Flash memory can be executable but requires more cycles to be read which may affect system performance. The Data Flash cannot be cached. The Data Flash is organized into rows, where each row contains four pages. The Data Flash has a row-erase and a page-write granularity. Table 10-4. Data Flash Memory Parameters Device Memory Size [KB] Number of Rows Row size [Bytes] Number of Pages Page size [Bytes] 2 8 256 32 64 SAM L10/L11 The Data Flash is divided into one or two regions. Each region has a dedicated lock bit preventing from writing and erasing pages on it. Refer to the NVM Memory Organization figures in the NVMCTRL chapter to obtain the definitions of the different regions. Note:  The regions size is configured by the Boot ROM at device startup by reading the NVM Boot Configuration Row (BOCOR). Table 10-5. Data Flash Lock Regions Parameters Device Number of Data FLASH Lock Regions Regions Name 10.1.3 SAM L10 SAM L11 1 2 Data Flash Secure Data Flash / Non-Secure Data Flash SRAM SAM L10/L11 devices embed 4 KB, 8 KB, or 16 KB of internal SRAM mapped at address 0x2000 0000. Table 10-6. SRAM Memory Parameters Device Memory Size [KB] SAM L11x16 / SAM L10x16 (1) 16 SAM L11x15 / SAM L10x15 (1) 8 SAM L11x14 (1) 8 SAM L10x14 (1) 4 Note:  1. x = E or D. SRAM is composed of 4KB sub-blocks which can be retained or not in STANDBY Low-Power mode to optimize power consumption. By default, all sub-blocks are retained, but it is possible to switch them off using the Power Manager (PM). SRAM retention is guaranteed for Watchog, External and System Reset resets. However, the two first 2kB of SRAM are reset by the Boot ROM. Important:  SRAM retention is not guaranteed after Power Supply Resets (POR, BOD12 and BOD33). 10.1.4 TrustRAM SAM L10/L11 devices embed an additional 256 bytes TrustRAM with physical protection features. Note:  Refer to 31. TrustRAM (TRAM) for more details. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 33 SAM L10/L11 Family Memories 10.1.5 Boot ROM SAM L10/L11 devices embed 8 KB of internal ROM mapped at address 0x0200 0000. Note:  For additional information, refer to the section 14. Boot ROM. 10.2 NVM Rows SAM L10 and SAM L11 have different Non Volatile Memory (NVM) rows which contain device configuration data that can be used by the system: Table 10-7. NVM Rows Mapping NVM Rows 10.2.1 Address User Row (UROW) 0x00804000 Software Calibration Row 0x00806020 Temperature Log Row 0x00806038 Boot Configuration Row (BOCOR) 0x0080C000 NVM User Row (UROW) The Non Volatile Memory User Row (UROW) contains device configuration data that are automatically read at device power-on. This row can be updated using the NVMCTRL peripheral. When writing to the NVM User Row, the new values are not loaded by the other peripherals on the device until a device reset occurs. The NVM User Row can be read at the address 0x00804000. SAM L10 and SAM L11 have different NVM User Row mappings. Related Links 30. NVMCTRL – Nonvolatile Memory Controller 25. SUPC – Supply Controller 25.8.5 BOD33 26. WDT – Watchdog Timer 26.8.1 CTRLA 26.8.2 CONFIG 26.8.3 EWCTRL 10.2.1.1 SAM L10 User Row Table 10-8. SAM L10 UROW Bitfields Definition Bit Pos. Name Usage Factory Setting Related Peripheral Register 2:0 Reserved Reserved Reserved Reserved 5:3 NSULCK NVM UnLock Bits 0x7 NVMCTRL.NSULCK 6 Reserved Reserved Reserved Reserved 12:7 BOD33_LEVEL BOD33 threshold level at power-on 0x6 SUPC.BOD33 13 BOD33_DIS BOD33 Disable at power-on 0x0 SUPC.BOD33 15:14 BOD33_ACTION BOD33 Action at power-on 0x1 SUPC.BOD33 24:16 BOD12 Calibration Parameters DO NOT CHANGE(1) 0x08F Reserved 25 WDT_RUNSTDBY WDT Runstdby at power-on 0x0 WDT.CTRLA 26 WDT_ENABLE WDT Enable at power-on 0x0 WDT.CTRLA © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 34 SAM L10/L11 Family Memories ...........continued Bit Pos. Name Usage Factory Setting Related Peripheral Register 27 WDT_ALWAYSON WDT Always-On at power-on 0x0 WDT.CTRLA 31:28 WDT_PER WDT Period at power-on 0xB WDT.CONFIG 35:32 WDT_WINDOW WDT Window mode time-out at power-on 0xB WDT.CONFIG 39:36 WDT_EWOFFSET WDT Early Warning Interrupt Time Offset at power-on 0xB WDT.EWCTRL 40 WDT_WEN WDT Timer Window Mode Enable at power-on 0x0 WDT.CTRLA 41 BOD33_HYST BOD33 Hysteresis configuration at power-on 0x0 SUPC.BOD33 255:42 Reserved Reserved Reserved Reserved CAUTION 1. BOD12 is calibrated in production and its calibration parameters must not be changed to ensure the correct device behavior. Table 10-9. SAM L10 UROW Mapping Offset Bit Pos. 0x00 7:0 0x01 15:8 0x02 23:16 0x03 31:24 0x04 39:32 0x05 47:40 0x06-0x1F 255:48 Name BOD33_LEVEL - NSULCK BOD33_ACTION Reserved BOD33_DIS BOD33_LEVEL BOD12 Calibration Parameters WDT_PER WDT_ALWAYSON WDT_ENABLE WDT_EWOFFSET WDT_RUNSTDBY BOD12 Calibration Parameters WDT_WINDOW Reserved BOD33_HYST WDT_WEN Reserved 10.2.1.2 SAM L11 User Row Table 10-10. SAM L11 UROW Bitfields Definition Bit Pos. Name Usage Factory Setting Related Peripheral Register 2:0 SULCK NVM Secure Region UnLock Bits 0x7 NVMCTRL.SULCK 5:3 NSULCK NVM Non-Secure Region UnLock Bits 0x7 NVMCTRL.NSULCK 6 Reserved Reserved Reserved Reserved 12:7 BOD33_LEVEL BOD33 threshold level at power-on. 0x6 SUPC.BOD33 13 BOD33_DIS BOD33 Disable at power-on 0x0 SUPC.BOD33 15:14 BOD33_ACTION BOD33 Action at power-on 0x1 SUPC.BOD33 24:16 BOD12 Calibration Parameters Do not change(See Note 1 under Caution) 0x08F Reserved 25 WDT_RUNSTDBY WDT Runstdby at power-on 0x0 WDT.CTRLA 26 WDT_ENABLE WDT Enable at power-on 0x0 WDT.CTRLA 27 WDT_ALWAYSON WDT Always-On at power-on 0x0 WDT.CTRLA 31:28 WDT_PER WDT Period at power-on 0xB WDT.CONFIG 35:32 WDT_WINDOW WDT Window mode time-out at power-on 0xB WDT.CONFIG 39:36 WDT_EWOFFSET WDT Early Warning Interrupt Time Offset at power-on 0xB WDT.EWCTRL 40 WDT_WEN WDT Timer Window Mode Enable at power-on 0x0 WDT.CTRLA 41 BOD33_HYST BOD33 Hysteresis configuration at power-on 0x0 SUPC.BOD33 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 35 SAM L10/L11 Family Memories ...........continued Bit Pos. Name Usage Factory Setting Related Peripheral Register 42 Reserved Reserved Reserved Reserved 43 RXN RAM is eXecute Never 0x1 IDAU.SECCTRL 44 DXN Data Flash is eXecute Never 0x1 NVMCTRL.SECCTRL 63:45 Reserved Reserved Reserved Reserved 71:64 AS Secure Flash (AS region) Size = AS*0x100(5) 0xFF IDAU.SCFGA 77:72 ANSC Non-Secure Callable Flash (APPLICATION region) Size = ANSC*0x20 0x0 IDAU.SCFGA 79:78 Reserved Reserved Reserved Reserved 83:80 DS Secure Data Flash Size = DS*0x100 0x8 IDAU.SCFGA 87:84 Reserved Reserved Reserved Reserved 94:88 RS Secure SRAM Size = RS*0x80 0x7F IDAU.SCFGR 95 Reserved Reserved Reserved Reserved 96 URWEN User Row Write Enable 0x1 NVMCTRL.SCFGAD 127:97 Reserved Reserved Reserved Reserved 159:128 NONSECA(1) Peripherals Non-Secure Status Fuses for Bridge A 0x0000_0000 PAC.NONSECA 191:160 NONSECB(2, 3) Peripherals Non-Secure Status Fuses for Bridge B 0x0000_0000 PAC.NONSECB 223:192 NONSECC Peripherals Non-Secure Status Fuses for Bridge C 0x0000_0000 PAC.NONSECC CRC of NVM User Row bits 223:64 0x8433651E(4) Boot ROM 255:224 USERCRC Notes:  1. The PAC Peripheral is always secured regardless of its bit value 2. The IDAU and NVMCTRL peripherals are always secured regardless of their bit values. 3. The DSU peripheral is always non-secured regardless of its bit value. 4. USERCRC value after a ChipErase_ALL (CE2) is 0x3389CD7C. 5. Secure Flash (AS region) = Secure Flash (APPLICATION region) + Non-Secure Callable Flash (APPLICATION region) CAUTION 1. BOD12 is calibrated in production and its calibration parameters must not be changed to ensure the correct device behavior. Table 10-11. SAM L11 UROW Mapping Offset Bit Pos. 0x00 7:0 0x01 15:8 0x02 23:16 0x03 31:24 0x04 39:32 0x05 47:40 Name BOD33_LEVEL - NSULCK BOD33_ACTION SULCK BOD33_DIS BOD33_LEVEL BOD12 Calibration Parameters WDT_PER WDT_ALWAYSON WDT_ENABLE RXN Reserved WDT_EWOFFSET Reserved BOD12 Calibration Parameters WDT_WINDOW DXN 0x06 55:48 Reserved 0x07 63:56 Reserved 0x08 71:64 AS © 2020 Microchip Technology Inc. WDT_RUNSTDBY Datasheet BOD33_HYST WDT_WEN DS60001513F-page 36 SAM L10/L11 Family Memories ...........continued Offset Bit Pos. 0x09 79:72 0x0A 87:80 0x0B 95:88 0x0C 103:96 Name Reserved ANSC Reserved DS Reserved RS Reserved URWEN 0x0D-0xF 127:104 Reserved 0x10-0x13 159:128 NONSECA 0x14-0x17 191:160 NONSECB 0x18-0x1B 223:192 NONSECC 0x1C-0x1F 255:224 USERCRC 10.2.2 NVM Software Calibration Row The NVM Software Calibration Row contains calibration data that can be used by some peripherals, such as the ADC. The NVM Software Calibration Row can be read at address 0x00806020. . Note:  Calibration data are determined and written during production test and cannot be written. Table 10-12. NVM Software Calibration Bitfields Definition Bit Position Name Description 2:0 ADC BIASREFBUF ADC Bias Reference Buffer Scaling. Should be written to CALIB register. 5:3 ADC BIASCOMP ADC Bias Comparator Scaling. Should be written to CALIB register. 8:6 DFLLULP Division Factor in PL0 DFLLULP Division Factor in PL0. Should be written to DFLLULPCTRL register. 11:9 DFLLULP Division Factor in PL2 DFLLULP Division Factor in PL2. Should be written to DFLLULPCTRL register. 127:12 Reserved Reserved Table 10-13. NVM Software Calibration Row Mapping Offset Bit Pos. 0x00 7:0 0x01 15:8 0x02-0xF 127:16 10.2.3 Name DFLLULP Division Factor in PL0 ADC BIASCOMP ADC BIASREFBUF Reserved ADC BIASCOMP Division Factor in PL2 DFLLULP Division Factor in PL0 Reserved NVM Temperature Log Row The NVM Temperature Log Row contains calibration data that are determined and written during production test and cannot be written. These calibration values are required for calculating the temperature from measuring the temperature sensor in the Supply Controller (SUPC) by the ADC. The NVM Temperature Log Row can be read at address 0x00806038. Table 10-14. Temperature Log Row Bitfields Definition Bit Position Name Description 7:0 ROOM_TEMP_VAL_INT Integer part of room temperature in °C 11:8 ROOM_TEMP_VAL_DEC Decimal part of room temperature 19:12 HOT_TEMP_VAL_INT Integer part of hot temperature in °C 23:20 HOT_TEMP_VAL_DEC Decimal part of hot temperature © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 37 SAM L10/L11 Family Memories ...........continued Bit Position Name Description 31:24 ROOM_INT1V_VAL 2’s complement of the internal 1V reference drift at room temperature (versus a 1.0 centered value) 39:32 HOT_INT1V_VAL 2’s complement of the internal 1V reference drift at hot temperature (versus a 1.0 centered value) 51:40 ROOM_ADC_VAL Temperature sensor 12bit ADC conversion at room temperature 63:52 HOT_ADC_VAL Temperature sensor 12bit ADC conversion at hot temperature Important:  Hot temperature corresponds to the maximum operating temperature +/- 5%, hence 85°C +/5% (package grade 'U') or 125°C +/- 5% (package grade 'F'). Table 10-15. Temperature Log Row Mapping Offset Bit Pos. Name 0x00 7:0 ROOM_TEMP_VAL_INT 0x01 15:8 HOT_TEMP_VAL_INT ROOM_TEMP_VAL_DEC 0x02 23:16 HOT_TEMP_VAL_DEC HOT_TEMP_VAL_INT 0x03 31:24 ROOM_INT1V_VAL 0x04 39:32 HOT_INT1V_VAL 0x05 47:40 0x06 55:48 0x07 63:56 10.2.4 ROOM_ADC_VAL HOT_ADC_VAL ROOM_ADC_VAL HOT_ADC_VAL NVM Boot Configuration Row (BOCOR) The Non-Volatile Memory Boot Configuration Row (BOCOR) contains device configuration data that are automatically read by the Boot ROM program at device startup. This row can be updated using the NVMCTRL peripheral. When writing to the NVM Boot Configuration Row, the new values are not loaded by the other peripherals on the device until a device reset occurs. The NVM Boot Configuration Row can be read at address 0x0080C000. SAM L10 and SAM L11 have different NVM Boot Configuration Row mappings. 10.2.4.1 SAM L10 Boot Configuration Row Table 10-16. SAM L10 BOCOR Bitfields Definition Bit Pos. Name Usage Factory Setting Related Peripheral Register 31:0 Reserved Reserved Reserved Reserved 39:32 BOOTPROT Boot Protection size = BOOTPROT*0x100 0x00 Boot ROM 95:40 Reserved Reserved Reserved Reserved 127:96 Reserved Reserved Reserved Reserved 511:128 Reserved Reserved Reserved Reserved 639:512 CRCKEY CRC Key All '1's Boot ROM 2047:640 Reserved Reserved Reserved Reserved © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 38 SAM L10/L11 Family Memories Table 10-17. SAM L10 BOCOR Mapping Offset Bit Pos. Name 0x00-0x03 31:0 Reserved 0x04 39:32 BOOTPROT 0x05-0x0B 95:40 Reserved 0x0C-0x0F 127:96 Reserved 0x10-0x3F 511:128 Reserved 0x40-0x4F 639:512 CRCKEY 0x50-0xFF 2047:640 Reserved 10.2.4.2 SAM L11 Boot Configuration Row Table 10-18. SAM L11 BOCOR Bitfields Definition Bit Pos. Name Usage Factory Setting Related Peripheral Register 7:0 Reserved Reserved Reserved Reserved 15:8 BS Secure Flash (BS region) Size = BS*0x100 (2) 0x00 IDAU.SCFGB 21:16 BNSC Non-Secure Callable Flash (BOOT region) Size = BNSC*0x20 0x00 IDAU.SCFGB 23:22 Reserved Reserved Reserved Reserved 25:24 BOOTOPT Boot Option 0x0 Boot ROM 31:26 Reserved Reserved Reserved Reserved 39:32 BOOTPROT Boot Protection size = BOOTPROT*0x100 0x00 IDAU.SCFGB 47:40 Reserved Reserved Reserved Reserved 48 BCWEN Boot Configuration Write Enable 0x1 NVMCTRL.SCFGB 49 BCREN Boot Configuration Read Enable 0x1 NVMCTRL.SCFGB 63:50 Reserved Reserved Reserved Reserved 95:64 BOCORCRC Boot Configuration CRC for bit 63:0 0xDDE78140(1) Boot ROM 127:96 Reserved Reserved Reserved Reserved 255:128 CEKEY0 Chip Erase Key 0 All 1s Boot ROM 383:256 CEKEY1 Chip Erase Key 1 All 1s Boot ROM 511:384 CEKEY2 Chip Erase Key 2 All 1s Boot ROM 639:512 CRCKEY CRC Key All 1s Boot ROM 895:640 BOOTKEY Secure Boot Key All 1s Boot ROM 1791:896 Reserved Reserved Reserved Reserved 2047:1792 BOCORHASH Boot Configuration Row Digest All 1s Boot ROM Notes:  1. BOCORCRC value after a ChipErase_ALL (CE2) is 0xC1D7ECC3. 2. Secure Flash (BS region) = Secure Flash (BOOT region) + Non-Secure Callable Flash (BOOT region). Table 10-19. SAM L11 BOCOR Mapping Offset Bit Pos. Name 0x00 7:0 Reserved 0x01 15:8 0x02 23:16 BS Reserved © 2020 Microchip Technology Inc. BNSC Datasheet DS60001513F-page 39 SAM L10/L11 Family Memories ...........continued Offset Bit Pos. 0x03 31:24 Name Reserved BOOTOPT 0x04 39:32 BOOTPROT 0x05 47:40 Reserved 0x06 55:48 Reserved BCREN 0x07 63:56 Reserved 0x08-0x0B 95:64 BOCORCRC 0x0C-0x0F 127:96 Reserved 0x10-0x1F 255:128 CEKEY0 0x20-0x2F 383:256 CEKEY1 0x30-0x3F 511:384 CEKEY2 0x40-0x4F 639:512 CRCKEY 0x50-0x6F 895:640 BOOTKEY 0x70-0xDF 1791:896 Reserved 0xE0-0xFF 2047:1792 BOCORHASH 10.3 BCWEN Serial Number Each device has a unique 128-bit serial number which is a concatenation of four 32-bit words contained at the following addresses of the NVM Rows memory space: • • • • Word 0: 0x0080A00C Word 1: 0x0080A040 Word 2: 0x0080A044 Word 3: 0x0080A048 Note:  The uniqueness of the serial number is only guaranteed when considering all 128 bits. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 40 SAM L10/L11 Family Processor and Architecture 11. Processor and Architecture 11.1 Cortex-M23 Processor The SAM L10/L11 implement the ARM® Cortex®-M23 processor, based on the ARMv8-M Baseline Architecture, which is the smallest and most energy efficient ARM processor with ARM TrustZone® security technology. TrustZone® for ARMv8-M provides hardware-enforced security isolation between trusted and the untrusted resources on a Cortex™-M23 based device, while maintaining the efficient exception handling. The implemented ARM Cortex-M23 is revision r1p0. The ARM Cortex-M23 core has two bus interfaces: • • Single 32-bit AMBA®-5 AHB-Lite system interface that provides connections to peripherals and memories. Single 32-bit I/O port bus interfacing to the PORT and Crypto Accelerator peripherals with 1-cycle load and store. Note:  For more information refer to www.arm.com 11.1.1 Cortex-M23 Configuration The following table gives the configuration for the ARM Cortex-M23 processor. Table 11-1. SAM L10/L11 Cortex-M23 Configuration Features Cortex-M23 Configurable Options SAM L10 Implementation SAM L11 Implementation Memory Protection Unit (MPU) Not present, 4, 8, 12, or 16 regions One MPU with 4 regions Two MPUs with 4 regions each (one Secure / one Non-Secure) Security Attribute Unit (SAU) Absent, 4-region, or 8-region Absent Absent Implementation Defined Attribution Unit (IDAU) Present or Absent Absent Present SysTick timer(s) Absent, 1 timer or 2 timers (one Secure and one Non-Secure) One SysTick timer Two timers (One Secure / One NonSecure) Vector Table Offset Register Present or absent Present (one Vector table) Present (two Vector tables) Reset all registers Present or absent Absent Absent Multiplier Fast (one cycle) or slow (32 cycles) Fast (one cycle) Fast (one cycle) Divider Fast (17 cycles) or slow (34 cycles) Fast (17 cycles) Fast (17 cycles) Interrupts External interrupts 0-240 45(1) 45(1) Instruction fetch width 16-bit only or 32-bit 32-bit 32-bit Single-cycle I/O port Present or absent Present Present Architectural clock gating present Present or absent Present Present Data endianness Little-endian or big-endian Little-endian Little-endian Halting debug support Present or absent Present Present Wake-up interrupt controller (WIC) Present or absent Absent Absent Number of breakpoint comparators 0, 1, 2, 3, 4 4 4 Number of watchpoint comparators 0, 1, 2, 3, 4 2 2 Cross Trigger Interface (CTI) Present or absent Absent Absent Micro Trace Buffer (MTB) Present or absent Absent Absent Embedded Trace Macrocell (ETM) Present or absent Absent Absent © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 41 SAM L10/L11 Family Processor and Architecture ...........continued Features Cortex-M23 Configurable Options SAM L10 Implementation SAM L11 Implementation JTAGnSW debug protocol Selects between JTAG or Serial-Wire interfaces for the DAP Serial-Wire Serial-Wire Multi-drop for Serial Wire Present or absent Absent Absent Note:  1. Refer to Table 11-3 for more information. For more details, refer to the ARM Cortex-M23 Processor Technical Reference Manual (www.arm.com). 11.1.2 Cortex-M23 Core Peripherals The processor has the following core peripheral: • System Timer (SysTick) – The System Timer is a 24-bit timer clocked by the core frequency. Important:  On SAM L11 devices, there are two System timers, one for Secure state and one for Non-Secure state. • Nested Vectored Interrupt Controller (NVIC) – The NVIC is an embedded interrupt controller that supports low latency interrupt processing. Important:  On SAM L11 devices, there are two Vector tables: the Secure Vector table and the Non-Secure Vector table. • • System Control Block (SCB) – The System Control Block (SCB) provides system implementation information and system control that includes configuration, control, and reporting of system exceptions Memory Protection Unit (MPU) – The MPU improves system reliability by defining the memory attributes for different memory regions. Important:  On SAM L11 devices, there are two MPUs: one for the Secure state and one for the Non-Secure state. Each MPU can define memory access permissions and attributes independently. • Security Attribution Unit (SAU) – The SAU improves system security by defining security attributes for different regions. Important:  The SAU is absent from SAM L10 and SAM L11 devices. For more details, refer to the ARM Cortex-M23 Processor Technical Reference Manual (www.arm.com). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 42 SAM L10/L11 Family Processor and Architecture Table 11-2. Cortex-M23 Core Peripherals Address Map Core Peripherals 11.1.3 Base Address (Non-Secure) Alias Base Address (SAM L10 and SAM L11) (SAM L11 only) System Timer (SysTick) 0xE000E010 0xE002E010 Nested Vectored Interrupt Controller (NVIC) 0xE000E100 0xE002E100 System Control Block (SCB) 0xE000ED00 0xE002ED00 Memory Protection Unit (MPU) 0xE000ED90 0xE002ED90 Single Cycle I/O Port The device allows direct access to PORT registers. Accesses to the AMBA® AHB-Lite™ and the single cycle I/O interface can be made concurrently, so the Cortex-M23 processor can fetch the next instructions while accessing the I/Os. This enables single cycle I/O access to be sustained for as long as necessary. Note:  The Crypto Accelerator peripheral also benefits from this port. Refer to the 13.3 Crypto Acceleration section for more information. 11.2 Nested Vector Interrupt Controller 11.2.1 Overview The Nested Vectored Interrupt Controller (NVIC) in the SAM L10/L11 supports up to 45 interrupt lines with four different priority levels + 1 Non Maskable Interrupt (NMI) line. For more details, refer to the Cortex-M23 Technical Reference Manual (www.arm.com). 11.2.2 Interrupt Line Mapping Each interrupt line is connected to one peripheral instance, as shown in the table below. Each peripheral can have one or more interrupt flags, located in the peripheral’s Interrupt Flag Status and Clear (INTFLAG) register. An interrupt flag is set when the interrupt condition occurs. Each interrupt in the peripheral can be individually enabled by writing a 1 to the corresponding bit in the peripheral’s Interrupt Enable Set (INTENSET) register, and disabled by writing 1 to the corresponding bit in the peripheral’s Interrupt Enable Clear (INTENCLR) register. An interrupt request is generated from the peripheral when the interrupt flag is set and the corresponding interrupt is enabled. The interrupt requests for one peripheral are ORed together on system level, generating one interrupt request for each peripheral. An interrupt request will set the corresponding interrupt pending bit in the NVIC interrupt pending registers (SETPEND/CLRPEND bits in ISPR/ICPR). For the NVIC to activate the interrupt, it must be enabled in the NVIC interrupt enable register (SETENA/CLRENA bits in ISER/ICER). The NVIC interrupt priority registers IPR0-IPR11 provide a priority field for each interrupt. Table 11-3. Interrupt Line Mapping Module Source NVIC line EIC NMI – External Interrupt Controller NMI NMI © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 43 SAM L10/L11 Family Processor and Architecture ...........continued Module Source NVIC line PM – Power Manager PLRDY 0 MCLK - Main Clock CKRDY OSCCTRL - Oscillators Controller XOSCRDY CLKFAIL OSC16MRDY DFLLULPRDY DFLLULPLOCK DFLLULPNOLOCK DPLLLCKR DPLLLCKF DPLLLTO DPLLLDRTO OSC32KCTRL - 32KHz Oscillators Controller XOSC32KRDY CLKFAIL SUPC - Supply Controller BOD33RDY BOD33DET B33SRDY VREGRDY VCORERDY ULPVREFRDY WDT – Watchdog Timer EW 1 RTC – Real Time Counter CMP0 2 CMP1 OVF PER0 PER1 PER2 PER3 PER4 PER5 PER6 PER7 TAMPER EIC – External Interrupt Controller EXTINT 0 3 EXTINT 1 4 EXTINT 2 5 EXTINT 3 6 EXTINT 4..7 7 NSCHK(1) FREQM - Frequency Meter © 2020 Microchip Technology Inc. DONE Datasheet 8 DS60001513F-page 44 SAM L10/L11 Family Processor and Architecture ...........continued Module Source NVIC line NVMCTRL – Non-Volatile Memory Controller DONE 9 PROGE LOCKE NVME KEYE NSCHK(1) PORT - I/O Pin Controller NSCHK(1) 10 DMAC - Direct Memory Access Controller SUSP 0 11 TERR 0 TCMPL 0 SUSP 1 12 TERR 1 TCMPL 1 SUSP 2 13 TERR 2 TCMPL 2 SUSP 3 14 TERR 3 TCMPL 3 SUSP 4..7 15 TERR 4..7 TCMPL 4..7 EVSYS – Event System EVD 0 16 OVR 0 EVD 1 17 OVR 1 EVD 2 18 OVR 2 EVD 3 19 OVR 3 NSCHK(1) 20 PAC - Peripheral Access Controller ERR 21 SERCOM0 – Serial Communication Interface 0 (Interrupt Sources vary depending on SERCOM mode) Interrupt Bit 0 22 Interrupt Bit 1 23 Interrupt Bit 2 24 Interrupt Bits 3..6 25 Interrupt Bit 0 26 Interrupt Bit 1 27 Interrupt Bit 2 28 Interrupt Bit 3..6 29 SERCOM1 – Serial Communication Interface 1 (Interrupt Sources vary depending on SERCOM mode) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 45 SAM L10/L11 Family Processor and Architecture ...........continued Module Source NVIC line SERCOM2 – Serial Communication Interface 2 (Interrupt Sources vary depending on SERCOM mode) Interrupt Bit 0 30 Interrupt Bit 1 31 Interrupt Bit 2 32 Interrupt Bits 3..6 33 ERR A 34 TC0 – Timer Counter 0 MC 0 MC 1 OVF TC1 – Timer Counter 1 ERR A 35 MC 0 MC 1 OVF TC2 – Timer Counter 2 ERR A 36 MC 0 MC 1 OVF ADC – Analog-to-Digital Converter OVERRUN 37 WINMON AC – Analog Comparator RESRDY 38 COMP 0 39 COMP 1 WIN 0 DAC – Digital-to-Analog Converter UNDERRUN 40 EMPTY 41 PTC – Peripheral Touch Controller EOC 42 TRNG - True Random Number Generator DATARDY 43 TRAM - TrustRAM DRP 44 WCOMP ERR Note:  1. NSCHK interrupt sources will not generate any interrupts for SAM L10 devices. 11.3 High-Speed Bus System 11.3.1 Features The High-Speed Bus Matrix has the following features: • • • 11.3.2 32-bit data bus Allows concurrent accesses from different masters to different slaves Operation at a one-to-one clock frequency with the bus masters Configuration There are two master-to-slave connections to optimize system bandwidth: • Multi-Slave Masters which are connected through the AHB bus matrix © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 46 SAM L10/L11 Family Processor and Architecture Table 11-4. AHB Multi-Slave Masters AHB Multi-Slave Masters Cortex-M23 Processor DSU - Device Service Unit DMAC - Direct Memory Access Controller / Data Access Table 11-5. AHB Slaves AHB Slaves Flash Memory AHB-APB Bridge A (APBA) AHB-APB Bridge B (APBB) AHB-APB Bridge C (APBC) SRAM Port 0 - Cortex-M23 Access SRAM Port 1 - DMAC Access SRAM Port 2 - DSU Access Boot ROM • Privileged SRAM-access Masters which have a direct access to some dedicated SRAM ports Table 11-6. Privileged SRAM-access Masters Privileged SRAM-access Masters DMAC - Fetch 0 Access DMAC - Fetch 1 Access DMAC - Write Back 0 Access DMAC - Write Back 1 Access Note:  Privileged SRAM-access Masters rely on SRAM quality of service to define priority levels (SRAM Port ID). Refer to 11.4 SRAM Quality of Service for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 47 SAM L10/L11 Family Processor and Architecture Figure 11-1. Master-to-Slave Access Privileged SRAM-access MASTERS Multi-Slave MASTERS 11.4 Cortex-M23 0 DSU 1 DMAC Data DSU 2 CM23 DSU DMAC Data DMAC Fetch 0 DMAC Fetch 1 DMAC WB 0 DMAC WB 1 SRAM Boot ROM AHB-APB Bridge C AHB-APB Bridge B AHB-APB Bridge A Flash High-Speed Bus SLAVES 0 1 2 3 4 5 6 SRAM PORT ID DMAC Fetch 0 DMAC DSU Fetch 1 DMAC DSU WB 0 DMAC WB 1 SRAM Quality of Service To ensure that masters with latency requirements get sufficient priority when accessing RAM, priority levels can be assigned to the masters for different types of access. The Quality of Service (QoS) level is independently selected for each master accessing the RAM. For any access to the RAM, the RAM also receives a QoS level. The QoS levels and their corresponding bit values are shown in the following table. Table 11-7. Quality of Service Value Name Description 0x0 DISABLE Background (no sensitive operation) 0x1 LOW Sensitive Bandwidth 0x2 MEDIUM Sensitive Latency 0x3 HIGH Critical Latency Note:  If a master is configured with QoS level DISABLE (0x0) or LOW (0x1), there will be a minimum latency of one cycle to get RAM access. The priority order for concurrent accesses are decided by two factors: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 48 SAM L10/L11 Family Processor and Architecture • • As first priority, the QoS level for the master. As a second priority, a static priority given by the port ID. The lowest port ID has the highest static priority. See the tables below for more details. Table 11-8. HS SRAM Port Connections QoS HS SRAM Port Connection Port ID Connection Type QoS default QoS DMAC - Direct Memory Access Controller Write-Back 1 Access 6 Direct DMAC QOSCTRL.WRBQOS 0x2 DMAC - Direct Memory Access Controller Write-Back 0 Access 5 Direct DMAC QOSCTRL.WRBQOS 0x2 DMAC - Direct Memory Access Controller Fetch 1 Access 4 Direct DMAC QOSCTRL.FQOS 0x2 DMAC - Direct Memory Access Controller Fetch 0 Access 3 Direct DMAC QOSCTRL.FQOS 0x2 DMAC - Direct Memory Access Controller Data Access 2 Bus Matrix DMAC QOSCTRL.DQOS 0x2 DSU - Device Service Unit 1 Bus Matrix DSU CFG.LQOS 0x2 CM23 - Cortex M23 Processor 0 Bus Matrix 0x41008114, bits[1:0](1) 0x3 Note:  1. The CPU QoS level can be written/read, using 32-bit access only. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 49 SAM L10/L11 Family Peripherals Configuration Summary 12. Peripherals Configuration Summary Table 12-1. Peripherals Configuration Summary Peripheral name Base address IRQ line — AHB clock APB clock Generic Clock PAC Events DMA Power domain Index Enabled at Reset Index Enabled at Reset Index Index Write Protection at Reset User Generator Sleep Walking Index Name 0 Y — — — — — — — N/A — PDSW AHB-APB Bridge A (APBA) 0x40000000 PAC 0x40000000 21: ERR 6 Y 0 Y — 0 N — 49: ERR Y — PDSW PM 0x40000400 0: PLRDY — — 1 Y — 1 N — — N/A — PDAO MCLK 0x40000800 0: CKRDY — — 2 Y — 2 N — — N/A — PDSW RSTC 0x40000C00 — — — 3 Y — 3 N — — N/A — PDAO OSCCTRL 0x40001000 0: XOSCRDY, CLKFAIL, OSC16MRDY, DFLLULPRDY , DFLLULPLOC K, DFLLULPNOL OCK, DPLLLCKR, DPLLLCKF, DPLLLTO, DPLLLDRTO — — 4 Y 0: FDPLL96M clk source 4 N 0: TUNE 1: CLKFAIL Y — PDSW 1: FDPLL96M 32 kHz 2: DFLLULP reference OSC32KCTR L 0x40001400 0: XOSC32KRD Y, CLKFAIL — — 5 Y — 5 N — 2: CLKFAIL Y — PDAO SUPC 0x40001800 0: BOD33RDY,B OD33DET, B33SRDY, VREGRDY, VCORERDY, ULPVREFRD Y — — 6 Y — 6 N — 3: BOD33DET Y — PDAO GCLK 0x40001C00 — — — 7 Y — 7 N — — N/A — PDSW WDT 0x40002000 1: EW — — 8 Y — 8 N — — N/A — PDSW RTC 0x40002400 2: CMP0-1, TAMPER, OVF, PER0-7 — — 9 Y — 9 N 1: TAMPEVT 4-11 : PER0-7 Y 1: TIMESTAMP PDAO 12: ALARM0, 12-13 : CMP0-1 14 : TAMPER 15 : OVF 16 : PERD EIC 0x40002800 3: EXTINT0 — — 10 Y 3 10 N — 17-24: EXTINT0-7 Y — PDAO — — 11 Y 4: FREQM_MSR 11 N — — N/A — PDSW 4: EXTINT1 5: EXTINT2 6: EXTINT3 7: EXTINT4-7, NSCHK NMI FREQM 0x40002C00 8: DONE 5: FREQM_REF PORT 0x40003000 10: NSCHK — — 12 Y — 12 N 3-6 : EVU0-3 — Y — PDAO AC 0x40003400 39: COMP0-1, WIN0 — — 13 Y 17 13 N 16-17: COMP0-1 40-41: COMP0-1 Y — PDAO AHB-APB Bridge B (APBB) 0x41000000 — 1 Y — — — — — — — N/A — PDSW DSU 0x41002000 — 4 Y 1 Y — 1 Y — — N/A 2-3: DCC0-1 PDSW 42: WIN0 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 50 SAM L10/L11 Family Peripherals Configuration Summary ...........continued Peripheral name Base address IRQ line AHB clock APB clock Generic Clock PAC Events DMA Power domain Index Enabled at Reset Index Enabled at Reset Index Index Write Protection at Reset User Generator Sleep Walking Index Name NVMCTRL 0x41004000 9: DONE, PROGE, LOCKE, NVME, KEYE, NSCHK 7 Y 2 Y — 2 N 2: AUTOW — Y — PDSW DMAC 0x41006000 11: SUSP0, TERR0, TCMPL0 3 Y — — — 3 — 7-10: CH0-3 25-28: CH0-3 Y — PDSW 12: SUSP1, TERR1, TCMPL1 13: SUSP2, TERR2, TCMPL2 14: SUSP3, TERR3, TCMPL3 15: SUSP4-7, TERR4-7, TCMPL4-7 HMATRIXHS 0x41008000 — 5 Y — — — 4 N — — N/A — PDSW AHB-APB Bridge C (APBC) 0x42000000 — 2 Y — — — — — — — N/A — PDSW EVSYS 0x42000000 16: EVD0, OVR0 — — 0 Y 6: CH0 0 N — — N/A — PDSW 1 N — — N/A 4: RX PDSW 7: CH1 17: EVD1, OVR1 8: CH2 9: CH3 18: EVD2, OVR2 19: EVD3, OVR3 20: NSCHK SERCOM0 0x42000400 22: bit 0 — — 1 Y 23: bit 1 11: CORE 10: SLOW 5: TX 24: bit 2 25: bit 3-6 SERCOM1 0x42000800 26: bit 0 — — 2 Y 27: bit 1 12: CORE 2 N — — N/A 10: SLOW 6: RX PDSW 7: TX 28: bit 2 29: bit 3-6 SERCOM2 0x42000C00 30: bit 0 — — 3 Y 31: bit 1 13: CORE 3 N — — N/A 10: SLOW 8: RX PDSW 9: TX 32: bit 2 33: bit 3-6 TC0 TC1 TC2 ADC 0x42001000 0x42001400 0x42001800 0x42001C00 34: ERR, MC0, MC1, OVF — 35: ERR, MC0, MC1, OVF — 36: ERR, MC0, MC1, OVF — 37: OVERRUN, WINMON 38:RESRDY — — 4 Y 14 4 N 11: EVU 29: OVF Y 30-31: MCX0-1 — 5 Y 14 5 N 12: EVU 32: OVF Y 33-34: MCX0-1 — 6 Y 15 6 N 13: EVU 35: OVF 7 Y 16 7 N 14: START 38: RESRDY 15 : FLUSH 39: WINMON PDSW 13: OVF PDSW 14-15: MC0-1 Y 36-37: MCX0-1 — 10: OVF 11-12: MC0-1 16: OVF PDSW 17-18: MC0-1 Y 19: RESRDY PDSW 43: EMPTY Y 20: EMPTY PDSW Y 21 : EOC PDSW DAC 0x42002000 40: UNDERRUN 41: EMPTY — — 8 Y 18 8 N 18: START PTC 0x42002400 42: EOC, WCOMP — — 9 Y 19 9 N 19 : STCONV 44: EOC 20 : DSEQR 45: WCOMP 43: DATARDY — — 46 : DATARDY 22 : SEQ 23 : WCOMP TRNG 0x42002800 — © 2020 Microchip Technology Inc. 10 Y — 10 Datasheet N Y — DS60001513F-page 51 PDSW SAM L10/L11 Family Peripherals Configuration Summary ...........continued Peripheral name CCL Base address 0x42002C00 IRQ line — AHB clock APB clock Generic Clock PAC Events DMA Power domain Index Enabled at Reset Index Enabled at Reset Index Index Write Protection at Reset User Generator Sleep Walking Index Name — — 11 Y 20 11 N 21 : LUT0 47 : LUT0 Y — PDSW 22 : LUT1 48 : LUT1 OPAMP 0x42003000 — — — 12 Y — 12 N — — N/A — PDSW TRAM 0x42003400 44: DRP, ERR 12 Y — — — 13 — — — N/A — PDSW © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 52 SAM L10/L11 Family SAM L11 Specific Security Features 13. SAM L11 Specific Security Features This chapter provides an overview of the security features which are specific to the SAM L11. 13.1 Features SAM L11-specific security features can be divided into two main categories. The first category relates to the ARM TrustZone for Cortex-M technology features: • • • • Flexible hardware isolation of memories and peripherals: – Up to six regions for the Flash – Up to two regions for the Data Flash – Up to two regions for the SRAM – Individual security attribution (secure or non-secure) for each peripheral using the Peripheral Access Controller (PAC) – Mix-Secure peripherals which support both secure and non-secure security attributions Three debug access levels allowing: – The highest debug level with no restrictions in term of memory and peripheral accesses – A restricted debug level with non-secure memory regions access only – The lowest debug level where no access is authorized except with a debugger using a Boot ROM-specific mode Different chip erase support according to security settings Security configuration is fully stored in Flash and safely auto-loaded at startup during Boot ROM execution using CRC checks Important:  Debug access levels transitions as Chip Erase commands support are described in the Boot ROM chapter. The second category relates to the SAM L11-specific security features, which are not related to ARM TrustZone for Cortex-M technology support: • • • • Built-in cryptographic accelerator accessible through cryptographic libraries stored in ROM – Supporting AES-128 encryption/decryption, SHA-256 authentication, GCM encryption and authentication Secure Boot, which performs integrity check on a configurable portion of the Flash (BS memory area) Secure pin multiplexing to isolate on dedicated SERCOM I/O pins a secured communication with external devices from the Non-Secure application Data Flash Scrambling The SAM L11 has other security features, which are not described in this chapter as they are common to both SAM L10 and SAM L11 such as: • • • 13.2 One True Random Number Generator (TRNG) Data Flash and TrustRAM rapid tamper, silent access features A unique 128-bit serial number Arm TrustZone Technology for Armv8-M Arm TrustZone for Cortex-M technology is an optional core extension, which enables the system and the software to be partitioned into Secure and Non-Secure domains. Secure software can access both Secure and Non-Secure memories and resources, while Non-Secure software can only access Non-Secure memories and resources. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 53 SAM L10/L11 Family SAM L11 Specific Security Features Figure 13-1. TrustZone for ARMv8-M Non-Secure Application Secure Application/Library Non-Secure OS Secure OS Non-Secure states Secure states If the TrustZone is implemented (SAM L11 devices), the system starts up in Secure state by default. The security state of the processor can be either Secure or Non-Secure. Important:  For additional information, refer to “TrustZone Technology for ARMv8-M Architecture”, which is available on the Arm web site (www.arm.com). 13.2.1 Memory System and Memory Partitioning The memory space is partitioned into Non-Secure and Secure memory regions: • Non-Secure (NS): Non-Secure addresses are used for memory and peripherals accessible by all software, that is, running on the device. • Secure (S): Secure addresses are used for memory and peripherals accessible only by Secure software or masters. • Non-Secure Callable (NSC): NSC is a special type of Secure memory location. It allows software to transition from Non-Secure to Secure state. The Cortex-M23 provides two ways for managing the security configurations of the device. The first solution consists in using the Cortex-M23 SAU (Security Attribution Unit), which is a Memory Protection Unit (MPU) like hardware embedded in the core. The role of the SAU is to manage all the Secure and Non-Secure transactions coming from the core. However, using the SAU implies that the security configuration must be propagated somewhere else in the MCU architecture for security awareness. The second approach, which is the one used for SAM L11 devices, is articulated around a centralized Implementation Defined Attribution Unit (IDAU), which is a hardware unit external to the core. For SAM L11 devices, the IDAU is coupled to the Cortex-M23 and manages all the security configurations related to the core. In addition, the IDAU propagates all the security configurations to the memory controllers. The IDAU, Flash, Data Flash and SRAM embedded memories can be split in sub-regions, which are reserved either for the Secure or for the Non-Secure application. Therefore, the SAU is not required and is absent from SAM L10/L11 devices. The peripherals security attribution is managed by the Peripherals Access Controller (PAC). The PAC and each peripheral can be allocated either to the Secure or to the Non-Secure application, with the exception of the PAC, NVMCTRL, and DSU. Notes:  1. The PAC and NVMCTRL peripherals are always secured. 2. The DSU peripheral is always non-secured. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 54 SAM L10/L11 Family SAM L11 Specific Security Features Both IDAU and PAC security configurations are stored in NVM fuses, which are read after each reset during Boot ROM execution and are loaded after Boot ROM verifications into their respective registers. The peripherals security attribution (using PAC) is locked before exiting the Boot ROM execution sequence, that is, it is not possible to change a peripheral's configuration (Secure or Non-Secure) during application execution. However, the security attribution of each peripheral, excluding the PAC, NVMCTRL, and DSU, can be modified using the NONSECx NVM fused from the User Row (UROW) during application execution, hence it can be considered after any reset. 13.2.2 Memories Security Attribution The IDAU is used to indicate the processor if a particular memory region is Secure (S), Non-Secure Callable (NSC), or Non-Secure (NS). It can also mark a memory region to be exempted from security checking. Table 13-1. IDAU Memory Attribution Definition Attribute Description Non-Secure Memory can be accessed in Secure or Non-Secure state. Secure Memory can only be accessed in Secure state. It cannot be called from Non-Secure state. Non-Secure callable Memory can only be accessed in Secure state, but can be called from Non-Secure state. Exempt No attribution check will be done, and the operation will take place on the bus Note:  Refer to " SAM L11 Security Attribution" chapter for the detailed SAM L11 memories and peripherals security attribution description. The Cortex-M23 will search each access (fetch or data) in the IDAU, which returns the privilege information about that specific address. If the access is not permitted, the CPU enters a HardFault exception. The IDAU memory region's attributes are partly hardwired and partly set by NVM configuration fuses, and are loaded into the IDAU by the Boot ROM before application execution. The IDAU memory region's attributes are blocked for further writes from the application, but their current state can still be read through dedicated IDAU registers. Note:  Refer to the "SAM L11 IDAU Memory Mapping Registers". 13.2.2.1 Flash The SAM L11 Flash can be divided into six regions: • The first three regions are called Boot regions and can be configured to support a first-level bootloader for the application. • The other regions are called Application regions and relate to the application itself. The total size of the Boot regions is defined by the BOOTPROT fuses from the NVM Boot Configuration Row (BOCOR), the Application regions total size being the remaining available size of the Flash. Each of these Boot/Application global regions can be divided into three sub-regions: • The Secure sub-region • The Non-Secure Callable (NSC) sub-region • The Non-Secure (NS) sub-region Each sub-region size can be configured using dedicated fuses from the NVM Boot Configuration Row (BOCOR): • BS fuse corresponds to the size of the Secure + NSC sub-regions of the BOOT region • BNSC fuse corresponds to the NSC sub-region size of the BOOT region • AS fuse corresponds to the size of the Secure + NSC sub-regions of the APPLICATION region • ANSC fuse corresponds to the NSC sub-region size of the APPLICATION region © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 55 SAM L10/L11 Family SAM L11 Specific Security Features Figure 13-2. SAM L11 Flash Memory Mapping Secure Flash (BOOT Region) Non-Secure Callable Flash (BOOT Region) Non-Secure Flash (BOOT Region) BS BNSC BOOTPROT Secure Flash (APPLICATION Region) AS Non-Secure Callable Flash (APPLICATION Region) ANSC Non-Secure Flash (APPLICATION Region) 13.2.2.2 Data Flash The SAM L11 Data Flash can be divided into two regions: • • The Secure Data Flash region, with a size defined by the DS fuse from the NVM User Row (UROW) The Non-Secure (NS) Data Flash region Figure 13-3. SAM L11 Data Flash Memory Mapping DS Secure Data Flash Non-Secure Data Flash 13.2.2.3 SRAM The SAM L11 SRAM can be divided into two regions: • The Secure SRAM region, with a size defined by the RS fuse from the NVM User Row (UROW) • The Non-Secure (NS) SRAM region © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 56 SAM L10/L11 Family SAM L11 Specific Security Features Figure 13-4. SAM L11 SRAM Memory Mapping RS Secure SRAM Non-Secure SRAM 13.2.3 SAM L11 Memory Mapping Configuration Summary The table below summarizes the mapping of the SAM L11 memory regions. Table 13-2. SAM L11 Memory Regions Mapping Memory region Base address Size Flash (BOOT region) 0x00000000 BOOTPROT * 256Bytes Secure Flash (BOOT region) 0x00000000 BS*256Bytes - BNSC*32Bytes Non-Secure Callable Flash (BOOT region) Contiguous to Secure Flash (BOOT region) BNSC * 32Bytes Non-Secure Flash (BOOT region) (1) BS * 256Bytes Flash (BOOT region) remaining size = (BOOTPROT * 256Bytes BS*256Bytes) Flash (APPLICATION region) BOOTPROT * 256Bytes Flash size - BOOTPROT * 256Bytes (Flash BOOT region) Secure Flash (APPLICATION region) BOOTPROT * 256Bytes AS*256Bytes-ANSC*32Bytes Non-Secure Callable Flash (APPLICATION region) Contiguous to Secure Flash (APPLICATION region) ANSC * 32Bytes Non-Secure Flash (APPLICATION region) (BOOTPROT+AS) * 256Bytes Flash (APPLICATION region) remaining size = (Flash size BOOTPROT*256Bytes - AS*256Bytes) Secure Data Flash 0x00400000 DS * 256Bytes Non-Secure Data Flash Contiguous to Secure Data Flash 2KB - Secure Data Flash size Secure SRAM 0x20000000 RS * 128Bytes Non-Secure SRAM Contiguous to Secure SRAM SRAM size - Secure SRAM size Note:  1. Secure Flash (BOOT region) size cannot be null if a Non-Secure Flash (BOOT region) size is defined. Here is a typical configuration for a device with 64KB of Flash, 2KB of Data Flash and 16KB of SRAM: • BOOT region: – Flash (BOOT region) size = 8KB => BOOTPROT = 8192 / 256 = 0x20 – Secure Flash (BOOT region) + Non-Secure Callable Flash (BOOT region) size = 1KB => BS = 1024 / 256 = 0x4 – Non-Secure Callable Flash (BOOT region) size = 32Bytes => BNSC = 32 / 32 = 0x1 – Non-Secure Flash (BOOT region) size = 8KB - 1KB = 7KB • APPLICATION region: – Flash (APPLICATION region) size = 64 KB - 8KB = 56KB – Secure Flash (APPLICATION region) + Non-Secure Callable Flash (APPLICATION region) size = 16KB => AS = 16 * 1024 / 256 = 0x40 – Non-Secure Callable Flash (APPLICATION region) size = 32Bytes => ANSC = 32 / 32 = 0x1 – Non-Secure Flash (APPLICATION region) size = 56KB - 16KB = 40KB © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 57 SAM L10/L11 Family SAM L11 Specific Security Features • • 13.2.4 Data Flash region: – Secure Data Flash size = 2KB => DS = 2048 / 256 = 0x8 – Non-Secure Data Flash size = 2 KB - 2 KB = 0KB SRAM region: – Secure SRAM size = 4KB => RS = 4096 / 128 = 0x20 – Non-Secure SRAM size = 16KB - 4KB = 12KB SAM L11 IDAU Memory Mapping Registers The tables below summarizes the mapping of the SAM L11 IDAU memory regions. All the following registers are Read-only registers. Table 13-3. SAM L11 IDAU Memory Register Address Registers (Read-only) Address SECCTRL 0x41000001 SCFGB 0x41000004 SCFGA 0x41000008 SCFGR 0x4100000C Table 13-4. SAM L11 IDAU SECCTRL Register (8-bit) Bit Position Name 7:0 Reserved RXN (Bit 2) Reserved Table 13-5. SAM L11 IDAU SCFGB Register (32-bit) Bit Position Name 7:0 BS 15:8 Reserved BNSC (bit 8-13) 23:16 BOOTPROT 31:24 Reserved Table 13-6. SAM L11 IDAU SCFGA Register (32-bit) Bit Position Name 7:0 AS 15:8 Reserved ANSC (bit 8-13) 23:16 Reserved DS (bit 16-19) 31:24 Reserved Table 13-7. SAM L11IDAU SCFGR Register (8-bit) Bit Position 7:0 13.2.5 Name Reserved RS (bit 0-6) Peripherals Security Attribution In addition to generic protection features, the Peripheral Access Controller (PAC) configures the security privileges for each individual peripheral in the system. Each peripheral can only be configured either in Secure or in Non-Secure mode except the IDAU and NVMCTRL peripherals, which are always Secured, and the DSU peripheral which is always Non-Secured. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 58 SAM L10/L11 Family SAM L11 Specific Security Features The PAC NONSECx registers (read only) contain one bit per peripheral for that purpose, which is the image of the NONSECx fuses from the NVM User row (UROW). During Boot ROM execution, the NONSECx fuses from the NVM User row are copied in the PAC peripheral NONSECx registers so that they can be read by the application. All peripherals are marked as "exempt" in the memory map, meaning that all bus transactions are propagated. As a consequence, any illegal accesses are reported back to the PAC and trigger an interrupt if enabled. The security configuration (Secure or Non-Secure) is propagated to each individual peripheral, thus it is the responsibility of the peripheral to grant or not the access with the following rules: • • If the peripheral is configured as Non-Secure in the PAC: – Secure and Non-Secure accesses are granted If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0), a PAC error is triggered Important:  These rules do not apply to the specific peripherals called Mix-Secure peripherals. Note:  The Secure application will usually provide an API for the Non-Secure application using the Non-Secure Callable region (NSC) to allow the Non-Secure application to request specific resources. Table 13-8. Peripheral PAC Security Attribution (Excluding Mix-Secure Peripherals) Mode Secure Master Access Non-Secure Master Access Non-Secure Read / Write Read / Write Secure Read / Write Discarded (Write ignored / Read 0x0) PAC Error is generated 13.2.5.1 SAM L11 Peripherals Configuration Example Below is a typical configuration examples where all peripherals except the TC0 and SERCOM0 are reserved to the Secure application: • Secure/Non-Secure Peripherals PAC configuration: – PAC.NONSECA=PAC.NONSECB=0x0000_0000 – PAC.NONSECC=0x0000_0012 (TC0 and SERCOM0 available for the Non-Secure application) 13.2.6 SAM L11 Memory Space Security Attribution This table provides the security attributions of the SAM L11 memory space: Table 13-9. SAM L11 Memory Space Security Attributions Memory region Attribute Secure Flash (BOOT region) Secure Non-Secure Callable Flash (BOOT region) Non-secure callable Non-Secure Flash (BOOT region) Non-secure Secure Flash (APPLICATION region) Secure Non-Secure Callable Flash (APPLICATION region) Non-secure callable Non-Secure Flash (APPLICATION region) Non-secure Secure Data Flash Secure Non-Secure Data Flash Non-secure © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 59 SAM L10/L11 Family SAM L11 Specific Security Features ...........continued Memory region Attribute Exempt - eXecute Never Secure (R/W access) NVM Rows Non-Secure (Discarded for BOCOR, Read-only for the others) 13.2.7 Boot ROM Secure Execute-only for CRYA functions Secure SRAM Secure Non-Secure SRAM Non-secure Peripherals Exempt - eXecute Never IOBUS Exempt - eXecute Never Others (Reserved, Undefined...) Secure Cortex-M23 Test Target Instructions Software may check the privilege state of a memory location by using the Cortex-M23 Test Target instructions: TT, TTT, TTA, and TTAT. The memory location is referenced using the Cortex-M23 IREGION bitfield, which specifies the IDAU region number (see the ARMv8-M Architecture Reference Manual for more information). Table 13-10. SAM L11 IDAU Region Number for TT, TTT, TTA and TTAT Cortex-M23 Instructions Memory Region IDAU Region Number for TTx Instructions (IREGION bits) Secure Flash (BOOT region) 0x01 Non-Secure Callable Flash (BOOT region) 0x02 Non-Secure Flash (BOOT region) 0x03 Secure Flash (APPLICATION region) 0x04 Non-Secure Callable Flash (APPLICATION region) 0x05 Non-Secure Flash (APPLICATION region) 0x06 Secure Data Flash 0x07 Non-Secure Data Flash 0x08 NVM User Rows 0x00 (invalid) Boot ROM 0x09 Secure SRAM 0x0A Non-Secure SRAM 13.2.8 0x0B Peripherals 0x00 (invalid) IOBUS 0x00 (invalid) Others (Reserved, Undefined...) 0x00 (invalid) Mix-Secure Peripherals There are five Mix-Secure peripherals that allow internal resources to be shared between the Secure and NonSecure applications: • • • • The PAC controller which manages peripherals security attribution (Secure or Non-Secure). The Flash memory controller (NVMCTRL) which supports Secure and Non-Secure Flash regions programming. The I/O controller (PORT) which allows to individually allocate each I/O to the Secure or Non-Secure applications. The External Interrupt Controller (EIC) which allows to individually assign each external interrupt to the Secure or Non-Secure applications. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 60 SAM L10/L11 Family SAM L11 Specific Security Features • The Event System (EVSYS) allows to individually assign each event channel to the Secure or Non-Secure applications. When a Mix-Secure peripheral is configured as Secure in the PAC, its register map is automatically duplicated in a Secure and Non-Secure alias: • The Non-Secure alias is at the peripheral base address. • The Secure alias is located at the peripheral base address: – + 0x200 offset for the PAC, EIC, PORT and EVSYS peripherals PAC, PORT, EIC and EVSYS Cases Base Address Base Address Registers Table Non-Secure Alias Base Address + 0x200 Secure Alias Mix-Secure Peripheral (Not PAC Secured) Mix-Secure Peripheral (PAC Secured) – + 0x1000 offset for the NVMCTRL peripheral. NVMCTRL Case Base Address Base Address Registers Table Non-Secure Alias Base Address + 0x1000 Secure Alias Mix-Secure Peripheral (PAC Secured) Mix-Secure Peripheral (Not PAC Secured) The Secure alias has the following characteristics: • All of the peripheral registers are available for the Secure application through the Secure alias • When an internal resource becomes available to the Non-Secure application, the corresponding registers (called Mix-Secure registers) or bitfields in registers are still accessible through this Secure alias by the Secure application • Non-Secure accesses to this Secure alias are discarded (Write is ignored, Read is 0x0) and a PAC error is triggered The Non-Secure alias has the following characteristics: • Only a restricted set of registers are available for the Non-Secure application through the Non-Secure alias • It is the responsibility of the Secure application to assign some resources to the Non-Secure application. This is done by setting the corresponding bits in the NONSECx registers of the Mix-Secure peripheral. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 61 SAM L10/L11 Family SAM L11 Specific Security Features • – When an internal resource becomes available for the Non-Secure application, the corresponding registers (called Mix-Secure and Write-Mix-Secure registers) or bitfields in the registers are accessible through the Non-Secure alias by the Non-Secure application – Non-Secure accesses to Secure resources (registers, bitfields) are silently discarded (Write is ignored, Read is 0x0) and no error is generated Secure accesses to the Non-Secure alias are silently discarded (Write is ignored, Read is 0x0) and no error is generated Mix-Secure Peripheral Base Address Base Address Registers Non-Secure registers +Table Non-Secure registers Write-Secure registers + Mix-Secure registers Write-Mix-Secure registers Write-Secure registers Non-Secure Alias Base Address + 0x200 or 0x1000 Non-Secure Alias + Base Address + 0x200 or 0x1000 Non-Secure registers Secure registers Write-Secure registers Mix-Secure registers Write-Mix-Secure registers Non-Secure OS Non-Secure registers Secure registers Write-Secure registers Mix-Secure registers Write-Mix-Secure registers Secure Alias No registers/bitfields assigned to Non-Secure Accesses Secure Alias Some registers/bitfields assigned to Non-Secure Accesses Mix-Secure peripherals have always the following registers: • NONSEC register is a generic register that tells the Non-Secure application which resources inside a MixSecure peripheral can be used • NSCHK register is a register allowing the Non-Secure application to be notified when the security configuration of a Mix-Secure peripheral is being modified during application execution Important:  It is recommended that the Non-Secure application first copy the content of NONSEC register inside NSCHK register, and then enable the NSCHK interrupt flags. Once done, any changes to the NONSEC register by the Secure application will trigger an interrupt so that Non-Secure application can take appropriate actions. This mechanism allows the Secure application to dynamically change the security attribution of a Mix-Secure peripheral and avoid illegal accesses from the Non-Secure application. The interrupt handler should always copy the NONSEC register to NSCHK register before exiting it. Mix-Secure peripherals can have five type of registers: • Non-Secure: these registers will always be available in both the Secure and Non-Secure aliases • Secure: these registers will never be available in the Non-Secure alias and always available in the Secure alias • Write-Secure: these are registers than can: – Be written or read by the Secure application only in the Secure alias – Only read by the Non-Secure application in Non-Secure alias. Write is forbidden. • Mix-Secure registers : these ones are used when a resource can be allocated to either the Secure and NonSecure alias – Note that, in some cases, the Mix-Secure properties apply to a bitfield only (like one I/O bit in the PORT peripheral register) • Write-Mix-Secure registers (NVMCTRL peripheral only): these are Mix-Secure registers, which: – can be written or read by the Secure application only in the Secure alias – can only be read by the Non-Secure application in Non-Secure alias except if Non-Secure writes are authorized in NVMCTRL.NONSEC register © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 62 SAM L10/L11 Family SAM L11 Specific Security Features Table 13-11. SAM L11 Mix-Secure Peripheral Registers Access Mix-Secure Peripheral Register Secure Master Access Secure Alias Non-Secure Alias Non-Secure Master Access Secure Alias Non-Secure Alias Non-Secure Read / Write Secure Discarded (Write ignored / Read 0x0) No Error is generated Write-Secure Mix-Secure Read-only (Write ignored) Read / Write Discarded Discarded No Error is generated (Write ignored / Read 0x0) (Write ignored / Read 0x0) No Error is generated PAC Error is generated Read/Write if the resource is available for the Non-Secure Application Discarded if not (Write ignored / Read 0x0) and no error is generated Write-Mix-Secure Read /Write if the resource is available for the Non-Secure Application Read-only if not (Write ignored) and no error is generated 13.3 13.3.1 Crypto Acceleration Overview The SAM L11 product embeds a hardware/software cryptographic accelerator (CRYA) which supports Advanced Encryption Standard (AES) encryption and decryption, Secure Hash Algorithm 2 (SHA-256) authentication, and Galois Counter Mode (GCM) encryption and authentication through a set of APIs, which are only accessible once the Boot ROM has completed. Note:  The CRYA cryptographic accelerator is mapped as a slave on the IOBUS port and is driven by the CPU using assembly code (located in ROM). The Advanced Encryption Standard (AES) is compliant with the American FIPS (Federal Information Processing Standard) Publication 197 specification. The AES operates on a 128-bit block of input data. The key size used for an AES cipher specifies the number of repetitions of transformation rounds that convert the input plaintext, into the final output, called the ciphertext. The AES works on a symmetric-key algorithm, meaning the same key is used for both encrypting and decrypting the data. The SHA-256 is a cryptographic hash function that creates a 256-bit digest of a data block. The data block is processed in chunks of 512 bits. The GCM is a mode of operation for AES that combines the CTR (Counter) mode of operation with an authentication hash function. For detail algorithm specification, refer to following standards and specification: • • • 13.3.2 AES: FIPS Publication 197, Advanced Encryption Standard (AES) SHA: FIPS Pub 180-4, The Secure Hash Standard GCM: NIST Special Publication 800-38D Recommendation Features • • • Advanced Encryption Standard (AES), compliant with FIPS Publication 197 – Encryption with 128-bit cryptographic key – Decryption with 128-bit cryptographic key Secure Hash Algorithm 2 (SHA-256), compliant with FIPS Pub 180-4 – Accelerates message schedule and inner compression loop Galois Counter Mode (GCM) encryption using AES engine and authentication – Accelerates the GF(2128) multiplication for AES-GCM hash function © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 63 SAM L10/L11 Family SAM L11 Specific Security Features 13.3.3 CRYA APIs The CRYA APIs which are located in a dedicated Boot ROM area are only accessible from the user application after the Boot ROM has completed. This area is an execute-only area, meaning the CPU cannot do any loads, but can call the APIs. The Boot ROM memory space is a secure area, only the secure application can directly call these APIs. Table 13-12. CRYA APIs Addresses CRYA API Address AES Encryption 0x02001904 AES Decryption 0x02001908 SHA Process 0x02001900 GCM Process 0x0200190C Important:  All 8-bit pointers from CRYA API functions must be 32-bit aligned. 13.3.3.1 AES API The AES software has two function routines to do encryption and decryption on a 128 bit block of input data. The AES encryption function entry point is located at the Boot ROM address 0x02001904 and the encryption function parameters are: • • • • Src[in] : a pointer to a 128-bit data block to be encrypted Dst[out]: a pointer to 128 bit encrypted data Keys[in]: a pointer to 128 bit key Length[in]: Number of 32-bit words comprising the Key, 4 for 128 bits key The AES decryption function entry point is located at the Boot ROM address 0x02001908 and the decryption function parameters are: • • • • Src[in] : a pointer to a 128-bit data block to be decrypted Dst[out]: a pointer to 128 bit decrypted data Keys[in]: a pointer to 128 bit key Length[in]: Number of 32-bit words comprising the Key, 4 for 128 bits key The APIs are: /* Type definition for CRYA AES functions. */ typedef void (*crya_aes_encrypt_t) (const uint8_t *keys, uint32_t key_len, const uint8_t *src, uint8_t *dst); typedef void (*crya_aes_decrypt_t) (const uint8_t *keys, uint32_t key_len, const uint8_t *src, uint8_t *dst); /* AES encrypt function * \param keys[in]: A pointer to 128-bit key * \param key_len[in]: Number of 32-bit words comprising the key, 4 for 128-bit key * \param src[in]: A pointer to a 128-bit data block to be encrypted * \param dst[out]: A pointer to a 128-bit encrypted data */ #define secure_crya_aes_encrypt ((crya_aes_encrypt_t ) (0x02001904 | 0x1)) /* AES decrypt function * \param keys[in]: A pointer to 128-bit key * \param key_len[in]: Number of 32-bit words comprising the key, 4 for 128-bit key * \param src[in]: A pointer to a 128-bit data block to be decrypted * \param dst[out]: A pointer to a 128-bit decrypted data © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 64 SAM L10/L11 Family SAM L11 Specific Security Features */ #define secure_crya_aes_decrypt ((crya_aes_decrypt_t ) (0x02001908 | 0x1)) 13.3.3.2 SHA API The SHA software function can update the digest value based on the 512-bit data. It is assumed that the message is already preprocessed properly for the SHA algorithm, so that the SHA software can work directly on 512-bit portions. The SHA function entry point is located at the Boot ROM address 0x02001900 and has three parameters: • • • [In/out]: A pointer to a digest location (digest input and output) [In]: A pointer to a 512-bit data block [In]: A pointer to a RAM buffer (256B needed for internal algorithm) The updated digest value is put at first parameter after the function exit. The API is: /* Type definition for CRYA SHA function. */ typedef void (*crya_sha_process_t) (uint32_t digest_in_out[8], const uint8_t data[64], uint32_t ram_buf[64]); /* CRYA SHA function * \param digest_in_out[In/out]: A pointer to a digest location (digest input and output) * \param data[In]: A pointer to a 512 bit data block * \param ram_buf[In]: A pointer to a RAM buffer (256B needed for internal algorithm) */ #define crya_sha_process ((crya_sha_process_t ) (0x02001900 | 0x1)) Code example of using CRYA SHA software: void sha256_process(uint32_t digest[8], const uint8_t data[64]) { uint32_t ram_buf[64]; /* 256 bytes needed for message schedule table */ /* Pointer to CRYA SHA function in ROM */ static void (*crya_sha_process)(uint32_t digest_in_out[8], const uint8_t data[64], uint32_t ram_buf[64]); crya_sha_process = (void (*)(uint32_t *, const uint8_t *, uint32_t *)) *((uint32_t*)0x02001900); } crya_sha_process (digest, data, ram_buf); 13.3.3.3 GCM API The GCM function entry point is is located at the Boot ROM address 0x0200190C and the function parameters are: • • • Block1[in]: a pointer to 128-bit data blocks that are to be multiplied Block2[in]: a pointer to 128-bit data blocks that are to be multiplied dst[out]: a pointer to a location for storing the result The API is: /* Type definition for GF(2^128) multiplication */ typedef void (*crya_gf_mult128_t) (const uint32_t *block1, const uint32_t *block2, uint32_t *dst); /* GF(2^128) multiplication. * * \param block1[In]: A pointer to 128-bit data blocks that are to be multiplied * \param block2[In]: A pointer to 128-bit data blocks that are to be multiplied * \param dst[out]: A pointer to a location for storing the result */ #define secure_crya_gf_mult128 ((crya_gf_mult128_t ) (0x0200190C | 0x1)) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 65 SAM L10/L11 Family SAM L11 Specific Security Features 13.4 Secure Boot A Secure Boot with SHA-256-based authentication on a configurable portion on the Flash (BS memory area) is available with verification mechanisms allowing to reset and restart the authentication process in case of a failure. Refer to 14. Boot ROM for more information. 13.5 Secure Pin Multiplexing on SERCOM The Secure Pin Multiplexing feature can be used on dedicated SERCOM I/O pins to isolate a secured communication with external devices from the non-secure application. This feature is automatically enabled as soon as the security attribution of the SERCOM is set to Secured using the PAC peripheral. When this operation occurs: • • • • The secured SERCOM instances become mapped only on a specific set of I/Os All of the alternate I/O pins of the secured SERCOM instance are kept in a Hi-Z configuration The PTC cannot enable PTC lines mapped to any of the secured SERCOM instance I/O pins The CCL I/Os mapped to the secured SERCOM instance I/O pins are set to '0' Refer to Table 34-1 to obtain the list of pins supporting that feature. 13.6 Data Flash Scrambling When Data Flash scrambling is enabled, address and data in the secure portion of the Data Flash are scrambled when written, and de-scrambled when read. Refer to 30. NVMCTRL – Nonvolatile Memory Controller for more details. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 66 SAM L10/L11 Family Boot ROM 14. Boot ROM The Boot ROM allows to ensure the integrity of the device at boot. The Boot ROM features Boot Interactive mode, which allows the user to perform several actions on the device, such as NVM areas integrity check and chip erase via a debugger connection. Unless a debugger is connected and places the Boot ROM in Boot Interactive mode, the CPU will jump to the Flash memory, loading the Program Counter (PC) and Stack Pointer (SP) values, and will start fetching Flash user code. Note:  Before jumping to the Flash, the Boot ROM resets the first 2kB of SRAM. The Clocks remain unchanged. In addition, the SAM L11 Boot ROM has extra security features, such as device integrity checks, memories/ peripherals security attributions, and secure boot, which can be executed before jumping to the Flash in Secure state. For security reasons, while the Boot ROM is executing, no debug is possible except when entering a specific Boot ROM mode called CPU Park mode. Related Links 13.1 Features 14.1 Features • • • Command interface for the host debugger supporting: – Chip erase commands to provide secure transitions between the different Debug Access Levels (DAL) – Device integrity check of the NVM memory regions – Debugger read access of the NVM rows CPU Park mode to get access for a debugger to the resources of the device depending on Debug Access Level (DAL) SAM L11 Added features: – Device integrity checks – Memory and peripheral security attributions from user configuration stored in NVM rows – Secure Boot on Secure Flash (BOOT region) and Non-Secure Callable Flash (BOOT region) Related Links 13.1 Features 14.2 Block Diagram Figure 14-1. Boot ROM Block Diagram PAC DSU NVMCTRL Device Service Unit IDAU (SAM L11) CRYA Boot ROM BCC SWD Boot Communication Channels Serial Wire Debug Host Debugger TRNG Related Links 13.1 Features © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 67 SAM L10/L11 Family Boot ROM 14.3 Product Dependencies In order to use this module, other parts of the system must be configured correctly, as described below. Related Links 13.1 Features 14.3.1 Clocks The device selects the OSC16M oscillator which is enabled by default after reset and configured at 4 MHz. 14.3.2 NVM User (UROW) and Boot Configuration (BOCOR) rows The Boot ROM reads the different NVM rows during its execution. The relevant fuses must be set appropriately by any configuration tools supporting the device in order to operate correctly. Refer to the 10.2 NVM Rows section for additional information. 14.3.3 Debug Operations For security reasons, no debug is possible during the Boot ROM execution except when entering the Boot ROM CPU Park mode. 14.4 Functional Description Related Links 13.1 Features 14.4.1 SAM L10 Boot ROM Flow The SAM L10 Boot ROM checks firstly if a debugger is present to enter the Boot Interactive mode which allows the user to perform specific tasks via a debugger connection. Before jumping to the application, the Boot ROM can also enter in a specific mode called CPU Park to allow the debugger to get access to the resources of the device depending on Debug Access Level (DAL). Note:  Boot Interactive and CPU Park modes are described later on. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 68 SAM L10/L11 Family Boot ROM Figure 14-2. SAM L10 Boot ROM Flow If no debugger is connected: automatic exit from Boot interactive mode RESET Is Debugger Connected ? Yes "Init" Command Wait for Debugger Command No "Exit" command Is Debugger Connected AND BREXT ==1 ? Yes CPU Park Mode Boot Interactive Mode BREXT == 1 BREXT == 0 No Start Application System RESET 14.4.1.1 Typical Boot Timings The delay is given from the release of the CPU reset to the execution of the first instruction of the user code: Table 14-1. SAM L10 Typical Boot Timing Time to reach User Code 1.33 ms 14.4.2 SAM L11 Boot ROM Flow The SAM L11 Boot ROM sequence consists in performing several security tasks (integrity checks, memories and peripherals security attribution, secure boot...) before starting the application. The Boot ROM checks firstly if a debugger is present to enter the Boot Interactive mode which allows the user to perform specific tasks via a debugger connection. Before jumping to the application in Secure state, the Boot ROM can also enter in a specific mode called CPU Park to allow the debugger to get access to the resources of the device depending on Debug Access Level (DAL). Note:  Boot Interactive and CPU Park modes are described later on. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 69 SAM L10/L11 Family Boot ROM Figure 14-3. SAM L11 Boot ROM Flow If no debugger is connected: automatic exit from Boot interactive mode RESET Not OK Device Integrity Checks OK Apply Memories & Peripherals Security Settings Yes Is Debugger Connected ? "Init" Command No Wait for Debugger Command Boot Interactive Mode "Exit" Command Yes BOOTOPT>0 ? No Bootloader Authentication Not OK BS and BOCOR Verifications OK Yes IS Debugger Connected AND BREXT == 1? CPU Park Mode No Start Application BREXT == 1 BREXT == 0 System RESET 14.4.2.1 Device Integrity Checks For SAM L11 devices, the Boot ROM performs security checks on two CRCs: • The User Row CRC (USERCRC) which is located in the NVM User Row (UROW) at: [0x80401C:0x80401F]: • UROW Offset Bit Position Name 0x1C-0x1F 255:224 USERCRC The Boot Configuration Row CRC (BOCORCRC) which is located in the NVM Boot Configuration Row (BOCOR) at: [0x80C008:0x80C00B]: BCOR Offset Bit Position Name 0x08-0x0B 95:64 BOCORCRC 14.4.2.1.1 User Row CRC (USER CRC) USERCRC allows to check the following fuses parameters integrity: • • • AS, ANSC, DS, RS URWEN NONSECA, NONSECB, NONSECC © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 70 SAM L10/L11 Family Boot ROM USERCRC is the CRC of the NVM User row area which starts from 0x00804008 and finish at 0x0080401B (bit 64 to bit 223): Table 14-2. SAM L11 UROW Area Computed in USERCRC Offset Bit Pos. Name 0x08 71:64 AS 0x09 79:72 0x0A 87:80 0x0B 95:88 Reserved ANSC Reserved DS Reserved RS 0x0C 103:96 0x0D-0xF 127:104 Reserved Reserved URWEN 0x10-0x13 159:128 NONSECA 0x14-0x17 191:160 NONSECB 0x18-0x1B 223:192 NONSECC 14.4.2.1.2 Boot Configuration Row CRC (BOCORCRC) BOCORCRC allows to check the following fuses parameters integrity: • • • BS, BNSC BOOTOPT BOOTPROT, BCWEN, BCREN BOCORCRC is the CRC of the NVM Boot Configuration row area, which starts from 0x0080C000 and finish at 0x00800C007 (bit 0 to bit 63). Table 14-3. SAM L11 BOCOR Area Computed in BOCORCRC Offset Bit Pos. Name 0x00 7:0 Reserved 0x01 15:8 BS 0x02 23:16 0x03 31:24 BOOTOPT 0x04 39:32 BOOTPROT 0x05 47:40 Reserved 0x06 55:48 0x07 63:56 Reserved BNSC Reserved BCREN BCWEN Reserved If one of the checks fails, the Boot ROM will report the error to the DSU peripheral and will enter the Boot Interactive mode: • This will allow, if a debugger is connected, to put the device in the highest debug access level mode (DAL = 2) by issuing a Chip Erase command . Once in that mode, it is possible for a programming tool to reprogram the NVM Rows. • When the check fails and no debugger is connected, the part will reset and restart the check sequence again. Note:  Boot Interactive mode is described later in this chapter. 14.4.2.1.3 CRC Computation and Programming The CRCs needs to be recalculated and updated in their respective NVM row as soon as a data from any of the checked regions is changed. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 71 SAM L10/L11 Family Boot ROM Important:  USERCRC and BOCORCRC CRCs programming must be done by any programming tool supporting the SAM L11 devices. The algorithm is a CRC-32 module embedded in the DSU peripheral and that uses for both CRC calculation with the following parameters: • Width = 32 bits • Polynomial = 0x04C11DB7 (Poly) • Initial Value = 0xFFFFFFFF (Init) • Input Data is reflected (RefIn) • Output Data is reflected (RefOut) • No XOR is performed on the output CRC (XorOut) Example: the DSU CRC of 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39 is 0x340BC6D9 14.4.2.2 Memories and Peripherals Configurations Initialization For SAM L11 devices, memories and peripherals security attributions are done by reading the different fuses values from the NVM User (UROW) and Boot Configuration (BOCOR) rows. The Boot ROM is responsible for setting these attributions on the different concerned memory and peripheral controllers: • Set memory security attribution according to AS, ANSC, DS, RS, BS, BSNC and BOOTPROT fuses • Set peripherals security attribution according to NONSECA, NONSECB and NONSECC fuses Important:  The Boot ROM does not perform any consistency checks on the configured memory attributions (e.g setting BS>BOOTPROT will not trigger any errors during Boot ROM execution). 14.4.2.3 Secure Boot Depending on the BOOTOPT fuse value (from BOCOR NVM row), the following secure boot integrity checks will be performed on: • The Secure Flash (BS region) which is composed by: – The Secure Flash (BOOT region) – The Non-Secure Callable Flash (BOOT region) • And the NVM Boot Configuration row (BOCOR) Table 14-4. Secure Boot Options BOOTOPT Verified Areas Verification Method 0 None - 1 Secure Flash (BS region) SHA-256 + NVM BOCOR row 2 or 3 Secure Flash (BS region) + SHA-256 with BOOTKEY (defined in BOCOR) NVM BOCOR row If the verification fails, the Boot ROM will report the error to the DSU peripheral and will enter the Boot Interactive mode. This will allow, if a debugger is connected, to put the device in the highest debug level access mode (DAL = 2) by issuing a Chip Erase command. Once in that mode, it is possible for a programming tool to reprogram the different memory regions and/or NVM rows. When verification fails and no debugger is connected, the part will reset and restart the integrity checks sequences again. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 72 SAM L10/L11 Family Boot ROM 14.4.2.3.1 Hash algorithm (SHA-256) Verification Method The verifications are done using the standard SHA256 hash algorithm. Both Secure Flash (BS region) and NVM BOCOR row digests are computed on the defined memory/row area and compared to their expected reference digest value. Note:  The digest consists of 256 bits, i.e. 32 bytes. SHA256 with BOOTKEY Variant To prevent unauthorized change of the bootloader code, the digest computation can be slightly modified to require a key to produce a valid digest. When SHA with BOOTKEY is selected (BOOTOPT=2 or =3), the digest computation (for both Secure Flash (BS region) and NVM BOCOR row) starts by processing the secure boot key (BOOTKEY) data twice, then proceeds with the rest of data. This secure boot key (BOOTKEY) is located in the NVM Boot Configuration row (BOCOR) at [0x80C0050:0x80C006F]: BOCOR Offset Bit Position Name 0x50-0x6F 895:640 BOOTKEY 14.4.2.3.2 BS Verification When BOOTOPT>0, the bootloader authentication starts allowing a secure bootloader code to be protected against inadvertent or malicious changes. The digest is computed on the Secure Flash (BOOT region) and the Non-Secure Callable Flash (BOOT region). The digest reference value for this area is stored at the end of the Secure Flash (BOOT region), just before the NonSecure Callable Flash (BOOT region). Note:  The last 256 bits where the digest is stored are not included in the computation. Figure 14-4. BS Digest location in BS memory area 0x00000000 Secure Flash (BOOT Region) BS BS Reference Digest : 256bits (32 bytes) Non-Secure Callable Flash (BOOT Region) BNSC BS * Granularity Important:  The Non-Secure Flash (BOOT region) as well as Flash (APPLICATION region) are not part of the Secure Boot verification. So if an authentication of one of these memory regions is required, it must be handled by the user code itself. 14.4.2.3.3 BOCOR Verification When BOOTOPT>0, the digest for the NVM BOCOR row is computed on the whole NVM BOCOR row excluding BOCORHASH fuse value which is the fuse where to store the digest reference value [0x80C00E0:0x80C00FF]: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 73 SAM L10/L11 Family Boot ROM BOCOR Offset Bit Position Name 0xE0-0xFF 2047:1792 BOCORHASH 14.4.2.4 Typical Boot Timings Depending on the boot authentication options, the Boot ROM will require a certain time to complete its different tasks. The delay is given from the release of the CPU reset to the execution of the first instruction of the user code. Table 14-5. SAM L11 Typical Boot Timings 14.4.3 Boot options Time to reach User Code BOOTOPT=0 2.30 ms BOOTOPT=1, BS=0x40 207 ms BOOTOPT=1, BS=0x80 409 ms BOOTOPT=2, BS=0x40 209 ms BOOTOPT=2, BS=0x80 411 ms Debug Access Levels The SAM L10 has only two debug access levels (DAL): • DAL2: Highest debug level access with no restrictions in term of memory and peripheral accesses. • DAL0: No access is authorized except with a debugger using the Boot ROM Interactive mode. The possible transitions between each debug access level are described below: Figure 14-5. SAM L10 Debug Access Levels Transitions 1) Program NVM regions 2) Send SDAL0 command (NVMCTRL) Delivered parts DAL2 After Reset DAL0 ChipErase No key required The SAM L11 has three possible debug access levels (DAL): • • • DAL2: Highest debug level access with no restrictions in term of memory and peripheral accesses. DAL1: Access is limited to the Non-Secure memory regions. Secure memory regions accesses are forbidden. DAL0: No access is authorized except with a debugger using the Boot ROM Interactive mode. The possible transitions between each debug access level are described below: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 74 SAM L10/L11 Family Boot ROM Figure 14-6. SAM L11 Debug Access Levels Transitions 1) Program NVM regions 2) Send SDAL0 command (NVMCTRL) Delivered parts After Reset 1) Program NVM regions 2) Send SDAL1 command (NVMCTRL) 1) Program Non-Secure NVM regions 2) Send SDAL0 command (NVMCTRL) After Reset After Reset DAL1 DAL2 DAL0 ChipErase_S with CEKEY1 key if BS ==0 ChipErase_NS with CEKEY0 key ChipErase_ALL with CEKEY2 key Decreasing the Debug Level Access is done using the NVMCTRL peripheral command from the debugger or the CPU. Note:  Refer to 30. NVMCTRL – Nonvolatile Memory Controller for more information. For security reasons, increasing the Debug Level Access is only possible during Boot ROM execution and will be always preceded by a specific chip erase depending on the Debug Access Level. 14.4.4 Chip Erase The chip erase commands allow to erase memories of the device and provide secure transitions between the different Debug Access Levels. Important:  Chip Erase commands are only issued using the Boot ROM Interactive mode (CMD_CE0, CMD_CE1, CMD_CE2 and CMD_CHIPERASE commands). For SAM L10, the chip erase command does not require a key. For SAM L11, the chip erase commands are protected with keys (CEKEYx) defined in the NVM BOCOR row. Note:  The chip erase keys can only be read if BOCOR.BCREN=1. By default, the devices are delivered with these keys set at “All 1s”. Important:  If the key is set at “All 0s”, the corresponding chip erase command is disabled and it will be impossible for the debugger to use it. If both the ChipErase_ALL (CE2) key is set at "All 0s" and BOCOR.BCWEN=0, full chip erase is permanently disabled. Depending on Debug Access Levels (DAL0 or DAL1), Microchip’s failure analysis capabilities are limited when this feature is used. The following table gives the effect of the Chip Erase commands on the different memories: Table 14-6. Chip Erase Commands Effects SAM L11 Boot ROM Command Key Requirement © 2020 Microchip Technology Inc. SAM L10 ChipErase_NS (CE0) ChipErase_S (CE1) ChipErase_ALL (CE2) ChipErase (CHIPERASE) Yes (CEKEY0) Yes (CEKEY1) Yes (CEKEY2) No Datasheet DS60001513F-page 75 SAM L10/L11 Family Boot ROM ...........continued SAM L11 Flash (BOOT region) BOOTPROT (BS+BNSC+BNS) No SAM L10 No Yes No Flash (APPLICATION region) - - - Yes Data Flash - - - Yes Secure Flash (AS region) No Yes Yes - Non-Secure Flash (APPLICATION region) Yes Yes Yes - Secure Data Flash (DS) No Yes Yes - Non-Secure Data Flash Yes Yes Yes - NVM User Row (UROW) No No Yes No NVM Boot Configuration Row (BOCOR) No No Yes No Volatile Memories Yes Yes Yes Yes 2 (if DAL was 2) else 1 2 (if DAL was 2 or BS==0) else 1 2 2 Debugger Access Level after reset Note:  Only the ChipErase_ALL (CE2) command affects rows belonging to the BOOT area (BOOTPROT fuse bits) and the BOCOR row. 14.4.5 Boot ROM Interactive Mode The interactive mode allows the user to perform several actions on the device during the Boot ROM execution via a debugger connection. The debugger communicates with the device using the DSU Boot Communication Channels (BCC) through the external address range of the DSU peripheral, regardless of the DAL setting. This communication is bi-directional and allows the debugger to post commands and receive status from the Boot ROM. Note:  Refer to Device Service Unit for more information on BCC. 14.4.5.1 Enter Interactive Mode (CMD_INIT) This command allows launching the Boot Interactive command mode of the Boot ROM. To reach interactive mode, the debugger will trigger a “cold plugging” sequence as described in DSU chapter. Important:  Debugger must not clear DSU.STATUSA.BREXT bit before clearing DSU.STATUSA.CRSTEXT bit. When CRSTEXT is cleared, CPU starts Boot ROM Interactive mode execution. After a small delay (5ms advised), the debugger must check if the Boot ROM has not flagged any errors by checking the BCCD1 bit in DSU.STATUSB register. If errors are reported, the debugger can get the error type by checking the DSU.BCC1 register from the DSU external address space. Note:  Errors reported by the Boot ROM in the DSU.BCC1 register are listed later on in the Boot Interactive Mode Status section. If no error is reported, the debugger writes the CMD_INIT command to DSU.BCC0 register to request Boot ROM Interactive mode entry. When command is successful, Boot ROM will place the “SIG_COMM” status in DSU.BCC1 register. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 76 SAM L10/L11 Family Boot ROM 14.4.5.1.1 CMD_INIT Figure 14-7. CMD_INIT Flow diagram Boot Communication Channels BCC1 Dev to Dbg Boot ROM BCC0 Dbg to Dev Debugger Cold Plugging Sequence Debugger clears CRSTEXT CPU in reset CPU executes Boot ROM Sanity checks If error Wait for command Signal command mode entry Check if error flagged after 5 ms from CPU release (DSU CPU reset extension) Error code Debugger triggers interactive mode entry (DSU CPU Get command code SIG_COMM CMD_INIT Check status after command Boot ROM in interactive mode Debugger idle 14.4.5.2 Exit Interactive Mode (CMD_EXIT) This command allows exiting the Boot Interactive mode. Exiting the Boot Interactive mode allows to jump to one of the following: • The Application • The CPU Park Mode © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 77 SAM L10/L11 Family Boot ROM 14.4.5.2.1 CMD_EXIT Figure 14-8. CMD_EXIT to APP flow diagram Boot Communication Channels BCC1 Device to Dbg Boot ROM BCC0 Dbg to Device Debugger Cold Plugging Sequence Debugger clears CRSTEXT CPU in reset CPU executes Boot ROM Sanity checks Wait for command If error Check if error flagged after 5 ms from CPU release (DSU CPU reset extension) Error code Debugger triggers exit to app Debugger clears BREXT Get command code CMD_EXIT Check status Signal command mode entry SIG_BOOTOK after command CPU executes application Debugger idle © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 78 SAM L10/L11 Family Boot ROM Figure 14-9. CMD_EXIT to Park mode flow diagram Boot Communication Channels BCC1 Device to Dbg Boot ROM BCC0 Dbg to Device Cold Plugging Sequence NOTE : debugger does not clear BREXT before CRSTEXT Debugger clears CRSTEXT CPU in reset CPU executes Boot ROM Sanity checks Wait for command Debugger If error Check if error flagged after 5 ms from CPU release (DSU CPU reset extension Error code Get command code Signal command mode entry SIG_BOOTOK Debugger triggers interactive mode entry CMD_EXIT Check status after command CPU parked in a while loop waits for BREXT cleared Debugger idle 14.4.5.3 System Reset Request (CMD_RESET) This command allows resetting the system using a system reset request. Since the reset is executed immediately after receiving the command, no reply is sent to the debugger. After reset, the CPU executes the Boot ROM code from the beginning 14.4.5.4 Chip Erase (CMD_CHIPERASE) - SAM L10 only CMD_CHIPERASE command erases the entire device except BOOT area, and reverts to Debug Access Level 2. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 79 SAM L10/L11 Family Boot ROM 14.4.5.4.1 CMD_CHIPERASE (SAM L10 only) Figure 14-10. CMD_CHIPERASE Flow diagram Boot Communication Channels Boot ROM BCC1 Dev to Dbg BCC0 Dbg to Dev Debugger Boot ROM in interactive mode Wait for command CMD_CHIPERASE Get command code SAM L10 ? SIG_CMD_VALID Erase targeted memories SIG_CMD_SUCCESS Boot ROM in interactive mode Debugger requests Chip Erase Get data On error, one of SIG_CE_x is reported Debugger polls for status update on BCC1 Debugger idle 14.4.5.5 Chip Erase (CMD_CEx) - SAM L11 only CMD_CEx commands are used to erase specific part of the device and to increase the Debug Access Level. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 80 SAM L10/L11 Family Boot ROM 14.4.5.5.1 CMD_CEx (SAM L11 only) Figure 14-11. CMD_CEx Flow diagram Boot Communication Channels BCC1 Dev to Dbg Boot ROM BCC0 Dbg to Dev Debugger Boot ROM in interactive mode CMD_CEx Get command code Wait for command SAML11 ? SIG_CMD_VALID Get 128 bits key as 4x32bits words NOTE : a 100us delay is inserted before sending BADKEY status Get data Get keyword 0 CEx_Keyword0 Get keyword 1 CEx_Keyword1 Get keyword 2 CEx_Keyword2 Get keyword 3 CEx_Keyword3 Debugger requests Chip Erase 0 / 1 / 2 NOTE : debugger polls the BCCD0 bit to know when bootrom has read the word before sending the next Verify key Ce disabled ChipErase_x disabled? SIG_CMD_INVALID Ce not disabled Key matches BOCOR key? Keys match Erase targeted memories keys don't match SIG_CMD_BADKEY On error, one of SIG_CE_x is reported Debugger polls for status update on BCC1 SIG_CMD_SUCCESS Boot ROM in interactive mode Debugger idle 14.4.5.6 NVM Memory Regions Integrity Checks (CMD_CRC) The Boot ROM provides a way to check the integrity of the embedded non-volatile memories which may be of interest in case of a failure analysis. This requires the user to place tables describing the memory area to be checked with their expected CRC values. Note:  During this integrity check process, the debugger sends the CRC table address to the device. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 81 SAM L10/L11 Family Boot ROM Important:  The table(s) must be programmed by the programming tool in addition to the application binaries. 14.4.5.6.1 CRC Table format Table 14-7. CRC Table Fields Description Description Header Start Address (1) Size in bytes (2) Expected value (3) Field HDR ADDR SIZE REFVAL Offset 0x0 0x4 0x8 0xC Value 0x43524349 0x00000000 0x100 0xAABBCCDD Note 1: ADDR must be a multiple of 4 (Only ADDR[31:2] are used). Note 2: SIZE must be a multiple of 4 (Only SIZE[31:2] are used). Note 3: The expected value is the computed CRC32 value of the memory target. 14.4.5.6.2 Requirements • Each table occupies 16 bytes in memory. • The table must start at a 16byte aligned address. (i.e. 0xXXXXXXX0) • The table must be placed in the same memory region as its target memory range. (i.e. a table placed in the Secure Flash (APPLICATION region) can only target Secure Flash (APPLICATION region) memory addresses). Note: There are two exceptions to this rule: • For SAM L10: all non-volatile memories are considered as a single region (e.g. a table located in Data Flash can target Flash) • For SAM L11: ANSC and BNSC regions are considered to belong to the same region as their “parent” region: AS for ANSC and BS for BNSC. 14.4.5.6.3 CRC Command Key The CRC command (CMD_ CRC) requires an access key (CRCKEY) which is in the NVM BOCOR row at: [0x80C040:0x80C04F]: BOCOR Offeset Bit Position Name 0x40-0x4F 639:512 CRCKEY Just like the ChipErase keys, the key can be set to all 0s to prevent any access to the command. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 82 SAM L10/L11 Family Boot ROM 14.4.5.6.4 CMD_CRC Figure 14-12. CMD_CRC Flow diagram Boot Communication Channels BCC1 Dev to Dbg Boot ROM BCC0 Dbg to Dev Debugger Boot ROM in interactive mode CMD_CRC Get command code Wait for command Internal checks SIG_CMD_VALID Get 128 bits key as 4x32bits words NOTE : a 100us delay is inserted before sending BADKEY status Get data Get keyword 0 CRC_Keyword0 Get keyword 1 CRC_Keyword1 Get keyword 2 CRC_Keyword2 Get keyword 3 CRC_Keyword3 NOTE : debugger polls the BCCD0 bit to know when Boot ROM has read the word before sending the next Debugger requests CRC of a table Verify key Crc disabled CRC command disabled? SIG_CMD_INVALID Crc not disabled Debugger polls for status update on BCC1 keys don't match Key matches BOCOR key? SIG_CMD_BADKEY Keys match Read Status Signal crc start SIG_CMD_VALID Wait for table address Get table address CRC Table Address Send CRC table address Table incorrect Process CRC table SIG_CMD_BADTBL Crc fail Check CRC of target area Debugger polls for status update on BCC1 SIG_CMD_FAIL Crc ok SIG_CMD_SUCCESS Boot ROM in interactive mode © 2020 Microchip Technology Inc. Read Status Debugger idle Datasheet DS60001513F-page 83 SAM L10/L11 Family Boot ROM 14.4.5.7 Random Session Key Generation (CMD_DCEK) - SAM L11 only This command allows using a challenge-response scheme to prevent exposure of the keys in clear text on the debugger communication lines. The different keys sent by the debugger during the Boot ROM for Chip Erase (CMD_CEx) and CRC (CMD_CRC) commands execution are: • • CRCKEY for CMD_CRC command CEKEYx for CMD_CEx commands Note:  The CMD_DCEK command has no effect on the SAM L10, the key derivation will not be enabled. The random challenge value is generated using the TRNG of the device. It is generated once the CMD_DCEK is received and communicated to the debugger. The next CMD_CEx or CMD_CRC commands will expect the key value to be replaced by the computed response corresponding to the challenge. The challenge value is valid only for the next CMD_CEx/ CMD_CRC command. Before sending a new CMD_CEx/ CMD_CRC command, a CMD_DCEK shall be used to re-enable the challengeresponse scheme a get a new challenge value. On the debugger side, the response shall be computed using the following algorithm: Figure 14-13. Debugger Algorithm Where KeyIndex is: • • • • 0 for ChipErase_NS 1 for ChipErase_S 2 for ChipErase_ALL 3 for CRC Command Notes:  • HMAC is described in FIPS PUB 198-1 • The hash used for HMAC is SHA-256 • The output of the HMAC-SHA256 is truncated to obtain an HMAC-SHA256-128 as explained in RFC4868 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 84 SAM L10/L11 Family Boot ROM 14.4.5.7.1 CMD_DCEK (SAM L11 only) Figure 14-14. CMD_DCEK Flow diagram Boot Communication Channels Boot ROM BCC1 Dev to Dbg BCC0 Dbg to Dev Debugger Boot ROM in interactive mode CMD_DCEK Wait for command Get command code Generate random data RandomDat0 Get data RandomDat1 Send 128 bits random number as 4x32bits words Debugger requests key derivation Get data RandomDat2 Get data RandomDat3 Get data Set key derivation on Set key derivation on Boot ROM in interactive mode Debugger idle 14.4.5.8 NVM Rows Content Checks (CMD_RAUX) The Boot ROM provides a way to check the content of the NVM rows. When device is secured (DAL0), the fuse configuration can still be read by the debugger using the Read Auxiliary command (CMD_RAUX). The following areas are accessible: Table 14-8. Accessible Memory Range by Read Auxiliary Row Command(1) Area Start address End address User row (UROW) 0x00804000 0x0080401F Software Calibration row 0x00806020 0x0080602F © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 85 SAM L10/L11 Family Boot ROM ...........continued Area Start address End address Temperature Log row 0x00806038 0x0080603F Note:  1. Boot Configuration row (BOCOR) is not accessible by the Read Auxiliary Row command. 14.4.5.8.1 CMD_RAUX Figure 14-15. CMD_RAUX Flow diagram Boot Communication Channels BCC1 Dev to Dbg Boot ROM BCC0 Dbg to Dev Debugger Boot ROM in interactive mode Wait for command Get command code CMD_RAUX Wait for address Get address Target Address Address in allowed range ? Yes Send value SIG_ARG_VALID Get status DATA_VALUE Get Value out of range Address (eg 0x0) Wait for address Address in allowed range ? No SIG_ARG_INVALID Get status Boot ROM in interactive mode Debugger requests a word in AUX address space Debugger polls for status update on BCC1 Debugger exits read loop Debugger polls for status update on BCC1 Debugger idle Note: After the CMD_RAUX is sent, the debugger can read multiple data, the read loop is exit when an out of range address is sent. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 86 SAM L10/L11 Family Boot ROM 14.4.5.9 Boot Interactive Mode Commands Table 14-9. Boot Interactive Mode Commands Command Name Description Command prefix Command CMD_INIT Entering Interactive Mode 0x444247 55 CMD_EXIT Exit Interactive Mode 0x444247 AA CMD_RESET System Reset Request 0x444247 52 CMD_CE0 ChipErase_NS for SAM L11 0x444247 E0 CMD_CE1 ChipErase_S for SAM L11 0x444247 E1 CMD_CE2 ChipErase_ALL for SAM L11 0x444247 E2 CMD_CHIPERASE ChipErase for SAM L10 0x444247 E3 CMD_CRC NVM Memory Regions Integrity Checks 0x444247 C0 CMD_DCEK Random Session Key Generation for SAM L11 0x444247 44 CMD_RAUX NVM Rows Integrity Checks 0x444247 4C 14.4.5.10 Boot Interactive Mode Status Table 14-10. Boot Interactive Mode Status Status Name Description SIG_NO No Error 0xEC0000 00 SIG_SAN_FFF Fresh from factory error 0xEC0000 10 SIG_SAN_UROW UROW checksum error 0xEC0000 11 SIG_SAN_SECEN SECEN parameter error 0xEC0000 12 SIG_SAN_BOCOR BOCOR checksum error 0xEC0000 13 SIG_SAN_BOOTPROT BOOTPROT parameter error 0xEC0000 14 SIG_SAN_NOSECREG No secure register parameter error 0xEC0000 15 SIG_COMM Debugger start communication command 0xEC0000 20 SIG_CMD_SUCCESS Debugger command success 0xEC0000 21 SIG_CMD_FAIL Debugger command fail 0xEC0000 22 SIG_CMD_BADKEY Debugger bad key 0xEC0000 23 SIG_CMD_VALID Valid command 0xEC0000 24 SIG_CMD_INVALID Invalid command 0xEC0000 25 SIG_ARG_VALID Valid argument 0xEC0000 26 SIG_ARG_INVALID Invalid argument 0xEC0000 27 SIG_CE_CVM Chip erase error: CVM 0xEC0000 30 SIG_CE_ARRAY_ERASEFAIL Chip erase error: array erase fail 0xEC0000 31 SIG_CE_ARRAY_NVME Chip erase error: array NVME 0xEC0000 32 SIG_CE_DATA_ERASEFAIL Chip erase error: data erase fail 0xEC0000 33 SIG_CE_DATA_NVME Chip erase error: data NVME 0xEC0000 34 SIG_CE_BCUR Chip erase error: BOCOR, UROW 0xEC0000 35 SIG_CE_BC Chip erase error: BC check 0xEC0000 36 SIG_BOOT_OPT BOOTOPT parameter error 0xEC0000 40 © 2020 Microchip Technology Inc. Status prefix Datasheet Status coding DS60001513F-page 87 SAM L10/L11 Family Boot ROM ...........continued 14.4.6 Status Name Description Status prefix Status coding SIG_BOOT_ERR Boot image digest verify fail 0xEC0000 41 SIG_BOCOR_HASH BOCOR hash error 0xEC0000 42 SIG_CRC_BADTBL Bad CRC table 0xEC0000 50 SIG_SECEN0_ERR PAC or IDAU cfg check failure 0xEC0000 60 SIG_SECEN1_ERR PAC or IDAU cfg check failure 0xEC0000 61 SIG_EXIT_ERR Exit: BC or check error 0xEC0000 70 SIG_HARDFAULT Hardfault error 0xEC0000 F0 SIG_BOOTOK Boot ROM ok to exit 0xEC0000 39 CPU Park mode This mode allows the debugger to get access to the resources of the device during Boot ROM execution while the CPU is trapped in a while loop. The debug access level when entering that mode corresponds to the DAL value which is programmed in the device. Important:  This mode is the recommended way to enter a debugging session in a safe way even if it is also possible to launch a debug session when the application is running. This mode is reached by sending the Exit command (CMD_EXIT) without clearing the DSU.STATUSA.BREXT bit to the Boot ROM. As soon as the BREXT bit is cleared, the device exits this state and performs a system reset. At this point, the MPU is still enabled and prevents software execution elsewhere than in Boot ROM region. If the host needs to run software on the device, MPU shall be disabled by accessing the Cortex-M23 MPU CTRL register with the debugger. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 88 SAM L10/L11 Family PAC - Peripheral Access Controller 15. PAC - Peripheral Access Controller 15.1 Overview The Peripheral Access Controller provides an interface for the locking and unlocking and for managing security attribution of peripheral registers within the device. It reports all violations that could happen when accessing a peripheral: write protected access, illegal access, enable protected access, access when clock synchronization or software reset is on-going. These errors are reported in a unique interrupt flag for a peripheral. The PAC module also reports errors occurring at the slave bus level, when an access to a non-existing address is detected. 15.2 Features • • 15.3 Manages write protection access and reports access errors for the peripheral modules or bridges. Manages security attribution for the peripheral modules (SAM L11) Block Diagram Figure 15-1. PAC Block Diagram PAC IRQ Slave ERROR SLAVEs INTFLAG APB Peripheral ERROR PERIPHERAL m BUSn WRITE CONTROL PAC CONTROL PERIPHERAL 0 Peripheral ERROR PERIPHERAL m BUS0 WRITE CONTROL 15.4 PERIPHERAL 0 Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described below. 15.4.1 IO Lines Not applicable. 15.4.2 Power Management The PAC can continue to operate in any Sleep mode where the selected source clock is running. The PAC interrupts can be used to wake up the device from Sleep modes. The events can trigger other operations in the system without exiting sleep modes. Related Links 22. PM – Power Manager © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 89 SAM L10/L11 Family PAC - Peripheral Access Controller 15.4.3 Clocks The PAC bus clocks (CLK_PAC_APB and CLK_PAC_AHB) can be enabled and disabled in the Main Clock module. The default state of CLK_PAC_APB and CLK_PAC_AHB can be found in the related links. Related Links 19. MCLK – Main Clock 19.6.2.6 Peripheral Clock Masking 15.4.4 DMA Not applicable. 15.4.5 Interrupts The interrupt request line is connected to the Interrupt Controller. Using the PAC interrupt requires the Interrupt Controller to be configured first. Table 15-1. Interrupt Lines 15.4.6 Instances NVIC Line PAC ERR Events The events are connected to the Event System, which may need configuration. Related Links 33. EVSYS – Event System 15.4.7 Debug Operation When the CPU is halted in Debug mode, write protection of all peripherals is disabled and the PAC continues normal operation. 15.4.8 Register Access Protection All registers with write-access can be write-protected optionally by the Peripheral Access Controller (PAC), except for the following registers: • • • Write Control (WRCTRL) register AHB Slave Bus Interrupt Flag Status and Clear (INTFLAGAHB) register Peripheral Interrupt Flag Status and Clear n (INTFLAG A/B/C...) registers Optional write-protection by the Peripheral Access Controller (PAC) is denoted by the "PAC Write-Protection" property in each individual register description. PAC write-protection does not apply to accesses through an external debugger. 15.4.9 SAM L11 TrustZone Specific Register Access Protection All PAC registers can only be accessed in the secure alias, with the following exceptions: • Write Control (WRCTRL) register is also accessible in the Non-Secure Alias, but only for write protection requests on non-secured peripherals. • Peripheral Write Protection Status (STATUSn) registers are also accessible in the Non-Secure Alias, but they will only report information on non-secured peripherals. Note:  Refer to the Mix-Secure Peripherals section in the SAM L11 Security Features chapter for more information. 15.5 Functional Description 15.5.1 Principle of Operation The Peripheral Access Control module allows the user to set a write protection or security attribution on peripheral modules and generate an interrupt in case of a peripheral access violation. The peripheral’s protection can be set, © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 90 SAM L10/L11 Family PAC - Peripheral Access Controller cleared or locked at the user discretion. A set of Interrupt Flag and Status registers informs the user on the status of the violation in the peripherals. In addition, slaves bus errors can be also reported in the cases where reserved area is accessed by the application. 15.5.2 Basic Operation 15.5.2.1 Initialization After reset, the PAC is enabled. 15.5.2.2 Initialization, Enabling and Resetting The PAC is always enabled after reset. Only a hardware reset will reset the PAC module. 15.5.2.3 Operations The PAC module allows the user to set, clear or lock the write protection status and security attribution of all peripherals on all Peripheral Bridges. If a peripheral register violation occurs, the Peripheral Interrupt Flag n registers (INTFLAGn) are updated to inform the user on the status of the violation in the peripherals connected to the Peripheral Bridge n (n = A,B,C ...). The corresponding Peripheral Write Control Status n register (STATUSn) gives the state of the write protection for all peripherals connected to the corresponding Peripheral Bridge n. The corresponding Peripheral Non-Secure Status n register (NONSECn) gives the state of the security attribution for all peripherals connected to the corresponding Peripheral Bridge n. Refer to 15.5.2.4 Peripheral Access Errors for details. The PAC module also report the errors occurring at slave bus level when an access to reserved area is detected. AHB Slave Bus Interrupt Flag register (INTFLAGAHB) informs the user on the status of the violation in the corresponding slave. Refer to the 15.5.2.9 AHB Slave Bus Errors for details. 15.5.2.4 Peripheral Access Errors The following events will generate a Peripheral Access Error: • • • Protected write: To avoid unexpected writes to a peripheral's registers, each peripheral can be write protected. Only the registers denoted as “PAC Write-Protection” in the module’s datasheet can be protected. If a peripheral is not write protected, write data accesses are performed normally. If a peripheral is write protected and if a write access is attempted, data will not be written and peripheral returns an access error. The corresponding interrupt flag bit in the INTFLAGn register will be set. Illegal access: Access to an unimplemented register within the module. Synchronized write error: For write-synchronized registers an error will be reported if the register is written while a synchronization is ongoing. When any of the INTFLAGn registers bit are set, an interrupt will be requested if the PAC interrupt enable bit is set. 15.5.2.5 Write Access Protection Management Peripheral access control can be enabled or disabled by writing to the WRCTRL register. The data written to the WRCTRL register is composed of two fields; WRCTRL.PERID and WRCTRL.KEY. The WRCTRL.PERID is an unique identifier corresponding to a peripheral. The WRCTRL.KEY is a key value that defines the operation to be done on the control access bit. These operations can be “clear protection”, “set protection” and “set and lock protection bit”. The “clear protection” operation will remove the write access protection for the peripheral selected by WRCTRL.PERID. Write accesses are allowed for the registers in this peripheral. The “set protection” operation will set the write access protection for the peripheral selected by WRCTRL.PERID. Write accesses are not allowed for the registers with write protection property in this peripheral. The “set and lock protection” operation will set the write access protection for the peripheral selected by WRCTRL.PERID and locks the access rights of the selected peripheral registers. The write access protection will only be cleared by a hardware reset. The peripheral access control status can be read from the corresponding STATUSn register. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 91 SAM L10/L11 Family PAC - Peripheral Access Controller 15.5.2.6 Write Access Protection Management Errors Only word-wise writes to the WRCTRL register will effectively change the access protection. Other type of accesses will have no effect and will cause a PAC write access error. This error is reported in the INTFLAGn.PAC bit corresponding to the PAC module. PAC also offers an additional safety feature for correct program execution with an interrupt generated on double write clear protection or double write set protection. If a peripheral is write protected and a subsequent set protection operation is detected then the PAC returns an error, and similarly for a double clear protection operation. In addition, an error is generated when writing a “set and lock” protection to a write-protected peripheral or when a write access is done to a locked set protection. This can be used to ensure that the application follows the intended program flow by always following a write protect with an unprotect and conversely. However in applications where a write protected peripheral is used in several contexts, e.g. interrupt, care should be taken so that either the interrupt can not happen while the main application or other interrupt levels manipulates the write protection status or when the interrupt handler needs to unprotect the peripheral based on the current protection status by reading the STATUS register. The errors generated while accessing the PAC module registers (eg. key error, double protect error...) will set the INTFLAGn.PAC flag. 15.5.2.7 SAM L11 Security Attribution Management The peripheral security attribution status can be read from the corresponding NONSECn register. 15.5.2.8 SAM L11 Security Attribution Management Errors The errors generated while accessing the PAC module registers (e.g., key error, double protect error...) will set the INTFLAGn.PAC flag. 15.5.2.9 AHB Slave Bus Errors The PAC module reports errors occurring at the AHB Slave bus level. These errors are generated when an access is performed at an address where no slave (bridge or peripheral) is mapped or where non-secure accesses are prohibited. These errors are reported in the corresponding bits of the INTFLAGAHB register. 15.5.2.10 Generating Events The PAC module can also generate an event when any of the Interrupt Flag registers bit are set. To enable the PAC event generation, the control bit EVCTRL.ERREO must be set a '1'. 15.5.3 DMA Operation Not applicable. 15.5.4 Interrupts The PAC has the following interrupt source: • Error (ERR): Indicates that a peripheral access violation occurred in one of the peripherals controlled by the PAC module, or a bridge error occurred in one of the bridges reported by the PAC – This interrupt is a synchronous wake-up source. Each interrupt source has an interrupt flag associated with it. The interrupt flag in the Interrupt Flag Status and Clear (INTFLAGAHB and INTFLAGn) registers is set when the interrupt condition occurs. Each interrupt can be individually enabled by writing a '1' to the corresponding bit in the Interrupt Enable Set (INTENSET) register, and disabled by writing a '1' to the corresponding bit in the Interrupt Enable Clear (INTENCLR) register. An interrupt request is generated when the interrupt flag is set and the corresponding interrupt is enabled. The interrupt request remains active until the interrupt flag is cleared, the interrupt is disabled, or the PAC is reset. All interrupt requests from the peripheral are ORed together on system level to generate one combined interrupt request to the NVIC. The user must read the INTFLAGAHB and INTFLAGn registers to determine which interrupt condition is present. Note that interrupts must be globally enabled for interrupt requests to be generated. Related Links 22.6.3.3 Sleep Mode Controller 15.5.5 Events The PAC can generate the following output event: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 92 SAM L10/L11 Family PAC - Peripheral Access Controller • Error (ERR): Generated when one of the interrupt flag registers bits is set Writing a '1' to an Event Output bit in the Event Control Register (EVCTRL.ERREO) enables the corresponding output event. Writing a '0' to this bit disables the corresponding output event. 15.5.6 Sleep Mode Operation In Sleep mode, the PAC is kept enabled if an available bus master (CPU, DMA) is running. The PAC will continue to catch access errors from the module and generate interrupts or events. 15.5.7 SAM L11 Secure and Non-Secure Read/Write Accesses Non-Secure write to EVCTRL, INTENCLR, INTENSET, INTFLAGAHB, INTFLAGx, and NONSECx registers is prohibited. Non-Secure read to EVCTRL, INTENCLR, INTENSET, INTFLAGAHB, and INTFLAGx registers will return zero with no error resulting. Non-secure write to a bit of STATUSx registers (by writing to the WRCTRL register) is prohibited if the corresponding bit in NONSECx is zero. STATUSx bits relating to secure peripherals (i.e., the corresponding bits in NONSECx are zero), read as zero in NonSecure mode, with no error resulting. 15.5.8 Synchronization Not applicable. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 93 SAM L10/L11 Family PAC - Peripheral Access Controller 15.6 Register Summary Important:  For SAM L11, the PAC register map is automatically duplicated in a Secure and Non-Secure alias: • The Non-Secure alias is at the peripheral base address • The Secure alias is located at the peripheral base address + 0x200 Refer to Mix-Secure Peripherals for more information on register access rights Offset Name 0x00 WRCTRL 0x04 0x05 ... 0x07 0x08 0x09 0x0A ... 0x0F EVCTRL Bit Pos. INTENCLR INTENSET 0x18 INTFLAGAHB INTFLAGA INTFLAGB INTFLAGC 0x20 ... 0x33 Reserved 0x3C 3 2 1 0 PERID[7:0] PERID[15:8] KEY[7:0] ERREO ERR ERR STATUSA STATUSB STATUSC BROM HSRAMDSU GCLK SUPC HSRAMDMA HSRAMCPU C APBC APBB APBA FLASH OSCCTRL RSTC MCLK PM PAC PORT FREQM EIC RTC WDT Reserved DMAC NVMCTRL DSU IDAU TC1 TC0 SERCOM2 SERCOM1 SERCOM0 EVSYS TRAM OPAMP CCL TRNG PTC DAC OSCCTRL RSTC MCLK PM PAC PORT FREQM EIC RTC WDT Reserved DMAC NVMCTRL DSU IDAU TC0 OPAMP SERCOM2 CCL SERCOM1 TRNG SERCOM0 PTC EVSYS DAC 15:8 23:16 31:24 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 ADC TC2 15:8 23:16 31:24 7:0 0x38 4 Reserved 0x1C 0x34 5 7:0 7:0 7:0 0x14 6 Reserved 7:0 0x10 7 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 GCLK ADC © 2020 Microchip Technology Inc. SUPC TC2 OSC32KCTR L AC OSC32KCTR L AC TC1 TRAM Datasheet DS60001513F-page 94 SAM L10/L11 Family PAC - Peripheral Access Controller ...........continued Offset Name 0x40 ... 0x53 Reserved 0x54 0x58 0x5C 15.7 Bit Pos. 7 6 7:0 GCLK SUPC 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 NONSECA NONSECB NONSECC ADC TC2 5 OSC32KCTR L AC TC1 TRAM 4 3 2 1 0 OSCCTRL RSTC MCLK PM PAC PORT FREQM EIC RTC WDT HMATRIXHS DMAC NVMCTRL DSU IDAU TC0 OPAMP SERCOM2 CCL SERCOM1 TRNG SERCOM0 PTC EVSYS DAC Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16- and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers are optionally write-protected by the Peripheral Access Controller (PAC). Optional PAC writeprotection is denoted by the "PAC Write-Protection" property in each individual register description. For details, refer to the related links. On SAM L11 devices, the Mix-Secure peripheral has different types of registers (Non-Secure, Secure, Write-Secure, Mix-Secure, and Write-Mix-Secure) with different access permissions for each bitfield. Refer to Mix-Secure Peripherals for more details. In the following register descriptions, the access permissions are specified as shown in the following figure. Bit 7 6 5 4 R/-/RW R/-/RW R/-/RW R/-/RW 3 2 1 0 R/-/RW R/-/RW R/-/RW R/-/RW CMD[7:0] Access TrustZone Non-Protected Devices Access TrustZone Protected Devices Non-Secure Access TrustZone Protected Devices Secure Access © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 95 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.1 Write Control Name:  Offset:  Reset:  Property:  Bit WRCTRL 0x00 0x00000000 Mix-Secure 31 30 29 28 Bit 23 22 21 20 Bit 15 14 13 Bit 7 6 5 27 26 25 24 Access Reset 19 18 17 16 KEY[7:0] Access RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW Reset 0 0 0 0 0 0 0 0 12 11 10 9 8 PERID[15:8] Access RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW Reset 0 0 0 0 0 0 0 0 4 3 2 1 0 PERID[7:0] Access RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW Reset 0 0 0 0 0 0 0 0 Bits 23:16 – KEY[7:0] Peripheral Access Control Key These bits define the peripheral access control key: Value Name Description 0x0 OFF No action 0x1 CLEAR Clear the peripheral write control 0x2 SET Set the peripheral write control 0x3 LOCK Set and lock the peripheral write control until the next hardware reset Bits 15:0 – PERID[15:0] Peripheral Identifier The PERID represents the peripheral whose control is changed using the WRCTRL.KEY. The Peripheral Identifier is calculated by the following formula: ����� = 32* BridgeNumber + N Where BridgeNumber represents the Peripheral Bridge Number (0 for Peripheral Bridge A, 1 for Peripheral Bridge B, etc.). N represents the peripheral index from the respective Peripheral Bridge Number, which can be retrieved in the Peripherals Configuration Summary table: Table 15-2. PERID Values Peripheral Bridge Name BridgeNumber PERID Values A B C 0 1 2 0+N 32+N 64+N © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 96 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.2 Event Control Name:  Offset:  Reset:  Property:  Bit 7 EVCTRL 0x04 0x00 PAC Write-Protection, Secure 6 5 4 3 Access Reset 2 1 0 ERREO RW/-/RW 0 Bit 0 – ERREO Peripheral Access Error Event Output This bit indicates if the Peripheral Access Error Event Output is enabled or disabled. When enabled, an event will be generated when one of the interrupt flag registers bits (INTFLAGAHB, INTFLAGn) is set: Value Description 0 Peripheral Access Error Event Output is disabled. 1 Peripheral Access Error Event Output is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 97 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.3 Interrupt Enable Clear Name:  Offset:  Reset:  Property:  INTENCLR 0x08 0x00 PAC Write-Protection, Secure This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set register (INTENSET). Bit 7 6 5 4 3 Access Reset 2 1 0 ERR RW/-/RW 0 Bit 0 – ERR Peripheral Access Error Interrupt Disable This bit indicates that the Peripheral Access Error Interrupt is enabled and an interrupt request will be generated when one of the interrupt flag registers bits (INTFLAGAHB, INTFLAGn) is set: Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Peripheral Access Error interrupt Enable bit and disables the corresponding interrupt request. Value Description 0 Peripheral Access Error interrupt is disabled. 1 Peripheral Access Error interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 98 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.4 Interrupt Enable Set Name:  Offset:  Reset:  Property:  INTENSET 0x09 0x00 PAC Write-Protection, Secure This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set register (INTENCLR). Bit 7 6 5 4 3 Access Reset 2 1 0 ERR RW/-/RW 0 Bit 0 – ERR Peripheral Access Error Interrupt Enable This bit indicates that the Peripheral Access Error Interrupt is enabled and an interrupt request will be generated when one of the interrupt flag registers bits (INTFLAGAHB, INTFLAGn) is set: Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Peripheral Access Error interrupt Enable bit and enables the corresponding interrupt request. Value Description 0 Peripheral Access Error interrupt is disabled. 1 Peripheral Access Error interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 99 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.5 AHB Slave Bus Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  INTFLAGAHB 0x10 0x000000 Secure This flag is cleared by writing a '1' to the flag. This flag is set when an access error is detected by the SLAVE n, and will generate an interrupt request if INTENCLR/SET.ERR is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the corresponding INTFLAGAHB interrupt flag. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 3 APBC 2 APBB 1 APBA 0 FLASH RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 7 BROM RW/-/RW 0 6 5 4 HSRAMDSU HSRAMDMA HSRAMCPU C RW/-/RW RW/-/RW RW/-/RW 0 0 0 Bit 7 – BROM Interrupt Flag for Boot ROM Bit 6 – HSRAMDSU Interrupt Flag for SLAVE HS SRAM Port 2 - DSU Access Bit 5 – HSRAMDMAC Interrupt Flag for SLAVE HS SRAM Port 1 - DMAC Access Bit 4 – HSRAMCPU Interrupt Flag for SLAVE HS SRAM Port 0 - CPU Access Bit 3 – APBC Interrupt Flag for SLAVE AHB-APB Bridge C Bit 2 – APBB Interrupt Flag for SLAVE AHB-APB Bridge B Bit 1 – APBA Interrupt Flag for SLAVE AHB-APB Bridge A Bit 0 – FLASH Interrupt Flag for SLAVE FLASH © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 100 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.6 Peripheral Interrupt Flag Status and Clear A Name:  Offset:  Reset:  Property:  INTFLAGA 0x14 0x000000 Secure This flag is cleared by writing a one to the flag. This flag is set when a Peripheral Access Error occurs while accessing the peripheral associated with the respective INTFLAGA bit, and will generate an interrupt request if INTENCLR/SET.ERR is one. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the corresponding INTFLAGA interrupt flag. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 AC RW/-/RW 0 12 PORT RW/-/RW 0 11 FREQM RW/-/RW 0 10 EIC RW/-/RW 0 9 RTC RW/-/RW 0 8 WDT RW/-/RW 0 7 GCLK 6 SUPC 3 RSTC 2 MCLK 1 PM 0 PAC RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 5 4 OSC32KCTR OSCCTRL L RW/-/RW RW/-/RW 0 0 Bit 13 – AC Interrupt Flag for AC Bit 12 – PORT Interrupt Flag for PORT Bit 11 – FREQM Interrupt Flag for FREQM Bit 10 – EIC Interrupt Flag for EIC Bit 9 – RTC Interrupt Flag for RTC Bit 8 – WDT Interrupt Flag for WDT Bit 7 – GCLK Interrupt Flag for GCLK Bit 6 – SUPC Interrupt Flag for SUPC Bit 5 – OSC32KCTRL Interrupt Flag for OSC32KCTRL Bit 4 – OSCCTRL Interrupt Flag for OSCCTRL Bit 3 – RSTC Interrupt Flag for RSTC © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 101 SAM L10/L11 Family PAC - Peripheral Access Controller Bit 2 – MCLK Interrupt Flag for MCLK Bit 1 – PM Interrupt Flag for PM Bit 0 – PAC Interrupt Flag for PAC © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 102 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.7 Peripheral Interrupt Flag Status and Clear B Name:  Offset:  Reset:  Property:  INTFLAGB 0x18 0x000000 Secure This flag is cleared by writing a '1' to the flag. This flag is set when a Peripheral Access Error occurs while accessing the peripheral associated with the respective INTFLAGB bit, and will generate an interrupt request if INTENCLR/SET.ERR is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the corresponding INTFLAGB interrupt flag. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 Reserved RW/-/RW 0 3 DMAC RW/-/RW 0 2 NVMCTRL RW/-/RW 0 1 DSU RW/-/RW 0 0 IDAU RW/-/RW 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 4 – Reserved Reserved Bit 3 – DMAC Interrupt Flag for DMAC Bit 2 – NVMCTRL Interrupt Flag for NVMCTRL Bit 1 – DSU Interrupt Flag for DSU Bit 0 – IDAU Interrupt Flag for IDAU © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 103 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.8 Peripheral Interrupt Flag Status and Clear C Name:  Offset:  Reset:  Property:  INTFLAGC 0x1C 0x000000 Secure This flag is cleared by writing a one to the flag. This flag is set when a Peripheral Access Error occurs while accessing the peripheral associated with the respective INTFLAGC bit, and will generate an interrupt request if INTENCLR/SET.ERR is one. Writing a zero to this bit has no effect. Writing a one to this bit will clear the corresponding INTFLAGC interrupt flag. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 TRAM RW/-/RW 0 12 OPAMP RW/-/RW 0 11 CCL RW/-/RW 0 10 TRNG RW/-/RW 0 9 PTC RW/-/RW 0 8 DAC RW/-/RW 0 7 ADC RW/-/RW 0 6 TC2 RW/-/RW 0 5 TC1 RW/-/RW 0 4 TC0 RW/-/RW 0 3 SERCOM2 RW/-/RW 0 2 SERCOM1 RW/-/RW 0 1 SERCOM0 RW/-/RW 0 0 EVSYS RW/-/RW 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 13 – TRAM Interrupt Flag for TRAM Bit 12 – OPAMP Interrupt Flag for OPAMP Bit 11 – CCL Interrupt Flag for CCL Bit 10 – TRNG Interrupt Flag for TRNG Bit 9 – PTC Interrupt Flag for PTC Bit 8 – DAC Interrupt Flag for DAC Bit 7 – ADC Interrupt Flag for ADC Bits 4, 5, 6 – TC Interrupt Flag for TCn [n = 2..0] Bits 1, 2, 3 – SERCOM Interrupt Flag for SERCOMn [n = 2..0] Bit 0 – EVSYS Interrupt Flag for EVSYS © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 104 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.9 Peripheral Write Protection Status A Name:  Offset:  Reset:  Property:  STATUSA 0x34 0x0000C000 Mix-Secure Reading STATUSA register returns peripheral write protection status: Value Description 0 Peripheral is not write protected. 1 Peripheral is write protected. Important:  For SAM L11 Non-Secure accesses, read accesses (R*) are allowed only if the peripheral security attribution for the corresponding peripheral is set as Non-Secured in the NONSECx register. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 AC R/R*/R 0 12 PORT R/R*/R 0 11 FREQM R/R*/R 0 10 EIC R/R*/R 0 9 RTC R/R*/R 0 8 WDT R/R*/R 0 Bit 7 GCLK 6 SUPC 3 RSTC 2 MCLK 1 PM 0 PAC Access Reset R/R*/R 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 Access Reset Bit Access Reset Bit Access Reset 5 4 OSC32KCTR OSCCTRL L R/R*/R R/R*/R 0 0 Bit 13 – AC Peripheral AC Write Protection Status Bit 12 – PORT Peripheral PORT Write Protection Status Bit 11 – FREQM Peripheral FREQM Write Protection Status Bit 10 – EIC Peripheral EIC Write Protection Status Bit 9 – RTC Peripheral RTC Write Protection Status Bit 8 – WDT Peripheral WDT Write Protection Status Bit 7 – GCLK Peripheral GCLK Write Protection Status Bit 6 – SUPC Peripheral SUPC Write Protection Status © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 105 SAM L10/L11 Family PAC - Peripheral Access Controller Bit 5 – OSC32KCTRL Peripheral OSC32KCTRL Write Protection Status Bit 4 – OSCCTRL Peripheral OSCCTRL Write Protection Status Bit 3 – RSTC Peripheral RSTC Write Protection Status Bit 2 – MCLK Peripheral MCLK Write Protection Status Bit 1 – PM Peripheral PM Write Protection Status Bit 0 – PAC Peripheral PAC Write Protection Status © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 106 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.10 Peripheral Write Protection Status B Name:  Offset:  Reset:  Property:  STATUSB 0x38 0x00000002 Mix-Secure Reading the STATUSB register returns the peripheral write protection status: Value Description 0 Peripheral is not write protected. 1 Peripheral is write protected. Important:  For SAM L11 Non-Secure accesses, read accesses (R*) are allowed only if the peripheral security attribution for the corresponding peripheral is set as Non-Secured in the NONSECx register. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 Reserved R/R*/R 0 3 DMAC R/R*/R 0 2 NVMCTRL R/R*/R 0 1 DSU R/R*/R 0 0 IDAU R/R*/R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 4 – Reserved Reserved Bit 3 – DMAC Peripheral DMAC Write Protection Status Bit 2 – NVMCTRL Peripheral NVMCTRL Write Protection Status Bit 1 – DSU Peripheral DSU Write Protection Status Bit 0 – IDAU Peripheral IDAU Write Protection Status © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 107 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.11 Peripheral Write Protection Status C Name:  Offset:  Reset:  Property:  STATUSC 0x3C 0x000000 Mix-Secure Reading the STATUSC register returns the peripheral write protection status: Value Description 0 Peripheral is not write protected. 1 Peripheral is write protected. Important:  For SAM L11 Non-Secure accesses, read accesses (R*) are allowed only if the peripheral security attribution for the corresponding peripheral is set as Non-Secured in the NONSECx register. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 TRAM R/R*/R 0 12 OPAMP R/R*/R 0 11 CCL R/R*/R 0 10 TRNG R/R*/R 0 9 PTC R/R*/R 0 8 DAC R/R*/R 0 7 ADC R/R*/R 0 6 TC2 R/R*/R 0 5 TC1 R/R*/R 0 4 TC0 R/R*/R 0 3 SERCOM2 R/R*/R 0 2 SERCOM1 R/R*/R 0 1 SERCOM0 R/R*/R 0 0 EVSYS R/R*/R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 13 – TRAM Peripheral TRAM Write Protection Status Bit 12 – OPAMP Peripheral OPAMP Write Protection Status Bit 11 – CCL Peripheral CCL Write Protection Status Bit 10 – TRNG Peripheral TRNG Write Protection Status Bit 9 – PTC Peripheral PTC Write Protection Status Bit 8 – DAC Peripheral DAC Write Protection Status Bit 7 – ADC Peripheral ADC Write Protection Status Bits 4, 5, 6 – TC Peripheral TCn Write Protection Status [n = 2..0] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 108 SAM L10/L11 Family PAC - Peripheral Access Controller Bits 1, 2, 3 – SERCOM Peripheral SERCOMn Write Protection Status [n = 2..0] Bit 0 – EVSYS Peripheral EVSYS Write Protection Status © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 109 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.12 Peripheral Non-Secure Status - Bridge A Name:  Offset:  Reset:  Property:  NONSECA 0x54 x initially determined from NVM User Row after reset Write-Secure This register is loaded from UROW at boot. Important:  This register is only available for SAM L11 and has no effect for SAM L10. Reading NONSEC register returns peripheral security attribution status: Value Description 0 Peripheral is secured. 1 Peripheral is non-secured. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 AC R/R/R x 12 PORT R/R/R x 11 FREQM R/R/R x 10 EIC R/R/R x 9 RTC R/R/R x 8 WDT R/R/R x Bit 7 GCLK 6 SUPC 3 RSTC 2 MCLK 1 PM 0 PAC Access Reset R/R/R x R/R/R x R/R/R x R/R/R x R/R/R x R/R/R x Access Reset Bit Access Reset Bit Access Reset 5 4 OSC32KCTR OSCCTRL L R/R/R R/R/R x x Bit 13 – AC Peripheral AC Non-Secure Bit 12 – PORT Peripheral PORT Non-Secure Bit 11 – FREQM Peripheral FREQM Non-Secure Bit 10 – EIC Peripheral EIC Non-Secure Bit 9 – RTC Peripheral RTC Non-Secure Bit 8 – WDT Peripheral WDT Non-Secure Bit 7 – GCLK Peripheral GCLK Non-Secure © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 110 SAM L10/L11 Family PAC - Peripheral Access Controller Bit 6 – SUPC Peripheral SUPC Non-Secure Bit 5 – OSC32KCTRL Peripheral OSC32KCTRL Non-Secure Bit 4 – OSCCTRL Peripheral OSCCTRL Non-Secure Bit 3 – RSTC Peripheral RSTC Non-Secure Bit 2 – MCLK Peripheral MCLK Non-Secure Bit 1 – PM Peripheral PM Non-Secure Bit 0 – PAC Peripheral PAC Non-Secure The PAC Peripheral is always secured. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 111 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.13 Peripheral Non-Secure Status - Bridge B Name:  Offset:  Reset:  Property:  NONSECB 0x58 x initially determined from NVM User Row after reset Write-Secure This register is loaded from UROW at boot. Important:  This register is only available for SAM L11 and has no effect for SAM L10. Reading NONSEC register returns peripheral security attribution status: Value Description 0 Peripheral is secured. 1 Peripheral is non-secured. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 HMATRIXHS R/R/R x 3 DMAC R/R/R x 2 NVMCTRL R/R/R 0 1 DSU R/R/R 1 0 IDAU R/R/R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 4 – HMATRIXHS Peripheral HMATRIXHS Non-Secure Bit 3 – DMAC Peripheral DMAC Non-Secure Bit 2 – NVMCTRL Peripheral NVMCTRL Non-Secure The NVMCTRL Peripheral is always secured. Bit 1 – DSU Peripheral DSU Non-Secure The DSU Peripheral is always non-secured. Bit 0 – IDAU Peripheral IDAU Non-Secure The IDAU Peripheral is always secured. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 112 SAM L10/L11 Family PAC - Peripheral Access Controller 15.7.14 Peripheral Non-Secure Status - Bridge C Name:  Offset:  Reset:  Property:  NONSECC 0x5C x initially determined from NVM User Row after reset Write-Secure This register is loaded from UROW at boot. Important:  This register is only available for SAM L11 and has no effect for SAM L10. Reading NONSEC register returns peripheral Security Attribution status: Value Description 0 Peripheral is secured. 1 Peripheral is non-secured. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 TRAM R/R/R x 12 OPAMP R/R/R x 11 CCL R/R/R x 10 TRNG R/R/R x 9 PTC R/R/R x 8 DAC R/R/R x 7 ADC R/R/R x 6 TC2 R/R/R x 5 TC1 R/R/R x 4 TC0 R/R/R x 3 SERCOM2 R/R/R x 2 SERCOM1 R/R/R x 1 SERCOM0 R/R/R x 0 EVSYS R/R/R x Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 13 – TRAM Peripheral TRAM Non-Secure Bit 12 – OPAMP Peripheral OPAMP Non-Secure Bit 11 – CCL Peripheral CCL Non-Secure Bit 10 – TRNG Peripheral TRNG Non-Secure Bit 9 – PTC Peripheral PTC Non-Secure Bit 8 – DAC Peripheral DAC Non-Secure Bit 7 – ADC Peripheral ADC Non-Secure Bits 4, 5, 6 – TC Peripheral TCn Non-Secure [n = 2..0] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 113 SAM L10/L11 Family PAC - Peripheral Access Controller Bits 1, 2, 3 – SERCOM Peripheral SERCOMn Non-Secure [n = 2..0] Bit 0 – EVSYS Peripheral EVSYS Non-Secure © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 114 SAM L10/L11 Family Device Service Unit (DSU) 16. 16.1 Device Service Unit (DSU) Overview The Device Service Unit (DSU) provides a means to detect debugger probes. This enables the ARM Debug Access Port (DAP) to have control over multiplexed debug pads and CPU reset. The DSU also provides system-level services to debug adapters in an ARM debug system. It implements a CoreSight Debug ROM that provides device identification as well as identification of other debug components within the system. Hence, it complies with the ARM Peripheral Identification specification. The DSU also provides system services to applications that need memory testing, as required for IEC60730 Class B compliance, for example. The DSU can be accessed simultaneously by a debugger and the CPU, as it is connected on the High-Speed Bus Matrix. It implements communication channels between the device and external tools which can be used at boot time to make use of Boot ROM services. For security reasons, some of the DSU features will be limited or unavailable when the Debug Access Level (DAL) is less than 0x2. Related Links 30. NVMCTRL – Nonvolatile Memory Controller 16.2 Features • • • • • • • • CPU reset extension Debugger probe detection (Cold- and Hot-Plugging) 32-bit cyclic redundancy check (CRC32) of any memory accessible through the bus matrix ARM® CoreSight™ compliant device identification Two debug communications channels Two Boot communications channels Debug access port security filter Onboard memory built-in self-test (MBIST) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 115 SAM L10/L11 Family Device Service Unit (DSU) 16.3 Block Diagram Figure 16-1. DSU Block Diagram debugger_present DSU RESET DEBUGGER PROBE INTERFACE SWCLK cpu_reset_extension CPU CORESIGHT ROM NVMCTRL DBG DAP AHB-AP DAP SECURITY FILTER S M CRC-32 PORT M HIGH-SPEED BUS MATRIX MBIST SWDIO AHB-APB BRIDGE B 16.4 Signal Description The DSU uses three signals to function. 16.5 Signal Name Type Description RESET Digital Input External reset SWCLK Digital Input SW clock SWDIO Digital I/O SW bidirectional data pin Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described below. 16.5.1 I/O Lines The SWCLK pin is by default assigned to the DSU module to allow debugger probe detection and to stretch the CPU reset phase. For more information, refer to 16.6.3 Debugger Probe Detection. The Hot-Plugging feature depends on the PORT configuration. If the SWCLK pin function is changed in the PORT or if the PORT_MUX is disabled, the HotPlugging feature is disabled until a power-reset or an external reset is performed. 16.5.2 Power Management The DSU will continue to operate in Idle mode. Related Links 22. PM – Power Manager © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 116 SAM L10/L11 Family Device Service Unit (DSU) 16.5.3 Clocks The DSU bus clocks (CLK_DSU_APB and CLK_DSU_AHB) can be enabled and disabled by the Main Clock Controller. Related Links 22. PM – Power Manager 19. MCLK – Main Clock 19.6.2.6 Peripheral Clock Masking 16.5.4 DMA The DMA request lines are connected to the DMA Controller (DMAC). To use DMA requests with this peripheral, the DMAC must be configured first. Refer to 28. DMAC – Direct Memory Access Controller for details. The CFG.DCCDMALEVEL bitfield must be configured depending on the DMA channels access modes (read or write for DCC0 and DCC1). 16.5.5 Interrupts Not applicable. 16.5.6 Events Not applicable. 16.5.7 Register Access Protection Registers with write-access can be optionally write-protected by the Peripheral Access Controller (PAC), except for the following: • • • • Debug Communication Channel 0 register (DCC0) Debug Communication Channel 1 register (DCC1) Boot Communication Channel 0 register (BCC0) Boot Communication Channel 1 register (BCC1) Note:  Optional write-protection is indicated by the "PAC Write-Protection" property in the register description. Write-protection does not apply for accesses through an external debugger. Related Links 15. PAC - Peripheral Access Controller 16.5.8 SAM L11 TrustZone-Specific Register Access Protection On SAM L11 devices, this peripheral is always Non-Secured which means: • • Secure access is granted Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. 16.5.9 Analog Connections Not applicable. 16.6 Debug Operation 16.6.1 Principle of Operation The DSU provides basic services to allow on-chip debug using the Arm Debug Access Port and the ARM processor debug resources: • CPU reset extension • Debugger probe detection © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 117 SAM L10/L11 Family Device Service Unit (DSU) • Boot Communication Channels For more details on the ARM debug components, refer to the ARM Debug Interface v5 Architecture Specification. 16.6.2 CPU Reset Extension “CPU reset extension” refers to the extension of the reset phase of the CPU core after the external reset is released. This ensures that the CPU is not executing code at startup while a debugger connects to the system. It is detected on a RESET release event when SWCLK is low. At startup, SWCLK is internally pulled up to avoid false detection of a debugger if SWCLK is left unconnected. When the CPU is held in the reset extension phase, the CPU Reset Extension bit of the Status A register (STATUSA.CRSTEXT) is set. To release the CPU, write a '1' to STATUSA.CRSTEXT. STATUSA.CRSTEXT will then be set to zero. Writing a '0' to STATUSA.CRSTEXT has no effect. Releasing the "CPU reset extension" is possible for all DAL levels. The CPU then executes the Boot ROM that offers basic failure analysis services and security checks. It is not possible to access the bus system until the Boot ROM has performed these security checks. Note:  Refer to 14. Boot ROM for more information. Figure 16-2. Typical CPU Reset Extension Set and Clear Timing Diagram SWCLK RESET DSU CRSTEXT Clear CPU reset extension CPU_STATE 16.6.3 reset running Debugger Probe Detection 16.6.3.1 Cold Plugging Cold-Plugging is the detection of a debugger when the system is in reset. Cold-Plugging is detected when the CPU reset extension is requested, as described above. 16.6.3.2 Hot Plugging Hot-Plugging is the detection of a debugger probe when the system is not in reset. Hot-Plugging is not possible under reset because the detector is reset when POR or RESET are asserted. Hot-Plugging is active when a SWCLK falling edge is detected. The SWCLK pad is multiplexed with other functions and the user must ensure that its default function is assigned to the debug system. If the SWCLK function is changed, the Hot-Plugging feature is disabled until a power-reset or external reset occurs. Availability of the Hot-Plugging feature can be read from the HotPlugging Enable bit of the Status B register (STATUSB.HPE). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 118 SAM L10/L11 Family Device Service Unit (DSU) Figure 16-3. Hot-Plugging Detection Timing Diagram SWCLK RESET CPU_STATE reset running Hot-Plugging The presence of a debugger probe is detected when either Hot-Plugging or Cold-Plugging is detected. Once detected, the Debugger Present bit of the Status B register (STATUSB.DBGPRES) is set. For security reasons, HotPlugging is not available when DAL equals to 0x0. This detection requires that pads are correctly powered. Thus, at cold startup, this detection cannot be done until POR is released. If DAL equals 0x0, Cold-Plugging is the only way to detect a debugger probe, and so the external reset timing must be longer than the POR timing. If external reset is de-asserted before POR release, the user must retry the procedure above until it gets connected to the device. Related Links 30. NVMCTRL – Nonvolatile Memory Controller 16.6.4 Boot Communication Channels Boot Communication Channels allow communication between a debug adapter and the CPU executing the Boot ROM at startup. The Boot ROM implements system level commands. Refer to 14. Boot ROM for more information. 16.7 Programming Programming the Flash or RAM memories is only possible when the debugger access level is sufficient to access the desired resource: If DAL is equal to: • 0x2: debugger can access secured and non-secure areas • 0x1 (SAM L11 only): debugger can access only non-secure areas, refer to Table 16-4. • 0x0: debugger can only access the DSU external address space making it possible to communicate with the Boot ROM after reset. A typical programming procedure when DAL=0x2 is as follows: 1. At power up, RESET is driven low by a debugger. The on-chip regulator holds the system in a POR state until the input supply is above the POR threshold. The system continues to be held in this static state until the internally regulated supplies have reached a safe operating state. 2. The Power Manager (PM) starts, clocks are switched to the slow clock (Core Clock, System Clock, Flash Clock and any Bus Clocks that do not have clock gate control). Internal resets are maintained due to the external reset. 3. The debugger maintains a low level on SWCLK. RESET is released, resulting in a debugger Cold-Plugging procedure. 4. The debugger generates a clock signal on the SWCLK pin, the Debug Access Port (DAP) receives a clock. 5. The CPU executes the Boot ROM. 6. It is recommended to issue a Chip-Erase (supported by the Boot ROM) to ensure that the Flash is fully erased prior to programming. 7. If the operation issued above was accepted and has completed successfully then DAL equals 0x2 thus programming is available through the AHB-AP. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 119 SAM L10/L11 Family Device Service Unit (DSU) 8. After the operation is completed, the chip can be restarted either by asserting RESET, toggling power, or sending a command to the Boot ROM to jump to the NVM code. Make sure that the SWCLK pin is high when releasing RESET to prevent entering again the cold-plugging procedure with the Boot ROM stalling the CPU. Related Links 30. NVMCTRL – Nonvolatile Memory Controller 16.8 Security Enforcement Security enforcement aims at protecting intellectual property, which includes: • Restricts access to internal memories from external tools depending on the debugger access level. • Restricts access to a portion of the DSU address space from non-secure AHB masters depending on the debugger access level. The DAL setting can be locked or reverted using Boot ROM commands depending on the Boot ROM user configuration. When DAL is equal to 0x0, read/write accesses using the AHB-AP are limited to the DSU external address range and DSU commands are restricted. When issuing a Boot ROM Chip-Erase, sensitive information is erased from volatile memory and Flash. Refer to 14. Boot ROM more information about the Boot ROM features. The DSU implements a security filter that monitors the AHB transactions generated by the ARM AHB-AP inside the DAP. If DAL=0x0, then AHB-AP read/write accesses outside the DSU external address range are discarded, causing an error response that sets the ARM AHB-AP sticky error bits (refer to the "ARM Debug Interface v5 Architecture Specification", which is available for download at www.arm.com). For security reasons, DSU features have limitations when used from a debug adapter. To differentiate external accesses from internal ones, the first 0x100 bytes of the DSU register map have been replicated at offset 0x100: • The first 0x100 bytes form the internal address range • The next 0x1F00 bytes form the external address range When the device is protected, the DAP can only issue MEM-AP accesses in the DSU address range limited to the 0x100- 0x2000 offset range. The DSU operating registers are located in the 0x00-0xFF area and mirrored to 0x100-0x1FF to differentiate accesses coming from a debugger and the CPU. If the device is protected and an access is issued in the region 0x100-0x1FF, it is subject to security restrictions. For more information, refer to the Table 16-2. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 120 SAM L10/L11 Family Device Service Unit (DSU) Figure 16-4. APB Memory Mapping 0x0000 Internal address range (cannot be accessed from debug tools when STATUSB.DALPLCFG.PLSEL=0) or Performance Level is disabled (PM->PLCFG.PLDIS=1), writing the VREFSEL bit in the VREG register to '1' selects ULPVREF as voltage reference for the main voltage regulator. Note:  The ULPVREF reference cannot be used in PL2 mode. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 309 SAM L10/L11 Family SUPC – Supply Controller 25.7 Offset Register Summary Name Bit Pos. 7 6 5 4 3 7:0 0x00 INTENCLR 15:8 23:16 31:24 7:0 0x04 INTENSET 15:8 23:16 31:24 7:0 0x08 INTFLAG 15:8 1 0 B33SRDY ULPVREFRD VCORERDY Y BOD33DET BOD33RDY B33SRDY ULPVREFRD VCORERDY Y BOD33DET B33SRDY ULPVREFRD VCORERDY Y BOD33DET 23:16 31:24 7:0 0x0C STATUS 0x10 BOD33 0x14 ... 0x17 Reserved 0x18 VREG 0x1C VREF 0x20 ... 0x2B Reserved B33SRDY ULPVREFRD Y 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 RUNSTDBY STDBYCFG PSEL[3:0] RUNSTDBY STDBYPL0 25.8 EVCTRL VREGRDY SEL[1:0] BOD33RDY VREGRDY BOD33RDY VREGRDY BOD33DET VCORERDY ACTION[1:0] HYST VREFSEL LEVEL[5:0] BOD33RDY VREGRDY ENABLE ACTCFG ENABLE VREFSEL VSVSTEP[3:0] LPEFF VSPER[7:0] ONDEMAND RUNSTDBY VREFOE TSEN SEL[3:0] BOD33DETE O 7:0 0x2C 2 15:8 23:16 31:24 Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16-, and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers are optionally write-protected by the Peripheral Access Controller (PAC). PAC Write-protection is denoted by the "PAC Write-Protection" property in each individual register description. Refer to 25.5.8 Register Access Protection for details. Some registers require synchronization when read and/or written. Synchronization is denoted by the "WriteSynchronized" or the "Read-Synchronized" property in each individual register description. Refer to 25.6.6 Synchronization for details. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 310 SAM L10/L11 Family SUPC – Supply Controller On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 311 SAM L10/L11 Family SUPC – Supply Controller 25.8.1 Interrupt Enable Clear Name:  Offset:  Reset:  Property:  INTENCLR 0x00 0x00000000 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set register (INTENSET). Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 9 8 VREGRDY Access Reset Bit Access Reset Bit Access Reset Bit 7 6 Access Reset 5 4 11 10 ULPVREFRD VCORERDY Y R/W R/W 0 0 3 2 B33SRDY R/W 0 R/W 0 1 BOD33DET R/W 0 0 BOD33RDY R/W 0 Bit 11 – ULPVREFRDY Low Power Voltage Reference Ready Interrupt Enable Writing a '0' to this bit has no effect. The ULPVREFRDY bit will clear on a zero-to-one transition of the Low Power Voltage Reference Ready bit in the Status register (STATUS.ULPVREFRDY). Value Description 0 The Low Power Ready interrupt is disabled. 1 The Low Power Ready interrupt is enabled and an interrupt request will be generated when the ULPVREFRDY Interrupt Flag is set. Bit 10 – VCORERDY VDDCORE Voltage Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the VDDCORE Ready Interrupt Enable bit, which disables the VDDCORE Ready interrupt. Value Description 0 The VDDCORE Ready interrupt is disabled. 1 The VDDCORE Ready interrupt is enabled and an interrupt request will be generated when the VCORERDY Interrupt Flag is set. Bit 8 – VREGRDY Voltage Regulator Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Voltage Regulator Ready Interrupt Enable bit, which disables the Voltage Regulator Ready interrupt. Value Description 0 The Voltage Regulator Ready interrupt is disabled. 1 The Voltage Regulator Ready interrupt is enabled and an interrupt request will be generated when the Voltage Regulator Ready Interrupt Flag is set. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 312 SAM L10/L11 Family SUPC – Supply Controller Bit 2 – B33SRDY  BOD33 Synchronization Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the BOD33 Synchronization Ready Interrupt Enable bit, which disables the BOD33 Synchronization Ready interrupt. Value Description 0 The BOD33 Synchronization Ready interrupt is disabled. 1 The BOD33 Synchronization Ready interrupt is enabled, and an interrupt request will be generated when the BOD33 Synchronization Ready Interrupt flag is set. Bit 1 – BOD33DET  BOD33 Detection Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the BOD33 Detection Interrupt Enable bit, which disables the BOD33 Detection interrupt. Value Description 0 The BOD33 Detection interrupt is disabled. 1 The BOD33 Detection interrupt is enabled, and an interrupt request will be generated when the BOD33 Detection Interrupt flag is set. Bit 0 – BOD33RDY  BOD33 Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the BOD33 Ready Interrupt Enable bit, which disables the BOD33 Ready interrupt. Value Description 0 The BOD33 Ready interrupt is disabled. 1 The BOD33 Ready interrupt is enabled, and an interrupt request will be generated when the BOD33 Ready Interrupt flag is set. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 313 SAM L10/L11 Family SUPC – Supply Controller 25.8.2 Interrupt Enable Set Name:  Offset:  Reset:  Property:  INTENSET 0x04 0x00000000 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear register (INTENCLR). Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 9 8 VREGRDY Access Reset Bit Access Reset Bit Access Reset Bit 7 6 Access Reset 5 4 11 10 ULPVREFRD VCORERDY Y R/W R/W 0 0 3 2 B33SRDY R/W 0 R/W 0 1 BOD33DET R/W 0 0 BOD33RDY R/W 0 Bit 11 – ULPVREFRDY Low Power Voltage Reference Ready Interrupt Enable Writing a '0' to this bit has no effect. The ULPVREFRDY bit is set on a zero-to-one transition of the Low Power Voltage Reference Ready bit in the Status register (STATUS.ULPVREFRDY). Value Description 0 The Low Power Ready interrupt is disabled. 1 The Low Power Ready interrupt is enabled and an interrupt request will be generated when the ULPVREFRDY Interrupt Flag is set. Bit 10 – VCORERDY VDDCORE Voltage Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the VDDCORE Ready Interrupt Enable bit, which enables the VDDCORE Ready interrupt. Value Description 0 The VDDCORE Ready interrupt is disabled. 1 The VDDCORE Ready interrupt is enabled and an interrupt request will be generated when the VCORERDY Interrupt Flag is set. Bit 8 – VREGRDY Voltage Regulator Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Voltage Regulator Ready Interrupt Enable bit, which enables the Voltage Regulator Ready interrupt. Value Description 0 The Voltage Regulator Ready interrupt is disabled. 1 The Voltage Regulator Ready interrupt is enabled and an interrupt request will be generated when the Voltage Regulator Ready Interrupt Flag is set. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 314 SAM L10/L11 Family SUPC – Supply Controller Bit 2 – B33SRDY  BOD33 Synchronization Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the BOD33 Synchronization Ready Interrupt Enable bit, which enables the BOD33 Synchronization Ready interrupt. Value Description 0 The BOD33 Synchronization Ready interrupt is disabled. 1 The BOD33 Synchronization Ready interrupt is enabled, and an interrupt request will be generated when the BOD33 Synchronization Ready Interrupt flag is set. Bit 1 – BOD33DET  BOD33 Detection Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the BOD33 Detection Interrupt Enable bit, which enables the BOD33 Detection interrupt. Value Description 0 The BOD33 Detection interrupt is disabled. 1 The BOD33 Detection interrupt is enabled, and an interrupt request will be generated when the BOD33 Detection Interrupt flag is set. Bit 0 – BOD33RDY  BOD33 Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the BOD33 Ready Interrupt Enable bit, which enables the BOD33 Ready interrupt. Value Description 0 The BOD33 Ready interrupt is disabled. 1 The BOD33 Ready interrupt is enabled, and an interrupt request will be generated when the BOD33 Ready Interrupt flag is set. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 315 SAM L10/L11 Family SUPC – Supply Controller 25.8.3 Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  Bit INTFLAG 0x08 x initially determined from NVM User Row after reset - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 9 8 VREGRDY Access Reset Bit Access Reset Bit Access Reset Bit 7 6 Access Reset 5 4 11 10 ULPVREFRD VCORERDY Y R/W R/W 0 0 3 2 B33SRDY R/W 0 R/W 1 1 BOD33DET R/W 0 0 BOD33RDY R/W x Bit 11 – ULPVREFRDY Low Power Voltage Reference Ready Interrupt Enable Writing a '0' to this bit has no effect. The ULPVREFRDY bit will clear on a zero-to-one transition of the Low Power Voltage Reference Ready bit in the Status register (STATUS.ULPVREFRDY) and will generate an interrupt request if INTENSET.ULPVREFRDY=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the ULPVREFRDY interrupt flag. Bit 10 – VCORERDY VDDCORE Voltage Ready This flag is cleared by writing a '1 to it. This flag is set on a zero-to-one transition of the VDDCORE Ready bit in the Status register (STATUS.VCORERDY) and will generate an interrupt request if INTENSET.VCORERDY=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the VCORERDY interrupt flag. Bit 8 – VREGRDY Voltage Regulator Ready This flag is cleared by writing a '1' to it. This flag is set on a zero-to-one transition of the Voltage Regulator Ready bit in the Status register (STATUS.VREGRDY) and will generate an interrupt request if INTENSET.VREGRDY=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the VREGRDY interrupt flag. Bit 2 – B33SRDY  BOD33 Synchronization Ready This flag is cleared by writing a '1' to it. This flag is set on a zero-to-one transition of the BOD33 Synchronization Ready bit in the Status register (STATUS.B33SRDY) and will generate an interrupt request if INTENSET.B33SRDY=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the BOD33 Synchronization Ready interrupt flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 316 SAM L10/L11 Family SUPC – Supply Controller Bit 1 – BOD33DET  BOD33 Detection This flag is cleared by writing a '1' to it. This flag is set on a zero-to-one transition of the BOD33 Detection bit in the Status register (STATUS.BOD33DET) and will generate an interrupt request if INTENSET.BOD33DET=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the BOD33 Detection interrupt flag. Bit 0 – BOD33RDY  BOD33 Ready This flag is cleared by writing a '1' to it. This flag is set on a zero-to-one transition of the BOD33 Ready bit in the Status register (STATUS.BOD33RDY) and will generate an interrupt request if INTENSET.BOD33RDY=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the BOD33 Ready interrupt flag. The BOD33 can be enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 317 SAM L10/L11 Family SUPC – Supply Controller 25.8.4 Status Name:  Offset:  Reset:  Property:  Bit STATUS 0x0C x,y initially determined from NVM User Row after reset - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 ULPVREFRD Y R x 11 10 VCORERDY 9 8 VREGRDY 4 3 Access Reset Bit Access Reset Bit Access Reset Bit 7 6 5 R 1 Access Reset 2 B33SRDY R 0 R 1 1 BOD33DET R 0 0 BOD33RDY R y Bit 12 – ULPVREFRDY Low Power Voltage Reference Ready Value Description 0 The ULPVREF voltage is not as expected. 1 The ULPVREF voltage is the target voltage. Bit 10 – VCORERDY VDDCORE Voltage Ready Value Description 0 The VDDCORE voltage is not as expected. 1 The VDDCORE voltage is the target voltage. Bit 8 – VREGRDY Voltage Regulator Ready Value Description 0 The selected voltage regulator in VREG.SEL is not ready. 1 The voltage regulator selected in VREG.SEL is ready and the core domain is supplied by this voltage regulator. Bit 2 – B33SRDY  BOD33 Synchronization Ready Value Description 0 BOD33 synchronization is ongoing. 1 BOD33 synchronization is complete. Bit 1 – BOD33DET  BOD33 Detection Value Description 0 No BOD33 detection. 1 BOD33 has detected that the I/O power supply is going below the BOD33 reference value. Bit 0 – BOD33RDY  BOD33 Ready The BOD33 can be enabled at start-up from NVM User Row. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 318 SAM L10/L11 Family SUPC – Supply Controller Value 0 1 Description BOD33 is not ready. BOD33 is ready. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 319 SAM L10/L11 Family SUPC – Supply Controller 25.8.5 3.3V Brown-Out Detector (BOD33) Control Name:  Offset:  Reset:  Property:  Bit BOD33 0x10 x initially determined from NVM User Row after reset Write-Synchronized, Enable-Protected, PAC Write-Protection 31 30 29 28 27 23 22 21 20 19 R/W x R/W x 26 25 24 17 16 R/W x R/W x 10 9 8 ACTCFG R/W 0 2 HYST R/W x 1 ENABLE R/W x 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 15 R/W 0 7 14 13 PSEL[3:0] R/W R/W 0 0 6 5 RUNSTDBY STDBYCFG R/W R/W 0 0 12 R/W 0 18 LEVEL[5:0] R/W R/W x x 11 VREFSEL R/W 0 4 3 ACTION[1:0] R/W R/W x x Bits 21:16 – LEVEL[5:0]  BOD33 Threshold Level on VDD These bits set the triggering voltage threshold for the BOD33 when the BOD33 monitors the VDD. These bits are loaded from NVM User Row at start-up. This bit field is not synchronized. Bits 15:12 – PSEL[3:0] Prescaler Select Selects the prescaler divide-by output for the BOD33 sampling mode. The input clock comes from the OSCULP32K 1 KHz output. This bit field is not synchronized. Value Name Description 0x0 DIV2 Divide clock by 2 0x1 DIV4 Divide clock by 4 0x2 DIV8 Divide clock by 8 0x3 DIV16 Divide clock by 16 0x4 DIV32 Divide clock by 32 0x5 DIV64 Divide clock by 64 0x6 DIV128 Divide clock by 128 0x7 DIV256 Divide clock by 256 0x8 DIV512 Divide clock by 512 0x9 DIV1024 Divide clock by 1024 0xA DIV2048 Divide clock by 2048 0xB DIV4096 Divide clock by 4096 0xC DIV8192 Divide clock by 8192 0xD DIV16384 Divide clock by 16384 0xE DIV32768 Divide clock by 32768 0xF DIV65536 Divide clock by 65536 Bit 11 – VREFSEL  BOD33 Voltage Reference Selection This bit is not synchronized. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 320 SAM L10/L11 Family SUPC – Supply Controller Value 0 1 Description Selects VREF for the BOD33. Selects ULPVREF for the BOD33. Bit 8 – ACTCFG  BOD33 Configuration in Active Sleep Mode This bit is not synchronized. Value Description 0 In active mode, the BOD33 operates in continuous mode. 1 In active mode, the BOD33 operates in sampling mode. Bit 6 – RUNSTDBY Run in Standby This bit is not synchronized. Value Description 0 In standby sleep mode, the BOD33 is disabled. 1 In standby sleep mode, the BOD33 is enabled. Bit 5 – STDBYCFG  BOD33 Configuration in Standby Sleep Mode If the RUNSTDBY bit is set to '1', the STDBYCFG bit sets the BOD33 configuration in standby sleep mode. This bit is not synchronized. Value Description 0 In standby sleep mode, the BOD33 is enabled and configured in continuous mode. 1 In standby sleep mode, the BOD33 is enabled and configured in sampling mode. Bits 4:3 – ACTION[1:0]  BOD33 Action These bits are used to select the BOD33 action when the supply voltage crosses below the BOD33 threshold. These bits are loaded from NVM User Row at start-up. This bit field is not synchronized. Value Name 0x0 0x1 0x2 0x3 NONE RESET INT - Description No action The BOD33 generates a reset The BOD33 generates an interrupt Reserved Bit 2 – HYST Hysteresis This bit indicates whether hysteresis is enabled for the BOD33 threshold voltage. This bit is loaded from NVM User Row at start-up. This bit is not synchronized. Value Description 0 No hysteresis. 1 Hysteresis enabled. Bit 1 – ENABLE Enable This bit is loaded from NVM User Row at start-up. This bit is not enable-protected. Value Description 0 BOD33 is disabled. 1 BOD33 is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 321 SAM L10/L11 Family SUPC – Supply Controller 25.8.6 Voltage Regulator System (VREG) Control Name:  Offset:  Reset:  Property:  Bit Access Reset Bit VREG 0x18 0x00000002 PAC Write-Protection 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 28 27 VSPER[7:0] R/W R/W 0 0 20 Access Reset Bit 19 14 13 12 11 7 6 RUNSTDBY R/W 0 5 STDBYPL0 R/W 1 4 3 25 24 R/W 0 R/W 0 R/W 0 18 17 VSVSTEP[3:0] R/W R/W 0 0 R/W 0 15 26 Access Reset 9 VREFSEL R/W 0 8 LPEFF R/W 0 2 1 ENABLE R/W 1 0 SEL[1:0] R/W 0 R/W 0 10 Access Reset Bit 16 R/W 0 Bits 31:24 – VSPER[7:0] Voltage Scaling Period This bitfield sets the period between the voltage steps when the VDDCORE voltage is changing in µs. If VSPER=0, the period between two voltage steps is 1µs. Bits 19:16 – VSVSTEP[3:0] Voltage Scaling Voltage Step This field sets the voltage step height when the VDDCORE voltage is changing to reach the target VDDCORE voltage. The voltage step is equal to 2VSVSTEP* min_step. See the Electrical Characteristics chapters for the min_step voltage level. Bit 9 – VREFSEL Voltage Regulator Voltage Reference Selection This bit provides support of using ULPVREF during active function mode. Value Description 0 Selects VREF for the voltage regulator. 1 Selects ULPVREF for the voltage regulator. Bit 8 – LPEFF Low power Mode Efficiency Value Description 0 The voltage regulator in Low power mode has the default efficiency and supports the whole VDD range (1.62V to 3.63V). 1 The voltage regulator in Low power mode has the highest efficiency and supports a limited VDD range (2.5V to 3.63V). Bit 6 – RUNSTDBY Run in Standby Value Description 0 The voltage regulator is in low power mode in Standby sleep mode. 1 The voltage regulator is in normal mode in Standby sleep mode. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 322 SAM L10/L11 Family SUPC – Supply Controller Bit 5 – STDBYPL0 Standby in PL0 This bit selects the performance level (PL) of the main voltage regulator for the Standby sleep mode. This bit is only considered when RUNSTDBY=1. Value Description 0 In Standby sleep mode, the voltage regulator remains in the current performance level. 1 In Standby sleep mode, the voltage regulator is used in PL0. Bits 3:2 – SEL[1:0] Voltage Regulator Selection Value Description 0 The voltage regulator in active mode is a LDO voltage regulator. 1 The voltage regulator in active mode is a buck converter. 2-3 Reserved Bit 1 – ENABLE Must Be Set to 1. Bit 1 must always be set to ‘1’ when programming the VREG register. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 323 SAM L10/L11 Family SUPC – Supply Controller 25.8.7 Voltage References System (VREF) Control Name:  Offset:  Reset:  Property:  Bit VREF 0x1C 0x00000000 PAC Write-Protection 31 30 29 28 27 26 23 22 21 20 19 18 25 24 17 16 Access Reset Bit SEL[3:0] Access Reset Bit 15 14 R/W 0 R/W 0 R/W 0 R/W 0 13 12 11 10 9 8 5 4 3 2 VREFOE R/W 0 1 TSEN R/W 0 0 Access Reset Bit 7 6 ONDEMAND RUNSTDBY Access R/W R/W Reset 0 0 Bits 19:16 – SEL[3:0] Voltage Reference Selection These bits select the Voltage Reference for the ADC/DAC. Value Name Description 0x0 1V0 1.0V voltage reference typical value 0x1 1V1 1.1V voltage reference typical valueThe 1.1V voltage reference typical value must be selected for DAC use. Other values are not permitted. 0x2 1V2 1.2V voltage reference typical value 0x3 1V25 1.25V voltage reference typical value 0x4 2V0 2.0V voltage reference typical value 0x5 2V2 2.2V voltage reference typical value 0x6 2V4 2.4V voltage reference typical value 0x7 2V5 2.5V voltage reference typical value Others Reserved Bit 7 – ONDEMAND On Demand Control The On Demand operation mode allows to enable or disable the voltage reference depending on peripheral requests. Value Description 0 The voltage reference is always on, if enabled. 1 The voltage reference is enabled when a peripheral is requesting it. The voltage reference is disabled if no peripheral is requesting it. Bit 6 – RUNSTDBY Run In Standby The bit controls how the voltage reference behaves during standby sleep mode. Value Description 0 The voltage reference is halted during standby sleep mode. 1 The voltage reference is not stopped in standby sleep mode. If VREF.ONDEMAND=1, the voltage reference will be running when a peripheral is requesting it. If VREF.ONDEMAND=0, the voltage reference will always be running in standby sleep mode. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 324 SAM L10/L11 Family SUPC – Supply Controller Bit 2 – VREFOE Voltage Reference Output Enable Value Description 0 The Voltage Reference output (INTREF) is not available as an ADC input channel. 1 The Voltage Reference output (INTREF) is routed to an ADC input channel. Bit 1 – TSEN Temperature Sensor Enable Value Description 0 Temperature Sensor is disabled. 1 Temperature Sensor is enabled and routed to an ADC input channel. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 325 SAM L10/L11 Family SUPC – Supply Controller 25.8.8 Event Control Name:  Offset:  Reset:  Property:  EVCTRL 0x2C 0x0000000 Enable-Protected, PAC Write-Protection As long as BOD33.ENABLE=1, any writes to this register will be discarded, and an APB error will be generated. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 BOD33DETE O R/W 0 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 1 – BOD33DETEO BOD33 Detection Event Output Enable Value Description 0 BOD33 detection event output is disabled and event will not be generated 1 BOD33 detection event output is enabled and event will be generated © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 326 SAM L10/L11 Family WDT – Watchdog Timer 26. WDT – Watchdog Timer 26.1 Overview The Watchdog Timer (WDT) is a system function for monitoring correct program operation. It makes it possible to recover from error situations such as runaway or deadlocked code. The WDT is configured to a predefined time-out period, and is constantly running when enabled. If the WDT is not cleared within the time-out period, it will issue a system reset. An early-warning interrupt is available to indicate an upcoming watchdog time-out condition. The window mode makes it possible to define a time slot (or window) inside the total time-out period during which the WDT must be cleared. If the WDT is cleared outside this window, either too early or too late, a system reset will be issued. Compared to the normal mode, this can also catch situations where a code error causes the WDT to be cleared frequently. When enabled, the WDT will run in active mode and all sleep modes. It is asynchronous and runs from a CPUindependent clock source. The WDT will continue operation and issue a system reset or interrupt even if the main clocks fail. 26.2 Features • • • • • • 26.3 Issues a system reset if the Watchdog Timer is not cleared before its time-out period Early Warning interrupt generation Asynchronous operation from dedicated oscillator Two types of operation – Normal – Window mode Selectable time-out periods – From 8 cycles to 16,384 cycles in Normal mode – From 16 cycles to 32,768 cycles in Window mode Always-On capability Block Diagram Figure 26-1. WDT Block Diagram 0xA5 0 CLEAR OSC32KCTRL CLK_WDT_OSC COUNT PER/WINDOWS/EWOFFSET Early Warning Interrupt Reset © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 327 SAM L10/L11 Family WDT – Watchdog Timer 26.4 Signal Description Not applicable. 26.5 Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described below. 26.5.1 I/O Lines Not applicable. 26.5.2 Power Management The WDT can continue to operate in any sleep modes where the selected source clock is running. The WDT interrupts can be used to wake up the device from sleep modes. The events can trigger other operations in the system without exiting sleep modes. Related Links 22. PM – Power Manager 26.5.3 Clocks The WDT bus clock (CLK_WDT_APB) can be enabled and disabled (masked) in the Main Clock module (MCLK). A 1.024 kHz oscillator clock (CLK_WDT_OSC) is required to clock the WDT internal counter. The CLK_WDT_OSC CLOCK is sourced from the clock of the internal Ultra Low-Power Oscillator (OSCULP32K). Due to ultra low-power design, the oscillator is not accurate, hence the exact time-out period may vary from deviceto-device. This variation must be considered when designing software that uses the WDT to ensure that the time-out periods used are valid for all devices. The counter clock CLK_WDT_OSC is asynchronous to the bus clock (CLK_WDT_APB). Due to this asynchronicity, writing to certain registers will require synchronization between the clock domains. Refer to 26.6.7 Synchronization for further details. Related Links 19.6.2.6 Peripheral Clock Masking 24. OSC32KCTRL – 32KHz Oscillators Controller 26.5.4 DMA Not applicable. 26.5.5 Interrupts The interrupt request line is connected to the interrupt controller. Using the WDT interrupt(s) requires the interrupt controller to be configured first. 26.5.6 Events Not applicable. 26.5.7 Debug Operation When the CPU is halted in debug mode the WDT will halt normal operation. 26.5.8 Register Access Protection All registers with write-access can be write-protected optionally by the Peripheral Access Controller (PAC), except for the following registers: • • Interrupt Flag Status and Clear (INTFLAG) register Clear register (CLEAR) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 328 SAM L10/L11 Family WDT – Watchdog Timer Optional write-protection by the Peripheral Access Controller (PAC) is denoted by the "PAC Write-Protection" property in each individual register description. PAC write-protection does not apply to accesses through an external debugger. 26.5.9 SAM L11 TrustZone-Specific Register Access Protection On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. 26.5.10 Analog Connections Not applicable. 26.6 Functional Description 26.6.1 Principle of Operation The Watchdog Timer (WDT) is a system for monitoring correct program operation, making it possible to recover from error situations such as runaway code, by issuing a Reset. When enabled, the WDT is a constantly running timer that is configured to a predefined time-out period. Before the end of the time-out period, the WDT should be set back, or else, a system Reset is issued. The WDT has two modes of operation, Normal mode and Window mode. Both modes offer the option of Early Warning interrupt generation. The description for each of the basic modes is given below. The settings in the Control A register (CTRLA) and the Interrupt Enable register (handled by INTENCLR/INTENSET) determine the mode of operation: Table 26-1. WDT Operating Modes 26.6.2 CTRLA.ENABLE CTRLA.WEN Interrupt Enable Mode 0 x x Stopped 1 0 0 Normal mode 1 0 1 Normal mode with Early Warning interrupt 1 1 0 Window mode 1 1 1 Window mode with Early Warning interrupt Basic Operation 26.6.2.1 Initialization The following bits are enable-protected, meaning that they can only be written when the WDT is disabled (CTRLA.ENABLE=0): • • • Control A register (CTRLA), except the Enable bit (CTRLA.ENABLE) and Always-On bit (CTRLA.ALWAYSON) Configuration register (CONFIG) Early Warning Interrupt Control register (EWCTRL) Enable-protected bits in the CTRLA register can be written at the same time as CTRLA.ENABLE is written to '1', but not at the same time as CTRLA.ENABLE is written to '0'. The WDT can be configured only while the WDT is disabled. The WDT is configured by defining the required TimeOut Period bits in the Configuration register (CONFIG.PER). If Window mode operation is desired, the Window © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 329 SAM L10/L11 Family WDT – Watchdog Timer Enable bit in the Control A register must be set (CTRLA.WEN=1) and the Window Period bits in the Configuration register (CONFIG.WINDOW) must be defined. Enable-protection is denoted by the "Enable-Protected" property in the register description. 26.6.2.2 Configurable Reset Values After a Power-on Reset, some registers will be loaded with initial values from the NVM User Row. This includes the following bits and bit groups: • • • • • • • Enable bit in the Control A register, CTRLA.ENABLE Always-On bit in the Control A register, CTRLA.ALWAYSON Run In Standby Enable bit in the Control A register (CTRLA.RUNSTDBY) Watchdog Timer Windows Mode Enable bit in the Control A register, CTRLA.WEN Watchdog Timer Windows Mode Time-Out Period bits in the Configuration register, CONFIG.WINDOW Time-Out Period bits in the Configuration register, CONFIG.PER Early Warning Interrupt Time Offset bits in the Early Warning Interrupt Control register, EWCTRL.EWOFFSET 26.6.2.3 Enabling, Disabling, and Resetting The WDT is enabled by writing a '1' to the Enable bit in the Control A register (CTRLA.ENABLE). The WDT is disabled by writing a '0' to CTRLA.ENABLE. The WDT can be disabled only if the Always-On bit in the Control A register (CTRLA.ALWAYSON) is '0'. 26.6.2.4 Normal Mode In Normal mode operation, the length of a time-out period is configured in CONFIG.PER. The WDT is enabled by writing a '1' to the Enable bit in the Control A register (CTRLA.ENABLE). Once enabled, the WDT will issue a system reset if a time-out occurs. This can be prevented by clearing the WDT at any time during the time-out period. The WDT is cleared and a new WDT time-out period is started by writing 0xA5 to the Clear register (CLEAR). Writing any other value than 0xA5 to CLEAR will issue an immediate system reset. There are 12 possible WDT time-out (TOWDT) periods, selectable from 8ms to 16s. By default, the early warning interrupt is disabled. If it is desired, the Early Warning Interrupt Enable bit in the Interrupt Enable register (INTENSET.EW) must be written to '1'. The Early Warning Interrupt is disabled again by writing a '1' to the Early Warning Interrupt bit in the Interrupt Enable Clear register (INTENCLR.EW). If the Early Warning Interrupt is enabled, an interrupt is generated prior to a WDT time-out condition. In Normal mode, the Early Warning Offset bits in the Early Warning Interrupt Control register, EWCTRL.EWOFFSET, define the time when the early warning interrupt occurs. The Normal mode operation is illustrated in the figure Normal-Mode Operation. Figure 26-2. Normal-Mode Operation WDT Count Timely WDT Clear PER[3:0] = 1 WDT Timeout System Reset EWOFFSET[3:0] = 0 Early Warning Interrupt t[ms] 5 10 15 20 25 30 35 TOWDT 26.6.2.5 Window Mode In Window mode operation, the WDT uses two different time specifications: the WDT can only be cleared by writing 0xA5 to the CLEAR register after the closed window time-out period (TOWDTW), during the subsequent Normal timeout period (TOWDT). If the WDT is cleared before the time window opens (before TOWDTW is over), the WDT will issue a system reset. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 330 SAM L10/L11 Family WDT – Watchdog Timer Both parameters TOWDTW and TOWDT are periods in a range from 8ms to 16s, so the total duration of the WDT timeout period is the sum of the two parameters. The closed window period is defined by the Window Period bits in the Configuration register (CONFIG.WINDOW), and the open window period is defined by the Period bits in the Configuration register (CONFIG.PER). By default, the Early Warning interrupt is disabled. If it is desired, the Early Warning Interrupt Enable bit in the Interrupt Enable register (INTENSET.EW) must be written to '1'. The Early Warning Interrupt is disabled again by writing a '1' to the Early Warning Interrupt bit in the Interrupt Enable Clear (INTENCLR.EW) register. If the Early Warning interrupt is enabled in Window mode, the interrupt is generated at the start of the open window period, i.e. after TOWDTW. The Window mode operation is illustrated in figure Window-Mode Operation. Figure 26-3. Window-Mode Operation WDT Count Timely WDT Clear PER[3:0] = 0 Open WDT Timeout Early WDT Clear WINDOW[3:0] = 0 Closed Early Warning Interrupt System Reset t[ms] 5 10 15 20 TOWDTW 26.6.3 25 30 35 TOWDT DMA Operation Not applicable. 26.6.4 Interrupts The WDT has the following interrupt source: • Early Warning (EW): Indicates that the counter is approaching the time-out condition. – This interrupt is an asynchronous wake-up source. Each interrupt source has an interrupt flag associated with it. The interrupt flag in the Interrupt Flag Status and Clear (INTFLAG) register is set when the interrupt condition occurs. Each interrupt can be individually enabled by writing a '1' to the corresponding bit in the Interrupt Enable Set (INTENSET) register, and disabled by writing a '1' to the corresponding bit in the Interrupt Enable Clear (INTENCLR) register. An interrupt request is generated when the interrupt flag is set and the corresponding interrupt is enabled. The interrupt request remains active until the interrupt flag is cleared, the interrupt is disabled, or the WDT is reset. See the 26.8.6 INTFLAG register description for details on how to clear interrupt flags. All interrupt requests from the peripheral are ORed together on system level to generate one combined interrupt request to the NVIC. The user must read the INTFLAG register to determine which interrupt condition is present. Note:  Interrupts must be globally enabled for interrupt requests to be generated. Related Links 22. PM – Power Manager 22.6.3.3 Sleep Mode Controller 26.6.5 Events Not applicable. 26.6.6 Sleep Mode Operation The Run-In-Standby bit in Control A (CTRLA.RUNSTDBY) control the behavior of the WDT during standby sleep mode. When the bit is zero, the watchdog is disabled during sleep, but maintains its current configuration. When CTRLA.RUNSTDBY is '1', the WDT continues to operate during sleep. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 331 SAM L10/L11 Family WDT – Watchdog Timer Related Links 26.8.1 CTRLA 26.6.7 Synchronization Due to asynchronicity between the main clock domain and the peripheral clock domains, some registers need to be synchronized when written or read. The following registers are synchronized when written: • • Watchdog Control A register (CTRLA) Watchdog Clear register (CLEAR) Required write-synchronization is denoted by the "Write-Synchronized" property in the register description. Required read-synchronization is denoted by the "Read-Synchronized" property in the register description. 26.6.8 Additional Features 26.6.8.1 Always-On Mode The Always-On mode is enabled by setting the Always-On bit in the Control A register (CTRLA.ALWAYSON=1). When the Always-On mode is enabled, the WDT runs continuously, regardless of the state of CTRLA.ENABLE. Once written, the Always-On bit can only be cleared by a power-on reset. The Configuration (CONFIG) and Early Warning Control (EWCTRL) registers are read-only registers while the CTRLA.ALWAYSON bit is set. Thus, the time period configuration bits (CONFIG.PER, CONFIG.WINDOW, EWCTRL.EWOFFSET) of the WDT cannot be changed. Enabling or disabling Window mode operation by writing the Window Enable bit (CTRLA.WEN) is allowed while in Always-On mode, but note that CONFIG.PER cannot be changed. The Interrupt Clear and Interrupt Set registers are accessible in the Always-On mode. The Early Warning interrupt can still be enabled or disabled while in the Always-On mode, but note that EWCTRL.EWOFFSET cannot be changed. Table WDT Operating Modes With Always-On shows the operation of the WDT for CTRLA.ALWAYSON=1. Table 26-2. WDT Operating Modes With Always-On WEN Interrupt Enable Mode 0 0 Always-on and normal mode 0 1 Always-on and normal mode with Early Warning interrupt 1 0 Always-on and window mode 1 1 Always-on and window mode with Early Warning interrupt 26.6.8.2 Early Warning The Early Warning interrupt notifies that the WDT is approaching its time-out condition. The Early Warning interrupt behaves differently in Normal mode and in Window mode. In Normal mode, the Early Warning interrupt generation is defined by the Early Warning Offset in the Early Warning Control register (EWCTRL.EWOFFSET). The Early Warning Offset bits define the number of CLK_WDT_OSC clocks before the interrupt is generated, relative to the start of the watchdog time-out period. The user must take caution when programming the Early Warning Offset bits. If these bits define an Early Warning interrupt generation time greater than the watchdog time-out period, the watchdog time-out system reset is generated prior to the Early Warning interrupt. Consequently, the Early Warning interrupt will never be generated. In window mode, the Early Warning interrupt is generated at the start of the open window period. In a typical application where the system is in sleep mode, the Early Warning interrupt can be used to wake up and clear the Watchdog Timer, after which the system can perform other tasks or return to sleep mode. If the WDT is operating in Normal mode with CONFIG.PER = 0x2 and EWCTRL.EWOFFSET = 0x1, the Early Warning interrupt is generated 16 CLK_WDT_OSC clock cycles after the start of the © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 332 SAM L10/L11 Family WDT – Watchdog Timer time-out period. The time-out system reset is generated 32 CLK_WDT_OSC clock cycles after the start of the watchdog time-out period. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 333 SAM L10/L11 Family WDT – Watchdog Timer 26.7 Register Summary Offset Name Bit Pos. 7 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 CTRLA CONFIG EWCTRL Reserved INTENCLR INTENSET INTFLAG Reserved 7:0 7:0 7:0 ALWAYSON 0x08 SYNCBUSY 0x0C CLEAR 26.8 6 5 4 3 RUNSTDBY WINDOW[3:0] 2 1 WEN ENABLE PER[3:0] EWOFFSET[3:0] 7:0 7:0 7:0 7:0 15:8 23:16 31:24 7:0 0 EW EW EW CLEAR ALWAYSON RUNSTDBY WEN ENABLE CLEAR[7:0] Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16- and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers are optionally write-protected by the Peripheral Access Controller (PAC). Optional PAC writeprotection is denoted by the "PAC Write-Protection" property in each individual register description. For details, refer to 26.5.8 Register Access Protection. Some registers are synchronized when read and/or written. Synchronization is denoted by the "Write-Synchronized" or the "Read-Synchronized" property in each individual register description. For details, refer to 26.6.7 Synchronization. Some registers are enable-protected, meaning they can only be written when the peripheral is disabled. Enableprotection is denoted by the "Enable-Protected" property in each individual register description. On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 334 SAM L10/L11 Family WDT – Watchdog Timer 26.8.1 Control A Name:  Offset:  Reset:  Property:  CTRLA 0x00 x initially determined from NVM User Row after reset PAC Write-Protection, Write-Synchronized, Enable-Protected Bit 7 6 ALWAYSON RUNSTDBY Access R/W R/W Reset x x 5 4 3 2 WEN R/W x 1 ENABLE R/W x 0 Bit 7 – ALWAYSON Always-On This bit allows the WDT to run continuously. After being set, this bit cannot be written to '0', and the WDT will remain enabled until a power-on Reset is received. When this bit is '1', the Control A register (CTRLA), the Configuration register (CONFIG) and the Early Warning Control register (EWCTRL) will be read-only, and any writes to these registers are not allowed. Writing a '0' to this bit has no effect. This bit is not Enable-Protected. This bit is loaded from NVM User Row at start-up. Value Description 0 The WDT is enabled and disabled through the ENABLE bit. 1 The WDT is enabled and can only be disabled by a power-on reset (POR). Bit 6 – RUNSTDBY Run in Standby This bit controls the behavior of the watchdog during standby sleep mode. This bit can only be written when CTRLA.ENABLE is zero or CTRLA.ALWAYSON is one: • When CTRLA.ALWAYSON=0, this bit is enable-protected by CTRLA.ENABLE. • When CTRLA.ALWAYSON=1, this bit is not enable-protected by CTRLA.ENABLE. These bits are loaded from NVM User Row at startup. Value Description 0 The WDT is disabled during standby sleep. 1 The WDT is enabled continues to operate during standby sleep. Bit 2 – WEN Watchdog Timer Window Mode Enable This bit enables Window mode. It can only be written if the peripheral is disabled unless CTRLA.ALWAYSON=1. The initial value of this bit is loaded from Flash Calibration. This bit is loaded from NVM User Row at startup. Value Description 0 Window mode is disabled (normal operation). 1 Window mode is enabled. Bit 1 – ENABLE Enable This bit enables or disables the WDT. It can only be written if CTRLA.ALWAYSON=0. Due to synchronization, there is delay between writing CTRLA.ENABLE until the peripheral is enabled/disabled. The value written to CTRLA.ENABLE will read back immediately, and the Enable bit in the Synchronization Busy register (SYNCBUSY.ENABLE) will be set. SYNCBUSY.ENABLE will be cleared when the operation is complete. This bit is not Enable-Protected. This bit is loaded from NVM User Row at startup. Value Description 0 The WDT is disabled. 1 The WDT is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 335 SAM L10/L11 Family WDT – Watchdog Timer 26.8.2 Configuration Name:  Offset:  Reset:  Property:  Bit Access Reset 7 R/W x CONFIG 0x01 x initially determined from NVM User Row after reset PAC Write-Protection, Enable-Protected 6 5 WINDOW[3:0] R/W R/W x x 4 3 2 1 0 R/W x R/W x PER[3:0] R/W x R/W x R/W x Bits 7:4 – WINDOW[3:0] Window Mode Time-Out Period In Window mode, these bits determine the watchdog closed window period as a number of cycles of the 1.024kHz CLK_WDT_OSC clock. These bits are loaded from NVM User Row at start-up. Value Name Description 0x0 CYC8 8 clock cycles 0x1 CYC16 16 clock cycles 0x2 CYC32 32 clock cycles 0x3 CYC64 64 clock cycles 0x4 CYC128 128 clock cycles 0x5 CYC256 256 clock cycles 0x6 CYC512 512 clock cycles 0x7 CYC1024 1024 clock cycles 0x8 CYC2048 2048 clock cycles 0x9 CYC4096 4096 clock cycles 0xA CYC8192 8192 clock cycles 0xB CYC16384 16384 clock cycles 0xC-0xF Reserved Reserved Bits 3:0 – PER[3:0]  Time-Out Period These bits determine the watchdog time-out period as a number of 1.024kHz CLK_WDTOSC clock cycles. In Window mode operation, these bits define the open window period. These bits are loaded from NVM User Row at startup. Value Name Description 0x0 CYC8 8 clock cycles 0x1 CYC16 16 clock cycles 0x2 CYC32 32 clock cycles 0x3 CYC64 64 clock cycles 0x4 CYC128 128 clock cycles 0x5 CYC256 256 clock cycles 0x6 CYC512 512 clock cycles 0x7 CYC1024 1024 clock cycles 0x8 CYC2048 2048 clock cycles 0x9 CYC4096 4096 clock cycles 0xA CYC8192 8192 clock cycles 0xB CYC16384 16384 clock cycles 0xC Reserved 0xF © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 336 SAM L10/L11 Family WDT – Watchdog Timer 26.8.3 Early Warning Control Name:  Offset:  Reset:  Property:  Bit 7 EWCTRL 0x02 x initially determined from NVM User Row after reset PAC Write-Protection, Enable-Protected 6 Access Reset 5 4 3 R/W x 2 1 EWOFFSET[3:0] R/W R/W x x 0 R/W x Bits 3:0 – EWOFFSET[3:0] Early Warning Interrupt Time Offset These bits determine the number of GCLK_WDT clock cycles between the start of the watchdog time-out period and the generation of the Early Warning interrupt. These bits are loaded from NVM User Row at start-up. Value Name Description 0x0 CYC8 8 clock cycles 0x1 CYC16 16 clock cycles 0x2 CYC32 32 clock cycles 0x3 CYC64 64 clock cycles 0x4 CYC128 128 clock cycles 0x5 CYC256 256 clock cycles 0x6 CYC512 512 clock cycles 0x7 CYC1024 1024 clock cycles 0x8 CYC2048 2048 clock cycles 0x9 CYC4096 4096 clock cycles 0xA CYC8192 8192 clock cycles 0xB Reserved Reserved 0xF © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 337 SAM L10/L11 Family WDT – Watchdog Timer 26.8.4 Interrupt Enable Clear Name:  Offset:  Reset:  Property:  INTENCLR 0x04 0x00 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set (INTENSET) register. Bit 7 6 5 4 3 Access Reset 2 1 0 EW R/W 0 Bit 0 – EW Early Warning Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Early Warning Interrupt Enable bit, which disables the Early Warning interrupt. Value Description 0 The Early Warning interrupt is disabled. 1 The Early Warning interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 338 SAM L10/L11 Family WDT – Watchdog Timer 26.8.5 Interrupt Enable Set Name:  Offset:  Reset:  Property:  INTENSET 0x05 0x00 PAC Write-Protection This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear (INTENCLR) register. Bit 7 6 5 4 3 Access Reset 2 1 0 EW R/W 0 Bit 0 – EW Early Warning Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the Early Warning Interrupt Enable bit, which enables the Early Warning interrupt. Value Description 0 The Early Warning interrupt is disabled. 1 The Early Warning interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 339 SAM L10/L11 Family WDT – Watchdog Timer 26.8.6 Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  Bit 7 INTFLAG 0x06 0x00 N/A 6 5 4 3 Access Reset 2 1 0 EW R/W 0 Bit 0 – EW Early Warning This flag is cleared by writing a '1' to it. This flag is set when an Early Warning interrupt occurs, as defined by the EWOFFSET bit group in EWCTRL. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Early Warning interrupt flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 340 SAM L10/L11 Family WDT – Watchdog Timer 26.8.7 Synchronization Busy Name:  Offset:  Reset:  Property:  Bit SYNCBUSY 0x08 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 CLEAR R 0 2 WEN R 0 1 ENABLE R 0 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 4 3 ALWAYSON RUNSTDBY R R 0 0 Bit 5 – CLEAR Clear Synchronization Busy Value Description 0 Write synchronization of the CLEAR register is complete. 1 Write synchronization of the CLEAR register is ongoing. Bit 4 – ALWAYSON Always-On Synchronization Busy Value Description 0 Write synchronization of the CTRLA.ALWAYSON bit is complete. 1 Write synchronization of the CTRLA.ALWAYSON bit is ongoing. Bit 3 – RUNSTDBY Run-In-Standby Synchronization Busy Value Description 0 Write synchronization of the CTRLA.RUNSTDBY bit is complete. 1 Write synchronization of the CTRLA.RUNSTDBY bit is ongoing. Bit 2 – WEN Window Enable Synchronization Busy Value Description 0 Write synchronization of the CTRLA.WEN bit is complete. 1 Write synchronization of the CTRLA.WEN bit is ongoing. Bit 1 – ENABLE Enable Synchronization Busy Value Description 0 Write synchronization of the CTRLA.ENABLE bit is complete. 1 Write synchronization of the CTRLA.ENABLE bit is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 341 SAM L10/L11 Family WDT – Watchdog Timer 26.8.8 Clear Name:  Offset:  Reset:  Property:  Bit 7 CLEAR 0x0C 0x00 Write-Synchronized 6 5 4 3 2 1 0 W 0 W 0 W 0 W 0 CLEAR[7:0] Access Reset W 0 W 0 W 0 W 0 Bits 7:0 – CLEAR[7:0] Watchdog Clear In Normal mode, writing 0xA5 to this register during the watchdog time-out period will clear the Watchdog Timer and the watchdog time-out period is restarted. In Window mode, any writing attempt to this register before the time-out period started (i.e., during TOWDTW) will issue an immediate system Reset. Writing 0xA5 during the time-out period TOWDT will clear the Watchdog Timer and the complete time-out sequence (first TOWDTW then TOWDT) is restarted. In both modes, writing any other value than 0xA5 will issue an immediate system Reset. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 342 SAM L10/L11 Family RTC – Real-Time Counter 27. RTC – Real-Time Counter 27.1 Overview The Real-Time Counter (RTC) is a 32-bit counter with a 10-bit programmable prescaler that typically runs continuously to keep track of time. The RTC can wake up the device from sleep modes using the alarm/compare wake up, periodic wake up, or overflow wake up mechanisms, or from the wake inputs. The RTC can generate periodic peripheral events from outputs of the prescaler, as well as alarm/compare interrupts and peripheral events, which can trigger at any counter value. Additionally, the timer can trigger an overflow interrupt and peripheral event, and can be reset on the occurrence of an alarm/compare match. This allows periodic interrupts and peripheral events at very long and accurate intervals. The 10-bit programmable prescaler can scale down the clock source. By this, a wide range of resolutions and timeout periods can be configured. With a 32.768kHz clock source, the minimum counter tick interval is 30.5µs, and timeout periods can range up to 36 hours. For a counter tick interval of 1s, the maximum time-out period is more than 136 years. 27.2 Features • • • • • • • • • 27.3 32-bit counter with 10-bit prescaler Multiple clock sources 32-bit or 16-bit counter mode One 32-bit or two 16-bit compare values Clock/Calendar mode – Time in seconds, minutes, and hours (12/24) – Date in day of month, month, and year – Leap year correction Digital prescaler correction/tuning for increased accuracy Overflow, alarm/compare match and prescaler interrupts and events – Optional clear on alarm/compare match 2 general purpose registers Tamper Detection – Timestamp on event or up to 5 inputs with debouncing – Active layer protection Block Diagram Figure 27-1. RTC Block Diagram (Mode 0 — 32-Bit Counter) 0x00000000 MATCHCLR OSC32KCTRL CLK_RTC_OSC PRESCALER CLK_RTC_CNT OVF COUNT = Periodic Events CMPn COMPn © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 343 SAM L10/L11 Family RTC – Real-Time Counter Figure 27-2. RTC Block Diagram (Mode 1 — 16-Bit Counter) 0x0000 OSC32KCTRL CLK_RTC_OSC PRESCALER CLK_RTC_CNT COUNT PER Periodic Events = OVF = CMPn COMPn Figure 27-3. RTC Block Diagram (Mode 2 — Clock/Calendar) 0x00000000 MATCHCLR OSC32KCTRL CLK_RTC_OSC CLK_RTC_CNT PRESCALER OVF CLOCK = MASKn Periodic Events ALARMn ALARMn Figure 27-4. RTC Block Diagram (Tamper Detection Use Case) TAMPEVT IN2 TAMPER TIMESTAMP CAPTURE Tamper Input IN1 DEBOUNCE IN0 ALSI3 = 1 CLOCK Pseudo-Random Bitstream PRESCALER TrustRAM shield OUT3 = OUT0 SEPTO SEPTO OUT1 OUT2 ALARM FREQCORR SEPTO PCB Active Layer Protection Related Links 27.6.2.3 32-Bit Counter (Mode 0) 27.6.2.4 16-Bit Counter (Mode 1) 27.6.2.5 Clock/Calendar (Mode 2) 27.6.8.4 Tamper Detection © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 344 SAM L10/L11 Family RTC – Real-Time Counter 27.4 Signal Description Table 27-1. Signal Description Signal Description Type INn [n=0..3] Tamper Detection Input Digital input OUTn [n=0..3] Tamper Detection Output Digital output One signal can be mapped to one of several pins. Related Links 4.1 Multiplexed Signals 27.5 Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described below. 27.5.1 I/O Lines For more information on I/O configurations, refer to the "RTC Pinout" section. Related Links: I/O Multiplexing and Considerations 27.5.2 Power Management The RTC will continue to operate in any sleep mode where the selected source clock is running. The RTC interrupts can be used to wake up the device from sleep modes. Events connected to the event system can trigger other operations in the system without exiting sleep modes. Refer to the Power Manager for details on the different sleep modes. The RTC will be reset only at power-on (POR) or by setting the Software Reset bit in the Control A register (CTRLA.SWRST=1). Related Links 22. PM – Power Manager 27.5.3 Clocks The RTC bus clock (CLK_RTC_APB) can be enabled and disabled in the Main Clock module MCLK, and the default state of CLK_RTC_APB can be found in Peripheral Clock Masking section. A 32KHz or 1KHz oscillator clock (CLK_RTC_OSC) is required to clock the RTC. This clock must be configured and enabled in the 32KHz oscillator controller (OSC32KCTRL) before using the RTC. This oscillator clock is asynchronous to the bus clock (CLK_RTC_APB). Due to this asynchronicity, writing to certain registers will require synchronization between the clock domains. Refer to 27.6.7 Synchronization for further details. Related Links 24. OSC32KCTRL – 32KHz Oscillators Controller 19.6.2.6 Peripheral Clock Masking 27.5.4 DMA The DMA request lines (or line if only one request) are connected to the DMA Controller (DMAC). Using the RTC DMA requests requires the DMA Controller to be configured first. Related Links 28. DMAC – Direct Memory Access Controller 27.5.5 Interrupts The interrupt request line is connected to the Interrupt Controller. Using the RTC interrupt requires the Interrupt Controller to be configured first. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 345 SAM L10/L11 Family RTC – Real-Time Counter 27.5.6 Events The events are connected to the Event System. Related Links 33. EVSYS – Event System 27.5.7 Debug Operation When the CPU is halted in debug mode the RTC will halt normal operation. The RTC can be forced to continue operation during debugging. Refer to 27.7.2.7 DBGCTRL for details. 27.5.8 Register Access Protection All registers with write-access are optionally write-protected by the peripheral access controller (PAC), except the following registers: • • Interrupt Flag Status and Clear (INTFLAG) register Tamper ID (TAMPID) register Write-protection is denoted by the "PAC Write-Protection" property in the register description. Write-protection does not apply to accesses through an external debugger. Refer to the PAC - Peripheral Access Controller for details. Related Links 15. PAC - Peripheral Access Controller 27.5.9 SAM L11 TrustZone-Specific Register Access Protection On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. 27.5.10 Analog Connections A 32.768kHz crystal can be connected to the XIN32 and XOUT32 pins, along with any required load capacitors. See the Electrical Characteristics Chapters for details on recommended crystal characteristics and load capacitors. 27.6 27.6.1 Functional Description Principle of Operation The RTC keeps track of time in the system and enables periodic events, as well as interrupts and events at a specified time. The RTC consists of a 10-bit prescaler that feeds a 32-bit counter. The actual format of the 32-bit counter depends on the RTC operating mode. The RTC can function in one of these modes: • Mode 0 - COUNT32: RTC serves as 32-bit counter • Mode 1 - COUNT16: RTC serves as 16-bit counter • Mode 2 - CLOCK: RTC serves as clock/calendar with alarm functionality 27.6.2 Basic Operation 27.6.2.1 Initialization The following bits are enable-protected, meaning that they can only be written when the RTC is disabled (CTRLA.ENABLE=0): © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 346 SAM L10/L11 Family RTC – Real-Time Counter • • • • • Operating Mode bits in the Control A register (CTRLA.MODE) Prescaler bits in the Control A register (CTRLA.PRESCALER) Clear on Match bit in the Control A register (CTRLA.MATCHCLR) Clock Representation bit in the Control A register (CTRLA.CLKREP) GP Registers Reset On Tamper Enable bit in the Control A register (CTRLA.GPTRST) The following registers are enable-protected: • • • • Control B register (CTRLB) Event Control register (EVCTRL) Tamper Control register (TAMPCTRL) Tamper Control B register (TAMPCTRLB) Enable-protected bits and registers can be changed only when the RTC is disabled (CTRLA.ENABLE=0). If the RTC is enabled (CTRLA.ENABLE=1), these operations are necessary: first write CTRLA.ENABLE=0 and check whether the write synchronization has finished, then change the desired bit field value. Enable-protected bits in CTRLA register can be written at the same time as CTRLA.ENABLE is written to '1', but not at the same time as CTRLA.ENABLE is written to '0'. Enable-protection is denoted by the "Enable-Protected" property in the register description. The RTC prescaler divides the source clock for the RTC counter. Note:  In Clock/Calendar mode, the prescaler must be configured to provide a 1Hz clock to the counter for correct operation. The frequency of the RTC clock (CLK_RTC_CNT) is given by the following formula: �CLK_RTC_CNT = �CLK_RTC_OSC 2PRESCALER The frequency of the oscillator clock, CLK_RTC_OSC, is given by fCLK_RTC_OSC, and fCLK_RTC_CNT is the frequency of the internal prescaled RTC clock, CLK_RTC_CNT. 27.6.2.2 Enabling, Disabling, and Resetting The RTC is enabled by setting the Enable bit in the Control A register (CTRLA.ENABLE=1). The RTC is disabled by writing CTRLA.ENABLE=0. The RTC is reset by setting the Software Reset bit in the Control A register (CTRLA.SWRST=1). All registers in the RTC, except DEBUG, will be reset to their initial state, and the RTC will be disabled. The RTC must be disabled before resetting it. 27.6.2.3 32-Bit Counter (Mode 0) When the RTC Operating Mode bits in the Control A register (CTRLA.MODE) are written to 0x0, the counter operates in 32-bit Counter mode. The block diagram of this mode is shown in Figure 27-1. When the RTC is enabled, the counter will increment on every 0-to-1 transition of CLK_RTC_CNT. The counter will increment until it reaches the top value of 0xFFFFFFFF, and then wrap to 0x00000000. This sets the Overflow Interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.OVF). The RTC counter value can be read from or written to the Counter Value register (COUNT) in 32-bit format. The counter value is continuously compared with the 32-bit Compare register (COMP0). When a compare match occurs, the Compare 0 Interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.CMP0) is set on the next 0-to-1 transition of CLK_RTC_CNT. If the Clear on Match bit in the Control A register (CTRLA.MATCHCLR) is '1', the counter is cleared on the next counter cycle when a compare match with COMP0 occurs. This allows the RTC to generate periodic interrupts or events with longer periods than the prescaler events. Note that when CTRLA.MATCHCLR is '1', INTFLAG.CMP0 and INTFLAG.OVF will both be set simultaneously on a compare match with COMP0. 27.6.2.4 16-Bit Counter (Mode 1) When the RTC Operating Mode bits in the Control A register (CTRLA.MODE) are written to 0x1, the counter operates in 16-bit Counter mode as shown in Figure 27-2. When the RTC is enabled, the counter will increment on every 0to-1 transition of CLK_RTC_CNT. In 16-bit Counter mode, the 16-bit Period register (PER) holds the maximum value © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 347 SAM L10/L11 Family RTC – Real-Time Counter of the counter. The counter will increment until it reaches the PER value, and then wrap to 0x0000. This sets the Overflow Interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.OVF). The RTC counter value can be read from or written to the Counter Value register (COUNT) in 16-bit format. The counter value is continuously compared with the 16-bit Compare registers (COMPn, n=0..1). When a compare match occurs, the Compare n Interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.CMPn, n=0..1) is set on the next 0-to-1 transition of CLK_RTC_CNT. 27.6.2.5 Clock/Calendar (Mode 2) When the RTC Operating Mode bits in the Control A register (CTRLA.MODE) are written to 0x2, the counter operates in Clock/Calendar mode, as shown in Figure 27-3. When the RTC is enabled, the counter will increment on every 0to-1 transition of CLK_RTC_CNT. The selected clock source and RTC prescaler must be configured to provide a 1Hz clock to the counter for correct operation in this mode. The time and date can be read from or written to the Clock Value register (CLOCK) in a 32-bit time/date format. Time is represented as: • • • Seconds Minutes Hours Hours can be represented in either 12- or 24-hour format, selected by the Clock Representation bit in the Control A register (CTRLA.CLKREP). This bit can be changed only while the RTC is disabled. The date is represented in this form: • • • Day as the numeric day of the month (starting at 1) Month as the numeric month of the year (1 = January, 2 = February, etc.) Year as a value from 0x00 to 0x3F. This value must be added to a user-defined reference year. The reference year must be a leap year (2016, 2020 etc). Example: the year value 0x2D, added to a reference year 2016, represents the year 2061. The RTC will increment until it reaches the top value of 23:59:59 December 31 of year value 0x3F, and then wrap to 00:00:00 January 1 of year value 0x00. This will set the Overflow Interrupt flag in the Interrupt Flag Status and Clear registers (INTFLAG.OVF). The clock value is continuously compared with the 32-bit Alarm register (ALARM0). When an alarm match occurs, the Alarm 0 Interrupt flag in the Interrupt Flag Status and Clear registers (INTFLAG.ALARM0) is set on the next 0to-1 transition of CLK_RTC_CNT. E.g. For a 1Hz clock counter, it means the Alarm 0 Interrupt flag is set with a delay of 1s after the occurrence of alarm match. A valid alarm match depends on the setting of the Alarm Mask Selection bits in the Alarm 0 Mask register (MASK0.SEL). These bits determine which time/date fields of the clock and alarm values are valid for comparison and which are ignored. If the Clear on Match bit in the Control A register (CTRLA.MATCHCLR) is set, the counter is cleared on the next counter cycle when an alarm match with ALARM0 occurs. This allows the RTC to generate periodic interrupts or events with longer periods than it would be possible with the prescaler events only (see 27.6.8.1 Periodic Intervals). Note:  When CTRLA.MATCHCLR is 1, INTFLAG.ALARM0 and INTFLAG.OVF will both be set simultaneously on an alarm match with ALARM0. 27.6.3 DMA Operation The RTC generates the following DMA request: • Tamper (TAMPER): The request is set on capture of the timestamp. The request is cleared when the Timestamp register is read. If the CPU accesses the registers which are source for DMA request set/clear condition, the DMA request can be lost or the DMA transfer can be corrupted, if enabled. 27.6.4 Interrupts The RTC has the following interrupt sources: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 348 SAM L10/L11 Family RTC – Real-Time Counter • • • • • Overflow (OVF): Indicates that the counter has reached its top value and wrapped to zero. Tamper (TAMPER): Indicates detection of valid signal on a tamper input pin or tamper event input. Compare (CMP0-1): Indicates a match between the counter value and the compare register. Alarm (ALARM0): Indicates a match between the clock value and the alarm register. Period n (PER0-7): The corresponding bit in the prescaler has toggled. Refer to 27.6.8.1 Periodic Intervals for details. Each interrupt source has an interrupt flag associated with it. The interrupt flag in the Interrupt Flag Status and Clear (INTFLAG) register is set when the interrupt condition occurs. Each interrupt can be individually enabled by setting the corresponding bit in the Interrupt Enable Set register (INTENSET=1), and disabled by setting the corresponding bit in the Interrupt Enable Clear register (INTENCLR=1). An interrupt request is generated when the interrupt flag is raised and the corresponding interrupt is enabled. The interrupt request remains active until either the interrupt flag is cleared, the interrupt is disabled or the RTC is reset. See the description of the INTFLAG registers for details on how to clear interrupt flags. All interrupt requests from the peripheral are ORed together on system level to generate one combined interrupt request to the NVIC. Refer to the Nested Vector Interrupt Controller for details. The user must read the INTFLAG register to determine which interrupt condition is present. Note:  Interrupts must be globally enabled for interrupt requests to be generated. Refer to the Nested Vector Interrupt Controller for details. 27.6.5 Events The RTC can generate the following output events: • • • • • • Overflow (OVF): Generated when the counter has reached its top value and wrapped to zero. Tamper (TAMPER): Generated on detection of valid signal on a tamper input pin or tamper event input. Compare (CMP0-1): Indicates a match between the counter value and the compare register. Alarm (ALARM0): Indicates a match between the clock value and the alarm register. Period n (PER0-7): The corresponding bit in the prescaler has toggled. Refer to 27.6.8.1 Periodic Intervals for details. Periodic Daily (PERD): Generated when the COUNT/CLOCK has incremented at a fixed period of time. Setting the Event Output bit in the Event Control Register (EVCTRL.xxxEO=1) enables the corresponding output event. Writing a zero to this bit disables the corresponding output event. Refer to the EVSYS - Event System for details on configuring the event system. The RTC can take the following actions on an input event: • Tamper (TAMPEVT): Capture the RTC counter to the timestamp register. See Tamper Detection. Writing a one to an Event Input bit into the Event Control register (EVCTRL.xxxEI) enables the corresponding action on input event. Writing a zero to this bit disables the corresponding action on input event. Related Links 33. EVSYS – Event System 27.6.6 Sleep Mode Operation The RTC will continue to operate in any sleep mode where the source clock is active. The RTC interrupts can be used to wake up the device from a sleep mode. RTC events can trigger other operations in the system without exiting the sleep mode. An interrupt request will be generated after the wake-up if the Interrupt Controller is configured accordingly. Otherwise the CPU will wake up directly, without triggering any interrupt. In this case, the CPU will continue executing right from the first instruction that followed the entry into sleep. The periodic events can also wake up the CPU through the interrupt function of the Event System. In this case, the event must be enabled and connected to an event channel with its interrupt enabled. See Event System for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 349 SAM L10/L11 Family RTC – Real-Time Counter 27.6.7 Synchronization Due to asynchronicity between the main clock domain and the peripheral clock domains, some registers need to be synchronized when written or read. The following bits are synchronized when written: • • • • Software Reset bit in Control A register, CTRLA.SWRST Enable bit in Control A register, CTRLA.ENABLE Count Read Synchronization bit in Control A register (CTRLA.COUNTSYNC) Clock Read Synchronization bit in Control A register (CTRLA.COUNTSYNC) The following registers are synchronized when written: • • • • • • • • Counter Value register, COUNT Clock Value register, CLOCK Counter Period register, PER Compare n Value registers, COMPn Alarm n Value registers, ALARMn Frequency Correction register, FREQCORR Alarm n Mask register, MASKn The General Purpose n registers (GPn) The following registers are synchronized when read: • • • The Counter Value register, COUNT, if the Counter Read Sync Enable bit in CTRLA (CTRLA.COUNTSYNC) is '1' The Clock Value register, CLOCK, if the Clock Read Sync Enable bit in CTRLA (CTRLA.CLOCKSYNC) is '1' The Timestamp Value register (TIMESTAMP) Required write-synchronization is denoted by the "Write-Synchronized" property in the register description. Required read-synchronization is denoted by the "Read-Synchronized" property in the register description. 27.6.8 Additional Features 27.6.8.1 Periodic Intervals The RTC prescaler can generate interrupts and events at periodic intervals, allowing flexible system tick creation. Any of the upper eight bits of the prescaler (bits 2 to 9) can be the source of an interrupt/event. When one of the eight Periodic Event Output bits in the Event Control register (EVCTRL.PEREO[n=0..7]) is '1', an event is generated on the 0-to-1 transition of the related bit in the prescaler, resulting in a periodic event frequency of: �PERIODIC(n) = �CLK_RTC_OSC 2n+3 fCLK_RTC_OSC is the frequency of the internal prescaler clock CLK_RTC_OSC, and n is the position of the EVCTRL.PEREOn bit. For example, PER0 will generate an event every eight CLK_RTC_OSC cycles, PER1 every 16 cycles, etc. This is shown in the figure below. Periodic events are independent of the prescaler setting used by the RTC counter, except if CTRLA.PRESCALER is zero. Then, no periodic events will be generated. Figure 27-5. Example Periodic Events CLK_RTC_OSC PER0 PER1 PER2 PER3 27.6.8.2 Frequency Correction The RTC Frequency Correction module employs periodic counter corrections to compensate for a too-slow or toofast oscillator. Frequency correction requires that CTRLA.PRESCALER is greater than 1. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 350 SAM L10/L11 Family RTC – Real-Time Counter The digital correction circuit adds or subtracts cycles from the RTC prescaler to adjust the frequency in approximately 1ppm steps. Digital correction is achieved by adding or skipping a single count in the prescaler once every 8192 CLK_RTC_OSC cycles. The Value bit group in the Frequency Correction register (FREQCORR.VALUE) determines the number of times the adjustment is applied over 128 of these periods. The resulting correction is as follows: Correction in ppm  = FREQCORR.VALUE ⋅ 106ppm 8192 ⋅ 128 This results in a resolution of 0.95367ppm. The Sign bit in the Frequency Correction register (FREQCORR.SIGN) determines the direction of the correction. A positive value will add counts and increase the period (reducing the frequency), and a negative value will reduce counts per period (speeding up the frequency). Digital correction also affects the generation of the periodic events from the prescaler. When the correction is applied at the end of the correction cycle period, the interval between the previous periodic event and the next occurrence may also be shortened or lengthened depending on the correction value. 27.6.8.3 General Purpose Registers The RTC includes four General Purpose registers (GPn). These registers are reset only when the RTC is reset or when tamper detection occurs while CTRLA.GPTRST=1, and remain powered while the RTC is powered. They can be used to store user-defined values while other parts of the system are powered off. The general purpose registers 2*n and 2*n+1 are enabled by writing a '1' to the General Purpose Enable bit n in the Control B register (CTRLB.GPnEN). The GP registers share internal resources with the COMPARE/ALARM features. Each COMPARE/ALARM register have a separate read buffer and write buffer. When the general purpose feature is enabled the even GP uses the read buffer while the odd GP uses the write buffer. When the COMPARE/ALARM register is written, the write buffer hold temporarily the COMPARE/ALARM value until the synchronisation is complete (bit SYNCBUSY.COMPn going to 0). After the write is completed the write buffer can be used as a odd general purpose register whithout affecting the COMPARE/ALARM function. If the COMPARE/ALARM function is not used, the read buffer can be used as an even general purpose register. In this case writing the even GP will temporarirely use the write buffer until the synchronisation is complete (bit SYNCBUSY.GPn going to 0). Thus an even GP must be written before writing the odd GP. Changing or writing an even GP needs to temporarily save the value of the odd GP. Before using an even GP, the associated COMPARE/ALARM feature must be disabled by writing a '1' to the General Purpose Enable bit in the Control B register (CTRLB.GPnEN). To re-enable the compare/alarm, CTRLB.GPnEN must be written to zero and the associated COMPn/ALARMn must be written with the correct value. An example procedure to write the general purpose registers GP0 and GP1 is: 1. Wait for any ongoing write to COMP0 to complete (SYNCBUSY.COMP0 = 0). If the RTC is operating in Mode 1, wait for any ongoing write to COMP1 to complete as well (SYNCBUSY.COMP1 = 0). 2. Write CTRLB.GP0EN = 1 if GP0 is needed. 3. Write GP0 if needed. 4. Wait for any ongoing write to GP0 to complete (SYNCBUSY.GP0 = 0). Note that GP1 will also show as busy when GP0 is busy. 5. Write GP1 if needed. The following table provides the correspondence of General Purpose Registers and the COMPARE/ALARM read or write buffer in all RTC modes. Table 27-2. General Purpose Registers Versus Compare/Alarm Registers: n in 0, 2, 4, 6... Register Mode 0 GPn GPn+1 Mode 2 Write Before COMPn/2 write buffer (COMPn , COMPn +1) write buffer ALARM0 write buffer GPn+1 COMPn/2 read buffer (COMPn , COMPn +1) read buffer ALARM0 read buffer - © 2020 Microchip Technology Inc. Mode 1 Datasheet DS60001513F-page 351 SAM L10/L11 Family RTC – Real-Time Counter 27.6.8.4 Tamper Detection The RTC provides four tamper channels that can be used for tamper detection. The action of each tamper channel is configured using the Input n Action bits in the Tamper Control register (TAMPCTRL.INnACT): • Off: Detection for tamper channel n is disabled. • Wake: A transition on INn input (tamper channel n) matching TAMPCTRL.TAMPLVLn will be detected and the tamper interrupt flag (INTFLAG.TAMPER) will be set. The RTC value will not be captured in the TIMESTAMP register. • Capture: A transition on INn input (tamper channel n) matching TAMPCTRL.TAMPLVLn will be detected and the tamper interrupt flag (INTFLAG.TAMPER) will be set. The RTC value will be captured in the TIMESTAMP register. • Active Layer Protection: A mismatch of an internal RTC signal routed between INn and OUTn pins will be detected and the tamper interrupt flag (INTFLAG.TAMPER) will be set. The RTC value will be captured in the TIMESTAMP register. In order to determine which tamper source caused a tamper event, the Tamper ID register (TAMPID) provides the detection status of each tamper channel. These bits remain active until cleared by software. A single interrupt request (TAMPER) is available for all tamper channels. The RTC also supports an input event (TAMPEVT) for generating a tamper condition within the Event System. The tamper input event is enabled by the Tamper Input Event Enable bit in the Event Control register (EVCTRL.TAMPEVEI). Up to four polarity external inputs (INn) can be used for tamper detection. The polarity for each input is selected with the Tamper Level bits in the Tamper Control register (TAMPCTRL.TAMPLVLn). Separate debouncers are embedded for each external input. The debouncer for each input is enabled/disabled with the Debounce Enable bits in the Tamper Control register (TAMPCTRL.DEBNCn). The debouncer configuration is fixed for all inputs as set by the Control B register (CTRLB). The debouncing period duration is configurable using the Debounce Frequency field in the Control B register (CTRLB.DEBF). The period is set for all debouncers (i.e., the duration cannot be adjusted separately for each debouncer). When TAMPCTRL.DEBNCn = 0, INn is detected asynchronously. See Edge Detection with Debouncer Disabled below for an example. When TAMPCTRL.DEBNCn = 1, the detection time depends on whether the debouncer operates synchronously or asynchronously, and whether majority detection is enabled or not. Refer to the table below for more details. Synchronous versus asynchronous stability debouncing is configured by the Debounce Asynchronous Enable bit in the Control B register (CTRLB.DEBASYNC): • Synchronous (CTRLB.DEBASYNC = 0): INn is synchronized in two CLK_RTC periods and then must remain stable for four CLK_RTC_DEB periods before a valid detection occurs. See Edge Detection with Synchronous Stability Debouncing below for an example. • Asynchronous (CTRLB.DEBASYNC = 1): The first edge on INn is detected. Further detection is blanked until INn remains stable for four CLK_RTC_DEB periods. See Edge Detection with Asynchronous Stability Debouncing below for an example. Majority debouncing is configured by the Debounce Majority Enable bit in the Control B register (CTRLB.DEBMAJ). INn must be valid for two out of three CLK_RTC_DEB periods. See Edge Detection with Asynchronous Stability Debouncing below for an example. Table 27-3. Debouncer Configuration TAMPCTRL. DEBNCn CTRLB. DEBMAJ CTRLB. DEBASYNC Description 0 X X Detect edge on INn with no debouncing. Every edge detected is immediately triggered. 1 0 0 Detect edge on INn with synchronous stability debouncing. Edge detected is only triggered when INn is stable for 4 consecutive CLK_RTC_DEB periods. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 352 SAM L10/L11 Family RTC – Real-Time Counter ...........continued TAMPCTRL. DEBNCn CTRLB. DEBMAJ CTRLB. DEBASYNC Description 1 0 1 Detect edge on INn with asynchronous stability debouncing. First detected edge is triggered immediately. All subsequent detected edges are ignored until INn is stable for 4 consecutive CLK_RTC_DEB periods. 1 1 X Detect edge on INn with majority debouncing. Pin INn is sampled for 3 consecutive CLK_RTC_DEB periods. Signal level is determined by majority-rule (LLL, LLH, LHL, HLL = '0' and LHH, HLH, HHL, HHH = '1'). Figure 27-6. Edge Detection with Debouncer Disabled CLK_RTC CLK_RTC_DEB IN NE PE NE PE NE PE OUT TAMLVL=0 CLK_RTC CLK_RTC_DEB IN NE PE NE PE NE PE OUT TAMLVL=1 Figure 27-7. Edge Detection with Synchronous Stability Debouncing CLK_RTC CLK_RTC_DEB IN NE PE NE PE NE PE Whenever an edge is detected, input must be stable for 4 consecutive CLK_RTC_DEB in order for edge to be considered valid OUT TAMLVL=0 CLK_RTC CLK_RTC_DEB IN NE PE NE PE NE PE Whenever an edge is detected, input must be stable for 4 consecutive CLK_RTC_DEB in order for edge to be considered valid OUT TAMLVL=1 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 353 SAM L10/L11 Family RTC – Real-Time Counter Figure 27-8. Edge Detection with Asynchronous Stability Debouncing CLK_RTC CLK_RTC_DEB IN PE NE PE NE PE NE Once a new edge is detected, ignore subsequent edges until input is stable for 4 consecutive CLK_RTC_DEB OUT TAMLVL=0 CLK_RTC CLK_RTC_DEB IN PE NE PE NE PE NE Once a new edge is detected, ignore subsequent edges until input is stable for 4 consecutive CLK_RTC_DEB OUT TAMLVL=1 Figure 27-9. Edge Detection with Majority Debouncing CLK_RTC CLK_RTC_DEB IN PE NE PE NE PE NE IN shift 0 1 0 1 0 0 0 0 0 1 1 1 1 0 1 1 IN shift 1 1 1 0 1 0 0 0 0 0 1 1 1 1 0 1 IN shift 2 1 1 1 0 1 0 0 0 0 0 1 1 1 1 0 MAJORITY3 1 1 1 0 0 0 0 0 0 1 1 1 1 1 1 1-to-0 transition OUT TAMLVL=0 CLK_RTC CLK_RTC_DEB IN PE NE PE NE PE NE IN shift 0 1 0 1 0 0 0 0 0 1 1 1 1 0 1 1 IN shift 1 1 1 0 1 0 0 0 0 0 1 1 1 1 0 1 IN shift 2 1 1 1 0 1 0 0 0 0 0 1 1 1 1 0 MAJORITY3 1 1 1 0 0 0 0 0 0 1 1 1 1 1 1 0-to-1 transition OUT TAMLVL=1 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 354 SAM L10/L11 Family RTC – Real-Time Counter Related Links 27.3 Block Diagram 27.6.8.4.1 Timestamp 27.6.8.4.2 Active Layer Protection 27.6.8.4.1 Timestamp As part of tamper detection the RTC can capture the counter value (COUNT/CLOCK) into the TIMESTAMP register. Three CLK_RTC periods are required to detect the tampering condition and capture the value. The TIMESTAMP value can be read once the Tamper flag in the Interrupt Flag register (INTFLAG.TAMPER) is set. If the DMA Enable bit in the Control B register (CTRLB.DMAEN) is ‘1’, a DMA request will be triggered by the timestamp. In order to determine which tamper source caused a capture, the Tamper ID register (TAMPID) provides the detection status of each tamper channel and the tamper input event. A DMA transfer can then read both TIMESTAMP and TAMPID in succession. A new timestamp value cannot be captured until the Tamper flag is cleared, either by reading the timestamp or by writing a ‘1’ to INTFLAG.TAMPER. If several tamper conditions occur in a short window before the flag is cleared, only the first timestamp may be logged. However, the detection of each tamper will still be recorded in TAMPID. The Tamper Input Event (TAMPEVT) will always perform a timestamp capture. To capture on the external inputs (INn), the corresponding Input Action field in the Tamper Control register (TAMPCTRL.INnACT) must be written to ‘1’. If an input is set for wake functionality it does not capture the timestamp; however the Tamper flag and TAMPID will still be updated. Related Links 27.6.8.4 Tamper Detection 27.6.8.4.2 Active Layer Protection The RTC provides a mean of detecting broken traces on the PCB , also known as Active layer Protection. In this mode, a generated internal RTC signal can be directly routed over critical components on the board using RTC OUT output pin to one RTC INn input pin. A tamper condition is detected if there is a mismatch on the generated RTC signal. The Active Layer Protection mode and the generation of the RTC signal is enabled by setting the RTCOUT bit in the Control B register (CTRLB.RTCOUT). Enabling active layer protection requires the following steps: • Enable the RTC prescaler output by writing a one to the RTC Out bit in the Control B register (CTRLB.RTCOUT). The I/O pins must also be configured to correctly route the signal to the external pins. • Select the frequency of the output signal by configuring the RTC Active Layer Frequency field in the Control B register (CTRLB.ACTF). CLK_RTC GCLK_RTC_OUT  = CTRLB.ACTF +1 2 • Enable the tamper input n (INn) in active layer mode by writing 3 to the corresponding Input Action field in the Tamper Control register (TAMPCTRL.INnACT). When active layer protection is enabled and INn and OUTn pin are used, the value of INn is sampled on the falling edge of CLK_RTC and compared to the expected value of OUTn. Therefore up to one half of a CLK_RTC period is available for propagation delay through the trace. • Select Active Layer Monitoring Source (TrustRAM or INn/OUTn tamper pins) using ALSIn bit of TAMPCTRLB register • Enable Active Layer Protection by setting CTRLB.RTCOUT bit. Related Links 27.6.8.4 Tamper Detection 27.7 Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16-, and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 355 SAM L10/L11 Family RTC – Real-Time Counter Some registers require synchronization when read and/or written. Synchronization is denoted by the "ReadSynchronized" and/or "Write-Synchronized" property in each individual register description. Optional write-protection by the Peripheral Access Controller (PAC) is denoted by the "PAC Write-Protection" property in each individual register description. Some registers are enable-protected, meaning they can only be written when the module is disabled. Enableprotection is denoted by the "Enable-Protected" property in each individual register description. On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 356 SAM L10/L11 Family RTC – Real-Time Counter 27.7.1 Offset 0x00 0x02 Register Summary - Mode 0 - 32-Bit Counter Name CTRLA CTRLB 0x04 EVCTRL 0x08 INTENCLR 0x0A INTENSET 0x0C INTFLAG 0x0E 0x0F DBGCTRL Reserved 0x10 SYNCBUSY 0x14 0x15 ... 0x17 FREQCORR Bit Pos. 7 7:0 MATCHCLR 15:8 7:0 15:8 7:0 15:8 23:16 31:24 7:0 15:8 7:0 15:8 7:0 15:8 7:0 7:0 15:8 23:16 31:24 7:0 6 4 3 2 MODE[1:0] COUNTSYNC GPTRST DMAEN RTCOUT SEPTO PEREO7 PEREO6 OVFEO TAMPEREO PER7 OVF PER7 OVF PER7 OVF 5 PER6 TAMPER PER6 TAMPER PER6 TAMPER 1 0 ENABLE SWRST PRESCALER[3:0] DEBASYNC ACTF[2:0] PEREO5 DEBMAJ PEREO4 PEREO3 PEREO2 DEBF[2:0] PEREO1 PER5 PER4 PER3 PER2 PER1 PER5 PER4 PER3 PER2 PER1 PER5 PER4 PER3 PER2 PER1 COUNT FREQCORR ENABLE SWRST GP1 GP0 COMP0 GP0EN PEREO0 CMPEO0 TAMPEVEI PERDEO PER0 CMP0 PER0 CMP0 PER0 CMP0 DBGRUN COUNTSYNC SIGN VALUE[6:0] Reserved 0x18 COUNT 0x1C ... 0x1F Reserved 0x20 COMP 0x24 ... 0x3F Reserved 0x40 GP0 0x44 GP1 0x48 ... 0x5F Reserved 0x60 TAMPCTRL 0x64 TIMESTAMP 7:0 15:8 23:16 31:24 COUNT[7:0] COUNT[15:8] COUNT[23:16] COUNT[31:24] 7:0 15:8 23:16 31:24 COMP[7:0] COMP[15:8] COMP[23:16] COMP[31:24] 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 GP[7:0] GP[15:8] GP[23:16] GP[31:24] GP[7:0] GP[15:8] GP[23:16] GP[31:24] 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 © 2020 Microchip Technology Inc. IN3ACT[1:0] IN2ACT[1:0] IN1ACT[1:0] TAMLVL3 DEBNC3 COUNT[7:0] COUNT[15:8] COUNT[23:16] COUNT[31:24] Datasheet TAMLVL2 DEBNC2 IN0ACT[1:0] TAMLVL1 DEBNC1 TAMLVL0 DEBNC0 DS60001513F-page 357 SAM L10/L11 Family RTC – Real-Time Counter ...........continued Offset Name 0x68 TAMPID 0x6C 27.7.2 TAMPCTRLB Bit Pos. 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7 6 5 4 3 2 1 0 TAMPID3 TAMPID2 TAMPID1 TAMPID0 ALSI3 ALSI2 ALSI1 ALSI0 TAMPEVT Register Description - Mode 0 - 32-Bit Counter This Register Description section is valid if the RTC is in COUNT32 mode (CTRLA.MODE=0). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 358 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.1 Control A in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit CTRLA 0x00 0x0000 PAC Write-Protection, Enable-Protected, Write-Synchronized 15 COUNTSYN C Access R/W Reset 0 Bit 7 MATCHCLR Access R/W Reset 0 14 GPTRST 13 12 R/W 0 6 11 R/W 0 5 4 3 10 9 PRESCALER[3:0] R/W 0 2 MODE[1:0] R/W R/W 0 0 8 R/W 0 R/W 0 1 ENABLE R/W 0 0 SWRST R/W 0 Bit 15 – COUNTSYNC COUNT Read Synchronization Enable The COUNT register requires synchronization when reading. Disabling the synchronization will prevent reading valid values from the COUNT register. This bit is not enable-protected. Value Description 0 COUNT read synchronization is disabled 1 COUNT read synchronization is enabled Bit 14 – GPTRST GP Registers Reset On Tamper Enable Only GP registers enabled by the CTRLB.GPnEN bits are affected. This bit can be written only when the peripheral is disabled. This bit is not synchronized. Bits 11:8 – PRESCALER[3:0] Prescaler These bits define the prescaling factor for the RTC clock source (GCLK_RTC) to generate the counter clock (CLK_RTC_CNT). Periodic events and interrupts are not available when the prescaler is off. These bits are not synchronized. Value Name Description 0x0 OFF CLK_RTC_CNT = GCLK_RTC/1 0x1 DIV1 CLK_RTC_CNT = GCLK_RTC/1 0x2 DIV2 CLK_RTC_CNT = GCLK_RTC/2 0x3 DIV4 CLK_RTC_CNT = GCLK_RTC/4 0x4 DIV8 CLK_RTC_CNT = GCLK_RTC/8 0x5 DIV16 CLK_RTC_CNT = GCLK_RTC/16 0x6 DIV32 CLK_RTC_CNT = GCLK_RTC/32 0x7 DIV64 CLK_RTC_CNT = GCLK_RTC/64 0x8 DIV128 CLK_RTC_CNT = GCLK_RTC/128 0x9 DIV256 CLK_RTC_CNT = GCLK_RTC/256 0xA DIV512 CLK_RTC_CNT = GCLK_RTC/512 0xB DIV1024 CLK_RTC_CNT = GCLK_RTC/1024 0xC-0xF Reserved Bit 7 – MATCHCLR Clear on Match This bit defines if the counter is cleared or not on a match. This bit is not synchronized. Value Description 0 The counter is not cleared on a Compare/Alarm 0 match 1 The counter is cleared on a Compare/Alarm 0 match © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 359 SAM L10/L11 Family RTC – Real-Time Counter Bits 3:2 – MODE[1:0] Operating Mode This bit group defines the operating mode of the RTC. This bit is not synchronized. Value Name Description 0x0 COUNT32 Mode 0: 32-bit counter 0x1 COUNT16 Mode 1: 16-bit counter 0x2 CLOCK Mode 2: Clock/calendar 0x3 Reserved Bit 1 – ENABLE Enable Due to synchronization there is a delay between writing CTRLA.ENABLE and until the peripheral is enabled/disabled. The value written to CTRLA.ENABLE will read back immediately and the Enable bit in the Synchronization Busy register (SYNCBUSY.ENABLE) will be set. SYNCBUSY.ENABLE will be cleared when the operation is complete. This bit is not enable-protected. Value Description 0 The peripheral is disabled 1 The peripheral is enabled Bit 0 – SWRST Software Reset Writing a '0' to this bit has no effect. Writing a '1' to this bit resets all registers in the RTC (except DBGCTRL) to their initial state, and the RTC will be disabled. Writing a '1' to CTRLA.SWRST will always take precedence, meaning that all other writes in the same write-operation will be discarded. Due to synchronization there is a delay between writing CTRLA.SWRST and until the reset is complete. CTRLA.SWRST will be cleared when the reset is complete. This bit is not enable-protected. Value Description 0 There is not reset operation ongoing 1 The reset operation is ongoing © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 360 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.2 Control B in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset 15 SEPTO R/W 0 7 DMAEN R/W 0 CTRLB 0x02 0x0000 PAC Write-Protection, Enable-Protected 14 R/W 0 13 ACTF[2:0] R/W 0 12 R/W 0 6 RTCOUT R/W 0 5 DEBASYNC R/W 0 4 DEBMAJ R/W 0 11 3 10 R/W 0 9 DEBF[2:0] R/W 0 2 1 8 R/W 0 0 GP0EN R/W 0 Bit 15 – SEPTO Separate Tamper Outputs Value Description 0 IN[n] is compared to OUT[0]. 1 IN[n] is compared to OUT[n]. Bits 14:12 – ACTF[2:0] Active Layer Frequency These bits define the prescaling factor for the RTC clock output (OUT) used during active layer protection in terms of the CLK_RTC. Value Name Description 0x0 DIV2 CLK_RTC_OUT = CLK_RTC / 2 0x1 DIV4 CLK_RTC_OUT = CLK_RTC / 4 0x2 DIV8 CLK_RTC_OUT = CLK_RTC / 8 0x3 DIV16 CLK_RTC_OUT = CLK_RTC / 16 0x4 DIV32 CLK_RTC_OUT = CLK_RTC / 32 0x5 DIV64 CLK_RTC_OUT = CLK_RTC / 64 0x6 DIV128 CLK_RTC_OUT = CLK_RTC / 128 0x7 DIV256 CLK_RTC_OUT = CLK_RTC / 256 Bits 10:8 – DEBF[2:0] Debounce Frequency These bits define the prescaling factor for the input debouncers in terms of the CLK_RTC. Value Name Description 0x0 DIV2 CLK_RTC_DEB = CLK_RTC / 2 0x1 DIV4 CLK_RTC_DEB = CLK_RTC / 4 0x2 DIV8 CLK_RTC_DEB = CLK_RTC / 8 0x3 DIV16 CLK_RTC_DEB = CLK_RTC / 16 0x4 DIV32 CLK_RTC_DEB = CLK_RTC / 32 0x5 DIV64 CLK_RTC_DEB = CLK_RTC / 64 0x6 DIV128 CLK_RTC_DEB = CLK_RTC / 128 0x7 DIV256 CLK_RTC_DEB = CLK_RTC / 256 Bit 7 – DMAEN DMA Enable The RTC can trigger a DMA request when the timestamp is ready in the TIMESTAMP register. Value Description 0 Tamper DMA request is disabled. Reading TIMESTAMP has no effect on INTFLAG.TAMPER. 1 Tamper DMA request is enabled. Reading TIMESTAMP will clear INTFLAG.TAMPER. Bit 6 – RTCOUT RTC Output Enable Value Description 0 The RTC active layer output is disabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 361 SAM L10/L11 Family RTC – Real-Time Counter Value 1 Description The RTC active layer output is enabled. Bit 5 – DEBASYNC Debouncer Asynchronous Enable Value Description 0 The tamper input debouncers operate synchronously. 1 The tamper input debouncers operate asynchronously. Bit 4 – DEBMAJ Debouncer Majority Enable Value Description 0 The tamper input debouncers match three equal values. 1 The tamper input debouncers match majority two of three values. Bit 0 – GP0EN General Purpose 0 Enable Value Description 0 COMP0 compare function enabled. GP0/GP1 disabled. 1 COMP0 compare function disabled. GP0/GP1 enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 362 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.3 Event Control in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit EVCTRL 0x04 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 PERDEO R/W 0 23 22 21 20 19 18 17 16 TAMPEVEI R/W 0 15 OVFEO R/W 0 14 TAMPEREO R/W 0 13 12 11 10 9 8 CMPEO0 R/W 0 7 PEREO7 R/W 0 6 PEREO6 R/W 0 5 PEREO5 R/W 0 4 PEREO4 R/W 0 3 PEREO3 R/W 0 2 PEREO2 R/W 0 1 PEREO1 R/W 0 0 PEREO0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 24 – PERDEO Periodic Interval Daily Event Output Enable Value Description 0 Periodic Daily event is disabled and will not be generated. 1 Periodic Daily event is enabled and will be generated. The event occurs at the overflow of the RTC counter (i.e., when the RTC counter goes from 0xFFFF to 0x0000). Bit 16 – TAMPEVEI Tamper Event Input Enable Value Description 0 Tamper event input is disabled and incoming events will be ignored. 1 Tamper event input is enabled and incoming events will capture the COUNT value. Bit 15 – OVFEO Overflow Event Output Enable Value Description 0 Overflow event is disabled and will not be generated. 1 Overflow event is enabled and will be generated for every overflow. Bit 14 – TAMPEREO Tamper Event Output Enable Value Description 0 Tamper event output is disabled and will not be generated. 1 Tamper event output is enabled and will be generated for every tamper input. Bit 8 – CMPEO0 Compare 0 Event Output Enable Value Description 0 Compare 0 event is disabled and will not be generated. 1 Compare 0 event is enabled and will be generated for every compare match. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PEREOn Periodic Interval n Event Output Enable [n = 7..0] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 363 SAM L10/L11 Family RTC – Real-Time Counter Value 0 1 Description Periodic Interval n event is disabled and will not be generated. Periodic Interval n event is enabled and will be generated. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 364 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.4 Interrupt Enable Clear in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  INTENCLR 0x08 0x0000 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set (INTENSET) register. Bit Access Reset Bit Access Reset 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 8 CMP0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Overflow Interrupt Enable bit, which disables the Overflow interrupt. Value Description 0 The Overflow interrupt is disabled. 1 The Overflow interrupt is enabled. Bit 14 – TAMPER Tamper Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this but will clear the Tamper Interrupt Enable bit, which disables the Tamper interrupt. Value Description 0 The Tamper interrupt is disabled. 1 The Tamper interrupt is enabled. Bit 8 – CMP0 Compare 0 Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Compare 0 Interrupt Enable bit, which disables the Compare 0 interrupt. Value Description 0 The Compare 0 interrupt is disabled. 1 The Compare 0 interrupt is enabled. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n Interrupt Enable [n = 7..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Periodic Interval n Interrupt Enable bit, which disables the Periodic Interval n interrupt. Value Description 0 Periodic Interval n interrupt is disabled. 1 Periodic Interval n interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 365 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.5 Interrupt Enable Set in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  INTENSET 0x0A 0x0000 PAC Write-Protection This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear (INTENCLR) register. Bit Access Reset Bit Access Reset 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 8 CMP0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Overflow Interrupt Enable bit, which enables the Overflow interrupt. Value Description 0 The Overflow interrupt is disabled. 1 The Overflow interrupt is enabled. Bit 14 – TAMPER Tamper Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Tamper Interrupt Enable bit, which enables the Tamper interrupt. Value Description 0 The Tamper interrupt is disabled. 1 The Tamper interrupt is enabled. Bit 8 – CMP0 Compare 0 Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Compare 0 Interrupt Enable bit, which enables the Compare 0 interrupt. Value Description 0 The Compare 0 interrupt is disabled. 1 The Compare 0 interrupt is enabled. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n Interrupt Enable [n = 7..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Periodic Interval n Interrupt Enable bit, which enables the Periodic Interval n interrupt. Value Description 0 Periodic Interval n interrupt is disabled. 1 Periodic Interval n interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 366 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.6 Interrupt Flag Status and Clear in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset INTFLAG 0x0C 0x0000 - 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 8 CMP0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow This flag is cleared by writing a '1' to the flag. This flag is set on the next CLK_RTC_CNT cycle after an overflow condition occurs, and an interrupt request will be generated if INTENCLR/SET.OVF is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Overflow interrupt flag. Bit 14 – TAMPER Tamper event This flag is set after a damper condition occurs, and an interrupt request will be generated if INTENCLR.TAMPER/ INTENSET.TAMPER is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Tamper interrupt flag. Bit 8 – CMP0 Compare 0 This flag is cleared by writing a '1' to the flag. This flag is set on the next CLK_RTC_CNT cycle after a match with the compare condition, and an interrupt request will be generated if INTENCLR/SET.COMP0 is one. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Compare 0 interrupt flag. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n [n = 7..0] This flag is cleared by writing a '1' to the flag. This flag is set on the 0-to-1 transition of prescaler bit [n+2], and an interrupt request will be generated if INTENCLR/ SET.PERn is one. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Periodic Interval n interrupt flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 367 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.7 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0E 0x00 PAC Write-Protection 6 5 4 3 Access Reset 2 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run This bit is not reset by a software reset. This bit controls the functionality when the CPU is halted by an external debugger. Value Description 0 The RTC is halted when the CPU is halted by an external debugger. 1 The RTC continues normal operation when the CPU is halted by an external debugger. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 368 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.8 Synchronization Busy in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit SYNCBUSY 0x10 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 GP1 R 0 16 GP0 R 0 14 13 12 11 10 9 8 6 5 COMP0 R 0 4 3 COUNT R 0 2 FREQCORR R 0 1 ENABLE R 0 0 SWRST R 0 Access Reset Bit Access Reset Bit 15 COUNTSYN C Access R Reset 0 Bit 7 Access Reset Bits 16, 17 – GPn General Purpose n Synchronization Busy Status [n = 1..0] Value Description 0 Write synchronization for GPn register is complete. 1 Write synchronization for GPn register is ongoing. Bit 15 – COUNTSYNC Count Read Sync Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.COUNTSYNC bit is complete. 1 Write synchronization for CTRLA.COUNTSYNC bit is ongoing. Bit 5 – COMP0 Compare 0 Synchronization Busy Status Value Description 0 Write synchronization for COMP0 register is complete. 1 Write synchronization for COMP0 register is ongoing. Bit 3 – COUNT Count Value Synchronization Busy Status Value Description 0 Read/write synchronization for COUNT register is complete. 1 Read/write synchronization for COUNT register is ongoing. Bit 2 – FREQCORR Frequency Correction Synchronization Busy Status Value Description 0 Write synchronization for FREQCORR register is complete. 1 Write synchronization for FREQCORR register is ongoing. Bit 1 – ENABLE Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.ENABLE bit is complete. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 369 SAM L10/L11 Family RTC – Real-Time Counter Value 1 Description Write synchronization for CTRLA.ENABLE bit is ongoing. Bit 0 – SWRST Software Reset Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.SWRST bit is complete. 1 Write synchronization for CTRLA.SWRST bit is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 370 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.9 Frequency Correction Name:  Offset:  Reset:  Property:  Bit Access Reset 7 SIGN R/W 0 FREQCORR 0x14 0x00 PAC Write-Protection, Write-Synchronized 6 5 4 R/W 0 R/W 0 R/W 0 3 VALUE[6:0] R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bit 7 – SIGN Correction Sign Value Description 0 The correction value is positive, i.e., frequency will be decreased. 1 The correction value is negative, i.e., frequency will be increased. Bits 6:0 – VALUE[6:0] Correction Value These bits define the amount of correction applied to the RTC prescaler. Value Description 0 Correction is disabled and the RTC frequency is unchanged. 1 - 127 The RTC frequency is adjusted according to the value. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 371 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.10 Counter Value in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset COUNT 0x18 0x00000000 PAC Write-Protection, Write-Synchronized, Read-Synchronized 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 28 27 COUNT[31:24] R/W R/W 0 0 20 19 COUNT[23:16] R/W R/W 0 0 12 11 COUNT[15:8] R/W R/W 0 0 4 3 COUNT[7:0] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – COUNT[31:0] Counter Value These bits define the value of the 32-bit RTC counter in mode 0. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 372 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.11 Compare 0 Value in COUNT32 mode (CTRLA.MODE=0) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset COMP 0x20 0x00000000 PAC Write-Protection, Write-Synchronized 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 28 27 COMP[31:24] R/W R/W 0 0 20 19 COMP[23:16] R/W R/W 0 0 12 11 COMP[15:8] R/W R/W 0 0 4 3 COMP[7:0] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – COMP[31:0] Compare Value The 32-bit value of COMP0 is continuously compared with the 32-bit COUNT value. When a match occurs, the Compare 0 interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.CMP0) is set on the next counter cycle, and the counter value is cleared if CTRLA.MATCHCLR is '1'. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 373 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.12 General Purpose n Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit GP 0x40 + n*0x04 [n=0..1] 0x00000000 PAC Write-Protection, Write-Synchronized 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 28 27 GP[31:24] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 11 10 9 8 R/W 0 R/W 0 R/W 0 R/W 0 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 20 19 GP[23:16] R/W R/W 0 0 12 GP[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 GP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – GP[31:0] General Purpose These bits are for user-defined general purpose use, see 27.6.8.3 General Purpose Registers. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 374 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.13 Tamper Control Name:  Offset:  Reset:  Property:  Bit 31 TAMPCTRL 0x60 0x00000000 PAC Write-Protection, Enable-Protected 30 29 28 27 DEBNC3 26 DEBNC2 25 DEBNC1 24 DEBNC0 0 0 0 0 19 TAMLVL3 18 TAMLVL2 17 TAMLVL1 16 TAMLVL0 0 0 0 0 8 Access Reset Bit 23 22 21 20 Access Reset Bit 15 14 13 12 11 10 9 7 6 5 4 3 2 1 Access Reset Bit IN3ACT[1:0] Access Reset 0 IN2ACT[1:0] 0 0 IN1ACT[1:0] 0 0 0 IN0ACT[1:0] 0 0 0 Bits 24, 25, 26, 27 – DEBNCn Debounce Enable of Tamper Input INn [n=0..3] Note:  Debounce feature does not apply to the Active Layer Protection mode (TAMPCTRL.INACT = ACTL). Value 0 1 Description Debouncing is disabled for Tamper input INn Debouncing is enabled for Tamper input INn Bits 16, 17, 18, 19 – TAMLVLn Tamper Level Select of Tamper Input INn [n=0..3] Note:  Tamper Level feature does not apply to the Active Layer Protection mode (TAMPCTRL.INACT = ACTL). Value 0 1 Description A falling edge condition will be detected on Tamper input INn. A rising edge condition will be detected on Tamper input INn. Bits 0:1, 2:3, 4:5, 6:7 – INnACT Tamper Channel n Action [n=0..3] These bits determine the action taken by Tamper Channel n. Value Name Description 0x0 OFF Off (Disabled) 0x1 WAKE Wake and set Tamper flag 0x2 CAPTURE Capture timestamp and set Tamper flag 0x3 ACTL Compare RTC signal routed between INn and OUT pins . When a mismatch occurs, capture timestamp and set Tamper flag © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 375 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.14 Timestamp Name:  Offset:  Reset:  Property:  TIMESTAMP 0x64 0x0 - Bit 31 30 29 28 27 COUNT[31:24] R R 0 0 26 25 24 Access Reset R 0 R 0 R 0 R 0 R 0 R 0 Bit 23 22 21 20 19 COUNT[23:16] R R 0 0 18 17 16 Access Reset R 0 R 0 R 0 R 0 R 0 R 0 Bit 15 14 13 10 9 8 R 0 12 11 COUNT[15:8] R R 0 0 Access Reset R 0 R 0 R 0 R 0 R 0 Bit 7 6 5 4 3 2 1 0 R 0 R 0 R 0 R 0 COUNT[7:0] Access Reset R 0 R 0 R 0 R 0 Bits 31:0 – COUNT[31:0] Count Timestamp Value The 32-bit value of COUNT is captured by the TIMESTAMP when a tamper condition occurs © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 376 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.15 Tamper ID Name:  Offset:  Reset:  Bit Access Reset Bit TAMPID 0x68 0x00000000 31 TAMPEVT R/W 0 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 TAMPID3 R/W 0 2 TAMPID2 R/W 0 1 TAMPID1 R/W 0 0 TAMPID0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit 31 – TAMPEVT Tamper Event Detected Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the tamper detection bit. Value Description 0 A tamper input event has not been detected 1 A tamper input event has been detected Bits 0, 1, 2, 3 – TAMPIDn Tamper on Channel n Detected [n=0..3] Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the tamper detection bit. Value Description 0 A tamper condition has not been detected on Channel n 1 A tamper condition has been detected on Channel n © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 377 SAM L10/L11 Family RTC – Real-Time Counter 27.7.2.16 Tamper Control B Name:  Offset:  Reset:  Property:  Bit TAMPCTRLB 0x6C 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 ALSI3 R/W 0 2 ALSI2 R/W 0 1 ALSI1 R/W 0 0 ALSI0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3 – ALSIn Active Layer Internal Select n [n=0..3] Note:  Only one ALSI bit must be set to enable Active Layer Protection on the TrustRAM. Value 0 1 Description Active layer Protection is monitoring the RTC signal using INn and OUTn tamper pins Active layer Protection is monitoring the RTC signal on the TrustRAM shield © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 378 SAM L10/L11 Family RTC – Real-Time Counter 27.7.3 Offset 0x00 0x02 Register Summary - Mode 1 - 16-Bit Counter Name CTRLA CTRLB 0x04 EVCTRL 0x08 INTENCLR 0x0A INTENSET 0x0C INTFLAG 0x0E 0x0F DBGCTRL Reserved 0x10 SYNCBUSY 0x14 0x15 ... 0x17 FREQCORR 0x18 COUNT 0x1A ... 0x1B Reserved 0x1C PER 0x1E ... 0x1F Reserved 0x20 COMP0 0x22 COMP1 0x24 ... 0x3F Reserved Bit Pos. 7 6 5 4 3 7:0 15:8 7:0 15:8 7:0 15:8 23:16 31:24 7:0 15:8 7:0 15:8 7:0 15:8 7:0 7:0 15:8 23:16 31:24 7:0 2 MODE[1:0] COUNTSYNC GPTRST DMAEN RTCOUT SEPTO PEREO7 PEREO6 OVFEO TAMPEREO PER7 OVF PER7 OVF PER7 OVF 1 0 ENABLE SWRST PRESCALER[3:0] DEBASYNC ACTF[2:0] PEREO5 DEBMAJ GP0EN PEREO4 PEREO3 PEREO2 PER6 TAMPER PER6 TAMPER PER6 TAMPER PER5 PER4 PER3 PER2 PER5 PER4 PER3 PER2 PER5 PER4 PER3 PER2 COMP1 COMP0 PER COUNT FREQCORR DEBF[2:0] PEREO1 CMPEO1 PER1 CMP1 PER1 CMP1 PER1 CMP1 PEREO0 CMPEO0 TAMPEVEI PERDEO PER0 CMP0 PER0 CMP0 PER0 CMP0 DBGRUN ENABLE SWRST GP1 GP0 COUNTSYNC SIGN VALUE[6:0] Reserved 0x40 GP0 0x44 GP1 0x48 ... 0x5F Reserved 0x60 TAMPCTRL 7:0 15:8 COUNT[7:0] COUNT[15:8] 7:0 15:8 PER[7:0] PER[15:8] 7:0 15:8 7:0 15:8 COMP[7:0] COMP[15:8] COMP[7:0] COMP[15:8] 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 GP[7:0] GP[15:8] GP[23:16] GP[31:24] GP[7:0] GP[15:8] GP[23:16] GP[31:24] 7:0 15:8 23:16 31:24 © 2020 Microchip Technology Inc. IN3ACT[1:0] IN2ACT[1:0] IN1ACT[1:0] TAMLVL3 DEBNC3 Datasheet TAMLVL2 DEBNC2 IN0ACT[1:0] TAMLVL1 DEBNC1 TAMLVL0 DEBNC0 DS60001513F-page 379 SAM L10/L11 Family RTC – Real-Time Counter ...........continued Offset Name 0x64 TIMESTAMP 0x68 0x6C 27.7.4 TAMPID TAMPCTRLB Bit Pos. 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7 6 5 4 3 2 1 0 TAMPID3 TAMPID2 TAMPID1 TAMPID0 ALSI3 ALSI2 ALSI1 ALSI0 COUNT[7:0] COUNT[15:8] TAMPEVT Register Description - Mode 1 - 16-Bit Counter This Register Description section is valid if the RTC is in COUNT16 mode (CTRLA.MODE=1). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 380 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.1 Control A in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit CTRLA 0x00 0x0000 PAC Write-Protection, Enable-Protected, Write-Synchronized 15 COUNTSYN C Access R/W Reset 0 Bit 7 14 GPTRST 13 12 R/W 0 6 Access Reset 11 R/W 0 5 4 10 9 PRESCALER[3:0] R/W 0 3 2 MODE[1:0] R/W R/W 0 0 8 R/W 0 R/W 0 1 ENABLE R/W 0 0 SWRST R/W 0 Bit 15 – COUNTSYNC COUNT Read Synchronization Enable The COUNT register requires synchronization when reading. Disabling the synchronization will prevent reading valid values from the COUNT register. This bit is not enable-protected. Value Description 0 COUNT read synchronization is disabled 1 COUNT read synchronization is enabled Bit 14 – GPTRST GP Registers Reset On Tamper Enable Only GP registers enabled by the CTRLB.GPnEN bits are affected. This bit can be written only when the peripheral is disabled. This bit is not synchronized. Value Description 0 GPn registers will not reset when a tamper condition occurs. 1 GPn registers will reset when a tamper condition occurs. Bits 11:8 – PRESCALER[3:0] Prescaler These bits define the prescaling factor for the RTC clock source (GCLK_RTC) to generate the counter clock (CLK_RTC_CNT). Periodic events and interrupts are not available when the prescaler is off. These bits are not synchronized. Value Name Description 0x0 OFF CLK_RTC_CNT = GCLK_RTC/1 0x1 DIV1 CLK_RTC_CNT = GCLK_RTC/1 0x2 DIV2 CLK_RTC_CNT = GCLK_RTC/2 0x3 DIV4 CLK_RTC_CNT = GCLK_RTC/4 0x4 DIV8 CLK_RTC_CNT = GCLK_RTC/8 0x5 DIV16 CLK_RTC_CNT = GCLK_RTC/16 0x6 DIV32 CLK_RTC_CNT = GCLK_RTC/32 0x7 DIV64 CLK_RTC_CNT = GCLK_RTC/64 0x8 DIV128 CLK_RTC_CNT = GCLK_RTC/128 0x9 DIV256 CLK_RTC_CNT = GCLK_RTC/256 0xA DIV512 CLK_RTC_CNT = GCLK_RTC/512 0xB DIV1024 CLK_RTC_CNT = GCLK_RTC/1024 0xC-0xF Reserved Bits 3:2 – MODE[1:0] Operating Mode This field defines the operating mode of the RTC. This bit is not synchronized. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 381 SAM L10/L11 Family RTC – Real-Time Counter Value 0x0 0x1 0x2 0x3 Name COUNT32 COUNT16 CLOCK - Description Mode 0: 32-bit counter Mode 1: 16-bit counter Mode 2: Clock/calendar Reserved Bit 1 – ENABLE Enable Due to synchronization there is delay from writing CTRLA.ENABLE until the peripheral is enabled/disabled. The value written to CTRLA.ENABLE will read back immediately and the Enable bit in the Synchronization Busy register (SYNCBUSY.ENABLE) will be set. SYNCBUSY.ENABLE will be cleared when the operation is complete. This bit is not enable-protected. Value Description 0 The peripheral is disabled 1 The peripheral is enabled Bit 0 – SWRST Software Reset Writing a '0' to this bit has no effect. Writing a '1' to this bit resets all registers in the RTC (except DBGCTRL) to their initial state, and the RTC will be disabled. Writing a '1' to CTRLA.SWRST will always take precedence, meaning that all other writes in the same write-operation will be discarded. Due to synchronization there is a delay from writing CTRLA.SWRST until the reset is complete. CTRLA.SWRST will be cleared when the reset is complete. This bit is not enable-protected. Value Description 0 There is not reset operation ongoing 1 The reset operation is ongoing © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 382 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.2 Control B in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset 15 SEPTO R/W 0 7 DMAEN R/W 0 CTRLB 0x02 0x0000 PAC Write-Protection, Enable-Protected 14 R/W 0 13 ACTF[2:0] R/W 0 12 R/W 0 6 RTCOUT R/W 0 5 DEBASYNC R/W 0 4 DEBMAJ R/W 0 11 3 10 R/W 0 9 DEBF[2:0] R/W 0 2 1 8 R/W 0 0 GP0EN R/W 0 Bit 15 – SEPTO Separate Tamper Outputs Value Description 0 IN[n] is compared to OUT[0] (backward-compatible). 1 IN[n] is compared to OUT[n]. Bits 14:12 – ACTF[2:0] Active Layer Frequency These bits define the prescaling factor for the RTC clock output (OUT) used during active layer protection in terms of the CLK_RTC. Value Name Description 0x0 DIV2 CLK_RTC_OUT = CLK_RTC / 2 0x1 DIV4 CLK_RTC_OUT = CLK_RTC / 4 0x2 DIV8 CLK_RTC_OUT = CLK_RTC / 8 0x3 DIV16 CLK_RTC_OUT = CLK_RTC / 16 0x4 DIV32 CLK_RTC_OUT = CLK_RTC / 32 0x5 DIV64 CLK_RTC_OUT = CLK_RTC / 64 0x6 DIV128 CLK_RTC_OUT = CLK_RTC / 128 0x7 DIV256 CLK_RTC_OUT = CLK_RTC / 256 Bits 10:8 – DEBF[2:0] Debounce Frequency These bits define the prescaling factor for the input debouncers in terms of the CLK_RTC. Value Name Description 0x0 DIV2 CLK_RTC_DEB = CLK_RTC / 2 0x1 DIV4 CLK_RTC_DEB = CLK_RTC / 4 0x2 DIV8 CLK_RTC_DEB = CLK_RTC / 8 0x3 DIV16 CLK_RTC_DEB = CLK_RTC / 16 0x4 DIV32 CLK_RTC_DEB = CLK_RTC / 32 0x5 DIV64 CLK_RTC_DEB = CLK_RTC / 64 0x6 DIV128 CLK_RTC_DEB = CLK_RTC / 128 0x7 DIV256 CLK_RTC_DEB = CLK_RTC / 256 Bit 7 – DMAEN DMA Enable The RTC can trigger a DMA request when the timestamp is ready in the TIMESTAMP register. Value Description 0 Tamper DMA request is disabled. Reading TIMESTAMP has no effect on INTFLAG.TAMPER. 1 Tamper DMA request is enabled. Reading TIMESTAMP will clear INTFLAG.TAMPER. Bit 6 – RTCOUT RTC Output Enable Value Description 0 The RTC active layer output is disabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 383 SAM L10/L11 Family RTC – Real-Time Counter Value 1 Description The RTC active layer output is enabled. Bit 5 – DEBASYNC Debouncer Asynchronous Enable Value Description 0 The tamper input debouncers operate synchronously. 1 The tamper input debouncers operate asynchronously. Bit 4 – DEBMAJ Debouncer Majority Enable Value Description 0 The tamper input debouncers match three equal values. 1 The tamper input debouncers match majority two of three values. Bit 0 – GP0EN General Purpose 0 Enable Value Description 0 COMP0 compare function enabled. GP0/GP1 disabled. 1 COMP0 compare function disabled. GP0/GP1 enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 384 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.3 Event Control in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit EVCTRL 0x04 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 PERDEO R/W 0 23 22 21 20 19 18 17 16 TAMPEVEI R/W 0 15 OVFEO R/W 0 14 TAMPEREO R/W 0 13 12 11 10 9 CMPEO1 R/W 0 8 CMPEO0 R/W 0 7 PEREO7 R/W 0 6 PEREO6 R/W 0 5 PEREO5 R/W 0 4 PEREO4 R/W 0 3 PEREO3 R/W 0 2 PEREO2 R/W 0 1 PEREO1 R/W 0 0 PEREO0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 24 – PERDEO Periodic Interval Daily Event Output Enable Value Description 0 Periodic Daily event is disabled and will not be generated. 1 Periodic Daily event is enabled and will be generated. The event occurs at the overflow of the RTC counter (i.e., when the RTC counter goes from 0xFFFF to 0x0000). Bit 16 – TAMPEVEI Tamper Event Input Enable Value Description 0 Tamper event input is disabled, and incoming events will be ignored 1 Tamper event input is enabled, and incoming events will capture the COUNT value Bit 15 – OVFEO Overflow Event Output Enable Value Description 0 Overflow event is disabled and will not be generated. 1 Overflow event is enabled and will be generated for every overflow. Bit 14 – TAMPEREO Tamper Event Output Enable Value Description 0 Tamper event output is disabled, and will not be generated. 1 Tamper event output is enabled, and will be generated for every tamper input. Bits 8, 9 – CMPEOn Compare n Event Output Enable [n = 1..0] Value Description 0 Compare n event is disabled and will not be generated. 1 Compare n event is enabled and will be generated for every compare match. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PEREOn Periodic Interval n Event Output Enable [n = 7..0] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 385 SAM L10/L11 Family RTC – Real-Time Counter Value 0 1 Description Periodic Interval n event is disabled and will not be generated. Periodic Interval n event is enabled and will be generated. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 386 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.4 Interrupt Enable Clear in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  INTENCLR 0x08 0x0000 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set (INTENSET) register. Bit Access Reset Bit Access Reset 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 CMP1 R/W 0 8 CMP0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Overflow Interrupt Enable bit, which disables the Overflow interrupt. Value Description 0 The Overflow interrupt is disabled. 1 The Overflow interrupt is enabled. Bit 14 – TAMPER Tamper Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Tamper Interrupt Enable bit, which disables the Tamper interrupt. Value Description 0 The Tamper interrupt is disabled. 1 The Tamper interrupt is enabled. Bits 8, 9 – CMPn Compare n Interrupt Enable [n = 1..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Compare n Interrupt Enable bit, which disables the Compare n interrupt. Value Description 0 The Compare n interrupt is disabled. 1 The Compare n interrupt is enabled. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n Interrupt Enable [n = 7..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Periodic Interval n Interrupt Enable bit, which disables the Periodic Interval n interrupt. Value Description 0 Periodic Interval n interrupt is disabled. 1 Periodic Interval n interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 387 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.5 Interrupt Enable Set in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  INTENSET 0x0A 0x0000 PAC Write-Protection This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear (INTENCLR) register. Bit Access Reset Bit Access Reset 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 CMP1 R/W 0 8 CMP0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Overflow Interrupt Enable bit, which enables the Overflow interrupt. Value Description 0 The Overflow interrupt is disabled. 1 The Overflow interrupt is enabled. Bit 14 – TAMPER Tamper Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Tamper Interrupt Enable bit, which enables the Tamper interrupt. Value Description 0 The Tamper interrupt is disabled. 1 The Tamper interrupt is enabled. Bits 8, 9 – CMPn Compare n Interrupt Enable [n = 1..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Compare n Interrupt Enable bit, which and enables the Compare n interrupt. Value Description 0 The Compare n interrupt is disabled. 1 The Compare n interrupt is enabled. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n Interrupt Enable [n = 7..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Periodic Interval n Interrupt Enable bit, which enables the Periodic Interval n interrupt. Value Description 0 Periodic Interval n interrupt is disabled. 1 Periodic Interval n interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 388 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.6 Interrupt Flag Status and Clear in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset INTFLAG 0x0C 0x0000 - 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 CMP1 R/W 0 8 CMP0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow This flag is cleared by writing a '1' to the flag. This flag is set on the next CLK_RTC_CNT cycle after an overflow condition occurs, and an interrupt request will be generated if INTENCLR/SET.OVF is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Overflow interrupt flag. Bit 14 – TAMPER Tamper This flag is set after a tamper condition occurs, and an interrupt request will be generated if INTENCLR.TAMPER/ INTENSET.TAMPER is one. Writing a '0' to this bit has no effect. Writing a one to this bit clears the Tamper interrupt flag. Bits 8, 9 – CMPn Compare n [n = 1..0] This flag is cleared by writing a '1' to the flag. This flag is set on the next CLK_RTC_CNT cycle after a match with the compare condition, and an interrupt request will be generated if INTENCLR/SET.COMPn is one. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Compare n interrupt flag. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n [n = 7..0] This flag is cleared by writing a '1' to the flag. This flag is set on the 0-to-1 transition of prescaler bit [n+2], and an interrupt request will be generated if INTENCLR/ SET.PERx is one. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Periodic Interval n interrupt flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 389 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.7 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0E 0x00 PAC Write-Protection 6 5 4 3 Access Reset 2 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run This bit is not reset by a software reset. This bit controls the functionality when the CPU is halted by an external debugger. Value Description 0 The RTC is halted when the CPU is halted by an external debugger. 1 The RTC continues normal operation when the CPU is halted by an external debugger. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 390 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.8 Synchronization Busy in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit SYNCBUSY 0x10 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 GP1 R 0 16 GP0 R 0 14 13 12 11 10 9 8 6 COMP1 R/W 0 5 COMP0 R/W 0 4 PER R 0 3 COUNT R 0 2 FREQCORR R 0 1 ENABLE R 0 0 SWRST R 0 Access Reset Bit Access Reset Bit 15 COUNTSYN C Access R Reset 0 Bit Access Reset 7 Bits 16, 17 – GPn General Purpose n Synchronization Busy Status [n = 1..0] Value Description 0 Write synchronization for GPn register is complete. 1 Write synchronization for GPn register is ongoing. Bit 15 – COUNTSYNC Count Read Sync Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.COUNTSYNC bit is complete. 1 Write synchronization for CTRLA.COUNTSYNC bit is ongoing. Bits 5, 6 – COMPn Compare n Synchronization Busy Status [n = 1..0] Value Description 0 Write synchronization for COMPn register is complete. 1 Write synchronization for COMPn register is ongoing. Bit 4 – PER Period Synchronization Busy Status Value Description 0 Write synchronization for PER register is complete. 1 Write synchronization for PER register is ongoing. Bit 3 – COUNT Count Value Synchronization Busy Status Value Description 0 Read/write synchronization for COUNT register is complete. 1 Read/write synchronization for COUNT register is ongoing. Bit 2 – FREQCORR Frequency Correction Synchronization Busy Status Value Description 0 Write synchronization for FREQCORR register is complete. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 391 SAM L10/L11 Family RTC – Real-Time Counter Value 1 Description Write synchronization for FREQCORR register is ongoing. Bit 1 – ENABLE Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.ENABLE bit is complete. 1 Write synchronization for CTRLA.ENABLE bit is ongoing. Bit 0 – SWRST Software Reset Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.SWRST bit is complete. 1 Write synchronization for CTRLA.SWRST bit is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 392 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.9 Frequency Correction Name:  Offset:  Reset:  Property:  Bit Access Reset 7 SIGN R/W 0 FREQCORR 0x14 0x00 PAC Write-Protection, Write-Synchronized 6 5 4 R/W 0 R/W 0 R/W 0 3 VALUE[6:0] R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bit 7 – SIGN Correction Sign Value Description 0 The correction value is positive, i.e., frequency will be decreased. 1 The correction value is negative, i.e., frequency will be increased. Bits 6:0 – VALUE[6:0] Correction Value These bits define the amount of correction applied to the RTC prescaler. Value Description 0 Correction is disabled and the RTC frequency is unchanged. 1 - 127 The RTC frequency is adjusted according to the value. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 393 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.10 Counter Value in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset COUNT 0x18 0x0000 PAC Write-Protection, Write-Synchronized, Read-Synchronized 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 12 11 COUNT[15:8] R/W R/W 0 0 4 3 COUNT[7:0] R/W R/W 0 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – COUNT[15:0] Counter Value These bits define the value of the 16-bit RTC counter in COUNT16 mode (CTRLA.MODE=1). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 394 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.11 Counter Period in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit PER 0x1C 0x0000 PAC Write-Protection, Write-Synchronized 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 12 11 PER[15:8] R/W R/W 0 0 4 10 9 8 R/W 0 R/W 0 R/W 0 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 PER[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – PER[15:0] Counter Period These bits define the value of the 16-bit RTC period in COUNT16 mode (CTRLA.MODE=1). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 395 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.12 Compare n Value in COUNT16 mode (CTRLA.MODE=1) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset COMP 0x20 + n*0x02 [n=0..1] 0x0000 PAC Write-Protection, Write-Synchronized 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 12 11 COMP[15:8] R/W R/W 0 0 4 3 COMP[7:0] R/W R/W 0 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – COMP[15:0] Compare Value The 16-bit value of COMPn is continuously compared with the 16-bit COUNT value. When a match occurs, the Compare n interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.CMPn) is set on the next counter cycle. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 396 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.13 General Purpose n Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit GP 0x40 + n*0x04 [n=0..1] 0x00000000 PAC Write-Protection, Write-Synchronized 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 28 27 GP[31:24] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 11 10 9 8 R/W 0 R/W 0 R/W 0 R/W 0 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 20 19 GP[23:16] R/W R/W 0 0 12 GP[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 GP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – GP[31:0] General Purpose These bits are for user-defined general purpose use, see 27.6.8.3 General Purpose Registers. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 397 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.14 Tamper Control Name:  Offset:  Reset:  Property:  Bit 31 TAMPCTRL 0x60 0x00000000 PAC Write-Protection, Enable-Protected 30 29 28 27 DEBNC3 26 DEBNC2 25 DEBNC1 24 DEBNC0 0 0 0 0 19 TAMLVL3 18 TAMLVL2 17 TAMLVL1 16 TAMLVL0 0 0 0 0 8 Access Reset Bit 23 22 21 20 Access Reset Bit 15 14 13 12 11 10 9 7 6 5 4 3 2 1 Access Reset Bit IN3ACT[1:0] Access Reset 0 IN2ACT[1:0] 0 0 IN1ACT[1:0] 0 0 0 IN0ACT[1:0] 0 0 0 Bits 24, 25, 26, 27 – DEBNCn Debounce Enable of Tamper Input INn [n=0..3] Note:  Debounce feature does not apply to the Active Layer Protection mode (TAMPCTRL.INACT = ACTL). Value 0 1 Description Debouncing is disabled for Tamper input INn Debouncing is enabled for Tamper input INn Bits 16, 17, 18, 19 – TAMLVLn Tamper Level Select of Tamper Input INn [n=0..3] Note:  Tamper Level feature does not apply to the Active Layer Protection mode (TAMPCTRL.INACT = ACTL). Value 0 1 Description A falling edge condition will be detected on Tamper input INn. A rising edge condition will be detected on Tamper input INn. Bits 0:1, 2:3, 4:5, 6:7 – INnACT Tamper Channel n Action [n=0..3] These bits determine the action taken by Tamper Channel n. Value Name Description 0x0 OFF Off (Disabled) 0x1 WAKE Wake and set Tamper flag 0x2 CAPTURE Capture timestamp and set Tamper flag 0x3 ACTL Compare RTC signal routed between INn and OUT pins . When a mismatch occurs, capture timestamp and set Tamper flag © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 398 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.15 Timestamp Name:  Offset:  Reset:  Property:  Bit TIMESTAMP 0x64 0x0000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 Bit 15 14 13 10 9 8 Access Reset R 0 R 0 R 0 12 11 COUNT[15:8] R R 0 0 R 0 R 0 R 0 Bit 7 6 5 4 3 2 1 0 R 0 R 0 R 0 R 0 Access Reset Bit Access Reset COUNT[7:0] Access Reset R 0 R 0 R 0 R 0 Bits 15:0 – COUNT[15:0] Count Timestamp Value The 16-bit value of COUNT is captured by the TIMESTAMP when a tamper condition occurs. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 399 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.16 Tamper ID Name:  Offset:  Reset:  Bit Access Reset Bit TAMPID 0x68 0x00000000 31 TAMPEVT R/W 0 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 TAMPID3 R/W 0 2 TAMPID2 R/W 0 1 TAMPID1 R/W 0 0 TAMPID0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit 31 – TAMPEVT Tamper Event Detected Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the tamper detection bit. Value Description 0 A tamper input event has not been detected 1 A tamper input event has been detected Bits 0, 1, 2, 3 – TAMPIDn Tamper on Channel n Detected [n=0..3] Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the tamper detection bit. Value Description 0 A tamper condition has not been detected on Channel n 1 A tamper condition has been detected on Channel n © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 400 SAM L10/L11 Family RTC – Real-Time Counter 27.7.4.17 Tamper Control B Name:  Offset:  Reset:  Property:  Bit TAMPCTRLB 0x6C 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 ALSI3 R/W 0 2 ALSI2 R/W 0 1 ALSI1 R/W 0 0 ALSI0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3 – ALSIn Active Layer Internal Select n [n=0..3] Note:  Only one ALSI bit must be set to enable Active Layer Protection on the TrustRAM. Value 0 1 Description Active layer Protection is monitoring the RTC signal using INn and OUTn tamper pins Active layer Protection is monitoring the RTC signal on the TrustRAM shield © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 401 SAM L10/L11 Family RTC – Real-Time Counter 27.7.5 Offset 0x00 0x02 Register Summary - Mode 2 - Clock/Calendar Name CTRLA CTRLB 0x04 EVCTRL 0x08 INTENCLR 0x0A INTENSET 0x0C INTFLAG 0x0E 0x0F DBGCTRL Reserved 0x10 SYNCBUSY 0x14 0x15 ... 0x17 FREQCORR 0x18 0x1C ... 0x1F 0x20 0x24 0x25 ... 0x3F 7 6 7:0 MATCHCLR CLKREP 15:8 7:0 15:8 7:0 15:8 23:16 31:24 7:0 15:8 7:0 15:8 7:0 15:8 7:0 7:0 15:8 23:16 31:24 7:0 5 CLOCKSYNC GPTRST DMAEN RTCOUT SEPTO PEREO7 PEREO6 OVFEO TAMPEREO PER7 OVF PER7 OVF PER7 OVF PER6 TAMPER PER6 TAMPER PER6 TAMPER 4 3 2 MODE[1:0] 1 0 ENABLE SWRST PRESCALER[3:0] DEBASYNC ACTF[2:0] PEREO5 DEBMAJ PEREO4 PEREO3 PEREO2 DEBF[2:0] PEREO1 PER5 PER4 PER3 PER2 PER1 PER5 PER4 PER3 PER2 PER1 PER5 PER4 PER3 PER2 PER1 CLOCK MASK0 FREQCORR ENABLE SWRST GP1 GP0 ALARM0 CLOCKSYNC SIGN GP0EN PEREO0 ALARMEO0 TAMPEVEI PERDEO PER0 ALARM0 PER0 ALARM0 PER0 ALARM0 DBGRUN VALUE[6:0] Reserved CLOCK 7:0 15:8 23:16 31:24 MINUTE[1:0] 7:0 15:8 23:16 31:24 7:0 MINUTE[1:0] SECOND[5:0] HOUR[3:0] MINUTE[5:2] MONTH[1:0] DAY[4:0] HOUR[4] MONTH[3:2] YEAR[5:0] Reserved ALARM MASK SECOND[5:0] HOUR[3:0] MINUTE[5:2] MONTH[1:0] DAY[4:0] YEAR[5:0] HOUR[4] MONTH[3:2] SEL[2:0] Reserved 0x40 GP0 0x44 GP1 0x48 ... 0x5F Reserved 0x60 TAMPCTRL 0x64 Bit Pos. TIMESTAMP 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 © 2020 Microchip Technology Inc. GP[7:0] GP[15:8] GP[23:16] GP[31:24] GP[7:0] GP[15:8] GP[23:16] GP[31:24] IN3ACT[1:0] IN2ACT[1:0] MINUTE[1:0] HOUR[3:0] MONTH[1:0] YEAR[5:0] Datasheet IN1ACT[1:0] IN0ACT[1:0] TAMLVL3 TAMLVL2 TAMLVL1 TAMLVL0 DEBNC3 DEBNC2 DEBNC1 DEBNC0 SECOND[5:0] MINUTE[5:2] DAY[4:0] HOUR[4] MONTH[3:2] DS60001513F-page 402 SAM L10/L11 Family RTC – Real-Time Counter ...........continued Offset Name 0x68 TAMPID 0x6C 27.7.6 TAMPCTRLB Bit Pos. 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7 6 5 4 3 2 1 0 TAMPID3 TAMPID2 TAMPID1 TAMPID0 ALSI3 ALSI2 ALSI1 ALSI0 TAMPEVT Register Description - Mode 2 - Clock/Calendar This Register Description section is valid if the RTC is in Clock/Calendar mode (CTRLA.MODE=2). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 403 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.1 Control A in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit CTRLA 0x00 0x0000 PAC Write-Protection, Enable-Protected, Write-Synchronized 15 CLOCKSYNC Access R/W Reset 0 Bit 7 MATCHCLR Access R/W Reset 0 14 GPTRST R/W 0 13 6 CLKREP R/W 0 5 12 11 R/W 0 4 3 10 9 PRESCALER[3:0] R/W R/W 0 0 2 MODE[1:0] R/W R/W 0 0 1 ENABLE R/W 0 8 R/W 0 0 SWRST R/W 0 Bit 15 – CLOCKSYNC CLOCK Read Synchronization Enable The CLOCK register requires synchronization when reading. Disabling the synchronization will prevent reading valid values from the CLOCK register. This bit is not enable-protected. Value Description 0 CLOCK read synchronization is disabled 1 CLOCK read synchronization is enabled Bit 14 – GPTRST GP Registers Reset On Tamper Enable Only GP registers enabled by the CTRLB.GPnEN bits are affected. This bit can be written only when the peripheral is disabled. This bit is not synchronized. Bits 11:8 – PRESCALER[3:0] Prescaler These bits define the prescaling factor for the RTC clock source (GCLK_RTC) to generate the counter clock (CLK_RTC_CNT). Periodic events and interrupts are not available when the prescaler is off. These bits are not synchronized. Value Name Description 0x0 OFF CLK_RTC_CNT = GCLK_RTC/1 0x1 DIV1 CLK_RTC_CNT = GCLK_RTC/1 0x2 DIV2 CLK_RTC_CNT = GCLK_RTC/2 0x3 DIV4 CLK_RTC_CNT = GCLK_RTC/4 0x4 DIV8 CLK_RTC_CNT = GCLK_RTC/8 0x5 DIV16 CLK_RTC_CNT = GCLK_RTC/16 0x6 DIV32 CLK_RTC_CNT = GCLK_RTC/32 0x7 DIV64 CLK_RTC_CNT = GCLK_RTC/64 0x8 DIV128 CLK_RTC_CNT = GCLK_RTC/128 0x9 DIV256 CLK_RTC_CNT = GCLK_RTC/256 0xA DIV512 CLK_RTC_CNT = GCLK_RTC/512 0xB DIV1024 CLK_RTC_CNT = GCLK_RTC/1024 0xC-0xF Reserved Bit 7 – MATCHCLR Clear on Match This bit is valid only in Mode 0 (COUNT32) and Mode 2 (CLOCK). This bit can be written only when the peripheral is disabled. This bit is not synchronized. Value Description 0 The counter is not cleared on a Compare/Alarm 0 match 1 The counter is cleared on a Compare/Alarm 0 match © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 404 SAM L10/L11 Family RTC – Real-Time Counter Bit 6 – CLKREP Clock Representation This bit is valid only in Mode 2 and determines how the hours are represented in the Clock Value (CLOCK) register. This bit can be written only when the peripheral is disabled. This bit is not synchronized. Value Description 0 24 Hour 1 12 Hour (AM/PM) Bits 3:2 – MODE[1:0] Operating Mode This field defines the operating mode of the RTC. This bit is not synchronized. Value Name Description 0x0 COUNT32 Mode 0: 32-bit counter 0x1 COUNT16 Mode 1: 16-bit counter 0x2 CLOCK Mode 2: Clock/calendar 0x3 Reserved Bit 1 – ENABLE Enable Due to synchronization there is delay from writing CTRLA.ENABLE until the peripheral is enabled/disabled. The value written to CTRLA.ENABLE will read back immediately and the Enable bit in the Synchronization Busy register (SYNCBUSY.ENABLE) will be set. SYNCBUSY.ENABLE will be cleared when the operation is complete. This bit is not enable-protected. Value Description 0 The peripheral is disabled 1 The peripheral is enabled Bit 0 – SWRST Software Reset Writing a '0' to this bit has no effect. Writing a '1' to this bit resets all registers in the RTC, except DBGCTRL, to their initial state, and the RTC will be disabled. Writing a '1' to CTRLA.SWRST will always take precedence, meaning that all other writes in the same write-operation will be discarded. Due to synchronization there is a delay from writing CTRLA.SWRST until the reset is complete. CTRLA.SWRST will be cleared when the reset is complete. This bit is not enable-protected. Value Description 0 There is not reset operation ongoing 1 The reset operation is ongoing © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 405 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.2 Control B in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset 15 SEPTO R/W 0 7 DMAEN R/W 0 CTRLB 0x2 0x0000 PAC Write-Protection, Enable-Protected 14 R/W 0 13 ACTF[2:0] R/W 0 12 R/W 0 6 RTCOUT R/W 0 5 DEBASYNC R/W 0 4 DEBMAJ R/W 0 11 3 10 R/W 0 9 DEBF[2:0] R/W 0 2 1 8 R/W 0 0 GP0EN R/W 0 Bit 15 – SEPTO Separate Tamper Outputs Value Description 0 IN[n] is compared tp OUT[0] (backward-compatible). 1 IN[n] is compared tp OUT[n]. Bits 14:12 – ACTF[2:0] Active Layer Frequency These bits define the prescaling factor for the RTC clock output (OUT) used during active layer protection in terms of the CLK_RTC. Value Name Description 0x0 DIV2 CLK_RTC_OUT = CLK_RTC / 2 0x1 DIV4 CLK_RTC_OUT = CLK_RTC / 4 0x2 DIV8 CLK_RTC_OUT = CLK_RTC / 8 0x3 DIV16 CLK_RTC_OUT = CLK_RTC / 16 0x4 DIV32 CLK_RTC_OUT = CLK_RTC / 32 0x5 DIV64 CLK_RTC_OUT = CLK_RTC / 64 0x6 DIV128 CLK_RTC_OUT = CLK_RTC / 128 0x7 DIV256 CLK_RTC_OUT = CLK_RTC / 256 Bits 10:8 – DEBF[2:0] Debounce Frequency These bits define the prescaling factor for the input debouncers in terms of the CLK_RTC. Value Name Description 0x0 DIV2 CLK_RTC_DEB = CLK_RTC / 2 0x1 DIV4 CLK_RTC_DEB = CLK_RTC / 4 0x2 DIV8 CLK_RTC_DEB = CLK_RTC / 8 0x3 DIV16 CLK_RTC_DEB = CLK_RTC / 16 0x4 DIV32 CLK_RTC_DEB = CLK_RTC / 32 0x5 DIV64 CLK_RTC_DEB = CLK_RTC / 64 0x6 DIV128 CLK_RTC_DEB = CLK_RTC / 128 0x7 DIV256 CLK_RTC_DEB = CLK_RTC / 256 Bit 7 – DMAEN DMA Enable The RTC can trigger a DMA request when the timestamp is ready in the TIMESTAMP register. Value Description 0 Tamper DMA request is disabled. Reading TIMESTAMP has no effect on INTFLAG.TAMPER. 1 Tamper DMA request is enabled. Reading TIMESTAMP will clear INTFLAG.TAMPER. Bit 6 – RTCOUT RTC Out Enable Value Description 0 The RTC active layer output is disabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 406 SAM L10/L11 Family RTC – Real-Time Counter Value 1 Description The RTC active layer output is enabled. Bit 5 – DEBASYNC Debouncer Asynchronous Enable Value Description 0 The tamper input debouncers operate synchronously. 1 The tamper input debouncers operate asynchronously. Bit 4 – DEBMAJ Debouncer Majority Enable Value Description 0 The tamper input debouncers match three equal values. 1 The tamper input debouncers match majority two of three values. Bit 0 – GP0EN General Purpose 0 Enable Value Description 0 COMP0 compare function enabled. GP0 disabled. 1 COMP0 compare function disabled. GP0 enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 407 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.3 Event Control in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit EVCTRL 0x04 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 PERDEO R/W 0 23 22 21 20 19 18 17 16 TAMPEVEI R/W 0 15 OVFEO R/W 0 14 TAMPEREO R/W 0 13 12 11 10 9 8 ALARMEO0 R/W 0 7 PEREO7 R/W 0 6 PEREO6 R/W 0 5 PEREO5 R/W 0 4 PEREO4 R/W 0 3 PEREO3 R/W 0 2 PEREO2 R/W 0 1 PEREO1 R/W 0 0 PEREO0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 24 – PERDEO Periodic Interval Daily Event Output Enable Value Description 0 Periodic Daily event is disabled and will not be generated. 1 Periodic Daily event is enabled and will be generated. The event occurs at the last second of each day depending on the CTRLA.CLKREP bit: • If CLKREP = 0, the event will occur at 23:59:59 • If CLKREP = 1, the event will occur at 11:59:59, PM = 1 Bit 16 – TAMPEVEI Tamper Event Input Enable Value Description 0 Tamper event input is disabled, and incoming events will be ignored. 1 Tamper event input is enabled, and all incoming events will capture the CLOCK value. Bit 15 – OVFEO Overflow Event Output Enable Value Description 0 Overflow event is disabled and will not be generated. 1 Overflow event is enabled and will be generated for every overflow. Bit 14 – TAMPEREO Tamper Event Output Enable Value Description 0 Tamper event output is disabled, and will not be generated 1 Tamper event output is enabled, and will be generated for every tamper input. Bit 8 – ALARMEO0 Alarm 0 Event Output Enable Value Description 0 Alarm 0 event is disabled and will not be generated. 1 Alarm 0 event is enabled and will be generated for every compare match. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 408 SAM L10/L11 Family RTC – Real-Time Counter Bits 0, 1, 2, 3, 4, 5, 6, 7 – PEREOn Periodic Interval n Event Output Enable [n = 7..0] Value Description 0 Periodic Interval n event is disabled and will not be generated. 1 Periodic Interval n event is enabled and will be generated. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 409 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.4 Interrupt Enable Clear in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  INTENCLR 0x08 0x0000 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set (INTENSET) register. Bit Access Reset Bit Access Reset 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 8 ALARM0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Overflow Interrupt Enable bit, which disables the Overflow interrupt. Value Description 0 The Overflow interrupt is disabled. 1 The Overflow interrupt is enabled. Bit 14 – TAMPER Tamper Interrupt Enable Bit 8 – ALARM0 Alarm 0 Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Alarm 0 Interrupt Enable bit, which disables the Alarm interrupt. Value Description 0 The Alarm 0 interrupt is disabled. 1 The Alarm 0 interrupt is enabled. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n Interrupt Enable [n = 7..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Periodic Interval n Interrupt Enable bit, which disables the Periodic Interval n interrupt. Value Description 0 Periodic Interval n interrupt is disabled. 1 Periodic Interval n interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 410 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.5 Interrupt Enable Set in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  INTENSET 0x0A 0x0000 PAC Write-Protection This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear (INTENCLR) register. Bit Access Reset Bit Access Reset 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 8 ALARM0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Overflow Interrupt Enable bit, which enables the Overflow interrupt. Value Description 0 The Overflow interrupt is disabled. 1 The Overflow interrupt is enabled. Bit 14 – TAMPER Tamper Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Tamper Interrupt Enable bit, which enables the Tamper interrupt. Value Description 0 The Tamper interrupt it disabled. 1 The Tamper interrupt is enabled. Bit 8 – ALARM0 Alarm 0 Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Alarm 0 Interrupt Enable bit, which enables the Alarm 0 interrupt. Value Description 0 The Alarm 0 interrupt is disabled. 1 The Alarm 0 interrupt is enabled. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n Interrupt Enable [n = 7..0] Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Periodic Interval n Interrupt Enable bit, which enables the Periodic Interval n interrupt. Value Description 0 Periodic Interval n interrupt is disabled. 1 Periodic Interval n interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 411 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.6 Interrupt Flag Status and Clear in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset INTFLAG 0x0C 0x0000 - 15 OVF R/W 0 14 TAMPER R/W 0 13 12 11 10 9 8 ALARM0 R/W 0 7 PER7 R/W 0 6 PER6 R/W 0 5 PER5 R/W 0 4 PER4 R/W 0 3 PER3 R/W 0 2 PER2 R/W 0 1 PER1 R/W 0 0 PER0 R/W 0 Bit 15 – OVF Overflow This flag is cleared by writing a '1' to the flag. This flag is set on the next CLK_RTC_CNT cycle after an overflow condition occurs, and an interrupt request will be generated if INTENCLR/SET.OVF is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Overflow interrupt flag. Bit 14 – TAMPER Tamper This flag is set after a tamper condition occurs, and an interrupt request will be generated if INTENCLR.TAMPER/ INTENSET.TAMPER is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Tamper interrupt flag. Bit 8 – ALARM0 Alarm 0 This flag is cleared by writing a '1' to the flag. This flag is set on the next CLK_RTC_CNT cycle after a match with the compare condition, and an interrupt request will be generated if INTENCLR/SET.ALARM0 is one. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Alarm 0 interrupt flag. Bits 0, 1, 2, 3, 4, 5, 6, 7 – PERn Periodic Interval n [n = 7..0] This flag is cleared by writing a '1' to the flag. This flag is set on the 0-to-1 transition of prescaler bit [n+2], and an interrupt request will be generated if INTENCLR/ SET.PERx is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Periodic Interval n interrupt flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 412 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.7 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0E 0x00 PAC Write-Protection 6 5 4 3 Access Reset 2 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run This bit is not reset by a software reset. This bit controls the functionality when the CPU is halted by an external debugger. Value Description 0 The RTC is halted when the CPU is halted by an external debugger. 1 The RTC continues normal operation when the CPU is halted by an external debugger. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 413 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.8 Synchronization Busy in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit SYNCBUSY 0x10 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 GP1 R 0 16 GP0 R 0 14 13 12 11 MASK0 R 0 10 9 8 6 5 ALARM0 R 0 4 3 CLOCK R 0 2 FREQCORR R 0 1 ENABLE R 0 0 SWRST R 0 Access Reset Bit Access Reset Bit 15 CLOCKSYNC Access R Reset 0 Bit 7 Access Reset Bits 16, 17 – GPn General Purpose n Synchronization Busy Status [n = 1..0] Value Description 0 Write synchronization for GPn register is complete. 1 Write synchronization for GPn register is ongoing. Bit 15 – CLOCKSYNC Clock Read Sync Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.CLOCKSYNC bit is complete. 1 Write synchronization for CTRLA.CLOCKSYNC bit is ongoing. Bit 11 – MASK0 Mask 0 Synchronization Busy Status Value Description 0 Write synchronization for MASK0 register is complete. 1 Write synchronization for MASK0 register is ongoing. Bit 5 – ALARM0 Alarm 0 Synchronization Busy Status Value Description 0 Write synchronization for ALARM0 register is complete. 1 Write synchronization for ALARM0 register is ongoing. Bit 3 – CLOCK Clock Register Synchronization Busy Status Value Description 0 Read/write synchronization for CLOCK register is complete. 1 Read/write synchronization for CLOCK register is ongoing. Bit 2 – FREQCORR Frequency Correction Synchronization Busy Status Value Description 0 Write synchronization for FREQCORR register is complete. 1 Write synchronization for FREQCORR register is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 414 SAM L10/L11 Family RTC – Real-Time Counter Bit 1 – ENABLE Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.ENABLE bit is complete. 1 Write synchronization for CTRLA.ENABLE bit is ongoing. Bit 0 – SWRST Software Reset Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.SWRST bit is complete. 1 Write synchronization for CTRLA.SWRST bit is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 415 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.9 Frequency Correction Name:  Offset:  Reset:  Property:  Bit Access Reset 7 SIGN R/W 0 FREQCORR 0x14 0x00 PAC Write-Protection, Write-Synchronized 6 5 4 R/W 0 R/W 0 R/W 0 3 VALUE[6:0] R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bit 7 – SIGN Correction Sign Value Description 0 The correction value is positive, i.e., frequency will be decreased. 1 The correction value is negative, i.e., frequency will be increased. Bits 6:0 – VALUE[6:0] Correction Value These bits define the amount of correction applied to the RTC prescaler. Value Description 0 Correction is disabled and the RTC frequency is unchanged. 1 - 127 The RTC frequency is adjusted according to the value. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 416 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.10 Clock Value in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset CLOCK 0x18 0x00000000 PAC Write-Protection, Write-Synchronized, Read-Synchronized 31 30 R/W 0 R/W 0 23 22 MONTH[1:0] R/W R/W 0 0 15 R/W 0 29 28 YEAR[5:0] R/W R/W 0 0 26 R/W 0 R/W 0 18 17 R/W 0 R/W 0 21 20 R/W 0 R/W 0 19 DAY[4:0] R/W 0 12 11 R/W 0 R/W 0 14 13 HOUR[3:0] R/W R/W 0 0 6 MINUTE[1:0] R/W R/W 0 0 27 7 5 4 R/W 0 R/W 0 25 24 MONTH[3:2] R/W R/W 0 0 10 9 MINUTE[5:2] R/W R/W 0 0 3 2 SECOND[5:0] R/W R/W 0 0 16 HOUR[4] R/W 0 8 R/W 0 1 0 R/W 0 R/W 0 Bits 31:26 – YEAR[5:0] Year The year offset with respect to the reference year (defined in software). The year is considered a leap year if YEAR[1:0] is zero. Bits 25:22 – MONTH[3:0] Month 1 – January 2 – February ... 12 – December Bits 21:17 – DAY[4:0] Day Day starts at 1 and ends at 28, 29, 30, or 31, depending on the month and year. Bits 16:12 – HOUR[4:0] Hour When CTRLA.CLKREP=0, the Hour bit group is in 24-hour format, with values 0-23. When CTRLA.CLKREP=1, HOUR[3:0] has values 1-12, and HOUR[4] represents AM (0) or PM (1). Bits 11:6 – MINUTE[5:0] Minute 0 – 59 Bits 5:0 – SECOND[5:0] Second 0 – 59 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 417 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.11 Alarm Value in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  ALARM 0x20 0x00000000 PAC Write-Protection, Write-Synchronized The 32-bit value of ALARM is continuously compared with the 32-bit CLOCK value, based on the masking set by MASK.SEL. When a match occurs, the Alarm n interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG.ALARM) is set on the next counter cycle, and the counter is cleared if CTRLA.MATCHCLR is '1'. Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 31 30 R/W 0 R/W 0 23 22 MONTH[1:0] R/W R/W 0 0 15 R/W 0 29 28 YEAR[5:0] R/W R/W 0 0 R/W 0 R/W 0 18 17 R/W 0 R/W 0 20 R/W 0 R/W 0 19 DAY[4:0] R/W 0 12 11 R/W 0 R/W 0 13 HOUR[3:0] R/W R/W 0 0 6 MINUTE[1:0] R/W R/W 0 0 26 21 14 7 27 5 4 R/W 0 R/W 0 25 24 MONTH[3:2] R/W R/W 0 0 10 9 MINUTE[5:2] R/W R/W 0 0 3 2 SECOND[5:0] R/W R/W 0 0 16 HOUR[4] R/W 0 8 R/W 0 1 0 R/W 0 R/W 0 Bits 31:26 – YEAR[5:0] Year The alarm year. Years are only matched if MASK.SEL is 6 Bits 25:22 – MONTH[3:0] Month The alarm month. Months are matched only if MASK.SEL is greater than 4. Bits 21:17 – DAY[4:0] Day The alarm day. Days are matched only if MASK.SEL is greater than 3. Bits 16:12 – HOUR[4:0] Hour The alarm hour. Hours are matched only if MASK.SEL is greater than 2. Bits 11:6 – MINUTE[5:0] Minute The alarm minute. Minutes are matched only if MASK.SEL is greater than 1. Bits 5:0 – SECOND[5:0] Second The alarm second. Seconds are matched only if MASK.SEL is greater than 0. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 418 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.12 Alarm Mask in Clock/Calendar mode (CTRLA.MODE=2) Name:  Offset:  Reset:  Property:  Bit 7 MASK 0x24 0x00 PAC Write-Protection, Write-Synchronized 6 5 4 3 Access Reset 2 R/W 0 1 SEL[2:0] R/W 0 0 R/W 0 Bits 2:0 – SEL[2:0] Alarm Mask Selection These bits define which bit groups of ALARM are valid. Value Name Description 0x0 OFF Alarm Disabled 0x1 SS Match seconds only 0x2 MMSS Match seconds and minutes only 0x3 HHMMSS Match seconds, minutes, and hours only 0x4 DDHHMMSS Match seconds, minutes, hours, and days only 0x5 MMDDHHMMSS Match seconds, minutes, hours, days, and months only 0x6 YYMMDDHHMMSS Match seconds, minutes, hours, days, months, and years 0x7 Reserved © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 419 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.13 General Purpose n Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit GP 0x40 + n*0x04 [n=0..1] 0x00000000 PAC Write-Protection, Write-Synchronized 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 28 27 GP[31:24] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 11 10 9 8 R/W 0 R/W 0 R/W 0 R/W 0 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 20 19 GP[23:16] R/W R/W 0 0 12 GP[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 GP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – GP[31:0] General Purpose These bits are for user-defined general purpose use, see 27.6.8.3 General Purpose Registers. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 420 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.14 Tamper Control Name:  Offset:  Reset:  Property:  Bit 31 TAMPCTRL 0x60 0x00000000 PAC Write-Protection, Enable-Protected 30 29 28 27 DEBNC3 26 DEBNC2 25 DEBNC1 24 DEBNC0 0 0 0 0 19 TAMLVL3 18 TAMLVL2 17 TAMLVL1 16 TAMLVL0 0 0 0 0 8 Access Reset Bit 23 22 21 20 Access Reset Bit 15 14 13 12 11 10 9 7 6 5 4 3 2 1 Access Reset Bit IN3ACT[1:0] Access Reset 0 IN2ACT[1:0] 0 0 IN1ACT[1:0] 0 0 0 IN0ACT[1:0] 0 0 0 Bits 24, 25, 26, 27 – DEBNCn Debounce Enable of Tamper Input INn [n=0..3] Note:  Debounce feature does not apply to the Active Layer Protection mode (TAMPCTRL.INACT = ACTL). Value 0 1 Description Debouncing is disabled for Tamper input INn Debouncing is enabled for Tamper input INn Bits 16, 17, 18, 19 – TAMLVLn Tamper Level Select of Tamper Input INn [n=0..3] Note:  Tamper Level feature does not apply to the Active Layer Protection mode (TAMPCTRL.INACT = ACTL). Value 0 1 Description A falling edge condition will be detected on Tamper input INn. A rising edge condition will be detected on Tamper input INn. Bits 0:1, 2:3, 4:5, 6:7 – INnACT Tamper Channel n Action [n=0..3] These bits determine the action taken by Tamper Channel n. Value Name Description 0x0 OFF Off (Disabled) 0x1 WAKE Wake and set Tamper flag 0x2 CAPTURE Capture timestamp and set Tamper flag 0x3 ACTL Compare RTC signal routed between INn and OUT pins . When a mismatch occurs, capture timestamp and set Tamper flag © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 421 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.15 Timestamp Value Name:  Offset:  Reset:  Property:  Bit 31 TIMESTAMP 0x64 0 - 30 29 28 27 26 R 0 R 0 R 0 R 0 R 0 25 24 MONTH[3:2] R R 0 0 23 22 MONTH[1:0] R R 0 0 21 20 18 17 R 0 R 0 19 DAY[4:0] R 0 R 0 R 0 13 12 11 R 0 R 0 R 0 R 0 6 MINUTE[1:0] R R 0 0 5 4 R 0 R 0 3 2 SECOND[5:0] R R 0 0 YEAR[5:0] Access Reset Bit Access Reset Bit R 0 15 14 HOUR[3:0] Access Reset R 0 Bit 7 Access Reset 10 9 MINUTE[5:2] R R 0 0 16 HOUR[4] R 0 8 R 0 1 0 R 0 R 0 Bits 31:26 – YEAR[5:0] Year The year value is captured by the TIMESTAMP when a tamper condition occurs. Bits 25:22 – MONTH[3:0] Month The month value is captured by the TIMESTAMP when a tamper condition occurs. Bits 21:17 – DAY[4:0] Day The day value is captured by the TIMESTAMP when a tamper condition occurs. Bits 16:12 – HOUR[4:0] Hour The hour value is captured by the TIMESTAMP when a tamper condition occurs. Bits 11:6 – MINUTE[5:0] Minute The minute value is captured by the TIMESTAMP when a tamper condition occurs. Bits 5:0 – SECOND[5:0] Second The second value is captured by the TIMESTAMP when a tamper condition occurs. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 422 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.16 Tamper ID Name:  Offset:  Reset:  Bit Access Reset Bit TAMPID 0x68 0x00000000 31 TAMPEVT R/W 0 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 TAMPID3 R/W 0 2 TAMPID2 R/W 0 1 TAMPID1 R/W 0 0 TAMPID0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit 31 – TAMPEVT Tamper Event Detected Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the tamper detection bit. Value Description 0 A tamper input event has not been detected 1 A tamper input event has been detected Bits 0, 1, 2, 3 – TAMPIDn Tamper on Channel n Detected [n=0..3] Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the tamper detection bit. Value Description 0 A tamper condition has not been detected on Channel n 1 A tamper condition has been detected on Channel n © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 423 SAM L10/L11 Family RTC – Real-Time Counter 27.7.6.17 Tamper Control B Name:  Offset:  Reset:  Property:  Bit TAMPCTRLB 0x6C 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 ALSI3 R/W 0 2 ALSI2 R/W 0 1 ALSI1 R/W 0 0 ALSI0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3 – ALSIn Active Layer Internal Select n [n=0..3] Note:  Only one ALSI bit must be set to enable Active Layer Protection on the TrustRAM. Value 0 1 Description Active layer Protection is monitoring the RTC signal using INn and OUTn tamper pins Active layer Protection is monitoring the RTC signal on the TrustRAM shield © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 424 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28. DMAC – Direct Memory Access Controller 28.1 Overview The Direct Memory Access Controller (DMAC) contains both a Direct Memory Access engine and a Cyclic Redundancy Check (CRC) engine. The DMAC can transfer data between memories and peripherals, and thus offload these tasks from the CPU. It enables high data transfer rates with minimum CPU intervention, and frees up CPU time. With access to all peripherals, the DMAC can handle automatic transfer of data between communication modules. The DMA part of the DMAC has several DMA channels which all can receive different types of transfer triggers to generate transfer requests from the DMA channels to the arbiter, see also the Block Diagram. The arbiter will grant one DMA channel at a time to act as the active channel. When an active channel has been granted, the fetch engine of the DMAC will fetch a transfer descriptor from the SRAM and store it in the internal memory of the active channel, which will execute the data transmission. An ongoing data transfer of an active channel can be interrupted by a higher prioritized DMA channel. The DMAC will write back the updated transfer descriptor from the internal memory of the active channel to SRAM, and grant the higher prioritized channel to start transfer as the new active channel. Once a DMA channel is done with its transfer, interrupts and events can be generated optionally. The DMAC has four bus interfaces: • • • • The data transfer bus is used for performing the actual DMA transfer. The AHB/APB Bridge bus is used when writing and reading the I/O registers of the DMAC. The descriptor fetch bus is used by the fetch engine to fetch transfer descriptors before data transfer can be started or continued. The write-back bus is used to write the transfer descriptor back to SRAM. All buses are AHB master interfaces but the AHB/APB Bridge bus, which is an APB slave interface. The CRC engine can be used by software to detect an accidental error in the transferred data and to take corrective action, such as requesting the data to be sent again or simply not using the incorrect data. 28.2 Features • • • • • Data transfer from: – Peripheral to peripheral – Peripheral to memory – Memory to peripheral – Memory to memory Transfer trigger sources – Software – Events from Event System – Dedicated requests from peripherals SRAM based transfer descriptors – Single transfer using one descriptor – Multi-buffer or circular buffer modes by linking multiple descriptors Up to 8 channels – Enable 8 independent transfers – Automatic descriptor fetch for each channel – Suspend/resume operation support for each channel Flexible arbitration scheme – 4 configurable priority levels for each channel © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 425 SAM L10/L11 Family DMAC – Direct Memory Access Controller • • • • • • • Block Diagram Figure 28-1. DMAC Block Diagram CPU M M AHB/APB Bridge SRAM Write-back S S Descriptor Fetch HIGH SPEED BUS MATRIX Data Transfer 28.3 – Fixed or round-robin priority scheme within each priority level From 1 to 256KB data transfer in a single block transfer Multiple addressing modes – Static – Configurable increment scheme Optional interrupt generation – On block transfer complete – On error detection – On channel suspend 4 event inputs – One event input for each of the 4 least significant DMA channels – Can be selected to trigger normal transfers, periodic transfers or conditional transfers – Can be selected to suspend or resume channel operation 4 event outputs – One output event for each of the 4 least significant DMA channels – Selectable generation on AHB, block, or transaction transfer complete Error management supported by write-back function – Dedicated Write-Back memory section for each channel to store ongoing descriptor transfer CRC polynomial software selectable to – CRC-16 (CRC-CCITT) – CRC-32 (IEEE® 802.3) DMAC MASTER Fetch Engine DMA Channels Channel n Transfer Triggers n n Channel 1 Channel 0 Interrupts Arbiter Active Channel Interrupt / Events Events CRC Engine © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 426 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.4 Signal Description Not applicable. 28.5 Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described below. 28.5.1 I/O Lines Not applicable. 28.5.2 Power Management The DMAC will continue to operate in any sleep mode where the selected source clock is running. The DMAC’s interrupts can be used to wake up the device from sleep modes. Events connected to the event system can trigger other operations in the system without exiting sleep modes. On hardware or software reset, all registers are set to their reset value. Related Links 22. PM – Power Manager 28.5.3 Clocks An AHB clock (CLK_DMAC_AHB) is required to clock the DMAC. This clock can be configured in the Main Clock peripheral (MCLK) before using the DMAC, and the default state of CLK_DMAC_AHB can be found in the MCLK.AHBMASK register. 28.5.4 DMA Not applicable. 28.5.5 Interrupts The interrupt request line is connected to the interrupt controller. Using the DMAC interrupt requires the interrupt controller to be configured first. 28.5.6 Events The events are connected to the event system. Related Links 33. EVSYS – Event System 28.5.7 Debug Operation When the CPU is halted in debug mode the DMAC will halt normal operation. The DMAC can be forced to continue operation during debugging. Refer to 28.8.6 DBGCTRL for details. 28.5.8 Register Access Protection All registers with write-access can be write-protected optionally by the Peripheral Access Controller (PAC), except for the following registers: • • • Interrupt Pending register (INTPEND) Channel ID register (CHID) Channel Interrupt Flag Status and Clear register (CHINTFLAG) Optional write-protection by the Peripheral Access Controller (PAC) is denoted by the "PAC Write-Protection" property in each individual register description. PAC write-protection does not apply to accesses through an external debugger. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 427 SAM L10/L11 Family DMAC – Direct Memory Access Controller Related Links 15. PAC - Peripheral Access Controller 28.5.9 SAM L11 TrustZone-Specific Register Access Protection On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. 28.5.10 Analog Connections Not applicable. 28.6 28.6.1 Functional Description Principle of Operation The DMAC consists of a DMA module and a CRC module. 28.6.1.1 DMA The DMAC can transfer data between memories and peripherals without interaction from the CPU. The data transferred by the DMAC are called transactions, and these transactions can be split into smaller data transfers. The following figure shows the relationship between the different transfer sizes: Figure 28-2. DMA Transfer Sizes Link Enabled Beat transfer • • • Link Enabled Burst transfer Link Enabled Block transfer DMA transaction Beat transfer: The size of one data transfer bus access, and the size is selected by writing the Beat Size bit group in the Block Transfer Control register (BTCTRL.BEATSIZE) Block transfer: The amount of data one transfer descriptor can transfer, and the amount can range from 1 to 64k beats. A block transfer can be interrupted. Transaction: The DMAC can link several transfer descriptors by having the first descriptor pointing to the second and so forth, as shown in the figure above. A DMA transaction is the complete transfer of all blocks within a linked list. A transfer descriptor describes how a block transfer should be carried out by the DMAC, and it must remain in SRAM. For further details on the transfer descriptor refer to 28.6.2.3 Transfer Descriptors. The figure above shows several block transfers linked together, which are called linked descriptors. For further information about linked descriptors, refer to 28.6.3.1 Linked Descriptors. A DMA transfer is initiated by an incoming transfer trigger on one of the DMA channels. This trigger can be configured to be either a software trigger, an event trigger, or one of the dedicated peripheral triggers. The transfer trigger will result in a DMA transfer request from the specific channel to the arbiter. If there are several DMA channels with pending transfer requests, the arbiter chooses which channel is granted access to become the active channel. The DMA channel granted access as the active channel will carry out the transaction as configured in the transfer © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 428 SAM L10/L11 Family DMAC – Direct Memory Access Controller descriptor. A current transaction can be interrupted by a higher prioritized channel, but will resume the block transfer when the according DMA channel is granted access as the active channel again. For each beat transfer, an optional output event can be generated. For each block transfer, optional interrupts and an optional output event can be generated. When a transaction is completed, dependent of the configuration, the DMA channel will either be suspended or disabled. 28.6.1.2 CRC The internal CRC engine supports two commonly used CRC polynomials: CRC-16 (CRC-CCITT) and CRC-32 (IEEE 802.3). It can be used on a selectable DMA channel, or on the I/O interface. Refer to 28.6.3.7 CRC Operation for details. 28.6.2 Basic Operation 28.6.2.1 Initialization The following DMAC registers are enable-protected, meaning that they can only be written when the DMAC is disabled (CTRL.DMAENABLE=0): • • Descriptor Base Memory Address register (BASEADDR) Write-Back Memory Base Address register (WRBADDR) The following DMAC bit is enable-protected, meaning that it can only be written when both the DMAC and CRC are disabled (CTRL.DMAENABLE=0 and CTRL.CRCENABLE=0): • Software Reset bit in Control register (CTRL.SWRST) The following DMA channel register is enable-protected, meaning that it can only be written when the corresponding DMA channel is disabled (CHCTRLA.ENABLE=0): • Channel Control B (CHCTRLB) register, except the Command bit (CHCTRLB.CMD) and the Channel Arbitration Level bit (CHCTRLB.LVL) The following DMA channel bit is enable-protected, meaning that it can only be written when the corresponding DMA channel is disabled: • Channel Software Reset bit in Channel Control A register (CHCTRLA.SWRST) The following CRC registers are enable-protected, meaning that they can only be written when the CRC is disabled (CTRL.CRCENABLE=0): • • CRC Control register (CRCCTRL) CRC Checksum register (CRCCHKSUM) Enable-protection is denoted by the "Enable-Protected" property in the register description. Before the DMAC is enabled it must be configured, as outlined by the following steps: • • • The SRAM address of where the descriptor memory section is located must be written to the Description Base Address (BASEADDR) register The SRAM address of where the write-back section should be located must be written to the Write-Back Memory Base Address (WRBADDR) register Priority level x of the arbiter can be enabled by setting the Priority Level x Enable bit in the Control register (CTRL.LVLENx=1) Before a DMA channel is enabled, the DMA channel and the corresponding first transfer descriptor must be configured, as outlined by the following steps: • • DMA channel configurations – The channel number of the DMA channel to configure must be written to the Channel ID (CHID) register – Trigger action must be selected by writing the Trigger Action bit group in the Channel Control B register (CHCTRLB.TRIGACT) – Trigger source must be selected by writing the Trigger Source bit group in the Channel Control B register (CHCTRLB.TRIGSRC) Transfer Descriptor © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 429 SAM L10/L11 Family DMAC – Direct Memory Access Controller – The size of each access of the data transfer bus must be selected by writing the Beat Size bit group in the Block Transfer Control register (BTCTRL.BEATSIZE) – The transfer descriptor must be made valid by writing a one to the Valid bit in the Block Transfer Control register (BTCTRL.VALID) – Number of beats in the block transfer must be selected by writing the Block Transfer Count (BTCNT) register – Source address for the block transfer must be selected by writing the Block Transfer Source Address (SRCADDR) register – Destination address for the block transfer must be selected by writing the Block Transfer Destination Address (DSTADDR) register If CRC calculation is needed, the CRC engine must be configured before it is enabled, as outlined by the following steps: • • • The CRC input source must selected by writing the CRC Input Source bit group in the CRC Control register (CRCCTRL.CRCSRC) The type of CRC calculation must be selected by writing the CRC Polynomial Type bit group in the CRC Control register (CRCCTRL.CRCPOLY) If I/O is selected as input source, the beat size must be selected by writing the CRC Beat Size bit group in the CRC Control register (CRCCTRL.CRCBEATSIZE) 28.6.2.2 Enabling, Disabling, and Resetting The DMAC is enabled by writing the DMA Enable bit in the Control register (CTRL.DMAENABLE) to '1'. The DMAC is disabled by writing a '0' to CTRL.DMAENABLE. A DMA channel is enabled by writing the Enable bit in the Channel Control A register (CHCTRLA.ENABLE) to '1', after writing the corresponding channel id to the Channel ID bit group in the Channel ID register (CHID.ID). A DMA channel is disabled by writing a '0' to CHCTRLA.ENABLE. The CRC is enabled by writing a '1' to the CRC Enable bit in the Control register (CTRL.CRCENABLE). The CRC is disabled by writing a '0' to CTRL.CRCENABLE. The DMAC is reset by writing a '1' to the Software Reset bit in the Control register (CTRL.SWRST) while the DMAC and CRC are disabled. All registers in the DMAC except DBGCTRL will be reset to their initial state. A DMA channel is reset by writing a '1' to the Software Reset bit in the Channel Control A register (CHCTRLA.SWRST), after writing the corresponding channel id to the Channel ID bit group in the Channel ID register (CHID.ID). The channel registers will be reset to their initial state. The corresponding DMA channel must be disabled in order for the reset to take effect. 28.6.2.3 Transfer Descriptors Together with the channel configurations the transfer descriptors decides how a block transfer should be executed. Before a DMA channel is enabled (CHCTRLA.ENABLE is written to one), and receives a transfer trigger, its first transfer descriptor has to be initialized and valid (BTCTRL.VALID). The first transfer descriptor describes the first block transfer of a transaction. All transfer descriptors must reside in SRAM. The addresses stored in the Descriptor Memory Section Base Address (BASEADDR) and Write-Back Memory Section Base Address (WRBADDR) registers tell the DMAC where to find the descriptor memory section and the write-back memory section. The descriptor memory section is where the DMAC expects to find the first transfer descriptors for all DMA channels. As BASEADDR points only to the first transfer descriptor of channel 0 (see figure below), all first transfer descriptors must be stored in a contiguous memory section, where the transfer descriptors must be ordered according to their channel number. For further details on linked descriptors, refer to 28.6.3.1 Linked Descriptors. The write-back memory section is the section where the DMAC stores the transfer descriptors for the ongoing block transfers. WRBADDR points to the ongoing transfer descriptor of channel 0. All ongoing transfer descriptors will be stored in a contiguous memory section where the transfer descriptors are ordered according to their channel number. The figure below shows an example of linked descriptors on DMA channel 0. For further details on linked descriptors, refer to 28.6.3.1 Linked Descriptors. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 430 SAM L10/L11 Family DMAC – Direct Memory Access Controller Figure 28-3. Memory Sections 0x00000000 DSTADDR DESCADDR Channel 0 – Last Descriptor SRCADDR BTCNT BTCTRL DESCADDR DSTADDR DESCADDR Channel 0 – Descriptor n-1 SRCADDR BTCNT BTCTRL Descriptor Section Channel n – First Descriptor DESCADDR BASEADDR Channel 2 – First Descriptor Channel 1 – First Descriptor Channel 0 – First Descriptor DSTADDR SRCADDR BTCNT BTCTRL Write-Back Section Channel n Ongoing Descriptor WRBADDR Channel 2 Ongoing Descriptor Channel 1 Ongoing Descriptor Channel 0 Ongoing Descriptor Undefined Undefined Undefined Undefined Undefined Device Memory Space The size of the descriptor and write-back memory sections is dependent on the number of the most significant enabled DMA channel m, as shown below: ���� = 128bits ⋅ � + 1 For memory optimization, it is recommended to always use the less significant DMA channels if not all channels are required. The descriptor and write-back memory sections can either be two separate memory sections, or they can share memory section (BASEADDR=WRBADDR). The benefit of having them in two separate sections, is that the same transaction for a channel can be repeated without having to modify the first transfer descriptor. The benefit of having descriptor memory and write-back memory in the same section is that it requires less SRAM. 28.6.2.4 Arbitration If a DMA channel is enabled and not suspended when it receives a transfer trigger, it will send a transfer request to the arbiter. When the arbiter receives the transfer request it will include the DMA channel in the queue of channels having pending transfers, and the corresponding Pending Channel x bit in the Pending Channels registers (PENDCH.PENDCHx) will be set. Depending on the arbitration scheme, the arbiter will choose which DMA channel will be the next active channel. The active channel is the DMA channel being granted access to perform its next transfer. When the arbiter has granted a DMA channel access to the DMAC, the corresponding bit PENDCH.PENDCHx will be cleared. See also the following figure. If the upcoming transfer is the first for the transfer request, the corresponding Busy Channel x bit in the Busy Channels register will be set (BUSYCH.BUSYCHx=1), and it will remain '1' for the subsequent granted transfers. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 431 SAM L10/L11 Family DMAC – Direct Memory Access Controller When the channel has performed its granted transfer(s) it will be either fed into the queue of channels with pending transfers, set to be waiting for a new transfer trigger, suspended, or disabled. This depends on the channel and block transfer configuration. If the DMA channel is fed into the queue of channels with pending transfers, the corresponding BUSYCH.BUSYCHx will remain '1'. If the DMA channel is set to wait for a new transfer trigger, suspended, or disabled, the corresponding BUSYCH.BUSYCHx will be cleared. If a DMA channel is suspended while it has a pending transfer, it will be removed from the queue of pending channels, but the corresponding PENDCH.PENDCHx will remain set. When the same DMA channel is resumed, it will be added to the queue of pending channels again. If a DMA channel gets disabled (CHCTRLA.ENABLE=0) while it has a pending transfer, it will be removed from the queue of pending channels, and the corresponding PENDCH.PENDCHx will be cleared. Figure 28-4. Arbiter Overview Arbiter Channel Pending Priority decoder Channel Suspend Channel 0 Channel Priority Level Channel Burst Done Burst Done Channel Pending Transfer Request Channel Number Channel Suspend Active Channel Channel N Channel Priority Level Channel Burst Done Level Enable Active.LVLEXx PRICTRLx.LVLPRI CTRL.LVLENx Priority Levels When a channel level is pending or the channel is transferring data, the corresponding Level Executing bit is set in the Active Channel and Levels register (ACTIVE.LVLEXx). Each DMA channel supports a 4-level priority scheme. The priority level for a channel is configured by writing to the Channel Arbitration Level bit group in the Channel Control B register (CHCTRLB.LVL). As long as all priority levels are enabled, a channel with a higher priority level number will have priority over a channel with a lower priority level number. Each priority level x is enabled by setting the corresponding Priority Level x Enable bit in the Control register (CTRL.LVLENx=1). Within each priority level the DMAC's arbiter can be configured to prioritize statically or dynamically: Static Arbitration within a priority level is selected by writing a '0' to the Level x Round-Robin Scheduling Enable bit in the Priority Control 0 register (PRICTRL0.RRLVLENx). When static arbitration is selected, the arbiter will prioritize a low channel number over a high channel number as shown in the figure below. When using the static arbitration there is a risk of high channel numbers never being granted access as the active channel. This can be avoided using a dynamic arbitration scheme. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 432 SAM L10/L11 Family DMAC – Direct Memory Access Controller Figure 28-5. Static Priority Scheduling Lowest Channel Channel 0 Highest Priority . . . Channel x Channel x+1 . . . Highest Channel Lowest Priority Channel N Dynamic Arbitration within a priority level is selected by writing a '1' to PRICTRL0.RRLVLENx. The dynamic arbitration scheme in the DMAC is round-robin. With the round-robin scheme, the channel number of the last channel being granted access will have the lowest priority the next time the arbiter has to grant access to a channel within the same priority level, as shown in Figure 28-6. The channel number of the last channel being granted access as the active channel is stored in the Level x Channel Priority Number bit group in the Priority Control 0 register (PRICTRL0.LVLPRIx) for the corresponding priority level. Figure 28-6. Dynamic (Round-Robin) Priority Scheduling Channel x last acknowledge request Channel (x+1) last acknowledge request Channel 0 Channel 0 . . . Channel x Channel x+1 Lowest Priority Channel x Highest Priority Channel x+1 Lowest Priority Channel x+2 Highest Priority . . . Channel N Channel N 28.6.2.5 Data Transmission Before the DMAC can perform a data transmission, a DMA channel has to be configured and enabled, its corresponding transfer descriptor has to be initialized, and the arbiter has to grant the DMA channel access as the active channel. Once the arbiter has granted a DMA channel access as the active channel (refer to DMA Block Diagram section) the transfer descriptor for the DMA channel will be fetched from SRAM using the fetch bus, and stored in the internal memory for the active channel. For a new block transfer, the transfer descriptor will be fetched from the descriptor memory section (BASEADDR); For an ongoing block transfer, the descriptor will be fetched from the write-back © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 433 SAM L10/L11 Family DMAC – Direct Memory Access Controller memory section (WRBADDR). By using the data transfer bus, the DMAC will read the data from the current source address and write it to the current destination address. For further details on how the current source and destination addresses are calculated, refer to the section on Addressing. The arbitration procedure is performed after each transfer. If the current DMA channel is granted access again, the block transfer counter (BTCNT) of the internal transfer descriptor will be decremented by the number of beats in a transfer, the optional output event Beat will be generated if configured and enabled, and the active channel will perform a new transfer. If a different DMA channel than the current active channel is granted access, the block transfer counter value will be written to the write-back section before the transfer descriptor of the newly granted DMA channel is fetched into the internal memory of the active channel. When a block transfer has come to its end (BTCNT is zero), the Valid bit in the Block Transfer Control register will be cleared (BTCTRL.VALID=0) before the entire transfer descriptor is written to the write-back memory. The optional interrupts, Channel Transfer Complete and Channel Suspend, and the optional output event Block, will be generated if configured and enabled. After the last block transfer in a transaction, the Next Descriptor Address register (DESCADDR) will hold the value 0x00000000, and the DMA channel will either be suspended or disabled, depending on the configuration in the Block Action bit group in the Block Transfer Control register (BTCTRL.BLOCKACT). If the transaction has further block transfers pending, DESCADDR will hold the SRAM address to the next transfer descriptor to be fetched. The DMAC will fetch the next descriptor into the internal memory of the active channel and write its content to the write-back section for the channel, before the arbiter gets to choose the next active channel. 28.6.2.6 Transfer Triggers and Actions A DMA transfer through a DMA channel can be started only when a DMA transfer request is detected, and the DMA channel has been granted access to the DMA. A transfer request can be triggered from software, from a peripheral, or from an event. There are dedicated Trigger Source selections for each DMA Channel Control B (CHCTRLB.TRIGSRC). The trigger actions are available in the Trigger Action bit group in the Channel Control B register (CHCTRLB.TRIGACT). By default, a trigger generates a request for a block transfer operation. If a single descriptor is defined for a channel, the channel is automatically disabled when a block transfer has been completed. If a list of linked descriptors is defined for a channel, the channel is automatically disabled when the last descriptor in the list is executed. If the list still has descriptors to execute, the channel will be waiting for the next block transfer trigger. When enabled again, the channel will wait for the next block transfer trigger. The trigger actions can also be configured to generate a request for a beat transfer (CHCTRLB.TRIGACT=0x2) or transaction transfer (CHCTRLB.TRIGACT=0x3) instead of a block transfer (CHCTRLB.TRIGACT=0x0). Figure 28-7 shows an example where triggers are used with two linked block descriptors. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 434 SAM L10/L11 Family DMAC – Direct Memory Access Controller Figure 28-7. Trigger Action and Transfers Beat Trigger Action CHENn Trigger Lost Trigger PENDCHn BUSYCHn Block Transfer Block Transfer Data Transfer BEAT BEAT BEAT BEAT BEAT BEAT Block Trigger Action CHENn Trigger Lost Trigger PENDCHn BUSYCHn Block Transfer Block Transfer Data Transfer BEAT BEAT BEAT BEAT BEAT BEAT BEAT BEAT BEAT BEAT Transaction Trigger Action CHENn Trigger Lost Trigger PENDCHn BUSYCHn Block Transfer Block Transfer Data Transfer BEAT BEAT If the trigger source generates a transfer request for a channel during an ongoing transfer, the new transfer request will be kept pending (CHSTATUS.PEND=1), and the new transfer can start after the ongoing one is done. Only one pending transfer can be kept per channel. If the trigger source generates more transfer requests while one is already pending, the additional ones will be lost. All channels pending status flags are also available in the Pending Channels register (PENDCH). When the transfer starts, the corresponding Channel Busy status flag is set in Channel Status register (CHSTATUS.BUSY). When the trigger action is complete, the Channel Busy status flag is cleared. All channel busy status flags are also available in the Busy Channels register (BUSYCH) in DMAC. 28.6.2.7 Addressing Each block transfer needs to have both a source address and a destination address defined. The source address is set by writing the Transfer Source Address (SRCADDR) register, the destination address is set by writing the Transfer Destination Address (SRCADDR) register. The addressing of this DMAC module can be static or incremental, for either source or destination of a block transfer, or both. Incrementation for the source address of a block transfer is enabled by writing the Source Address Incrementation Enable bit in the Block Transfer Control register (BTCTRL.SRCINC=1). The step size of the incrementation is configurable and can be chosen by writing the Step Selection bit in the Block Transfer Control register (BTCTRL.STEPSEL=1) and writing the desired step size in the Address Increment Step Size bit group in the Block Transfer Control register (BTCTRL.STEPSIZE). If BTCTRL.STEPSEL=0, the step size for the source incrementation will be the size of one beat. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 435 SAM L10/L11 Family DMAC – Direct Memory Access Controller When source address incrementation is configured (BTCTRL.SRCINC=1), SRCADDR is calculated as follows: If BTCTRL.STEPSEL=1: SRCADDR = SRCADDR����� + ����� ⋅ �������� + 1 ⋅ 2STEPSIZE If BTCTRL.STEPSEL=0: SRCADDR = SRCADDR����� + ����� ⋅ �������� + 1 • • • • SRCADDRSTART is the source address of the first beat transfer in the block transfer BTCNT is the initial number of beats remaining in the block transfer BEATSIZE is the configured number of bytes in a beat STEPSIZE is the configured number of beats for each incrementation The following figure shows an example where DMA channel 0 is configured to increment the source address by one beat after each beat transfer (BTCTRL.SRCINC=1), and DMA channel 1 is configured to increment the source address by two beats (BTCTRL.SRCINC=1, BTCTRL.STEPSEL=1, and BTCTRL.STEPSIZE=0x1). As the destination address for both channels are peripherals, destination incrementation is disabled (BTCTRL.DSTINC=0). Figure 28-8. Source Address Increment SRC Data Buffer a b c d e f Incrementation for the destination address of a block transfer is enabled by setting the Destination Address Incrementation Enable bit in the Block Transfer Control register (BTCTRL.DSTINC=1). The step size of the incrementation is configurable by clearing BTCTRL.STEPSEL=0 and writing BTCTRL.STEPSIZE to the desired step size. If BTCTRL.STEPSEL=1, the step size for the destination incrementation will be the size of one beat. When the destination address incrementation is configured (BTCTRL.DSTINC=1), DSTADDR must be set and calculated as follows: ������� = ������������ + ����� • �������� + 1 • 2�������� ������� = ������������ + ����� • �������� + 1 • • • • where BTCTRL.STEPSEL is zero where BTCTRL.STEPSEL is one DSTADDRSTART is the destination address of the first beat transfer in the block transfer BTCNT is the initial number of beats remaining in the block transfer BEATSIZE is the configured number of bytes in a beat STEPSIZE is the configured number of beats for each incrementation The followiong figure shows an example where DMA channel 0 is configured to increment destination address by one beat (BTCTRL.DSTINC=1) and DMA channel 1 is configured to increment destination address by two beats (BTCTRL.DSTINC=1, BTCTRL.STEPSEL=0, and BTCTRL.STEPSIZE=0x1). As the source address for both channels are peripherals, source incrementation is disabled (BTCTRL.SRCINC=0). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 436 SAM L10/L11 Family DMAC – Direct Memory Access Controller Figure 28-9. Destination Address Increment DST Data Buffer a b c d 28.6.2.8 Error Handling If a bus error is received from an AHB slave during a DMA data transfer, the corresponding active channel is disabled and the corresponding Channel Transfer Error Interrupt flag in the Channel Interrupt Status and Clear register (CHINTFLAG.TERR) is set. If enabled, the optional transfer error interrupt is generated. The transfer counter will not be decremented and its current value is written-back in the write-back memory section before the channel is disabled. When the DMAC fetches an invalid descriptor (BTCTRL.VALID=0) or when the channel is resumed and the DMA fetches the next descriptor with null address (DESCADDR=0x00000000), the corresponding channel operation is suspended, the Channel Suspend Interrupt Flag in the Channel Interrupt Flag Status and Clear register (CHINTFLAG.SUSP) is set, and the Channel Fetch Error bit in the Channel Status register (CHSTATUS.FERR) is set. If enabled, the optional suspend interrupt is generated. 28.6.3 Additional Features 28.6.3.1 Linked Descriptors A transaction can consist of either a single block transfer or of several block transfers. When a transaction consists of several block transfers it is done with the help of linked descriptors. Figure 28-3 illustrates how linked descriptors work. When the first block transfer is completed on DMA channel 0, the DMAC fetches the next transfer descriptor, which is pointed to by the value stored in the Next Descriptor Address (DESCADDR) register of the first transfer descriptor. Fetching the next transfer descriptor (DESCADDR) is continued until the last transfer descriptor. When the block transfer for the last transfer descriptor is executed and DESCADDR=0x00000000, the transaction is terminated. For further details on how the next descriptor is fetched from SRAM, refer to section 28.6.2.5 Data Transmission. 28.6.3.1.1 Adding Descriptor to the End of a List To add a new descriptor at the end of the descriptor list, create the descriptor in SRAM, with DESCADDR=0x00000000 indicating that it is the new last descriptor in the list, and modify the DESCADDR value of the current last descriptor to the address of the newly created descriptor. 28.6.3.1.2 Modifying a Descriptor in a List In order to add descriptors to a linked list, the following actions must be performed: 1. 2. 3. 4. Enable the Suspend interrupt for the DMA channel. Enable the DMA channel. Reserve memory space in SRAM to configure a new descriptor. Configure the new descriptor: – Set the next descriptor address (DESCADDR) – Set the destination address (DSTADDR) – Set the source address (SRCADDR) – Configure the block transfer control (BTCTRL) including • Optionally enable the Suspend block action © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 437 SAM L10/L11 Family DMAC – Direct Memory Access Controller 5. 6. 7. • Set the descriptor VALID bit Clear the VALID bit for the existing list and for the descriptor which has to be updated. Read DESCADDR from the Write-Back memory. – If the DMA has not already fetched the descriptor which requires changes (i.e., DESCADDR is wrong): • Update the DESCADDR location of the descriptor from the List • Optionally clear the Suspend block action • Set the descriptor VALID bit to '1' • Optionally enable the Resume software command – If the DMA is executing the same descriptor as the one which requires changes: • Set the Channel Suspend software command and wait for the Suspend interrupt • Update the next descriptor address (DESCRADDR) in the write-back memory • Clear the interrupt sources and set the Resume software command • Update the DESCADDR location of the descriptor from the List • Optionally clear the Suspend block action • Set the descriptor VALID bit to '1' Go to step 4 if needed. 28.6.3.1.3 Adding a Descriptor Between Existing Descriptors To insert a new descriptor 'C' between two existing descriptors ('A' and 'B'), the descriptor currently executed by the DMA must be identified. 1. 2. 3. If DMA is executing descriptor B, descriptor C cannot be inserted. If DMA has not started to execute descriptor A, follow the steps: 2.1. Set the descriptor A VALID bit to '0'. 2.2. Set the DESCADDR value of descriptor A to point to descriptor C instead of descriptor B. 2.3. Set the DESCADDR value of descriptor C to point to descriptor B. 2.4. Set the descriptor A VALID bit to '1'. If DMA is executing descriptor A: 3.1. Apply the software suspend command to the channel and 3.2. Perform steps 2.1 through 2.4. 3.3. Apply the software resume command to the channel. 28.6.3.2 Channel Suspend The channel operation can be suspended at any time by software by writing a '1' to the Suspend command in the Command bit field of Channel Control B register (CHCTRLB.CMD). After the ongoing burst transfer is completed, the channel operation is suspended and the suspend command is automatically cleared. When suspended, the Channel Suspend Interrupt flag in the Channel Interrupt Status and Clear register is set (CHINTFLAG.SUSP=1) and the optional suspend interrupt is generated. By configuring the block action to suspend by writing Block Action bit group in the Block Transfer Control register (BTCTRL.BLOCKACT is 0x2 or 0x3), the DMA channel will be suspended after it has completed a block transfer. The DMA channel will be kept enabled and will be able to receive transfer triggers, but it will be removed from the arbitration scheme. If an invalid transfer descriptor (BTCTRL.VALID=0) is fetched from SRAM, the DMA channel will be suspended, and the Channel Fetch Error bit in the Channel Status register(CHASTATUS.FERR) will be set. Note:  Only enabled DMA channels can be suspended. If a channel is disabled when it is attempted to be suspended, the internal suspend command will be ignored. For more details on transfer descriptors, refer to section 28.6.2.3 Transfer Descriptors. 28.6.3.3 Channel Resume and Next Suspend Skip A channel operation can be resumed by software by setting the Resume command in the Command bit field of the Channel Control B register (CHCTRLB.CMD). If the channel is already suspended, the channel operation resumes from where it previously stopped when the Resume command is detected. When the Resume command is issued © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 438 SAM L10/L11 Family DMAC – Direct Memory Access Controller before the channel is suspended, the next suspend action is skipped and the channel continues the normal operation. Figure 28-10. Channel Suspend/Resume Operation CHENn Memory Descriptor Fetch Transfer Descriptor 2 (suspend enabled) Descriptor 1 (suspend enabled) Descriptor 0 (suspend disabled) Block Transfer 1 Block Transfer 0 Channel suspended Descriptor 3 (last) Block Transfer 3 Block Transfer 2 Resume Command Suspend skipped 28.6.3.4 Event Input Actions The event input actions are available only on the four least significant DMA channels. For details on channels with event input support, refer to the in the Event system documentation. Before using event input actions, the event controller must be configured first according to the following table, and the Channel Event Input Enable bit in the Channel Control B register (CHCTRLB.EVIE) must be written to '1'. Refer also to 28.6.6 Events. Table 28-1. Event Input Action Action CHCTRLB.EVACT CHCTRLB.TRGSRC None NOACT - Normal Transfer TRIG DISABLE Conditional Transfer on Strobe TRIG any peripheral Conditional Transfer CTRIG Conditional Block Transfer CBLOCK Channel Suspend SUSPEND Channel Resume RESUME Skip Next Block Suspend SSKIP Normal Transfer The event input is used to trigger a beat or burst transfer on peripherals. The event is acknowledged as soon as the event is received. When received, both the Channel Pending status bit in the Channel Status register (CHSTATUS.PEND) and the corresponding Channel n bit in the Pending Channels register (28.8.13 PENDCH.PENDCHn) are set. If the event is received while the channel is pending, the event trigger is lost. The figure below shows an example where beat transfers are enabled by internal events. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 439 SAM L10/L11 Family DMAC – Direct Memory Access Controller Figure 28-11. Beat Event Trigger Action CHENn Peripheral Trigger Trigger Lost Event PENDCHn BUSYCHn Block Transfer Data Transfer BEAT Block Transfer BEAT BEAT BEAT BEAT BEAT Conditional Transfer on Strobe The event input is used to trigger a transfer on peripherals with pending transfer requests. This event action is intended to be used with peripheral triggers, e.g. for timed communication protocols or periodic transfers between peripherals: only when the peripheral trigger coincides with the occurrence of a (possibly cyclic) event the transfer is issued. The event is acknowledged as soon as the event is received. The peripheral trigger request is stored internally when the previous trigger action is completed (i.e. the channel is not pending) and when an active event is received. If the peripheral trigger is active, the DMA will wait for an event before the peripheral trigger is internally registered. When both event and peripheral transfer trigger are active, both CHSTATUS.PEND and 28.8.13 PENDCH.PENDCHn are set. A software trigger will now trigger a transfer. The figure below shows an example where the peripheral beat transfer is started by a conditional strobe event action. Figure 28-12. Periodic Event with Beat Peripheral Triggers Trigger Lost Trigger Lost Event Peripheral Trigger PENDCHn Block Transfer Data Transfer BEAT Conditional Transfer The event input is used to trigger a conditional transfer on peripherals with pending transfer requests. As example, this type of event can be used for peripheral-to-peripheral transfers, where one peripheral is the source of event and the second peripheral is the source of the trigger. Each peripheral trigger is stored internally when the event is received. When the peripheral trigger is stored internally, the Channel Pending status bit is set (CHSTATUS.PEND), the respective Pending Channel n Bit in the Pending Channels register is set (28.8.13 PENDCH.PENDCHn), and the event is acknowledged. A software trigger will now trigger a transfer. The figure below shows an example where conditional event is enabled with peripheral beat trigger requests. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 440 SAM L10/L11 Family DMAC – Direct Memory Access Controller Figure 28-13. Conditional Event with Beat Peripheral Triggers Event Peripheral Trigger PENDCHn Data Transfer Block Transfer BEAT BEAT Conditional Block Transfer The event input is used to trigger a conditional block transfer on peripherals. Before starting transfers within a block, an event must be received. When received, the event is acknowledged when the block transfer is completed. A software trigger will trigger a transfer. The figure below shows an example where conditional event block transfer is started with peripheral beat trigger requests. Figure 28-14. Conditional Block Transfer with Beat Peripheral Triggers Event Peripheral Trigger PENDCHn Block Transfer Data Transfer Block Transfer BEAT BEAT BEAT BEAT Channel Suspend The event input is used to suspend an ongoing channel operation. The event is acknowledged when the current AHB access is completed. For further details on Channel Suspend, refer to 28.6.3.2 Channel Suspend. Channel Resume The event input is used to resume a suspended channel operation. The event is acknowledged as soon as the event is received and the Channel Suspend Interrupt Flag (CHINTFLAG.SUSP) is cleared. For further details refer to 28.6.3.2 Channel Suspend. Skip Next Block Suspend This event can be used to skip the next block suspend action. If the channel is suspended before the event rises, the channel operation is resumed and the event is acknowledged. If the event rises before a suspend block action is detected, the event is kept until the next block suspend detection. When the block transfer is completed, the channel continues the operation (not suspended) and the event is acknowledged. 28.6.3.5 Event Output Selection Event output selection is available only for the four least significant DMA channels. The pulse width of an event output from a channel is one AHB clock cycle. The output of channel events is enabled by writing a '1' to the Channel Event Output Enable bit in the Control B register (CHCTRLB.EVOE). The event output cause is selected by writing to the Event Output Selection bits in the © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 441 SAM L10/L11 Family DMAC – Direct Memory Access Controller Block Transfer Control register (BTCTRL.EVOSEL). It is possible to generate events after each block transfer (BTCTRL.EVOSEL=0x1) or beat transfer (BTCTRL.EVOSEL=0x3). To enable an event being generated when a transaction is complete, the block event selection must be set in the last transfer descriptor only. The figure Figure 28-15 shows an example where the event output generation is enabled in the first block transfer, and disabled in the second block. Figure 28-15. Event Output Generation Beat Event Output Block Transfer Data Transfer Block Transfer BEAT BEAT BEAT BEAT Event Output Block Event Output Block Transfer Data Transfer BEAT Block Transfer BEAT BEAT BEAT Event Output 28.6.3.6 Aborting Transfers Transfers on any channel can be aborted gracefully by software by disabling the corresponding DMA channel. It is also possible to abort all ongoing or pending transfers by disabling the DMAC. When a DMA channel disable request or DMAC disable request is detected: • • Ongoing transfers of the active channel will be disabled when the ongoing beat transfer is completed and the write-back memory section is updated. This prevents transfer corruption before the channel is disabled. All other enabled channels will be disabled in the next clock cycle. The corresponding Channel Enable bit in the Channel Control A register is cleared (CHCTRLA.ENABLE=0) when the channel is disabled. The corresponding DMAC Enable bit in the Control register is cleared (CTRL.DMAENABLE=0) when the entire DMAC module is disabled. 28.6.3.7 CRC Operation A cyclic redundancy check (CRC) is an error detection technique used to find errors in data. It is commonly used to determine whether the data during a transmission, or data present in data and program memories has been corrupted or not. A CRC takes a data stream or a block of data as input and generates a 16- or 32-bit output that can be appended to the data and used as a checksum. When the data is received, the device or application repeats the calculation: If the new CRC result does not match the one calculated earlier, the block contains a data error. The application will then detect this and may take a corrective action, such as requesting the data to be sent again or simply not using the incorrect data. The CRC engine in DMAC supports two commonly used CRC polynomials: CRC-16 (CRC-CCITT) and CRC-32 (IEEE 802.3). Typically, applying CRC-n (CRC-16 or CRC-32) to a data block of arbitrary length will detect any single alteration that is ≤n bits in length, and will detect the fraction 1-2-n of all longer error bursts. • CRC-16: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 442 SAM L10/L11 Family DMAC – Direct Memory Access Controller • – Polynomial: x16+ x12+ x5+ 1 – Hex value: 0x1021 CRC-32: – Polynomial: x32+x26+ x23+ x22+x16+ x12+ x11+ x10+ x8+ x7+ x5+ x4+ x2+ x + 1 – Hex value: 0x04C11DB7 The data source for the CRC engine can either be one of the DMA channels or the APB bus interface, and must be selected by writing to the CRC Input Source bits in the CRC Control register (CRCCTRL.CRCSRC). The CRC engine then takes data input from the selected source and generates a checksum based on these data. The checksum is available in the CRC Checksum register (CRCCHKSUM). When CRC-32 polynomial is used, the final checksum read is bit reversed and complemented, as shown in Figure 28-16. The CRC polynomial is selected by writing to the CRC Polynomial Type bit in the CRC Control register (CRCCTRL.CRCPOLY), the default is CRC-16. The CRC engine operates on byte only. When the DMA is used as data source for the CRC engine, the DMA channel beat size setting will be used. When used with APB bus interface, the application must select the CRC Beat Size bit field of CRC Control register (CRCCTRL.CRCBEATSIZE). 8-, 16-, or 32-bit bus transfer access type is supported. The corresponding number of bytes will be written in the CRCDATAIN register and the CRC engine will operate on the input data in a byte by byte manner. Figure 28-16. CRC Generator Block Diagram DMAC Channels CRCDATAIN CRCCTRL 8 16 8 CRC-16 32 CRC-32 crc32 CHECKSUM bit-reverse + complement Checksum read CRC on DMA data CRC-16 or CRC-32 calculations can be performed on data passing through any DMA channel. Once a DMA channel is selected as the source, the CRC engine will continuously generate the CRC on the data passing through the DMA channel. The checksum is available for readout once the DMA transaction is completed or aborted. A CRC can also be generated on SRAM, Flash, or I/O memory by passing these data through a DMA channel. If the latter is done, the destination register for the DMA data can be the data input (CRCDATAIN) register in the CRC engine. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 443 SAM L10/L11 Family DMAC – Direct Memory Access Controller CRC using the I/O interface Before using the CRC engine with the I/O interface, the application must set the CRC Beat Size bits in the CRC Control register (CRCCTRL.CRCBEATSIZE). 8/16/32-bit bus transfer type can be selected. CRC can be performed on any data by loading them into the CRC engine using the CPU and writing the data to the CRCDATAIN register. Using this method, an arbitrary number of bytes can be written to the register by the CPU, and CRC is done continuously for each byte. This means if a 32-bit data is written to the CRCDATAIN register the CRC engine takes four cycles to calculate the CRC. The CRC complete is signaled by a set CRCBUSY bit in the CRCSTATUS register. New data can be written only when CRCBUSY flag is not set. 28.6.4 DMA Operation Not applicable. 28.6.5 Interrupts The DMAC channels have the following interrupt sources: • • • Transfer Complete (TCMPL): Indicates that a block transfer is completed on the corresponding channel. Refer to 28.6.2.5 Data Transmission for details. Transfer Error (TERR): Indicates that a bus error has occurred during a burst transfer, or that an invalid descriptor has been fetched. Refer to 28.6.2.8 Error Handling for details. Channel Suspend (SUSP): Indicates that the corresponding channel has been suspended. Refer to 28.6.3.2 Channel Suspend and 28.6.2.5 Data Transmission for details. Each interrupt source has an interrupt flag associated with it. The interrupt flag in the Channel Interrupt Flag Status and Clear (CHINTFLAG) register is set when the interrupt condition occurs. Each interrupt can be individually enabled by setting the corresponding bit in the Channel Interrupt Enable Set register (CHINTENSET=1), and disabled by setting the corresponding bit in the Channel Interrupt Enable Clear register (CHINTENCLR=1). An interrupt request is generated when the interrupt flag is set and the corresponding interrupt is enabled. The interrupt request remains active until the interrupt flag is cleared, the interrupt is disabled, the DMAC is reset or the corresponding DMA channel is reset. See CHINTFLAG for details on how to clear interrupt flags. All interrupt requests are ORed together on system level to generate one combined interrupt request to the NVIC. The user must read the Channel Interrupt Status (INTSTATUS) register to identify the channels with pending interrupts and must read the Channel Interrupt Flag Status and Clear (CHINTFLAG) register to determine which interrupt condition is present for the corresponding channel. It is also possible to read the Interrupt Pending register (INTPEND), which provides the lowest channel number with pending interrupt and the respective interrupt flags. Note:  Interrupts must be globally enabled for interrupt requests to be generated. 28.6.6 Events The DMAC can generate the following output events: • Channel (CH0-3): Generated when a block transfer for a given channel has been completed, or when a beat transfer within a block transfer for a given channel has been completed. Refer to Event Output Selection for details. Setting the Channel Control B Event Output Enable bit (CHCTRLB.EVOE=1) enables the corresponding output event configured in the Event Output Selection bit group in the Block Transfer Control register (BTCTRL.EVOSEL). Clearing CHCTRLB.EVOE=0 disables the corresponding output event. The DMAC can take the following actions on an input event (CH0-3): • • • • • • • Transfer and Periodic Transfer Trigger (TRIG): normal transfer or periodic transfers on peripherals are enabled Conditional Transfer Trigger (CTRIG): conditional transfers on peripherals are enabled Conditional Block Transfer Trigger (CBLOCK): conditional block transfers on peripherals are enabled Channel Suspend Operation (SUSPEND): suspend a channel operation Channel Resume Operation (RESUME): resume a suspended channel operation Skip Next Block Suspend Action (SSKIP): skip the next block suspend transfer condition Increase Priority (INCPRI): increase channel priority © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 444 SAM L10/L11 Family DMAC – Direct Memory Access Controller Setting the Channel Control B Event Input Enable bit (CHCTRLB.EVIE=1) enables the corresponding action on input event. Clearing this bit disables the corresponding action on input event. Note that several actions can be enabled for incoming events. If several events are connected to the peripheral, any enabled action will be taken for any of the incoming events. For further details on event input actions, refer to Event Input Actions. Note:  Event input and outputs are not available for every channel. Refer to 28.2 Features for more information. Related Links 33. EVSYS – Event System 28.6.7 Sleep Mode Operation Each DMA channel can be configured to operate in any sleep mode. To be able to run in standby, the RUNSTDBY bit in Channel Control A register (CHCTRLA.RUNSTDBY) must be written to '1'. The DMAC can wake up the device using interrupts from any sleep mode or perform actions through the Event System. For channels with CHCTRLA.RUNSTDBY = 0, it is up to software to stop DMA transfers on these channels and wait for completion before going to standby mode using the following sequence: 1. 2. 3. 4. 28.6.8 Suspend the DMAC channels for which CHCTRLA.RUNSTDBY = 0. Check the SYNCBUSY bits of registers accessed by the DMAC channels being suspended. Go to sleep. When the device wakes up, resume the suspended channels. Synchronization Not applicable. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 445 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.7 Register Summary Offset Name 0x00 CTRL 0x02 CRCCTRL 0x04 CRCDATAIN 0x08 CRCCHKSUM 0x0C 0x0D 0x0E 0x0F CRCSTATUS DBGCTRL QOSCTRL Reserved 0x10 SWTRIGCTRL 0x14 PRICTRL0 0x18 ... 0x1F Reserved 0x20 INTPEND 0x22 ... 0x23 Reserved 0x24 INTSTATUS 0x28 BUSYCH 0x2C PENDCH 0x30 ACTIVE 0x34 BASEADDR 0x38 WRBADDR Bit Pos. 7 6 7:0 15:8 7:0 15:8 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 7:0 7:0 5 4 2 1 0 CRCENABLE DMAENABLE SWRST LVLEN3 LVLEN2 LVLEN1 LVLEN0 CRCPOLY[1:0] CRCBEATSIZE[1:0] CRCSRC[5:0] CRCDATAIN[7:0] CRCDATAIN[15:8] CRCDATAIN[23:16] CRCDATAIN[31:24] CRCCHKSUM[7:0] CRCCHKSUM[15:8] CRCCHKSUM[23:16] CRCCHKSUM[31:24] CRCZERO CRCBUSY DBGRUN DQOS[1:0] FQOS[1:0] WRBQOS[1:0] 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 RRLVLEN0 RRLVLEN1 RRLVLEN2 RRLVLEN3 7:0 15:8 PEND BUSY FERR CHINT7 CHINT6 CHINT5 CHINT4 BUSYCH7 BUSYCH6 BUSYCH5 PENDCH7 PENDCH6 PENDCH5 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 3 SWTRIG7 SWTRIG6 SWTRIG5 SWTRIG4 SWTRIG3 SWTRIG2 SWTRIG1 SWTRIG0 LVLPRI0[3:0] LVLPRI1[3:0] LVLPRI2[3:0] LVLPRI3[3:0] ID[3:0] SUSP TCMPL TERR CHINT3 CHINT2 CHINT1 CHINT0 BUSYCH4 BUSYCH3 BUSYCH2 BUSYCH1 BUSYCH0 PENDCH4 PENDCH3 PENDCH2 PENDCH1 PENDCH0 LVLEX3 LVLEX2 ID[4:0] LVLEX1 LVLEX0 ABUSY © 2020 Microchip Technology Inc. BTCNT[7:0] BTCNT[15:8] BASEADDR[7:0] BASEADDR[13:8] WRBADDR[7:0] WRBADDR[13:8] Datasheet DS60001513F-page 446 SAM L10/L11 Family DMAC – Direct Memory Access Controller ...........continued Offset 0x3C ... 0x3E 0x3F 0x40 0x41 ... 0x43 0x44 0x48 ... 0x4B 0x4C 0x4D 0x4E 0x4F 28.8 Name Bit Pos. 7 6 5 4 3 2 1 0 Reserved CHID CHCTRLA 7:0 7:0 ID[3:0] ENABLE RUNSTDBY SWRST Reserved CHCTRLB 7:0 15:8 23:16 31:24 LVL[1:0] EVOE EVIE EVACT[2:0] TRIGSRC[4:0] TRIGACT[1:0] CMD[1:0] Reserved CHINTENCLR CHINTENSET CHINTFLAG CHSTATUS 7:0 7:0 7:0 7:0 SUSP SUSP SUSP FERR TCMPL TCMPL TCMPL BUSY TERR TERR TERR PEND Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16- and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers are optionally write-protected by the Peripheral Access Controller (PAC). Optional PAC writeprotection is denoted by the "PAC Write-Protection" property in each individual register description. For details, refer to 28.5.8 Register Access Protection. Some registers are enable-protected, meaning they can only be written when the peripheral is disabled. Enableprotection is denoted by the "Enable-Protected" property in each individual register description. On SAM L11 devices, this peripheral has different access permissions depending on PAC Security Attribution (Secure or Non-Secure): • If the peripheral is configured as Non-Secure in the PAC: – Secure access and Non-Secure access are granted • If the peripheral is configured as Secure in the PAC: – Secure access is granted – Non-Secure access is discarded (Write is ignored, read 0x0) and a PAC error is triggered Refer to Peripherals Security Attribution for more information. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 447 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.1 Control Name:  Offset:  Reset:  Property:  Bit CTRL 0x00 0x00X0 PAC Write-Protection, Enable-Protected 15 14 13 12 11 LVLEN3 R/W 0 7 6 5 4 3 Access Reset Bit Access Reset 10 LVLEN2 R/W 0 9 LVLEN1 R/W 0 2 1 CRCENABLE DMAENABLE R/W R/W 0 0 8 LVLEN0 R/W 0 0 SWRST R/W 0 Bits 8, 9, 10, 11 – LVLENx Priority Level x Enable [x=0..3] When this bit is set, all requests with the corresponding level will be fed into the arbiter block. When cleared, all requests with the corresponding level will be ignored. For details on arbitration schemes, refer to the Arbitration section. These bits are not enable-protected. Value Description 0 Transfer requests for Priority level x will not be handled 1 Transfer requests for Priority level x will be handled Bit 2 – CRCENABLE CRC Enable Writing a '0' to this bit will disable the CRC calculation when the CRC Status Busy flag is cleared (CRCSTATUS. CRCBUSY). The bit is zero when the CRC is disabled. Writing a '1' to this bit will enable the CRC calculation. This bit is not enable-protected. Value Description 0 The CRC calculation is disabled 1 The CRC calculation is enabled Bit 1 – DMAENABLE DMA Enable Setting this bit will enable the DMA module. Writing a '0' to this bit will disable the DMA module. When writing a '0' during an ongoing transfer, the bit will not be cleared until the internal data transfer buffer is empty and the DMA transfer is aborted. The internal data transfer buffer will be empty once the ongoing burst transfer is completed. This bit is not enable-protected. Value Description 0 The peripheral is disabled 1 The peripheral is enabled Bit 0 – SWRST Software Reset Writing a '0' to this bit has no effect. Writing a '1' to this bit when both the DMAC and the CRC module are disabled (DMAENABLE and CRCENABLE are '0') resets all registers in the DMAC (except DBGCTRL) to their initial state. If either the DMAC or CRC module is enabled, the Reset request will be ignored and the DMAC will return an access error. Value Description 0 There is no Reset operation ongoing 1 A Reset operation is ongoing © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 448 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.2 CRC Control Name:  Offset:  Reset:  Property:  Bit 15 CRCCTRL 0x02 0x0000 PAC Write-Protection, Enable-Protected 14 Access Reset Bit 7 6 Access Reset 13 12 R/W 0 R/W 0 5 4 11 10 CRCSRC[5:0] R/W R/W 0 0 9 8 R/W 0 R/W 0 3 2 CRCPOLY[1:0] R/W R/W 0 0 1 0 CRCBEATSIZE[1:0] R/W R/W 0 0 Bits 13:8 – CRCSRC[5:0] CRC Input Source These bits select the input source for generating the CRC, as shown in the table below. The selected source is locked until either the CRC generation is completed or the CRC module is disabled. This means the CRCSRC cannot be modified when the CRC operation is ongoing. The lock is signaled by the CRCBUSY Status bit. CRC generation complete is generated and signaled from the selected source when used with the DMA channel. Value Name Description 0x00 NOACT No action 0x01 IO I/O interface 0x02-0x1 Reserved F 0x20 CHN0 DMA channel 0 0x21 CHN1 DMA channel 1 0x22 CHN2 DMA channel 2 0x23 CHN3 DMA channel 3 0x24 CHN4 DMA channel 4 0x25 CHN5 DMA channel 5 0x26 CHN6 DMA channel 6 0x27 CHN7 DMA channel 7 Bits 3:2 – CRCPOLY[1:0] CRC Polynomial Type These bits define the size of the data transfer for each bus access when the CRC is used with I/O interface, as shown in the table below. Value Name Description 0x0 CRC16 CRC-16 (CRC-CCITT) 0x1 CRC32 CRC32 (IEEE 802.3) 0x2-0x3 Reserved Bits 1:0 – CRCBEATSIZE[1:0] CRC Beat Size These bits define the size of the data transfer for each bus access when the CRC is used with I/O interface. Value Name Description 0x0 BYTE 8-bit bus transfer 0x1 HWORD 16-bit bus transfer 0x2 WORD 32-bit bus transfer 0x3 Reserved © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 449 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.3 CRC Data Input Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset CRCDATAIN 0x04 0x00000000 PAC Write-Protection 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 28 27 CRCDATAIN[31:24] R/W R/W 0 0 20 19 CRCDATAIN[23:16] R/W R/W 0 0 12 11 CRCDATAIN[15:8] R/W R/W 0 0 4 3 CRCDATAIN[7:0] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – CRCDATAIN[31:0] CRC Data Input These bits store the data for which the CRC checksum is computed. A new CRC Checksum is ready (CRCBEAT+ 1) clock cycles after the CRCDATAIN register is written. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 450 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.4 CRC Checksum Name:  Offset:  Reset:  Property:  CRCCHKSUM 0x08 0x00000000 PAC Write-Protection, Enable-Protected The CRCCHKSUM represents the 16- or 32-bit checksum value and the generated CRC. The register is reset to zero by default, but it is possible to reset all bits to one by writing the CRCCHKSUM register directly. It is possible to write this register only when the CRC module is disabled. If CRC-32 is selected and the CRC Status Busy flag is cleared (i.e., CRC generation is completed or aborted), the bit reversed (bit 31 is swapped with bit 0, bit 30 with bit 1, etc.) and complemented result will be read from CRCCHKSUM. If CRC-16 is selected or the CRC Status Busy flag is set (i.e., CRC generation is ongoing), CRCCHKSUM will contain the actual content. Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 31 30 29 R/W 0 R/W 0 R/W 0 23 22 21 R/W 0 R/W 0 R/W 0 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 28 27 CRCCHKSUM[31:24] R/W R/W 0 0 20 19 CRCCHKSUM[23:16] R/W R/W 0 0 12 11 CRCCHKSUM[15:8] R/W R/W 0 0 4 3 CRCCHKSUM[7:0] R/W R/W 0 0 26 25 24 R/W 0 R/W 0 R/W 0 18 17 16 R/W 0 R/W 0 R/W 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 31:0 – CRCCHKSUM[31:0] CRC Checksum These bits store the generated CRC result. The 16 MSB bits are always read zero when CRC-16 is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 451 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.5 CRC Status Name:  Offset:  Reset:  Property:  Bit 7 CRCSTATUS 0x0C 0x00 PAC Write-Protection 6 5 4 3 Access Reset 2 1 CRCZERO R 0 0 CRCBUSY R/W 0 Bit 1 – CRCZERO CRC Zero This bit is cleared when a new CRC source is selected. This bit is set when the CRC generation is complete and the CRC Checksum is zero. When running CRC-32 and appending the checksum at the end of the packet (as little endian), the final checksum should be 0x2144df1c, and not zero. However, if the checksum is complemented before it is appended (as little endian) to the data, the final result in the checksum register will be zero. See the description of CRCCHKSUM to read out different versions of the checksum. Bit 0 – CRCBUSY CRC Module Busy This flag is cleared by writing a one to it when used with I/O interface. When used with a DMA channel, the bit is set when the corresponding DMA channel is enabled, and cleared when the corresponding DMA channel is disabled. This register bit cannot be cleared by the application when the CRC is used with a DMA channel. This bit is set when a source configuration is selected and as long as the source is using the CRC module. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 452 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.6 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0D 0x00 PAC Write-Protection 6 5 4 3 Access Reset 2 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run This bit is not reset by a software reset. This bit controls the functionality when the CPU is halted by an external debugger. Value Description 0 The DMAC is halted when the CPU is halted by an external debugger. 1 The DMAC continues normal operation when the CPU is halted by an external debugger. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 453 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.7 Quality of Service Control Name:  Offset:  Reset:  Property:  Bit QOSCTRL 0x0E 0x2A PAC Write-Protection 7 6 5 4 DQOS[1:0] R/W R/W 1 0 Access Reset 3 2 FQOS[1:0] R/W R/W 1 0 1 0 WRBQOS[1:0] R/W R/W 1 0 Bits 5:4 – DQOS[1:0] Data Transfer Quality of Service These bits define the memory priority access during the data transfer operation. DQOS[1:0] Name Description 0x0 0x1 0x2 0x3 DISABLE LOW MEDIUM HIGH Background (no sensitive operation) Sensitive Bandwidth Sensitive Latency Critical Latency Bits 3:2 – FQOS[1:0] Fetch Quality of Service These bits define the memory priority access during the fetch operation. FQOS[1:0] Name Description 0x0 0x1 0x2 0x3 DISABLE LOW MEDIUM HIGH Background (no sensitive operation) Sensitive Bandwidth Sensitive Latency Critical Latency Bits 1:0 – WRBQOS[1:0] Write-Back Quality of Service These bits define the memory priority access during the write-back operation. WRBQOS[1:0] Name Description 0x0 0x1 0x2 0x3 DISABLE LOW MEDIUM HIGH Background (no sensitive operation) Sensitive Bandwidth Sensitive Latency Critical Latency © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 454 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.8 Software Trigger Control Name:  Offset:  Reset:  Property:  Bit SWTRIGCTRL 0x10 0x00000000 PAC Write Protection 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 SWTRIG7 R/W 0 6 SWTRIG6 R/W 0 5 SWTRIG5 R/W 0 4 SWTRIG4 R/W 0 3 SWTRIG3 R/W 0 2 SWTRIG2 R/W 0 1 SWTRIG1 R/W 0 0 SWTRIG0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3, 4, 5, 6, 7 – SWTRIGn Channel n Software Trigger [n = 7..0] This bit is cleared when the Channel Pending bit in the Channel Status register (CHSTATUS.PEND) for the corresponding channel is either set, or by writing a '1' to it. This bit is set if CHSTATUS.PEND is already '1' when writing a '1' to that bit. Writing a '0' to this bit will clear the bit. Writing a '1' to this bit will generate a DMA software trigger on channel x, if CHSTATUS.PEND=0 for channel x. CHSTATUS.PEND will be set and SWTRIGn will remain cleared. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 455 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.9 Priority Control 0 Name:  Offset:  Reset:  Property:  Bit 31 RRLVLEN3 Access R/W Reset 0 Bit 23 RRLVLEN2 Access R/W Reset 0 Bit 15 RRLVLEN1 Access R/W Reset 0 Bit 7 RRLVLEN0 Access R/W Reset 0 PRICTRL0 0x14 0x00000000 PAC Write-Protection 30 29 28 27 R/W 0 22 21 20 19 R/W 0 14 13 12 11 R/W 0 6 5 4 3 R/W 0 26 25 LVLPRI3[3:0] R/W R/W 0 0 18 17 LVLPRI2[3:0] R/W R/W 0 0 10 9 LVLPRI1[3:0] R/W R/W 0 0 2 1 LVLPRI0[3:0] R/W R/W 0 0 24 R/W 0 16 R/W 0 8 R/W 0 0 R/W 0 Bit 31 – RRLVLEN3 Level 3 Round-Robin Arbitration Enable This bit controls which arbitration scheme is selected for DMA channels with priority level 3. For details on arbitration schemes, refer to 28.6.2.4 Arbitration. Value Description 0 Static arbitration scheme for channels with level 3 priority. 1 Round-robin arbitration scheme for channels with level 3 priority. Bits 27:24 – LVLPRI3[3:0] Level 3 Channel Priority Number When round-robin arbitration is enabled (PRICTRL0.RRLVLEN3=1) for priority level 3, this register holds the channel number of the last DMA channel being granted access as the active channel with priority level 3. When static arbitration is enabled (PRICTRL0.RRLVLEN3=0) for priority level 3, and the value of this bit group is nonzero, it will not affect the static priority scheme. This bit group is not reset when round-robin arbitration gets disabled (PRICTRL0.RRLVLEN3 written to '0'). Bit 23 – RRLVLEN2 Level 2 Round-Robin Arbitration Enable This bit controls which arbitration scheme is selected for DMA channels with priority level 2. For details on arbitration schemes, refer to 28.6.2.4 Arbitration. Value Description 0 Static arbitration scheme for channels with level 2 priority. 1 Round-robin arbitration scheme for channels with level 2 priority. Bits 19:16 – LVLPRI2[3:0] Level 2 Channel Priority Number When round-robin arbitration is enabled (PRICTRL0.RRLVLEN2=1) for priority level 2, this register holds the channel number of the last DMA channel being granted access as the active channel with priority level 2. When static arbitration is enabled (PRICTRL0.RRLVLEN2=0) for priority level 2, and the value of this bit group is nonzero, it will not affect the static priority scheme. This bit group is not reset when round-robin arbitration gets disabled (PRICTRL0.RRLVLEN2 written to '0'). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 456 SAM L10/L11 Family DMAC – Direct Memory Access Controller Bit 15 – RRLVLEN1 Level 1 Round-Robin Scheduling Enable For details on arbitration schemes, refer to 28.6.2.4 Arbitration. Value Description 0 Static arbitration scheme for channels with level 1 priority. 1 Round-robin arbitration scheme for channels with level 1 priority. Bits 11:8 – LVLPRI1[3:0] Level 1 Channel Priority Number When round-robin arbitration is enabled (PRICTRL0.RRLVLEN1=1) for priority level 1, this register holds the channel number of the last DMA channel being granted access as the active channel with priority level 1. When static arbitration is enabled (PRICTRL0.RRLVLEN1=0) for priority level 1, and the value of this bit group is nonzero, it will not affect the static priority scheme. This bit group is not reset when round-robin arbitration gets disabled (PRICTRL0.RRLVLEN1 written to '0'). Bit 7 – RRLVLEN0 Level 0 Round-Robin Scheduling Enable For details on arbitration schemes, refer to 28.6.2.4 Arbitration. Value Description 0 Static arbitration scheme for channels with level 0 priority. 1 Round-robin arbitration scheme for channels with level 0 priority. Bits 3:0 – LVLPRI0[3:0] Level 0 Channel Priority Number When round-robin arbitration is enabled (PRICTRL0.RRLVLEN0=1) for priority level 0, this register holds the channel number of the last DMA channel being granted access as the active channel with priority level 0. When static arbitration is enabled (PRICTRL0.RRLVLEN0=0) for priority level 0, and the value of this bit group is nonzero, it will not affect the static priority scheme. This bit group is not reset when round-robin arbitration gets disabled (PRICTRL0.RRLVLEN0 written to '0'). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 457 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.10 Interrupt Pending Name:  Offset:  Reset:  Property:  INTPEND 0x20 0x0000 - This register allows the user to identify the lowest DMA channel with pending interrupt. Bit Access Reset Bit 15 PEND R 0 14 BUSY R 0 13 FERR R 0 12 11 10 SUSP R/W 0 7 6 5 4 3 2 9 TCMPL R/W 0 8 TERR R/W 0 1 0 R/W 0 R/W 0 ID[3:0] Access Reset R/W 0 R/W 0 Bit 15 – PEND Pending This bit will read '1' when the channel selected by Channel ID field (ID) is pending. Bit 14 – BUSY Busy This bit will read '1' when the channel selected by Channel ID field (ID) is busy. Bit 13 – FERR Fetch Error This bit will read '1' when the channel selected by Channel ID field (ID) fetched an invalid descriptor. Bit 10 – SUSP Channel Suspend This bit will read '1' when the channel selected by Channel ID field (ID) has pending Suspend interrupt. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel ID (ID) Suspend interrupt flag. Bit 9 – TCMPL Transfer Complete This bit will read '1' when the channel selected by Channel ID field (ID) has pending Transfer Complete interrupt. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel ID (ID) Transfer Complete interrupt flag. Bit 8 – TERR Transfer Error This bit is read one when the channel selected by Channel ID field (ID) has pending Transfer Error interrupt. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel ID (ID) Transfer Error interrupt flag. Bits 3:0 – ID[3:0] Channel ID These bits store the lowest channel number with pending interrupts. The number is valid if Suspend (SUSP), Transfer Complete (TCMPL) or Transfer Error (TERR) bits are set. The Channel ID field is refreshed when a new channel (with channel number less than the current one) with pending interrupts is detected, or when the application clears the corresponding channel interrupt sources. When no pending channels interrupts are available, these bits will always return zero value when read. When the bits are written, indirect access to the corresponding Channel Interrupt Flag register is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 458 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.11 Interrupt Status Name:  Offset:  Reset:  Property:  Bit INTSTATUS 0x24 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 CHINT7 R 0 6 CHINT6 R 0 5 CHINT5 R 0 4 CHINT4 R 0 3 CHINT3 R 0 2 CHINT2 R 0 1 CHINT1 R 0 0 CHINT0 R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3, 4, 5, 6, 7 – CHINTn Channel n Pending Interrupt [n=7..0] This bit is set when Channel n has a pending interrupt/the interrupt request is received. This bit is cleared when the corresponding Channel n interrupts are disabled or the interrupts sources are cleared. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 459 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.12 Busy Channels Name:  Offset:  Reset:  Property:  Bit BUSYCH 0x28 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 BUSYCH7 R 0 6 BUSYCH6 R 0 5 BUSYCH5 R 0 4 BUSYCH4 R 0 3 BUSYCH3 R 0 2 BUSYCH2 R 0 1 BUSYCH1 R 0 0 BUSYCH0 R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3, 4, 5, 6, 7 – BUSYCHn Busy Channel n [x=7..0] This bit is cleared when the channel trigger action for DMA channel n is complete, when a bus error for DMA channel n is detected, or when DMA channel n is disabled. This bit is set when DMA channel n starts a DMA transfer. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 460 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.13 Pending Channels Name:  Offset:  Reset:  Property:  Bit PENDCH 0x2C 0x00000000 - 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 PENDCH7 R 0 6 PENDCH6 R 0 5 PENDCH5 R 0 4 PENDCH4 R 0 3 PENDCH3 R 0 2 PENDCH2 R 0 1 PENDCH1 R 0 0 PENDCH0 R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 0, 1, 2, 3, 4, 5, 6, 7 – PENDCH Pending Channel n [n=7..0] This bit is cleared when trigger execution defined by channel trigger action settings for DMA channel n is started, when a bus error for DMA channel n is detected or when DMA channel n is disabled. For details on trigger action settings, refer to TRIGACT bit in 28.8.19 CHCTRLB. This bit is set when a transfer is pending on DMA channel n. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 461 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.14 Active Channel and Levels Name:  Offset:  Reset:  Property:  ACTIVE 0x30 0x00000000 - Bit 31 30 29 Access Reset R 0 R 0 R 0 Bit 23 22 21 Access Reset R 0 R 0 15 ABUSY R 0 14 7 6 Bit Access Reset Bit Access Reset 28 27 BTCNT[15:8] R R 0 0 26 25 24 R 0 R 0 R 0 18 17 16 R 0 20 19 BTCNT[7:0] R R 0 0 R 0 R 0 R 0 13 12 11 9 8 R 0 R 0 10 ID[4:0] R 0 R 0 R 0 4 3 LVLEX3 R 0 2 LVLEX2 R 0 1 LVLEX1 R 0 0 LVLEX0 R 0 5 Bits 31:16 – BTCNT[15:0] Active Channel Block Transfer Count These bits hold the 16-bit block transfer count of the ongoing transfer. This value is stored in the active channel and written back in the corresponding Write-Back channel memory location when the arbiter grants a new channel access. The value is valid only when the active channel Active Busy flag (ABUSY) is set. Bit 15 – ABUSY Active Channel Busy This bit is cleared when the active transfer count is written back in the write-back memory section. This bit is set when the next descriptor transfer count is read from the write-back memory section. Bits 12:8 – ID[4:0] Active Channel ID These bits hold the channel index currently stored in the active channel registers. The value is updated each time the arbiter grants a new channel transfer access request. Bits 0, 1, 2, 3 – LVLEXx Level x Channel Trigger Request Executing [x=3..0] This bit is set when a level-x channel trigger request is executing or pending. This bit is cleared when no request is pending or being executed. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 462 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.15 Descriptor Memory Section Base Address Name:  Offset:  Reset:  Property:  Bit BASEADDR 0x34 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 9 8 R/W 0 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 7 6 5 R/W 0 R/W 0 R/W 0 11 10 BASEADDR[13:8] R/W R/W 0 0 4 3 BASEADDR[7:0] R/W R/W 0 0 Bits 13:0 – BASEADDR[13:0] Descriptor Memory Base Address These bits store the Descriptor memory section base address. The value must be 128-bit aligned. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 463 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.16 Write-Back Memory Section Base Address Name:  Offset:  Reset:  Property:  Bit WRBADDR 0x38 0x00000000 PAC Write-Protection, Enable-Protected 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 9 8 R/W 0 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 7 6 5 R/W 0 R/W 0 R/W 0 11 10 WRBADDR[13:8] R/W R/W 0 0 4 3 WRBADDR[7:0] R/W R/W 0 0 Bits 13:0 – WRBADDR[13:0] Write-Back Memory Base Address These bits store the Write-Back memory base address. The value must be 128-bit aligned. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 464 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.17 Channel ID Name:  Offset:  Reset:  Property:  Bit 7 CHID 0x3F 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 ID[3:0] Access Reset R/W 0 R/W 0 Bits 3:0 – ID[3:0] Channel ID These bits define the channel number that will be affected by the channel registers (CH*). Before reading or writing a channel register, the channel ID bit group must be written first. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 465 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.18 Channel Control A Name:  Offset:  Reset:  Property:  CHCTRLA 0x40 0x00 PAC Write-Protection, Enable-Protected This register affects the DMA channel that is selected in the Channel ID register (CHID.ID). Bit 7 Access Reset R 0 6 RUNSTDBY R/W 0 5 4 3 2 R 0 R 0 R 0 R 0 1 ENABLE R/W 0 0 SWRST R/W 0 Bit 6 – RUNSTDBY Channel run in standby This bit is used to keep the DMAC channel running in standby mode. This bit is not enable-protected. Value Description 0 The DMAC channel is halted in standby. 1 The DMAC channel continues to run in standby. Bit 1 – ENABLE Channel Enable Writing a '0' to this bit during an ongoing transfer, the bit will not be cleared until the internal data transfer buffer is empty and the DMA transfer is aborted. The internal data transfer buffer will be empty once the ongoing burst transfer is completed. Writing a '1' to this bit will enable the DMA channel. This bit is not enable-protected. Value Description 0 DMA channel is disabled. 1 DMA channel is enabled. Bit 0 – SWRST Channel Software Reset Writing a '0' to this bit has no effect. Writing a '1' to this bit resets the channel registers to their initial state. The bit can be set when the channel is disabled (ENABLE=0). Writing a '1' to this bit will be ignored as long as ENABLE=1. This bit is automatically cleared when the reset is completed. Value Description 0 There is no reset operation ongoing. 1 The reset operation is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 466 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.19 Channel Control B Name:  Offset:  Reset:  Property:  CHCTRLB 0x44 0x00000000 PAC Write-Protection, Enable-Protected This register affects the DMA channel that is selected in the Channel ID register (CHID.ID). Bit 31 30 29 28 27 26 25 24 CMD[1:0] Access Reset Bit Access Reset Bit 23 22 TRIGACT[1:0] R/W R/W 0 0 15 14 7 6 20 19 18 17 16 13 12 11 9 8 R/W 0 R/W 0 10 TRIGSRC[4:0] R/W 0 R/W 0 R/W 0 4 EVOE R/W 0 3 EVIE R/W 0 1 EVACT[2:0] R/W 0 0 5 LVL[1:0] Access Reset R/W 0 R/W 0 21 Access Reset Bit R/W 0 R/W 0 2 R/W 0 R/W 0 Bits 25:24 – CMD[1:0] Software Command These bits define the software commands. Refer to 28.6.3.2 Channel Suspend and 28.6.3.3 Channel Resume and Next Suspend Skip. These bits are not enable-protected. CMD[1:0] Name Description 0x0 0x1 0x2 0x3 NOACT SUSPEND RESUME - No action Channel suspend operation Channel resume operation Reserved Bits 23:22 – TRIGACT[1:0] Trigger Action These bits define the trigger action used for a transfer. TRIGACT[1:0] Name Description 0x0 0x1 0x2 0x3 BLOCK BEAT TRANSACTION One trigger required for each block transfer Reserved One trigger required for each beat transfer One trigger required for each transaction Bits 12:8 – TRIGSRC[4:0] Trigger Source These bits define the peripheral trigger which is source of the transfer. For details on trigger selection and trigger modes, refer to Transfer Triggers and Actions and CHCTRLB.TRIGACT. Value Name Description 0x00 DISABLE Only software/event triggers 0x01 RTC TIMESTAMP RTC Timestamp Trigger 0x02 DSU DCC0 ID for DCC0 register 0x03 DSU DCC1 ID for DCC1 register © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 467 SAM L10/L11 Family DMAC – Direct Memory Access Controller Value 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D 0x0E 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 0x17 Name SERCOM0 RX SERCOM0 TX SERCOM1 RX SERCOM1 TX SERCOM2 RX SERCOM2 TX TC0 OVF TC0 MC0 TC0 MC1 TC1 OVF TC1 MC0 TC1 MC1 TC2 OVF TC2 MC0 TC2 MC1 ADC RESRDY DAC EMPTY PTC EOC PTC SEQ PTC WCOMP Description SERCOM0 RX Trigger SERCOM0 TX Trigger SERCOM1 RX Trigger SERCOM1 TX Trigger SERCOM2 RX Trigger SERCOM2 TX Trigger TC0 Overflow Trigger TC0 Match/Compare 0 Trigger TC0 Match/Compare 1 Trigger TC1 Overflow Trigger TC1 Match/Compare 0 Trigger TC1 Match/Compare 1 Trigger TC2 Overflow Trigger TC2 Match/Compare 0 Trigger TC2 Match/Compare 1 Trigger ADC Result Ready Trigger DAC Empty Trigger PTC End of Conversion Trigger PTC Sequence Trigger PTC Window Compare Trigger Bits 6:5 – LVL[1:0] Channel Arbitration Level These bits define the arbitration level used for the DMA channel, where a high level has priority over a low level. For further details on arbitration schemes, refer to 28.6.2.4 Arbitration. These bits are not enable-protected. TRIGACT[1:0] Name Description 0x0 0x1 0x2 0x3 LVL0 LVL1 LVL2 LVL3 Channel Priority Level 0 Channel Priority Level 1 Channel Priority Level 2 Channel Priority Level 3 Bit 4 – EVOE Channel Event Output Enable This bit indicates if the Channel event generation is enabled. The event will be generated for every condition defined in the descriptor Event Output Selection (BTCTRL.EVOSEL). This bit is available only for the four least significant DMA channels. Refer to table: User Multiplexer Selection and Event Generator Selection of the Event System for details. Value Description 0 Channel event generation is disabled. 1 Channel event generation is enabled. Bit 3 – EVIE Channel Event Input Enable This bit is available only for the four least significant DMA channels. Refer to table: User Multiplexer Selection and Event Generator Selection of the Event System for details. Value Description 0 Channel event action will not be executed on any incoming event. 1 Channel event action will be executed on any incoming event. Bits 2:0 – EVACT[2:0] Event Input Action These bits define the event input action, as shown below. The action is executed only if the corresponding EVIE bit in the CHCTRLB register of the channel is set. These bits are available only for the four least significant DMA channels. Refer to table: User Multiplexer Selection and Event Generator Selection of the Event System for details. EVACT[2:0] Name Description 0x0 NOACT No action © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 468 SAM L10/L11 Family DMAC – Direct Memory Access Controller ...........continued EVACT[2:0] Name Description 0x1 0x2 0x3 0x4 0x5 0x6 0x7 TRIG CTRIG CBLOCK SUSPEND RESUME SSKIP - Normal Transfer and Conditional Transfer on Strobe trigger Conditional transfer trigger Conditional block transfer Channel suspend operation Channel resume operation Skip next block suspend action Reserved Related Links 33.7.8 CHANNEL © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 469 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.20 Channel Interrupt Enable Clear Name:  Offset:  Reset:  Property:  CHINTENCLR 0x4C 0x00 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Channel Interrupt Enable Set (CHINTENSET) register. This register affects the DMA channel that is selected in the Channel ID register (CHID.ID). Bit 7 6 5 4 3 Access Reset 2 SUSP R/W 0 1 TCMPL R/W 0 0 TERR R/W 0 Bit 2 – SUSP Channel Suspend Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel Suspend Interrupt Enable bit, which disables the Channel Suspend interrupt. Value Description 0 The Channel Suspend interrupt is disabled. 1 The Channel Suspend interrupt is enabled. Bit 1 – TCMPL Channel Transfer Complete Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel Transfer Complete Interrupt Enable bit, which disables the Channel Transfer Complete interrupt. Value Description 0 The Channel Transfer Complete interrupt is disabled. When block action is set to none, the TCMPL flag will not be set when a block transfer is completed. 1 The Channel Transfer Complete interrupt is enabled. Bit 0 – TERR Channel Transfer Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel Transfer Error Interrupt Enable bit, which disables the Channel Transfer Error interrupt. Value Description 0 The Channel Transfer Error interrupt is disabled. 1 The Channel Transfer Error interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 470 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.21 Channel Interrupt Enable Set Name:  Offset:  Reset:  Property:  CHINTENSET 0x4D 0x00 PAC Write-Protection This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Channel Interrupt Enable Clear (CHINTENCLR) register. This register affects the DMA channel that is selected in the Channel ID register (CHID.ID). Bit 7 6 5 4 3 Access Reset 2 SUSP R/W 0 1 TCMPL R/W 0 0 TERR R/W 0 Bit 2 – SUSP Channel Suspend Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Channel Suspend Interrupt Enable bit, which enables the Channel Suspend interrupt. Value Description 0 The Channel Suspend interrupt is disabled. 1 The Channel Suspend interrupt is enabled. Bit 1 – TCMPL Channel Transfer Complete Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Channel Transfer Complete Interrupt Enable bit, which enables the Channel Transfer Complete interrupt. Value Description 0 The Channel Transfer Complete interrupt is disabled. 1 The Channel Transfer Complete interrupt is enabled. Bit 0 – TERR Channel Transfer Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Channel Transfer Error Interrupt Enable bit, which enables the Channel Transfer Error interrupt. Value Description 0 The Channel Transfer Error interrupt is disabled. 1 The Channel Transfer Error interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 471 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.22 Channel Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  CHINTFLAG 0x4E 0x00 - This register affects the DMA channel that is selected in the Channel ID register (CHID.ID). Bit 7 6 5 4 3 Access Reset 2 SUSP R/W 0 1 TCMPL R/W 0 0 TERR R/W 0 Bit 2 – SUSP Channel Suspend This flag is cleared by writing a '1' to it. This flag is set when a block transfer with suspend block action is completed, when a software suspend command is executed, when a suspend event is received or when an invalid descriptor is fetched by the DMA. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Channel Suspend interrupt flag for the corresponding channel. For details on available software commands, refer to CHCTRLB.CMD. For details on available event input actions, refer to CHCTRLB.EVACT. For details on available block actions, refer to BTCTRL.BLOCKACT. Bit 1 – TCMPL Channel Transfer Complete This flag is cleared by writing a '1' to it. This flag is set when a block transfer is completed and the corresponding interrupt block action is enabled. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Transfer Complete interrupt flag for the corresponding channel. Bit 0 – TERR Channel Transfer Error This flag is cleared by writing a '1' to it. This flag is set when a bus error is detected during a beat transfer or when the DMAC fetches an invalid descriptor. Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Transfer Error interrupt flag for the corresponding channel. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 472 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.8.23 Channel Status Name:  Offset:  Reset:  Property:  CHSTATUS 0x4F 0x00 - This register affects the DMA channel that is selected in the Channel ID register (CHID.ID). Bit 7 6 5 4 3 Access Reset 2 FERR R 0 1 BUSY R 0 0 PEND R 0 Bit 2 – FERR Channel Fetch Error This bit is cleared when a software resume command is executed. This bit is set when an invalid descriptor is fetched. Bit 1 – BUSY Channel Busy This bit is cleared when the channel trigger action is completed, when a bus error is detected or when the channel is disabled. This bit is set when the DMA channel starts a DMA transfer. Bit 0 – PEND Channel Pending This bit is cleared when the channel trigger action is started, when a bus error is detected or when the channel is disabled. For details on trigger action settings, refer to CHCTRLB.TRIGACT. This bit is set when a transfer is pending on the DMA channel, as soon as the transfer request is received. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 473 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.9 Register Summary - SRAM Offset Name 0x00 BTCTRL 0x02 BTCNT 0x04 SRCADDR 0x08 DSTADDR 0x0C DESCADDR 28.10 Bit Pos. 7 7:0 15:8 7:0 15:8 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 6 STEPSIZE[2:0] 5 4 3 BLOCKACT[1:0] STEPSEL DSTINC BTCNT[7:0] BTCNT[15:8] SRCADDR[7:0] SRCADDR[15:8] SRCADDR[23:16] SRCADDR[31:24] DSTADDR[7:0] DSTADDR[15:8] DSTADDR[23:16] DSTADDR[31:24] DESCADDR[7:0] DESCADDR[15:8] DESCADDR[23:16] DESCADDR[31:24] 2 1 0 EVOSEL[1:0] VALID SRCINC BEATSIZE[1:0] Register Description - SRAM Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16- and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers are optionally write-protected by the Peripheral Access Controller (PAC). Optional PAC writeprotection is denoted by the "PAC Write-Protection" property in each individual register description. For details, refer to 28.5.8 Register Access Protection. Some registers are enable-protected, meaning they can only be written when the peripheral is disabled. Enableprotection is denoted by the "Enable-Protected" property in each individual register description. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 474 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.10.1 Block Transfer Control Name:  Offset:  Property:  BTCTRL 0x00 - The BTCTRL register offset is relative to (BASEADDR or WRBADDR) + Channel Number * 0x10 Bit 15 14 STEPSIZE[2:0] 13 7 6 5 12 STEPSEL 11 DSTINC 10 SRCINC 9 8 BEATSIZE[1:0] Access Reset Bit 4 3 BLOCKACT[1:0] 2 1 EVOSEL[1:0] 0 VALID Access Reset Bits 15:13 – STEPSIZE[2:0] Address Increment Step Size These bits select the address increment step size. The setting apply to source or destination address, depending on STEPSEL setting. Value Name Description 0x0 X1 Next ADDR = ADDR + (Beat size in byte) * 1 0x1 X2 Next ADDR = ADDR + (Beat size in byte) * 2 0x2 X4 Next ADDR = ADDR + (Beat size in byte) * 4 0x3 X8 Next ADDR = ADDR + (Beat size in byte) * 8 0x4 X16 Next ADDR = ADDR + (Beat size in byte) * 16 0x5 X32 Next ADDR = ADDR + (Beat size in byte) * 32 0x6 X64 Next ADDR = ADDR + (Beat size in byte) * 64 0x7 X128 Next ADDR = ADDR + (Beat size in byte) * 128 Bit 12 – STEPSEL Step Selection This bit selects if source or destination addresses are using the step size settings. Value Name Description 0x0 DST Step size settings apply to the destination address 0x1 SRC Step size settings apply to the source address Bit 11 – DSTINC Destination Address Increment Enable Writing a '0' to this bit will disable the destination address incrementation. The address will be kept fixed during the data transfer. Writing a '1' to this bit will enable the destination address incrementation. By default, the destination address is incremented by 1. If the STEPSEL bit is cleared, flexible step-size settings are available in the STEPSIZE register. Value Description 0 The Destination Address Increment is disabled. 1 The Destination Address Increment is enabled. Bit 10 – SRCINC Source Address Increment Enable Writing a '0' to this bit will disable the source address incrementation. The address will be kept fixed during the data transfer. Writing a '1' to this bit will enable the source address incrementation. By default, the source address is incremented by 1. If the STEPSEL bit is set, flexible step-size settings are available in the STEPSIZE register. Value Description 0 The Source Address Increment is disabled. 1 The Source Address Increment is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 475 SAM L10/L11 Family DMAC – Direct Memory Access Controller Bits 9:8 – BEATSIZE[1:0] Beat Size These bits define the size of one beat. A beat is the size of one data transfer bus access, and the setting apply to both read and write accesses. Value Name Description 0x0 BYTE 8-bit bus transfer 0x1 HWORD 16-bit bus transfer 0x2 WORD 32-bit bus transfer other Reserved Bits 4:3 – BLOCKACT[1:0] Block Action These bits define what actions the DMAC should take after a block transfer has completed. BLOCKACT[1:0] Name 0x0 0x1 0x2 0x3 Description NOACT INT Channel will be disabled if it is the last block transfer in the transaction Channel will be disabled if it is the last block transfer in the transaction and block interrupt SUSPEND Channel suspend operation is completed BOTH Both channel suspend operation and block interrupt Bits 2:1 – EVOSEL[1:0] Event Output Selection These bits define the event output selection. EVOSEL[1:0] Name Description 0x0 0x1 0x2 0x3 DISABLE BLOCK Event generation disabled Event strobe when block transfer complete Reserved Event strobe when beat transfer complete BEAT Bit 0 – VALID Descriptor Valid Writing a '0' to this bit in the Descriptor or Write-Back memory will suspend the DMA channel operation when fetching the corresponding descriptor. The bit is automatically cleared in the Write-Back memory section when channel is aborted, when an error is detected during the block transfer, or when the block transfer is completed. Value Description 0 The descriptor is not valid. 1 The descriptor is valid. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 476 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.10.2 Block Transfer Count Name:  Offset:  Property:  BTCNT 0x02 - The BTCNT register offset is relative to (BASEADDR or WRBADDR) + Channel Number * 0x10 Bit 15 14 13 12 11 BTCNT[15:8] 10 9 8 7 6 5 4 2 1 0 Access Reset Bit 3 BTCNT[7:0] Access Reset Bits 15:0 – BTCNT[15:0] Block Transfer Count This bit group holds the 16-bit block transfer count. During a transfer, the internal counter value is decremented by one after each beat transfer. The internal counter is written to the corresponding write-back memory section for the DMA channel when the DMA channel loses priority, is suspended or gets disabled. The DMA channel can be disabled by a complete transfer, a transfer error or by software. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 477 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.10.3 Block Transfer Source Address Name:  Offset:  Property:  SRCADDR 0x04 - The SRCADDR register offset is relative to (BASEADDR or WRBADDR) + Channel Number * 0x10 Bit 31 30 29 28 27 SRCADDR[31:24] 26 25 24 23 22 21 20 19 SRCADDR[23:16] 18 17 16 15 14 13 12 11 SRCADDR[15:8] 10 9 8 7 6 5 4 3 SRCADDR[7:0] 2 1 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 31:0 – SRCADDR[31:0] Transfer Source Address This bit field holds the block transfer source address. When source address incrementation is disabled (BTCTRL.SRCINC = 0), SRCADDR corresponds to the last beat transfer address in the block transfer. When source address incrementation is enabled (BTCTRL.SRCINC = 1), SRCADDR is calculated as follows: If BTCTRL.STEPSEL = 1: SRCADDR = SRCADDR����� + ����� ⋅ �������� + 1 ⋅ 2STEPSIZE If BTCTRL.STEPSEL = 0: SRCADDR = SRCADDR����� + ����� ⋅ �������� + 1 • • • • SRCADDRSTART is the source address of the first beat transfer in the block transfer BTCNT is the initial number of beats remaining in the block transfer BEATSIZE is the configured number of bytes in a beat STEPSIZE is the configured number of beats for each incrementation © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 478 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.10.4 Block Transfer Destination Address Name:  Offset:  Property:  DSTADDR 0x08 - The DSTADDR register offset is relative to (BASEADDR or WRBADDR) + Channel Number * 0x10 Bit 31 30 29 28 27 DSTADDR[31:24] 26 25 24 23 22 21 20 19 DSTADDR[23:16] 18 17 16 15 14 13 12 11 DSTADDR[15:8] 10 9 8 7 6 5 4 3 DSTADDR[7:0] 2 1 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 31:0 – DSTADDR[31:0] Transfer Destination Address This bit field holds the block transfer destination address. When destination address incrementation is disabled (BTCTRL.DSTINC = 0), DSTADDR corresponds to the last beat transfer address in the block transfer. When destination address incrementation is enabled (BTCTRL.DSTINC = 1), DSTADDR is calculated as follows: If BTCTRL.STEPSEL = 1: ������� = ������������ + ����� • �������� + 1 If BTCTRL.STEPSEL = 0: ������� = ������������ + ����� • �������� + 1 • 2�������� • • • • DSTADDRSTART is the destination address of the first beat transfer in the block transfer BTCNT is the initial number of beats remaining in the block transfer BEATSIZE is the configured number of bytes in a beat STEPSIZE is the configured number of beats for each incrementation © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 479 SAM L10/L11 Family DMAC – Direct Memory Access Controller 28.10.5 Next Descriptor Address Name:  Offset:  Property:  DESCADDR 0x0C - The DESCADDR register offset is relative to (BASEADDR or WRBADDR) + Channel Number * 0x10 Bit 31 30 29 28 27 DESCADDR[31:24] 26 25 24 23 22 21 20 19 DESCADDR[23:16] 18 17 16 15 14 13 12 11 DESCADDR[15:8] 10 9 8 7 6 5 4 3 DESCADDR[7:0] 2 1 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bits 31:0 – DESCADDR[31:0] Next Descriptor Address This bit group holds the SRAM address of the next descriptor. The value must be 128-bit aligned. If the value of this SRAM register is 0x00000000, the transaction will be terminated when the DMAC tries to load the next transfer descriptor. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 480 SAM L10/L11 Family EIC – External Interrupt Controller 29. EIC – External Interrupt Controller 29.1 Overview The External Interrupt Controller (EIC) allows external pins to be configured as interrupt lines. Each interrupt line can be individually masked and can generate an interrupt on rising, falling, or both edges, or on high or low levels. Each external pin has a configurable filter to remove spikes. Each external pin can also be configured to be asynchronous in order to wake up the device from sleep modes where all clocks have been disabled. External pins can also generate an event. Each external pin can be defined as secured or non-secured, where secured pins can only be handled by secure accesses. A separate non-maskable interrupt (NMI) is also supported. It has properties similar to the other external interrupts, but is connected to the NMI request of the CPU, enabling it to interrupt any other interrupt mode. 29.2 Features • • • • • • • • • • 29.3 Up to 8 external pins (EXTINTx), plus one non-maskable pin (NMI) Dedicated, individually maskable interrupt for each pin Interrupt on rising, falling, or both edges Synchronous or asynchronous edge detection mode Interrupt pin debouncing Interrupt on high or low levels Asynchronous interrupts for sleep modes without clock Filtering of external pins Event generation from EXTINTx Selectable secured or non-secured attribution for each individual external pin (SAM L11) Block Diagram Figure 29-1. EIC Block Diagram FILTENx SENSEx[2:0] Interrupt EXTINTx Filter Edge/Level Detection Wake Event NMIFILTEN Interrupt Edge/Level Detection Wake © 2020 Microchip Technology Inc. inwake_extint evt_extint NMISENSE[2:0] NMI Filter intreq_extint Datasheet intreq_nmi inwake_nmi DS60001513F-page 481 SAM L10/L11 Family EIC – External Interrupt Controller 29.4 Signal Description Signal Name Type Description EXTINT[7..0] Digital Input External interrupt pin NMI Digital Input Non-maskable interrupt pin One signal may be available on several pins. 29.5 Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described below. 29.5.1 I/O Lines Using the EIC’s I/O lines requires the I/O pins to be configured. Related Links 32. PORT - I/O Pin Controller 29.5.2 Power Management All interrupts are available down to STANDBY sleep mode, but the EIC can be configured to automatically mask some interrupts in order to prevent device wake-up. The EIC will continue to operate in any sleep mode where the selected source clock is running. The EIC’s interrupts can be used to wake up the device from sleep modes. Events connected to the Event System can trigger other operations in the system without exiting sleep modes. Related Links 22. PM – Power Manager 29.5.3 Clocks The EIC bus clock (CLK_EIC_APB) can be enabled and disabled by the Main Clock Controller, the default state of CLK_EIC_APB can be found in the Peripheral Clock Masking section. Some optional functions need a peripheral clock, which can either be a generic clock (GCLK_EIC, for wider frequency selection) or a Ultra Low-Power 32 KHz clock (CLK_ULP32K, for highest power efficiency). One of the clock sources must be configured and enabled before using the peripheral: GCLK_EIC is configured and enabled in the Generic Clock Controller. CLK_ULP32K is provided by the internal Ultra Low-Power (OSCULP32K) Oscillator in the OSC32KCTRL module. Both GCLK_EIC and CLK_ULP32K are asynchronous to the user interface clock (CLK_EIC_APB). Due to this asynchronicity, writes to certain registers will require synchronization between the clock domains. Refer to Synchronization for further details. Related Links 19. MCLK – Main Clock 19.6.2.6 Peripheral Clock Masking 18. GCLK - Generic Clock Controller 24. OSC32KCTRL – 32KHz Oscillators Controller 29.5.4 DMA Not applicable. 29.5.5 Interrupts There are several interrupt request lines, at least one for the external interrupts (EXTINT) and one for non-maskable interrupt (NMI). © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 482 SAM L10/L11 Family EIC – External Interrupt Controller The EXTINT interrupt request line is connected to the interrupt controller. Using the EIC interrupt requires the interrupt controller to be configured first. The NMI interrupt request line is also connected to the interrupt controller, but does not require the interrupt to be configured. 29.5.6 Events The events are connected to the Event System. Using the events requires the Event System to be configured first. Related Links 33. EVSYS – Event System 29.5.7 Debug Operation When the CPU is halted in debug mode, the EIC continues normal operation. If the EIC is configured in a way that requires it to be periodically serviced by the CPU through interrupts or similar, improper operation or data loss may result during debugging. 29.5.8 Register Access Protection All registers with write-access can be write-protected optionally by the Peripheral Access Controller (PAC), except for the following registers: • • Interrupt Flag Status and Clear register (INTFLAG) Non-Maskable Interrupt Flag Status and Clear register (NMIFLAG) Optional write-protection by the Peripheral Access Controller (PAC) is denoted by the "PAC Write-Protection" property in each individual register description. PAC write-protection does not apply to accesses through an external debugger. Related Links 15. PAC - Peripheral Access Controller 29.5.9 SAM L11 TrustZone Specific Register Access Protection When the EIC is not PAC secured, non-secure and secure code can both access all functionalities. When the EIC is PAC secured, all registers are by default available in the secure alias only. A PAC secured EIC can open up individual external interrupts for non-secure access. This is done using the NONSEC and the NONSECNMI registers. When an external interrupt has been set as non-secure, it can be handled from non-secure code, using the EIC module non-secure alias. Since only Secured code has the rights to modify the NONSEC register, an interrupt-based mechanism has been added to let Non Secured code know when these registers have been changed by Secured code. A single flag called NSCHK in the INTFLAG register will rise should changes, conditioned by the NSCHK register, occur in the NONSEC or NONSECNMI registers. • EIC Security Attribution registers (NONSEC and NONSECNMI) can only be written in the secure alias, otherwise a PAC error results. • The configuration of secured external interrupts can only be changed in the secure alias. Attempt to change the configuration in non-secure mode is silently ignored. Affected configuration registers are: CTRLA, NMICTRL, NMIFLAG, EVCTRL, INTENCLR, INTENSET, INTFLAG, ASYNCH, CONFIGn, DEBOUNCEN, DPRESCALER. Note:  Refer to the Mix-Secure Peripherals section in the SAM L11 Security Features chapter for more information. 29.5.10 Analog Connections Not applicable. 29.6 Functional Description 29.6.1 Principle of Operation The EIC detects edge or level condition to generate interrupts to the CPU interrupt controller or events to the Event System. Each external interrupt pin (EXTINT) can be filtered using majority vote filtering, clocked by GCLK_EIC or by CLK_ULP32K. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 483 SAM L10/L11 Family EIC – External Interrupt Controller 29.6.2 Basic Operation 29.6.2.1 Initialization The EIC must be initialized in the following order: 1. 2. 3. Enable CLK_EIC_APB If required, configure the NMI by writing the Non-Maskable Interrupt Control register (29.8.2 NMICTRL) Enable GCLK_EIC or CLK_ULP32K when one of the following configuration is selected: – the NMI uses edge detection or filtering. – one EXTINT uses filtering. – one EXTINT uses synchronous edge detection. – one EXTINT uses debouncing. GCLK_EIC is used when a frequency higher than 32KHz is required for filtering. 4. 5. 6. 7. CLK_ULP32K is recommended when power consumption is the priority. For CLK_ULP32K write a '1' to the Clock Selection bit in the Control A register (CTRLA.CKSEL). Configure the EIC input sense and filtering by writing the Configuration n register (CONFIG). Optionally, enable the asynchronous mode. Optionally, enable the debouncer mode. Enable the EIC by writing a ‘1’ to CTRLA.ENABLE. The following bits are enable-protected, meaning that it can only be written when the EIC is disabled (CTRLA.ENABLE=0): • Clock Selection bit in Control A register (CTRLA.CKSEL) The following registers are enable-protected: • • • • • Event Control register (29.8.5 EVCTRL) Configuration n register (CONFIG). External Interrupt Asynchronous Mode register (29.8.9 ASYNCH) Debouncer Enable register (29.8.11 DEBOUNCEN) Debounce Prescaler register (29.8.12 DPRESCALER) Enable-protected bits in the CTRLA register can be written at the same time when setting CTRLA.ENABLE to '1', but not at the same time as CTRLA.ENABLE is being cleared. Enable-protection is denoted by the "Enable-Protected" property in the register description. 29.6.2.2 Enabling, Disabling, and Resetting The EIC is enabled by writing a '1' the Enable bit in the Control A register (CTRLA.ENABLE). The EIC is disabled by writing CTRLA.ENABLE to '0'. The EIC is reset by setting the Software Reset bit in the Control register (CTRLA.SWRST). All registers in the EIC will be reset to their initial state, and the EIC will be disabled. Refer to the CTRLA register description for details. 29.6.3 External Pin Processing Each external pin can be configured to generate an interrupt/event on edge detection (rising, falling or both edges) or level detection (high or low). The sense of external interrupt pins is configured by writing the Input Sense x bits in the Config n register (CONFIG.SENSEx). The corresponding interrupt flag (INTFLAG.EXTINT[x]) in the Interrupt Flag Status and Clear register (29.8.8 INTFLAG) is set when the interrupt condition is met. When the interrupt flag has been cleared in edge-sensitive mode, INTFLAG.EXTINT[x] will only be set if a new interrupt condition is met. In level-sensitive mode, when interrupt has been cleared, INTFLAG.EXTINT[x] will be set immediately if the EXTINTx pin still matches the interrupt condition. Each external pin can be filtered by a majority vote filtering, clocked by GCLK_EIC or CLK_ULP32K. Filtering is enabled if bit Filter Enable x in the Configuration n register (CONFIG.FILTENx) is written to '1'. The majority vote filter © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 484 SAM L10/L11 Family EIC – External Interrupt Controller samples the external pin three times with GCLK_EIC or CLK_ULP32K and outputs the value when two or more samples are equal. Table 29-1. Majority Vote Filter Samples [0, 1, 2] Filter Output [0,0,0] 0 [0,0,1] 0 [0,1,0] 0 [0,1,1] 1 [1,0,0] 0 [1,0,1] 1 [1,1,0] 1 [1,1,1] 1 When an external interrupt is configured for level detection and when filtering is disabled, detection is done asynchronously. Level detection and asynchronous edge detection does not require GCLK_EIC or CLK_ULP32K, but interrupt and events can still be generated. If filtering or synchronous edge detection or debouncing is enabled, the EIC automatically requests GCLK_EIC or CLK_ULP32K to operate. The selection between these two clocks is done by writing the Clock Selection bits in the Control A register (CTRLA.CKSEL). GCLK_EIC must be enabled in the GCLK module. In these modes the external pin is sampled at the EIC clock rate, thus pulses with duration lower than two EIC clock periods may not be properly detected. Figure 29-2. Interrupt Detection Latency by modes (Rising Edge) GCLK_EIC CLK_EIC_APB EXTINTx intreq_extint[x] (level detection / no filter) No interrupt intreq_extint[x] (level detection / filter) intreq_extint[x] (edge detection / no filter) No interrupt intreq_extint[x] (edge detection / filter) clear INTFLAG.EXTINT[x] The detection latency depends on the detection mode. Table 29-2. Detection Latency Detection mode Latency (worst case) Level without filter Five CLK_EIC_APB periods Level with filter Four GCLK_EIC/CLK_ULP32K periods + five CLK_EIC_APB periods Edge without filter Four GCLK_EIC/CLK_ULP32K periods + five CLK_EIC_APB periods Edge with filter Six GCLK_EIC/CLK_ULP32K periods + five CLK_EIC_APB periods Related Links 18. GCLK - Generic Clock Controller © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 485 SAM L10/L11 Family EIC – External Interrupt Controller 29.6.4 Additional Features 29.6.4.1 Non-Maskable Interrupt (NMI) The non-maskable interrupt pin can also generate an interrupt on edge or level detection, but it is configured with the dedicated NMI Control register (NMICTRL). To select the sense for NMI, write to the NMISENSE bit group in the NMI Control register (NMICTRL.NMISENSE). NMI filtering is enabled by writing a '1' to the NMI Filter Enable bit (NMICTRL.NMIFILTEN). If edge detection or filtering is required, enable GCLK_EIC or CLK_ULP32K. NMI detection is enabled only by the NMICTRL.NMISENSE value, and the EIC is not required to be enabled. When an NMI is detected, the non-maskable interrupt flag in the NMI Flag Status and Clear register is set (NMIFLAG.NMI). NMI interrupt generation is always enabled, and NMIFLAG.NMI generates an interrupt request when set. 29.6.4.2 Asynchronous Edge Detection Mode (No Debouncing) The EXTINT edge detection can be operated synchronously or asynchronously, selected by the Asynchronous Control Mode bit for external pin x in the External Interrupt Asynchronous Mode register (ASYNCH.ASYNCH[x]). The EIC edge detection is operated synchronously when the Asynchronous Control Mode bit (ASYNCH.ASYNCH[x]) is '0' (default value). It is operated asynchronously when ASYNCH.ASYNCH[x] is written to '1'. In Synchronous Edge Detection Mode, the external interrupt (EXTINT) or the non-maskable interrupt (NMI) pins are sampled using the EIC clock as defined by the Clock Selection bit in the Control A register (CTRLA.CKSEL). The External Interrupt flag (INTFLAG.EXTINT[x]) or Non-Maskable Interrupt flag (NMIFLAG.NMI) is set when the last sampled state of the pin differs from the previously sampled state. In this mode, the EIC clock is required. The Synchronous Edge Detection Mode can be used in Idle and Standby sleep modes. In Asynchronous Edge Detection Mode, the external interrupt (EXTINT) pins or the non-maskable interrupt (NMI) pins set the External Interrupt flag or Non-Maskable Interrupt flag (INTFLAG.EXTINT[x] or NMIFLAG) directly. In this mode, the EIC clock is not requested. The asynchronous edge detection mode can be used in Idle and Standby sleep modes. 29.6.4.3 Interrupt Pin Debouncing The external interrupt pin (EXTINT) edge detection can use a debouncer to improve input noise immunity. When selected, the debouncer can work in the synchronous mode or the asynchronous mode, depending on the configuration of the ASYNCH.ASYNCH[x] bit for the pin. The debouncer uses the EIC clock as defined by the bit CTRLA.CKSEL to clock the debouncing circuitry. The debouncing time frame is set with the debouncer prescaler DPRESCALER.DPRESCALERn, which provides the low frequency clock tick that is used to reject higher frequency signals. The debouncing mode for pin EXTINT x can be selected only if the Sense bits in the Configuration y register (CONFIGy.SENSEx) are set to RISE, FALL or BOTH. If the debouncing mode for pin EXTINT x is selected, the filter mode for that pin (CONFIGy.FILTENx) can not be selected. The debouncer manages an internal “valid pin state” that depends on the external interrupt (EXTINT) pin transitions, the debouncing mode and the debouncer prescaler frequency. The valid pin state reflects the pin value after debouncing. The external interrupt pin (EXTINT) is sampled continously on EIC clock. The sampled value is evaluated on each low frequency clock tick to detect a transitional edge when the sampled value is different of the current valid pin state. The sampled value is evaluated on each EIC clock when DPRESCALER.TICKON=0 or on each low frequency clock tick when DPRESCALER.TICKON=1, to detect a bounce when the sampled value is equal to the current valid pin state. Transitional edge detection increments the transition counter of the EXTINT pin, while bounce detection resets the transition counter. The transition counter must exceed the transition count threshold as defined by the DPRESCALER.STATESn bitfield. In the synchronous mode the threshold is 4 when DPRESCALER.STATESn=0 or 8 when DPRESCALER.STATESn=1. In the asynchronous mode the threshold is 4. The valid pin state for the pins can be accessed by reading the register PINSTATE for both synchronous or asynchronous debouncing mode. Synchronous edge detection In this mode the external interrupt (EXTINT) pin is sampled continously on EIC clock. 1. A pin edge transition will be validated when the sampled value is consistently different of the current valid pin state for 4 (or 8 depending on bit DPRESCALER.STATESn) consecutive ticks of the low frequency clock. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 486 SAM L10/L11 Family EIC – External Interrupt Controller 2. 3. 4. 5. Any pin sample, at the low frequency clock tick rate, with a value opposite to the current valid pin state will increment the transition counter. Any pin sample, at EIC clock rate (when DPRESCALER.TICKON=0) or the low frequency clock tick (when DPRESCALER.TICKON=1), with a value identical to the current valid pin state will return the transition counter to zero. When the transition counter meets the count threshold, the pin edge transition is validated and the pin state PINSTATE.PINSTATE[x] is changed to the detected level. The external interrupt flag (INTFLAG.EXTINT[x]) is set when the pin state PINSTATE.PINSTATE[x] is changed. Figure 29-3. EXTINT Pin Synchronous Debouncing (Rising Edge) CLK_EIC CLK_PRESCALER EXTINTx PIN_STATE INTGLAG LOW HIGH TRANSITION Set INTFLAG In the synchronous edge detection mode, the EIC clock is required. The synchronous edge detection mode can be used in Idle and Standby sleep modes. Asynchronous edge detection In this mode, the external interrupt (EXTINT) pin directly drives an asynchronous edges detector which triggers any rising or falling edge on the pin: 1. Any edge detected that indicates a transition from the current valid pin state will immediately set the valid pin state PINSTATE.PINSTATE[x] to the detected level. 2. The external interrupt flag (INTFLAG.EXTINT[x] is immediately changed. 3. The edge detector will then be idle until no other rising or falling edge transition is detected during 4 consecutive ticks of the low frequency clock. 4. Any rising or falling edge transition detected during the idle state will return the transition counter to 0. 5. After 4 consecutive ticks of the low frequency clock without bounce detected, the edge detector is ready for a new detection. Figure 29-4. EXTINT Pin Asynchronous Debouncing (Rising Edge) CLK_EIC CLK_PRESCALER EXTINTx PIN_STATE INTGLAG LOW TRANSITION HIGH Set INTFLAG In this mode, the EIC clock is requested. The asynchronous edge detection mode can be used in Idle and Standby sleep modes. 29.6.5 DMA Operation Not applicable. 29.6.6 Interrupts The EIC has the following interrupt sources: • • • External interrupt pins (EXTINTx). See 29.6.2 Basic Operation. Non-maskable interrupt pin (NMI). See 29.6.4 Additional Features. Non-secure check interrupt pin (NSCHK). See 29.8.8 INTFLAG © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 487 SAM L10/L11 Family EIC – External Interrupt Controller Each interrupt source has an associated interrupt flag. The interrupt flag in the Interrupt Flag Status and Clear register (INTFLAG) is set when an interrupt condition occurs (NMIFLAG for NMI). Each interrupt, except NMI, can be individually enabled by setting the corresponding bit in the Interrupt Enable Set register (INTENSET=1), and disabled by setting the corresponding bit in the Interrupt Enable Clear register (INTENCLR=1). An interrupt request is generated when the interrupt flag is set and the corresponding interrupt is enabled. The interrupt request remains active until the interrupt flag is cleared, the interrupt is disabled, or the EIC is reset. See the INTFLAG register for details on how to clear interrupt flags. The EIC has at least one common interrupt request line for all the interrupt sources, and one interrupt request line for the NMI. The user must read the INTFLAG (or NMIFLAG) register to determine which interrupt condition is present. Note:  Interrupts must be globally enabled for interrupt requests to be generated. 29.6.7 Events The EIC can generate the following output events: • External event from pin (EXTINT0-7). Setting an Event Output Control register (EVCTRL.EXTINTEO) enables the corresponding output event. Clearing this bit disables the corresponding output event. Refer to Event System for details on configuring the Event System. When the condition on pin EXTINTx matches the configuration in the CONFIGn register, the corresponding event is generated, if enabled. 29.6.8 Sleep Mode Operation In sleep modes, an EXTINTx pin can wake up the device if the corresponding condition matches the configuration in the CONFIG register, and the corresponding bit in the Interrupt Enable Set register (29.8.7 INTENSET) is written to '1'. Figure 29-5. Wake-up Operation Example (High-Level Detection, No Filter, Interrupt Enable Set) CLK_EIC_APB EXTINTx intwake_extint[x] intreq_extint[x] wake from sleep mode 29.6.9 clear INTFLAG.EXTINT[x] SAM L11 Secure Access Rights Non-secure write to CTRLA register or DPRESCALER register is prohibited. Non-secure read to CTRLA or DPRESCALER register or SYNCBUSY register will return zero with no error resulting. Non-secure write to a bit of EVCTRL, ASYNCH, DEBOUNCEN, INTENCLR, INTENSET, INTFLAG and CONFIG registers is prohibited if the related bit of NONSEC.EXTINT is zero. Non-secure write to NMICTRL and NMIFLAG registers is prohibited if NONSECNMI.NMI is zero. Bits relating to secure EXTINT read as zero in non-secure mode with no error resulting. 29.6.10 Synchronization Due to asynchronicity between the main clock domain and the peripheral clock domains, some registers need to be synchronized when written or read. The following bits are synchronized when written: • • Software Reset bit in control register (CTRLA.SWRST) Enable bit in control register (CTRLA.ENABLE) Required write-synchronization is denoted by the "Write-Synchronized" property in the register description. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 488 SAM L10/L11 Family EIC – External Interrupt Controller 29.7 Register Summary Important:  For SAM L11, the EIC register map is automatically duplicated in a Secure and Non-Secure alias: • The Non-Secure alias is at the peripheral base address • The Secure alias is located at the peripheral base address + 0x200 Refer to Mix-Secure Peripherals for more information on register access rights Offset Name Bit Pos. 0x00 0x01 0x02 0x03 CTRLA NMICTRL NMIFLAG Reserved 7:0 7:0 7:0 0x04 0x08 0x0C 0x10 0x14 0x18 SYNCBUSY EVCTRL INTENCLR INTENSET INTFLAG ASYNCH 0x1C CONFIG 0x20 ... 0x2F Reserved 0x30 0x34 0x38 DEBOUNCEN DPRESCALER PINSTATE 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7 6 5 4 3 CKSEL NMIASYNCH NMIFILTEN 2 1 0 ENABLE NMISENSE[2:0] SWRST NMI ENABLE SWRST EXTINTEO[7:0] EXTINT[7:0] NSCHK EXTINT[7:0] NSCHK EXTINT[7:0] NSCHK ASYNCH[7:0] FILTEN1 FILTEN3 FILTEN5 FILTEN7 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 © 2020 Microchip Technology Inc. SENSE1[2:0] SENSE3[2:0] SENSE5[2:0] SENSE7[2:0] FILTEN0 FILTEN2 FILTEN4 FILTEN6 SENSE0[2:0] SENSE2[2:0] SENSE4[2:0] SENSE6[2:0] DEBOUNCEN[7:0] STATES PRESCALER[2:0] TICKON PINSTATE[7:0] Datasheet DS60001513F-page 489 SAM L10/L11 Family EIC – External Interrupt Controller ...........continued Offset Name 0x3C NSCHK 0x40 29.8 Bit Pos. 7 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 NONSEC 6 5 4 3 2 1 0 EXTINT[7:0] NMI EXTINT[7:0] NMI Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16-, and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers require synchronization when read and/or written. Synchronization is denoted by the "ReadSynchronized" and/or "Write-Synchronized" property in each individual register description. Some registers are enable-protected, meaning they can only be written when the module is disabled. Enableprotection is denoted by the "Enable-Protected" property in each individual register description. On SAM L11 devices, the Mix-Secure peripheral has different types of registers (Non-Secure, Secure, Write-Secure, Mix-Secure, and Write-Mix-Secure) with different access permissions for each bitfield. Refer to Mix-Secure Peripherals for more details. In the following register descriptions, the access permissions are specified as shown in the following figure. Bit 7 6 5 4 3 2 1 0 R/-/RW R/-/RW R/-/RW R/-/RW CMD[7:0] Access R/-/RW R/-/RW R/-/RW R/-/RW TrustZone Non-Protected Devices Access TrustZone Protected Devices Non-Secure Access TrustZone Protected Devices Secure Access © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 490 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.1 Control A Name:  Offset:  Reset:  Property:  Bit 7 CTRLA 0x00 0x00 PAC Write-Protection, Enable-Protected, Write-Synchronized, Secure 6 Access Reset 5 4 CKSEL RW/-/RW 0 3 2 1 ENABLE RW/-/RW 0 0 SWRST W/-/W 0 Bit 4 – CKSEL Clock Selection The EIC can be clocked either by GCLK_EIC (when a frequency higher than 32KHz is required for filtering) or by CLK_ULP32K (when power consumption is the priority). This bit is not Write-Synchronized. Value Description 0 The EIC is clocked by GCLK_EIC. 1 The EIC is clocked by CLK_ULP32K. Bit 1 – ENABLE Enable Due to synchronization there is a delay between writing to CTRLA.ENABLE until the peripheral is enabled/disabled. The value written to CTRLA.ENABLE will read back immediately and the Enable bit in the Synchronization Busy register will be set (SYNCBUSY.ENABLE=1). SYNCBUSY.ENABLE will be cleared when the operation is complete. This bit is not Enable-Protected. This bit is Write-Synchronized. Value Description 0 The EIC is disabled. 1 The EIC is enabled. Bit 0 – SWRST Software Reset Writing a '0' to this bit has no effect. Writing a '1' to this bit resets all registers in the EIC to their initial state, and the EIC will be disabled. Writing a '1' to CTRLA.SWRST will always take precedence, meaning that all other writes in the same write operation will be discarded. Due to synchronization there is a delay from writing CTRLA.SWRST until the Reset is complete. CTRLA.SWRST and SYNCBUSY.SWRST will both be cleared when the Reset is complete. This bit is not Enable-Protected. This bit is Write-Synchronized. Value Description 0 There is no ongoing reset operation. 1 The reset operation is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 491 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.2 Non-Maskable Interrupt Control Name:  Offset:  Reset:  Property:  NMICTRL 0x01 0x00 PAC Write-Protection, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the NMI interrupt is set as Non-Secure in the NONSEC register (NONSEC.NMI bit). Bit 7 6 Access Reset 5 4 3 2 1 0 NMIASYNCH NMIFILTEN NMISENSE[2:0] RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW 0 0 0 0 0 Bit 4 – NMIASYNCH Non-Maskable Interrupt Asynchronous Edge Detection Mode The NMI edge detection can be operated synchronously or asynchronously to the EIC clock. Value Description 0 The NMI edge detection is synchronously operated. 1 The NMI edge detection is asynchronously operated. Bit 3 – NMIFILTEN Non-Maskable Interrupt Filter Enable Value Description 0 NMI filter is disabled. 1 NMI filter is enabled. Bits 2:0 – NMISENSE[2:0] Non-Maskable Interrupt Sense Configuration These bits define on which edge or level the NMI triggers. Value Name Description 0x0 NONE No detection 0x1 RISE Rising-edge detection 0x2 FALL Falling-edge detection 0x3 BOTH Both-edge detection 0x4 HIGH High-level detection 0x5 LOW Low-level detection 0x6 Reserved 0x7 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 492 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.3 Non-Maskable Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  NMIFLAG 0x2 0x00 Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the NMI interrupt is set as Non-Secure in the NONSEC register (NONSEC.NMI bit). Bit 7 6 5 4 3 Access Reset 2 1 0 NMI RW/RW*/RW 0 Bit 0 – NMI Non-Maskable Interrupt This flag is cleared by writing a '1' to it. This flag is set when the NMI pin matches the NMI sense configuration, and will generate an interrupt request. Writing a '0' to this bit has no effect. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 493 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.4 Synchronization Busy Name:  Offset:  Reset:  Property:  Bit SYNCBUSY 0x04 0x00000000 Secure 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 ENABLE R/-/R 0 0 SWRST R/-/R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset Bit 1 – ENABLE Enable Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.ENABLE bit is complete. 1 Write synchronization for CTRLA.ENABLE bit is ongoing. Bit 0 – SWRST Software Reset Synchronization Busy Status Value Description 0 Write synchronization for CTRLA.SWRST bit is complete. 1 Write synchronization for CTRLA.SWRST bit is ongoing. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 494 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.5 Event Control Name:  Offset:  Reset:  Property:  EVCTRL 0x08 0x00000000 PAC Write-Protection, Enable-Protected, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). Some restrictions apply for the Non-Secure accesses to an Enable-Protected register as it will not be possible for the Non-Secure to configure it once this register is enabled by the Secure application. This will require some veneers to be implemented on Secure side. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 Access Reset Bit Access Reset Bit Access Reset Bit 4 3 2 1 0 EXTINTEO[7:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bits 7:0 – EXTINTEO[7:0] External Interrupt Event Output Enable The bit x of EXTINTEO enables the event associated with the EXTINTx pin. Value Description 0 Event from pin EXTINTx is disabled. 1 Event from pin EXTINTx is enabled and will be generated when EXTINTx pin matches the external interrupt sensing configuration. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 495 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.6 Interrupt Enable Clear Name:  Offset:  Reset:  Property:  INTENCLR 0x0C 0x00000000 PAC Write-Protection, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set register (INTENSET). Bit 31 NSCHK Access RW/RW/RW Reset 0 Bit 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 Access Reset Bit Access Reset Bit 3 2 1 0 EXTINT[7:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bit 31 – NSCHK Non-secure Check Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the NSCHK Interrupt Enable bit. Bits 7:0 – EXTINT[7:0] External Interrupt Enable The bit x of EXTINT enables the interrupt associated with the EXTINTx pin. Writing a '0' to bit x has no effect. Writing a '1' to bit x will clear the External Interrupt Enable bit x, which disables the external interrupt EXTINTx. Value Description 0 The external interrupt x is disabled. 1 The external interrupt x is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 496 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.7 Interrupt Enable Set Name:  Offset:  Reset:  Property:  INTENSET 0x10 0x00000000 PAC Write-Protection, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear (INTENCLR) register. Bit 31 NSCHK Access RW/RW/RW Reset 0 Bit 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 Access Reset Bit Access Reset Bit 3 2 1 0 EXTINT[7:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bit 31 – NSCHK Non-secure Check Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the NSCHK Interrupt Enable bit. Bits 7:0 – EXTINT[7:0] External Interrupt Enable The bit x of EXTINT enables the interrupt associated with the EXTINTx pin. Writing a '0' to bit x has no effect. Writing a '1' to bit x will set the External Interrupt Enable bit x, which enables the external interrupt EXTINTx. Value Description 0 The external interrupt x is disabled. 1 The external interrupt x is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 497 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.8 Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  INTFLAG 0x14 0x00000000 Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). Bit 31 NSCHK Access RW/RW/RW Reset 0 Bit 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 Access Reset Bit Access Reset Bit 3 2 1 0 EXTINT[7:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bit 31 – NSCHK Non-secure Check Interrupt The flag is cleared by writing a '1' to it. This flag is set when write to either NONSEC and NSCHK register and if the related bit of NSCHK is enabled and the related bit of NONSEC is zero. Bits 7:0 – EXTINT[7:0] External Interrupt The flag bit x is cleared by writing a '1' to it. This flag is set when EXTINTx pin matches the external interrupt sense configuration and will generate an interrupt request if 29.8.6 INTENCLR.EXTINT[x] or 29.8.7 INTENSET.EXTINT[x] is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the External Interrupt x flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 498 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.9 External Interrupt Asynchronous Mode Name:  Offset:  Reset:  Property:  ASYNCH 0x18 0x00000000 PAC Write-Protection, Enable-Protected, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). Some restrictions apply for the Non-Secure accesses to an Enable-Protected register as it will not be possible for the Non-Secure to configure it once this register is enabled by the Secure application. This will require some veneers to be implemented on Secure side. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 Access Reset Bit Access Reset Bit Access Reset Bit 4 3 2 1 0 ASYNCH[7:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bits 7:0 – ASYNCH[7:0] Asynchronous Edge Detection Mode The bit x of ASYNCH set the Asynchronous Edge Detection Mode for the interrupt associated with the EXTINTx pin. Value Description 0 The EXTINT x edge detection is synchronously operated. 1 The EXTINT x edge detection is asynchronously operated. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 499 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.10 External Interrupt Sense Configuration Name:  Offset:  Reset:  Property:  CONFIG 0x1C 0x00000000 PAC Write-Protection, Enable-Protected, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). Some restrictions apply for the Non-Secure accesses to an Enable-Protected register as it will not be possible for the Non-Secure to configure it once this register is enabled by the Secure application. This will require some veneers to be implemented on the Secure side. Bit 31 30 29 28 27 26 25 24 FILTEN7 SENSE7[2:0] FILTEN6 SENSE6[2:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bit 23 22 21 20 19 18 17 16 FILTEN5 SENSE5[2:0] FILTEN4 SENSE4[2:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bit 15 14 13 12 11 10 9 8 FILTEN3 SENSE3[2:0] FILTEN2 SENSE2[2:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bit 7 6 5 4 3 2 1 0 FILTEN1 SENSE1[2:0] FILTEN0 SENSE0[2:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bits 3, 7, 11, 15, 19, 23, 27, 31 – FILTENx Filter Enable x [x=7..0] Value Description 0 Filter is disabled for EXTINT[x] input. 1 Filter is enabled for EXTINT[x] input. Bits 0:2, 4:6, 8:10, 12:14, 16:18, 20:22, 24:26, 28:30 – SENSEx Input Sense Configuration x [x=7..0] These bits define on which edge or level the interrupt or event for EXTINT[x] will be generated. Value Name Description 0x0 NONE No detection 0x1 RISE Rising-edge detection 0x2 FALL Falling-edge detection 0x3 BOTH Both-edge detection 0x4 HIGH High-level detection 0x5 LOW Low-level detection 0x6 Reserved 0x7 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 500 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.11 Debouncer Enable Name:  Offset:  Reset:  Property:  DEBOUNCEN 0x30 0x00000000 PAC Write-Protection, Enable-Protected, Mix-Secure Important:  For SAM L11 Non-Secure accesses, read and write accesses (RW*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). Some restrictions apply for the Non-Secure accesses to an Enable-Protected register as it will not be possible for the Non-Secure to configure it once this register is enabled by the Secure application. This will require some veneers to be implemented on Secure side. Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 Access Reset Bit Access Reset Bit Access Reset Bit 4 3 2 1 0 DEBOUNCEN[7:0] Access RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW Reset 0 0 0 0 0 0 0 0 Bits 7:0 – DEBOUNCEN[7:0] Debouncer Enable The bit x of DEBOUNCEN set the Debounce mode for the interrupt associated with the EXTINTx pin. Value Description 0 The EXTINT x edge input is not debounced. 1 The EXTINT x edge input is debounced. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 501 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.12 Debouncer Prescaler Name:  Offset:  Reset:  Property:  Bit DPRESCALER 0x34 0x00000000 PAC Write-Protection, Enable-Protected, Secure 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 TICKON RW/-/RW 0 15 14 13 12 11 10 9 8 7 6 5 4 3 STATES RW/-/RW 0 2 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 1 0 PRESCALER[2:0] RW/-/RW RW/-/RW RW/-/RW 0 0 0 Bit 16 – TICKON Pin Sampler frequency selection This bit selects the clock used for the sampling of bounce during transition detection. Value Description 0 The bounce sampler is using GCLK_EIC. 1 The bounce sampler is using the low frequency clock. Bit 3 – STATES Debouncer Number of States This bit selects the number of samples by the debouncer low frequency clock needed to validate a transition from current pin state to next pin state in synchronous debouncing mode for pins EXTINT[7:0]. Value Description 0 The number of low frequency samples is 3. 1 The number of low frequency samples is 7. Bits 2:0 – PRESCALER[2:0] Debouncer Prescaler These bits select the debouncer low frequency clock for pins EXTINT[7:0]. Value Name Description 0x0 F/2 EIC clock divided by 2 0x1 F/4 EIC clock divided by 4 0x2 F/8 EIC clock divided by 8 0x3 F/16 EIC clock divided by 16 0x4 F/32 EIC clock divided by 32 0x5 F/64 EIC clock divided by 64 0x6 F/128 EIC clock divided by 128 0x7 F/256 EIC clock divided by 256 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 502 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.13 Pin State Name:  Offset:  Reset:  Property:  PINSTATE 0x38 0x00000000 PAC Mix-Secure Important:  For SAM L11 Non-Secure accesses, read accesses (R*) are allowed only if the external interrupt x (EXTINTx) is set as Non-Secure in the NONSEC register (NONSEC.EXTINTx bit). Bit 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 2 1 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 R/R*/R 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 4 3 PINSTATE[7:0] R/R*/R R/R*/R 0 0 Bits 7:0 – PINSTATE[7:0] Pin State These bits return the valid pin state of the debounced external interrupt pin EXTINTx. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 503 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.14 Security Attribution Check Name:  Offset:  Reset:  Property:  NSCHK 0x3C 0x00000000 PAC Write-Protection This register allows the user to select one or more external pins to check their security attribution as non-secured. Important:  This register is only available for SAM L11 and has no effect for SAM L10. Bit 31 NMI Access RW/RW/RW Reset 0 Bit 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 Access Reset Bit Access Reset Bit 3 2 1 0 EXTINT[7:0] Access RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW RW/RW/RW Reset 0 0 0 0 0 0 0 0 Bit 31 – NMI Non-Maskable Interrupt Security Attribution Check This bit selects the Non-Maskable Interrupt pin for security attribution check. If the NMI bit in NONSECNMI is set to the opposite value, then the NSCHK interrupt flag will be set. Value Description 0 0-to-1 transition will be detected on corresponding NONSEC bit. 1 1-to-0 transition will be detected on corresponding NONSEC bit. Bits 7:0 – EXTINT[7:0] External Interrupts Security Attribution Check These bits select the individual pins for security attribution check. If any pin selected in NSCHK has the corresponding bit in NONSEC set to the opposite value, then the NSCHK interrupt flag will be set. Value Description 0 0-to-1 transition will be detected on corresponding NONSEC bit. 1 1-to-0 transition will be detected on corresponding NONSEC bit. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 504 SAM L10/L11 Family EIC – External Interrupt Controller 29.8.15 Non-secure Interrupt Name:  Offset:  Reset:  Property:  NONSEC 0x40 0x00000000 PAC Write-Protection, Write-Secure This register allows to set the NMI or external interrupt control and status registers in non-secure mode, individually per interrupt pin. Important:  This register is only available for SAM L11 and has no effect for SAM L10. Bit Access Reset Bit 31 NMI RW/R/RW 0 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 2 1 0 RW/R/RW 0 RW/R/RW 0 RW/R/RW 0 RW/R/RW 0 RW/R/RW 0 RW/R/RW 0 Access Reset Bit Access Reset Bit Access Reset 3 EXTINT[7:0] RW/R/RW RW/R/RW 0 0 Bit 31 – NMI Non-Secure Non-Maskable Interrupt This bit enables the non-secure mode of NMI. The registers whose content is set in non-secure mode by NONSEC.NMI are NMICTRL and NMIFLAG registers. Value Description 0 NMI is secure. 1 NMI is non-secure. Bits 7:0 – EXTINT[7:0] Non-Secure External Interrupt The bit x of EXTINT enables the non-secure mode of EXTINTx. The registers whose EXTINT bit or bitfield x is set in non-secure mode by NONSEC.EXTINTx are EVCTRL, ASYNCH, IDEBOUNCEN, NTENCLR, INTENSET, INTFLAG and CONFIG registers. Value Description 0 EXTINTx is secure. 1 EXTINTx is non-secure. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 505 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30. 30.1 NVMCTRL – Nonvolatile Memory Controller Overview Non-Volatile Memory (NVM) is a reprogrammable Flash memory that retains program and data storage even with power off. It embeds three separate arrays, namely FLASH, Data FLASH and NVM Rows. The Data FLASH array can be programmed while reading the FLASH array. It is intended to store data while executing from the FLASH without stalling. NVM Rows store the data needed during the device startup, such as calibration and system configuration. The NVM Controller (NVMCTRL) connects to the AHB and APB bus interfaces for system access to the NVM block. The AHB interface is used for reads and writes to the NVM block, while the APB interface is used for commands and configuration. 30.2 Features • • • • • • • • • • • 30.3 32-bit AHB interface for reads and writes Write-While-Read (WWR) Data Flash All NVM sections are memory mapped to the AHB, including calibration and system configuration 32-bit APB interface for commands and control Programmable wait states for read optimization 6 regions can be individually protected or unprotected Additional protection for bootloader Interface to power manager for power-down of Flash blocks in sleep modes Can optionally wake-up on exit from sleep or on first access Direct-mapped cache TrustZone Support (SAM L11) Block Diagram Figure 30-1. Block Diagram NVMCTRL AHB NVM Block Cache Flash and NVM Rows array NVM Interface APB Command and Control © 2020 Microchip Technology Inc. Data Flash array Datasheet DS60001513F-page 506 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.4 Signal Description Not applicable. 30.5 Product Dependencies In order to use this peripheral, other parts of the system must be configured correctly, as described in the following sections. 30.5.1 Power Management The NVMCTRL will continue to operate in any sleep mode where the selected source clock is running. The NVMCTRL interrupts can be used to wake up the device from sleep modes. The Power Manager will automatically put the NVM block into a low-power state when entering sleep mode. This is based on the Control B register (CTRLB) SLEEPPRM bit setting. Refer to the 30.8.2 CTRLB.SLEEPPRM register description for more details. The NVM block goes into low-power mode automatically when the device enters STANDBY mode regardless of SLEEPPRM. The NVM Page Buffer is lost when the NVM goes into low power mode therefore a write command must be issued prior entering the NVM low power mode. NVMCTRL SLEEPPRM can be disabled to avoid such loss when the CPU goes into sleep except if the device goes into STANDBY mode for which there is no way to retain the Page Buffer. Related Links 22. PM – Power Manager 30.5.2 Clocks Two synchronous clocks are used by the NVMCTRL. One is provided by the AHB bus (CLK_NVMCTRL_AHB) and the other is provided by the APB bus (CLK_NVMCTRL_APB). For higher system frequencies, a programmable number of wait states can be used to optimize performance. When changing the AHB bus frequency, the user must ensure that the NVM Controller is configured with the proper number of wait states. Refer to the Electrical Characteristics for the exact number of wait states to be used for a particular frequency range. 30.5.3 Interrupts The NVM Controller interrupt request line is connected to the interrupt controller. Using the NVMCTRL interrupt requires the interrupt controller to be programmed first. 30.5.4 Events The NVMCTRL can take the following actions on an input event: • • Write zeroes in one Data FLASH row: Refer to 30.6.7 Tamper Erase for details. Write a page in the FLASH or in the Data FLASH: Refer to 30.6.6 Event Automatic Write for details. The NVMCTRL uses only asynchronous events, so the asynchronous Event System channel path must be configured. By default, the NVMCTRL will detect a rising edge on the incoming event. If the NVMCTRL action must be performed on the falling edge of the incoming event, the event line must be inverted first. This is done by setting the corresponding Event Invert Enable bit in Event Control register (NVMCTRL.AUTOWINV=1). 30.5.5 Debug Operation When an external debugger forces the CPU into debug mode, the peripheral continues normal operation except that FLASH reads are not cached so that the cache state is not altered by debug tools. 30.5.6 Register Access Protection All registers with write-access are optionally write-protected by the Peripheral Access Controller (PAC), except the following registers: • Interrupt Flag Status and Clear register (INTFLAG) Optional write-protection by the Peripheral Access Controller (PAC) is denoted by the "PAC Write-Protection" property in each individual register description. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 507 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller When TrustZone is supported (SAM L11 only), all register reads are allowed. Non-secure writes to APB registers are limited as follows. Illegal writes will be ignored. • • Some commands written to CTRLA such as Write/Erase and Lock/Unlock are only permitted to non-secure application and data space. Writes to all other registers except CTRLC and INTFLAG are not allowed. Related Links 15. PAC - Peripheral Access Controller 30.5.7 SAM L11 TrustZone Specific Register Access Protection The NVMCTRL is a split-secure APB module, all registers are available in the secure alias and only a subset of registers is available in the non-secure alias with limited access. When NONSEC.WRITE is read zero, all APB write accesses to the non-secure APB alias and all non-secure AHB write accesses to the Page Buffer are discarded. The latter returns a hardfault. Any attempt to change the configuration via the non-secure alias is silently ignored. Debug Access to the bus system can be restricted to allow only accesses to non-secure regions or reject all accesses. See the section on the NVMCTRL Debugger Access Level for details. Note:  Refer to the Mix-Secure Peripherals section in the SAM L11 Security Features chapter for more information. 30.5.8 Analog Connections Not applicable. 30.6 Functional Description 30.6.1 Principle of Operation The NVM Controller is a slave on the AHB and APB buses. It responds to commands, read requests and write requests, based on user configuration. 30.6.1.1 Initialization After power up, the NVM Controller goes through a power-up sequence. During this time, access to the NVM Controller from the AHB bus is halted. Upon power-up completion, the NVM Controller is operational without any need for user configuration. 30.6.2 Memory Organization Refer to the Physical Memory Map for memory sizes and addresses for each device. The NVM is organized into rows, where each row contains four pages, as shown in the NVM Row Organization figure. The NVM has a row-erase granularity, while the write granularity is by page. In other words, a single row erase will erase all four pages in the row, while four write operations are used to write the complete row. Figure 30-2. NVM Row Organization Row n Page (n*4) + 3 Page (n*4) + 2 Page (n*4) + 1 Page (n*4) + 0 The NVM block contains the NVM Rows which contain calibration and system configuration, the FLASH area intended to store code and a separate array dedicated to data storage called Data FLASH that can be modified while the FLASH is read (no bus stall). All these areas are memory mapped. Refer to the NVM Organization figure below for details. The NVM Rows contain factory calibration and system configuration information. These spaces can be read from the AHB bus in the same way as the FLASH. Note that Data FLASH requires more cycles to be read. The Data FLASH are can be executable, however this is not recommended as it can weaken an application security and also affect performances. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 508 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Figure 30-3. NVM Memory Organization 0x00400000 Data Flash Flash (APPLICATION Region) Flash (BOOT Region) BOOTPROT 0x00000000 The lower rows in the FLASH can be allocated as a boot loader section by using the BOOTPROT fuses. The boot loader section size is defined by the BOOTPROT fuses expressed in number of rows. Important:  Refer to the Boot ROM section to get Chip Erase commands effects for this specific BOOT area. 30.6.3 Region Unlock Bits The NVMCTRL has the ability to lock regions defined in the NVM Memory Organization figures. When a region is locked all modify (i.e. write or erase) commands directed to these regions are discarded. When such an operation occurs a LOCKE error is reported in the INTFLAG register and can generate an interruption. To lock or unlock a region, write a one to the bitfield corresponding to the selected regions in the SULCK and NSULCK registers with the correct key. Writes to these registers are silently discarded when the key is not correct. Writing these registers with the correct key will temporarily lock/unlock the corresponding regions. The new setting will stay in effect until the next Reset, or until the setting is changed again while writing SULCK and NSULCK. The current status of the lock can be determined by reading the SULCK and NSULCK registers. To change the default lock/unlock setting for a region, the NVM User Row (UROW) must be written using the Write Page command. Writing to the NVM User Row (UROW) will take effect after the next Reset. Therefore, a boot of the device is needed for changes in the lock/unlock setting to take effect. Refer to the Physical Memory Map for NVM User Row (UROW) space address mapping. 30.6.4 Command and Data Interface The NVM Controller is addressable from the APB bus, while the NVM main address space is addressable from the AHB bus. Read and automatic page write operations are performed by addressing the FLASH, Data FLASH and NVM Rows arrays directly, while other operations such as manual page writes and row erases must be performed by issuing commands through the NVM Controller. To issue a command, the CTRLA.CMD bits must be written along with the CTRLA.CMDEX value. When a command is issued, STATUS.READY is cleared and rises again when the command has completed. INTFLAG.DONE is also set when a command completes. Any commands written while INTFLAG.READY is low will be ignored. The CTRLB and CTRLC registers must be used to control the power reduction mode, read wait states, and the write mode. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 509 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.6.4.1 FLASH Read Reading from the FLASH is performed via the AHB bus. Read data is available after the configured number of read wait states (CTRLB.RWS) set in the NVM Controller. Reading the Flash while a programming or erase operation is ongoing on the Flash results in an AHB bus stall until the end of the operation. Reading the Flash does not stall the bus when the Data FLASH is being programmed or erased. 30.6.4.2 DATA FLASH Read Reading from the Data FLASH is performed via the AHB bus by addressing the Data FLASH address space directly. Read timings are increased by one cycle compared to regular FLASH read timings when access size is Byte or halfWord. The AHB data phase is twice as long in case of full-Word-size access. It is not possible to read the Data FLASH while the Flash is being written or erased (the read is stalled), whereas the Data FLASH can be written or erased while the Flash is being read. The Data FLASH address space is not cached, therefore it is recommended to limit access to this area for performance and power consumption considerations. 30.6.4.3 FLASH, DATA FLASH Write Data to be written to the NVM block are first written to and stored in an internal buffer called the page buffer. The page buffer contains the same number of bytes as an NVM page. Writes to the page buffer must be 16 or 32 bits. 8bit writes to the page buffer are not allowed and will cause a bus error. Both FLASH and Data FLASH share the same page buffer. Writing to the NVM block via the AHB bus is performed by a load operation to the page buffer. For each AHB bus write, the address is stored in the ADDR register. After the page buffer has been loaded with the required number of bytes, the page can be written to the array pointed by ADDR by setting CTRLA.CMD to 'Write Page' and setting the key value to CMDEX. The LOAD bit in the STATUS register indicates whether the page buffer has been loaded or not. If the NVMCTRL is busy processing a write command (STATUS.READY=0), then the AHB bus is stalled upon AHB write until the ongoing command completes. The NVM Controller requires that an erase must be done before programming. Rows can be individually erased by the Erase Row command to erase a row. Automatic page writes are enabled by writing the manual write bit to zero (CTRLC.MANW=0). This will trigger a write operation to the page addressed by ADDR when the last location of the page is written. Because the address is automatically stored in ADDR during the APB bus write operation, the last given address will be present in the ADDR register. There is no need to load the ADDR register manually, unless a different page in memory is to be written. The page buffer is automatically cleared upon a 'Write Page' command completion. 30.6.4.3.1 Procedure for Manual Page Writes (CTRLC.MANW=1) The row to be written to must be erased before the write command is given. • • • Write to the page buffer by addressing the NVM main address space directly Write the page buffer to memory: CTRL.CMD='Write Page' and CMDEX The READY bit in the INTFLAG register will be low while programming is in progress, and access through the AHB will be stalled 30.6.4.3.2 Procedure for Automatic Page Writes (CTRLC.MANW=0) The row to be written to must be erased before the last write to the page buffer is performed. Note that partially written pages must be written with a manual write. • • Write to the page buffer by addressing the NVM main address space directly. When the last location in the page buffer is written, the page is automatically written to NVM main address space. INTFLAG.READY will be zero while programming is in progress and access through the AHB will be stalled. 30.6.4.4 Page Buffer Clear The page buffer is automatically set to all '1' after a page write is performed. If a partial page has been written and it is desired to clear the contents of the page buffer, the Page Buffer Clear command can be used. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 510 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller The status of the Page Buffer is reflected by the STATUS.LOAD bitfield, when the PBC command is issued successfuly, STATUS.LOAD reads 0. 30.6.4.5 Erase Row Before a page can be written, the row containing that page must be erased. The Erase Row command can be used to erase the desired row in the NVM (same command for FLASH, Data FLASH and NVM Rows). Erasing the row sets all bits to '1'. If the row resides in a region that is locked, the erase will not be performed and the Lock Error bit in the INTFLAG register (INTFLAG.LOCKE) will be set. 30.6.4.5.1 Procedure for Erase Row • Write the address of the row to erase to ADDR. Any address within the row can be used. • Issue an Erase Row command. Note:  The NVM Address bit field in the Address register (ADDR.ADDR) uses 16-bit addressing. 30.6.4.6 Set and Clear Power Reduction Mode The NVM Controller and block can be taken in and out of power reduction mode through the Set and Clear Power Reduction Mode commands. When the NVM Controller and block are in power reduction mode, the Power Reduction Mode bit in the Status register (STATUS.PRM) is set. 30.6.5 NVM Rows Operations Reading from or writing/erasing to the NVM rows is performed in the same manner as Flash memory, the only difference being the addressed space. 30.6.6 Event Automatic Write The Event Automatic Write feature is enabled by setting EVCTRL.AUTOWEI=1. When enabled, an event input from EVSYS will trigger a page programming command. The polarity of the input event can be inverted by setting EVCTRL.AUTOWINV. The page written is addressed by the address register (ADDR) and can reside in program or data memory. To use this feature, the row must be previously erased and the page buffer must contain the desired data to be written. As the Page Buffer is lost when the NVM enters low power mode (refer to 30.5.1 Power Management ) cannot be used if the device enters STANDBY mode or if the NVM uses power reduction modes. The cache coherency is not ensured after an Event Automatic Write in a FLASH page. The FLASH region is cacheable, it is the user responsability to clear the cache after such an action. Note that the Data FLASH is not subject to cache coherency issues since it is not cacheble. 30.6.7 Tamper Erase Tamper Erase ensures rapid overwrite on tamper of a Data FLASH row selected by SECCTRL.TEROW. When a RTC tamper event occur while tamper erase is enabled (SECCTRL.TAMPEEN=1): • the Tamper Erase row in data space addressed by SECCTRL.TEROW is written to zero. This is performed using a special overwrite mechanism in the NVM block that overwrites the complete row with zero. The RTC must be configured to generate the tamper erase event. Note:  Data Flash endurance is affected by the tamper erase feature. Refer to the "NVM Reliability Characteristics" from Electrical Characteristics chapter. 30.6.8 Silent Access When enabled (SECCTRL.SILACC = 1), the silent access feature allows to store data and their 1's complement in one Data Flash row (selected by SECCTRL.TEROW), thus reducing the overall data reading noise, as always the same number of '0' and '1' will be read for each read access. When Silent Access is enabled, the logical size of the TEROW Flash row is divided by two to store each byte of Data and its 1’s complement (CompData) in the whole physical TEROW size. The data stored in the selected TEROW must be accessed using the logical mapping shown in the TEROW logical mapping table. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 511 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Table 30-1. TEROW logical mapping (SECCTRL.SILACC=1) Byte 63 Byte 62 Byte 61 … Byte 3 Byte 2 Byte 1 Byte 0 Page Data Data Data Data Data Data Data Data 0 Data Data Data Data Data Data Data Data 1 Reserved Reserved Reserved Reserve d Reserved Reserved Reserved Reserve d 2 Reserved Reserved Reserved Reserve d Reserved Reserved Reserved Reserve d 3 Note:  All accesses to the reserved area of the TEROW are discarded and generate a bus error. The physical mapping of the TEROW, when silent access feature is enabled, is represented in the TEROW physical mapping table: Table 30-2. TEROW physical mapping (SECCTRL.SILACC=1) Byte 63 Byte 62 Byte 61 … Byte 3 Byte 2 Byte 1 Byte 0 Page CompData Data CompData Data CompData Data CompData Data 0 CompData Data CompData Data CompData Data CompData Data 1 CompData Data CompData Data CompData Data CompData Data 2 CompData Data CompData Data CompData Data CompData Data 3 The NVMCTRL automatically manages both scrambling and differential data storage if the tamper row resides in the secure Data Flash area and both are enabled (SECCTRL.DSCEN = 1 and SECCTRL.SILACC = 1). 30.6.9 Chip Erase The various chip erase operations are managed by the boot ROM code. For more details, refer to the Boot ROM section. 30.6.10 Cache The NVM Controller cache reduces the device power consumption and improves system performance when wait states are required. Only the Flash area is cached (Data Flash is not). It is a direct-mapped cache that implements 64 lines of 64 bits (that is, 512 Bytes). NVM Controller cache can be enabled by writing a '0' to the Cache Disable bit in the Control B register (CTRLB.CACHEDIS). The cache can be configured to three different modes using the Read Mode bit group in the Control B register (CTRLB.READMODE). The INVALL command can be issued using the Command bits in the Control A register to invalidate all cache lines (CTRLA.CMD=INVALL). Commands affecting NVM content automatically invalidate cache lines. 30.6.11 Debugger Access Level The Debugger Access Level (DSU STATUSB.DAL) defines the access rights of a debugger connected to the device. • • • 0x0 = Access to very limited features (basically only the DSU external address space) 0x1 = Access to all non-secure memory; can debug non-secure CPU code (SAM L11 only) 0x2 = Access to all memory; can debug secure and non-secure CPU code DAL can be set to a lower setting using a SDAL command (CTRLA register). Important:  Issuing a SDAL command to set a higher setting for DAL will set INTFLAG.PROGE. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 512 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Only a Chip Erase can change DAL to a higher setting. 30.6.12 SAM L11 TrustZone Protection Considerations On TrustZone protected devices, the Flash and Data Flash areas are partitioned into secure, non-secure, and nonsecure callable sections to accommodate with TrustZone core capability. Figure 30-4. NVM Memory Organization Non-Secure Data Flash 0x00400000 Secure Data Flash DS Non-Secure Flash (APPLICATION Region) ANSC Non-Secure Callable Flash (APPLICATION Region) Secure Flash (APPLICATION Region) AS Non-Secure Flash (BOOT Region) BNSC Non-Secure Callable Flash (BOOT Region) 0x00000000 Secure Flash (BOOT Region) BOOTPROT BS The various memory regions and attributes are provides in the table below. Table 30-3. Memory Regions and Attributes Memory Region Base Address Size Attribute Secure Flash (BOOT region) 0x00000000 BS*ROWSIZE BNSC*0x20 Secure Non-Secure Callable Flash (BOOT region) BS*ROWSIZE-BNSC*0x20 BNSC*0x20 Secure Non-Secure Flash (BOOT region) BS*ROWSIZE (remaining BOOT region) Non-secure Secure Flash (APPLICATION region) BOOTPROT*ROWSIZE AS*ROWSIZE ANSC*0x20 Secure Non-Secure Callable Flash (APPLICATION region) BOOTPROT*ROWSIZEANSC*0x20 ANSC*0x20 Secure Non-Secure Flash (APPLICATION region) (BOOTPROT +AS)*ROWSIZE (remaining APPLICATION region) Non-secure Secure Data Flash 0x00400000 DS*ROWSIZE Secure © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 513 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller ...........continued Memory Region Base Address Size Attribute Non-Secure Data Flash 0x00400000 + DS*ROWSIZE (remaining Data NVM area) Non-secure Access to various sections is restricted as shown in the following table. All sections can be read and write without restriction when the access is secure. When the access is non-secure the secure sections are not accessible. When defined non-secure callable sections have the same attributes as the secure sections, therefore the NVMCTRL considers them as secure regions. The system may also have a secure callable boot and application regions. These regions have the same attributes as the secure sections, so there is no special treatment needed in NVMCTRL. Any illegal access will result in a bus error. The boot and application non-secure callable regions are shown for reference but have no effect on the NVMCTRL. These regions are included in secure regions therefore the NVMCTRL considers them as secure regions. Table 30-4. Memory Regions AHB Access Limitations Memory Region Secure Access Non-Secure Access Limitations Secure Flash (BOOT region) R+W - - Non-Secure Callable Flash (BOOT region) R+W - - Non-Secure Flash (BOOT region) R+W R+W Secure Flash (APPLICATION region) R+W - Non-Secure Callable Flash (APPLICATION region) R+W - Non-Secure Flash (APPLICATION region) R+W R+W Secure Data Flash R+W - Non-Secure Data Flash R+W R+W NVM Software Calibration Row R+W R NVM User Row (UROW) R+W R NVM Boot Configuration Row(BOCOR) R+W - - NVM Temperature Log Row No read if BCREN is cleared. No write if BCWEN is cleared. The Boot Configuration row (BOCOR) contains information that is read by the boot ROM and written to the IDAU and NVMCTRL registers. The BOCOR is read/writable if SCFGB.BCREN/BCWEN are set, respectively. Important:  SCFGB.BCREN/BCWEN are copied from BOCOR during the Boot ROM execution. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 514 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Table 30-5. Memory Regions Modify operations Limitations (WP, EP commands) Memory Region Secure Access NonSecure Access Limitations Secure Flash (BOOT region) Y N No if SULCK.BS=0 Non-Secure Callable Flash (BOOT region) Y N No if SULCK.BS=0 Non-Secure Flash (BOOT region) Y Y No if NSULCK.BNS=0 Secure Flash (APPLICATION region) Y N No if SULCK.AS=0 Non-Secure Callable Flash (APPLICATION region) Y N No if SULCK.AS=0 Non-Secure Flash (APPLICATION region) Y Y No if NSULCK.ANS=0 Secure Data Flash Y N No if SULCK.DS=0 Non-Secure Data Flash Y Y No if NSULCK.DNS=0 NVM User Row (UROW) Y N No if BOCOR.URWEN=0 NVM Boot Configuration Row (BOCOR) Y N No if BOCOR.BCWEN=0 The NSULCK SULCK bitfields in the user row define the NSULCK and SULCK register default value after a reset. Special care must be taken when sharing the NVMCTRL between the secure and non-secure domains. When the secure code modifies the NVM, it is recommended that it disables all write accesses to the APB non-secure alias and writes to AHB non-secure regions by writing a ‘0’ to NONSEC.WRITE. This avoids any interference with non-secure modify operations. In this case, even a secure application cannot write the page buffer at a non-secure location because the IDAU changes security attributions of Non-Secure transactions to Non-Secure regions to Non-Secure. The NONSEC.WRITE reset value is '1', meaning that it is always possible to program a Non-Secure Flash or Data Flash region after a debugger probe cold-plugging. But if the debugger connects with the hot-plugging procedure then NONSEC.WRITE must be '1' to let the debugger program Non-Secure regions otherwise the transaction will cause a hardfault (seen as a DAP fault at DAP level). For applications that do not require Non-Secure regions programming other than from a secure code, it is recommended to always disable Non-Secure writes by disabling NONSEC.WRITE. When disabled secure code needs to enable it to be able to modify Non-Secure regions following this procedure: 1. Disable the interrupt. 2. Write a ‘1” to NONSEC.WRITE to allow writes to the non-secure region. 3. Write the page buffer. 4. Write a ‘0’ to NONSEC.WRITE. 5. Enable the interrupt. If the NSCHK interrupt is enabled, a NONSEC.WRITE modification will generate an interrupt so that the non-secure world is aware of this change. Depending on NSCHK.WRITE and INTFLAG.NSCHK will rise upon a rising or falling NONSEC.WRITE transition. The interrupt can be configured as secure or non-secure in the NVIC. If secure then a software mechanism can be implemented to call a non-secure NVMCTRL IRQ handler from the secure world. The NVMCTRL monitors the Page Buffer write accesses and accepts only writes to non-secure regions when the transaction is non-secure. Moreover it checks that any write to the page buffer is in the same page as the previous write when the Page Buffer is not empty. When this check fails, an error is returned to the bus master that initiated the transaction. This ensures that it is not possible to mix different page writes into the Page Buffer. Therefore, any Page © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 515 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Buffer write access must at some point be followed by a manual or automatic Write Page (WP) that automatically clears the page buffer or a Clear Page Buffer (PBC) command. For security reasons, the ADDR register is not accessible from the non-secure alias. The only way to change it is to write a data to the Page Buffer. If the intention is to issue a command that doesn't write the NVM (for instance an Erase Row command (ER)) then the PBC command must be issued to avoid locking further write accesses (even secure writes). The status of the Page Buffer is reflected by the STATUS.LOAD bitfield. 30.6.12.1 Page Buffer Clear When Page Buffer Clear command is issued from the non-secure APB alias, ADDR must point on a non-secure region otherwise the command is silently discarded. For security reasons, the ADDR register is not accessible from the non-secure alias. The only way to change it is to write a data to the Page Buffer. If the intention is to issue a command that doesn't write the NVM (for instance an Erase Row command (ER)) then the PBC command must be issued to avoid locking further write accesses (even secure writes). ADDR must point to a non-secure NVM region when PBC is issued from the non-secure alias. 30.6.12.2 Page Write The NVMCTRL monitors the Page Buffer write accesses and accepts only writes to non-secure regions when the transaction is non-secure. Moreover it checks that any write to the page buffer is in the same page as the previous write when the Page Buffer is not empty. When this check fails, an error is returned to the bus master that initiated the transaction. This ensures that it is not possible to mix different page writes into the Page Buffer. Therefore, any Page Buffer write access must at some point be followed by a manual or automatic Write Page (WP) that automatically clears the page buffer or a Clear Page Buffer (PBC) command. For security reasons, the ADDR register is not accessible from the non-secure alias. The only way to change it is to write a data to the Page Buffer. If the intention is to issue a command that doesn't write the NVM (for instance an Erase Row command (ER)) then the PBC command must be issued to avoid locking further write accesses (even secure writes). The status of the Page Buffer is reflected by the STATUS.LOAD bitfield. 30.6.12.3 Erase Row ADDR must point to a non-secure region when an ER command is issued from the non-secure APB alias. 30.6.12.4 Lock Regions The NVMCTRL has the ability to lock regions with respect to the IDAU memory mapping: • • • • • • FLASH Boot Secure and Non-Secure Callable regions FLASH Boot Non-Secure region FLASH Application secure region FLASH Application non-Secure and Non-Secure Callable regions Data FLASH Secure region Data FLASH Non-Secure region When a region is locked, all modify commands (i.e. write or erase) directed to this region are discarded. A LOCKE error is reported in the INTFLAG register and can generate an interrupt. To lock or unlock a region, write a one to the corresponding bitfield in SULCK and NSULCK registers Writes to these registers are silently discarded if the key is not correct. Writing these registers with the correct key will temporarily lock or unlock the corresponding regions. The new lock setting will stay in effect until the next reset, or until the setting is changed again while writing SULCK and NSULCK. Note:  Writes to these registers are silently discarded if the key is not correct. The current status of the lock can be determined by reading the SULCK and NSULCK registers. To change the default lock/unlock setting for a region, the NVM User Row (UROW) must be written using the Write Page command. Writing to the NVM User Row (UROW) will take effect after the next Reset. Therefore, a boot of the device is needed for changes in the lock/unlock setting to take effect. Refer to the Physical Memory Map for NVM User Row (UROW) space address mapping. SULCK is a Write-Secure register: • This register can only be written by secure masters from the secure alias • This register is always readable by secure or non-secure masters from their respective alias NSULCK is a Write-Mix-Secure register: © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 516 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller • • • This register can always be written by a secure master from the secure alias Or, by a non-secure master from the non-secure alias only if NONSEC.WRITE is set This register is always readable by secure or non-secure masters in their respective alias 30.6.12.5 Cache When a line is cached, the type of transaction is stored in the cache. If the line has been updated upon a secure transaction, only secure transaction can hit, otherwise there is a cache miss and the transaction propagates to the NVMCTRL which enforces the security. If the line has been updated upon a non-secure transaction, it can be hit by both the secure or non-secure transactions. In case of a non-secure transaction cache miss, a line is replaced even if it contained a secure data. 30.6.12.6 Data Flash Scrambling When Data Flash scrambling is enabled (DSCC.DSCEN), address and data in the secure portion of the Data Flash are scrambled when written, and de-scrambled when read. Scrambling and differential operation can be performed on the same data if the tamper row resides in the secure Data Flash area and both are enabled. In this case, the process is serial starting with scrambling, followed by Silent Access on writes and the reverse on reads. 30.6.12.7 Tamper Erase The scrambling key stored in DSCC is written to zero when a RTC tamper event occurs in addition to the erase of the row. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 517 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.7 Register Summary Important:  For SAM L11, the NVMCTRL register map is automatically duplicated in a Secure and Non-Secure alias: • The Non-Secure alias is at the peripheral base address • The Secure alias is located at the peripheral base address + 0x1000 Refer to Mix-Secure Peripherals for more information on register access rights Offset Name Bit Pos. 0x00 CTRLA 7:0 15:8 0x02 ... 0x03 Reserved 0x04 CTRLB 0x08 0x09 0x0A 0x0B 0x0C 0x0D ... 0x0F 0x10 0x11 ... 0x13 0x14 0x15 ... 0x17 CTRLC Reserved EVCTRL Reserved INTENCLR 0x18 STATUS 0x1A ... 0x1B Reserved 6 5 4 3 2 1 0 CMD[6:0] CMDEX[7:0] 7:0 15:8 23:16 31:24 7:0 RWS[3:0] FWUP CACHEDIS SLEEPPRM[1:0] READMODE[1:0] MANW 7:0 AUTOWINV AUTOWEI 7:0 NSCHK KEYE NVME LOCKE PROGE DONE 7:0 NSCHK KEYE NVME LOCKE PROGE DONE 7:0 NSCHK KEYE NVME LOCKE PROGE DONE READY LOAD PRM DS AS BS DNS ANS BNS Reserved INTENSET Reserved INTFLAG Reserved 0x1C ADDR 0x20 SULCK 0x22 NSULCK 0x24 PARAM 0x28 ... 0x2F 7 7:0 15:8 DALFUSE[1:0] 7:0 15:8 23:16 31:24 7:0 15:8 7:0 15:8 7:0 15:8 23:16 31:24 AOFFSET[7:0] AOFFSET[15:8] ARRAY[1:0] SLKEY[7:0] NSLKEY[7:0] FLASHP[7:0] FLASHP[15:8] DFLASHP[3:0] PSZ[2:0] DFLASHP[11:4] Reserved © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 518 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller ...........continued Offset Name 0x30 DSCC 0x34 0x38 Bit Pos. SECCTRL SCFGB 0x3C SCFGAD 0x40 NONSEC 0x44 30.8 NSCHK 7 6 5 4 3 2 7:0 15:8 DSCKEY[7:0] DSCKEY[15:8] 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 7:0 15:8 23:16 31:24 DSCKEY[23:16] DSCKEY[29:24] DSCEN SILACC DXN 1 0 TAMPEEN TEROW[2:0] KEY[7:0] BCWEN BCREN URWEN WRITE WRITE Register Description Registers can be 8, 16, or 32 bits wide. Atomic 8-, 16-, and 32-bit accesses are supported. In addition, the 8-bit quarters and 16-bit halves of a 32-bit register, and the 8-bit halves of a 16-bit register can be accessed directly. Some registers require synchronization when read and/or written. Synchronization is denoted by the "ReadSynchronized" and/or "Write-Synchronized" property in each individual register description. Some registers are enable-protected, meaning they can only be written when the module is disabled. Enableprotection is denoted by the "Enable-Protected" property in each individual register description. Note:  A register with property "Enable-Protected" may contain bits that are not enable-protected. On SAM L11 devices, the Mix-Secure peripheral has different types of registers (Non-Secure, Secure, Write-Secure, Mix-Secure, and Write-Mix-Secure) with different access permissions for each bitfield. Refer to Mix-Secure Peripherals for more details. In the following register descriptions, the access permissions are specified as shown in the following figure. Bit 7 6 5 4 3 2 1 0 R/-/RW R/-/RW R/-/RW R/-/RW CMD[7:0] Access R/-/RW R/-/RW R/-/RW R/-/RW TrustZone Non-Protected Devices Access TrustZone Protected Devices Non-Secure Access TrustZone Protected Devices Secure Access © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 519 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.1 Control A Name:  Offset:  Reset:  Property:  CTRLA 0x00 0x0000 PAC Write-Protection, Write-Mix-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in the NONSEC register. Bit Access Reset 15 14 13 W/W*/W 0 W/W*/W 0 W/W*/W 0 7 6 5 4 W/W/W 0 W/W/W 0 W/W/W 0 Bit Access Reset 12 11 CMDEX[7:0] W/W*/W W/W*/W 0 0 3 CMD[6:0] W/W/W 0 10 9 8 W/W*/W 0 W/W*/W 0 W/W*/W 0 2 1 0 W/W/W 0 W/W/W 0 W/W/W 0 Bits 15:8 – CMDEX[7:0] Command Execution When this bit group is written to the key value 0xA5, the command written to CMD will be executed. If a value different from the key value is tried, the write will not be performed and the key error interrupt (INTFLAG.KEYE) will be set. PROGE is set if a previously written command is not completed yet or in case of bad conditions. The key value must be written at the same time as CMD. If a command is issued through the APB bus on the same cycle as an AHB bus access, the AHB bus access will be given priority. The command will then be executed when the NVM block and the AHB bus are idle. STATUS.READY must be '1' when the command has issued. Note:  The NVM Address bit field in the Address register (ADDR.ADDR) is driving the hardware (8-bit) address to the NVM when a command is executed using CMDEX. Bits 6:0 – CMD[6:0] Command These bits define the command to be executed when the CMDEX key is written. Important:  For SAM L11, only ER, WP, PBC, SDAL0 commands are available from the non-secure alias. Non-secure ER, WP, PBC are processed only if ADDR points to a non secure address, otherwise a PROGE error is issued. CMD[6:0] Group Configuration Description 0x00-0x01 0x02 ER 0x03 0x04 WP 0x05-0x41 0x42 0x43 0x44 0x45 0x46 SPRM CPRM PBC INVALL © 2020 Microchip Technology Inc. Reserved Erase Row - Erases the row addressed by the ADDR register in the Flash, Data Flash or NVM Rows. Reserved Write Page - Writes the contents of the page buffer to the page addressed by the ADDR register. Reserved Sets the Power Reduction Mode. Clears the Power Reduction Mode. Page Buffer Clear - Clears the page buffer. Reserved Invalidates all cache lines. Datasheet DS60001513F-page 520 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller ...........continued CMD[6:0] Group Configuration Description 0x47-0x4A 0x4B 0x4C (SAM L10 ) 0x4C (SAM L11 ) 0x4D-0x7F SDAL0 Reserved SDAL1 - © 2020 Microchip Technology Inc. Reserved Set DAL=0 Reserved Set DAL=1 Reserved Datasheet DS60001513F-page 521 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.2 Control B Name:  Offset:  Reset:  Property:  Bit CTRLB 0x04 0x00000000 PAC Write-Protection, Write-Secure 31 30 29 28 27 26 25 24 23 22 21 20 19 18 CACHEDIS RW/R/RW 0 17 16 READMODE[1:0] RW/R/RW RW/R/RW 0 0 15 14 13 12 11 FWUP RW/R/RW 0 10 9 8 SLEEPPRM[1:0] RW/R/RW RW/R/RW 0 0 7 6 5 4 3 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset RW/R/RW 0 2 RWS[3:0] RW/R/RW RW/R/RW 0 0 1 0 RW/R/RW 0 Bit 18 – CACHEDIS Cache Disable This bit is used to disable the cache. Value Description 0 The cache is enabled 1 The cache is disabled Bits 17:16 – READMODE[1:0] NVMCTRL Read Mode Value Name Description 0x0 NO_MISS_PENALTY The NVM Controller (cache system) does not insert wait states on a cache miss. Gives the best system performance. 0x1 LOW_POWER Reduces power consumption of the cache system, but inserts a wait state each time there is a cache miss. This mode may not be relevant if CPU performance is required, as the application will be stalled and may lead to increased run time. 0x2 DETERMINISTIC The cache system ensures that a cache hit or miss takes the same amount of time, determined by the number of programmed Flash wait states. This mode can be used for real-time applications that require deterministic execution timings. 0x3 Reserved Bit 11 – FWUP Cache Disable This bit is used to disable the cache. Value Description 0 Fast wake-up is turned off 1 Fast wake-up is turned on Bits 9:8 – SLEEPPRM[1:0] Power Reduction Mode during Sleep Indicates the Power Reduction Mode during sleep. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 522 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Value 0x0 Name WAKEUPACCESS 0x1 WAKEUPINSTANT 0x2 0x3 Reserved DISABLED Description NVM block enters low-power mode when entering sleep. NVM block exits low-power mode upon first access. NVM block enters low-power mode when entering sleep. NVM block exits low-power mode when exiting sleep. Auto power reduction disabled. Bits 4:1 – RWS[3:0] NVM Read Wait States These bits control the number of wait states for a read operation. '0' indicates zero wait states, '1' indicates one wait state, etc., up to 15 wait states. This register is initialized to 0 wait states. Software can change this value based on the NVM access time and system frequency. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 523 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.3 Control C Name:  Offset:  Reset:  Property:  CTRLC 0x08 0x01 PAC Write-Protection, Write-Mix-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in the NONSEC register. Bit 7 6 5 4 3 Access Reset 2 1 0 MANW RW/RW*/RW 1 Bit 0 – MANW Manual Write Value Description 0 Writing to the last word in the page buffer will initiate a write operation to the page addressed by the last write operation. This includes writes to FLASH, Data FLASH and NVM rows. 1 Write commands must be issued through the CTRLA.CMD register. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 524 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.4 Event Control Name:  Offset:  Reset:  Property:  Bit 7 EVCTRL 0x0A 0x00 PAC Write-Protection, Secure 6 5 4 3 Access Reset 2 1 AUTOWINV RW/-/RW 0 0 AUTOWEI RW/-/RW 0 Bit 1 – AUTOWINV Event Action Value Description 0 Input event polarity is not inverted. 1 Input event polarity is inverted. Bit 0 – AUTOWEI Event Action Value Description 0 Input event has no effect. 1 Input event triggers an Automatic Page Write © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 525 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.5 Interrupt Enable Clear Name:  Offset:  Reset:  Property:  INTENCLR 0x0C 0x00 PAC Write-Protection, Write-Mix-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in the NONSEC register. This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set register (INTENSET). Bit Access Reset 7 6 5 4 3 2 1 0 NSCHK KEYE NVME LOCKE PROGE DONE RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW 0 0 0 0 0 0 Bit 5 – NSCHK Non-secure Check Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the NSCHK interrupt enable. This bit will read as the current value of the NSCHK interrupt enable. Bit 4 – KEYE Key Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the KEYE interrupt enable. This bit will read as the current value of the KEYE interrupt enable. Bit 3 – NVME NVM internal Error Interrupt Clear Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the NVME interrupt enable. This bit will read as the current value of the NVME interrupt enable. Bit 2 – LOCKE Lock Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the LOCKE interrupt enable. This bit will read as the current value of the LOCKE interrupt enable. Bit 1 – PROGE Programming Error Interrupt Clear Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the PROGE interrupt enable. This bit will read as the current value of the PROGE interrupt enable. Bit 0 – DONE NVM Done Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the DONE interrupt enable. This bit will read as the current value of the DONE interrupt enable. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 526 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.6 Interrupt Enable Set Name:  Offset:  Reset:  Property:  INTENSET 0x10 0x00 PAC Write-Protection, Write-Mix-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in the NONSEC register. This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear register (INTENCLR). Bit Access Reset 7 6 5 4 3 2 1 0 NSCHK KEYE NVME LOCKE PROGE DONE RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW 0 0 0 0 0 0 Bit 5 – NSCHK Non-secure Check Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the NSCHK interrupt enable. This bit will read as the current value of the NSCHK interrupt enable. Bit 4 – KEYE Key Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the KEYE interrupt enable. This bit will read as the current value of the KEYE interrupt enable. Bit 3 – NVME NVM internal Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the NVME interrupt enable. This bit will read as the current value of the NVME interrupt enable. Bit 2 – LOCKE Lock Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the LOCKE interrupt enable. This bit will read as the current value of the LOCKE interrupt enable. Bit 1 – PROGE Programming Error Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the PROGE interrupt enable. This bit will read as the current value of the PROGE interrupt enable. Bit 0 – DONE NVM Done Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit sets the DONE interrupt enable. This bit will read as the current value of the DONE interrupt enable. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 527 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.7 Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  INTFLAG 0x14 0x00 Write-Mix-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in the NONSEC register. Bit Access Reset 7 6 5 4 3 2 1 0 NSCHK KEYE NVME LOCKE PROGE DONE RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW RW/RW*/RW 0 0 0 0 0 0 Bit 5 – NSCHK Non-Secure Check This flag is set when the NONSEC register is changed and the new value differs from the NSCHK value. This bit can be cleared by writing a '1' to its bit location. Value Description 0 The NONSEC configuration has not changed since last clear. 1 At least one change has been made to the NONSEC configuration since the last clear. Bit 4 – KEYE Key Error This flag is set when a key write-protected register has been accessed in write with a bad key. A one indicates that at least one write access has been discarded. This bit can be cleared by writing a '1' to its bit location. Value Description 0 No key error occured since the last clear. 1 At least one key error occured since the last clear. Bit 3 – NVME NVM internal Error This flag is set on the occurrence of a NVM internal error. This bit can be cleared by writing a '1' to its bit location. Value Description 0 No NVM internal error has happened since this bit was last cleared. 1 At least one NVM internal error has happened since this bit was last cleared. Bit 2 – LOCKE Lock Error This flag is set on the occurrence of a LOCKE error. This bit can be cleared by writing a '1' to its bit location. Value Description 0 No programming of any locked lock region has happened since this bit was last cleared. 1 Programming of at least one locked lock region has happened since this bit was last cleared. Bit 1 – PROGE Programming Error This flag is set on the occurrence of a PROGE error. This bit can be cleared by writing a '1' to its bit location. Value Description 0 No invalid commands or bad keywords were written in the NVM Command register since this bit was last cleared. 1 An invalid command and/or a bad keyword was/were written in the NVM Command register since this bit was last cleared. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 528 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller Bit 0 – DONE NVM Command Done This bit can be cleared by writing a one to its bit location Value Description 0 The NVM controller has not completed any commands since the last clear. 1 At least one command has completed since the last clear. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 529 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.8 Status Name:  Offset:  Reset:  Property:  STATUS 0x18 0x00xx (x determined from latest Set DAL or Chip Erase command) Write-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in NONSEC register. Bit 15 14 13 7 6 5 12 11 10 9 8 2 READY R/R/R 0 1 LOAD R/R/R 0 0 PRM R/R/R 0 Access Reset Bit Access Reset 4 3 DALFUSE[1:0] R/R/R R/R/R x x Bits 4:3 – DALFUSE[1:0] DAL Fuse Value This field is the current debugger access level fuse value. Value Description 0 DAL = 0 : Access to very limited features. 1 DAL = 1 (SAM L11 only): Access to all non-secure memory. Can debug non-secure CPU code. 2 DAL = 2 : Access to all memory. Can debug Secure and non-secure CPU code. 3 Reserved Bit 2 – READY NVM Ready Value Description 0 The NVM controller is busy programming or erasing. 1 The NVM controller is ready to accept a new command. Bit 1 – LOAD NVM Page Buffer Active Loading This bit indicates that the NVM page buffer has been loaded with one or more words. Immediately after an NVM load has been performed, this flag is set. It remains set until a page write or a page buffer clear (PBC) command is given. Bit 0 – PRM Power Reduction Mode This bit indicates the current NVM power reduction state. The NVM block can be set in power reduction mode in two ways: through the command interface or automatically when entering sleep with SLEEPPRM set accordingly. PRM can be cleared in three ways: through AHB access to the NVM block, through the command interface (SPRM and CPRM) or when exiting sleep with SLEEPPRM set accordingly. Value Description 0 NVM is not in power reduction mode. 1 NVM is in power reduction mode. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 530 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.9 Address Name:  Offset:  Reset:  Property:  ADDR 0x1C 0x00000000 PAC Write-Protection, Secure ADDR drives the hardware address to the NVM when a command is executed using CMDEX. This is a Byte aligned address. This register is automatically updated upon AHB writes to the page buffer. Bit 31 30 29 28 27 26 25 24 21 20 19 18 17 16 10 9 8 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 2 1 0 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 23 22 ARRAY[1:0] RW/-/RW RW/-/RW 0 0 15 14 13 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 7 6 5 RW/-/RW 0 RW/-/RW 0 RW/-/RW 0 12 11 AOFFSET[15:8] RW/-/RW RW/-/RW 0 0 4 3 AOFFSET[7:0] RW/-/RW RW/-/RW 0 0 Bits 23:22 – ARRAY[1:0] Array Select Value Description 00 Flash 01 Data Flash 10 NVM Rows Bits 15:0 – AOFFSET[15:0] Array Offset Address offset © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 531 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.10 Secure Region Unlock Bits Name:  Offset:  Reset:  Property:  SULCK 0x20 x initially determined from NVM User Row after reset PAC Write-Protection, Write-Secure Important:  This register is only available for SAM L11 and has no effect for SAM L10. Bit Access Reset Bit 15 14 13 W/-/W 0 W/-/W 0 W/-/W 0 7 6 5 12 11 SLKEY[7:0] W/-/W W/-/W 0 0 4 Access Reset 3 10 9 8 W/-/W 0 W/-/W 0 W/-/W 0 2 DS RW/R/RW x 1 AS RW/R/RW x 0 BS RW/R/RW x Bits 15:8 – SLKEY[7:0] Secure Unlock Key When this bit group is written to the key value 0xA5, the write will be performed. If a value different from the key value is tried, the write will be discarded and INTFLAG.KEYE set. Bit 2 – DS Data Flash Secure Unlock Bit Default state after erase will be unlocked (0x1). Value Description 0 The DS region is locked. 1 The DS region is not locked. Bit 1 – AS APPLICATION Secure Unlock Bit Default state after erase will be unlocked (0x1). Value Description 0 The Secure Flash (AS region) is locked. 1 The Secure Flash (AS region) is not locked. Bit 0 – BS BOOT Secure Unlock Bit Default state after erase will be unlocked (0x1). Value Description 0 The Secure Flash (BS region) is locked. 1 The Secure Flash (BS region) is not locked. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 532 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.11 Non-Secure Region Unlock Bits Name:  Offset:  Reset:  Property:  NSULCK 0x22 x initially determined from NVM User Row after reset PAC Write-Protection, Write-Mix-Secure Important:  For SAM L11 Non-Secure accesses, write accesses (W*) are allowed only if Non-Secure Write is set in the NONSEC register. Bit Access Reset 15 14 13 W/W*/W 0 W/W*/W 0 W/W*/W 0 7 6 5 Bit 12 11 NSLKEY[7:0] W/W*/W W/W*/W 0 0 4 3 Access Reset 10 9 8 W/W*/W 0 W/W*/W 0 W/W*/W 0 2 1 0 DNS ANS BNS RW/RW*/RW RW/RW*/RW RW/RW*/RW x x x Bits 15:8 – NSLKEY[7:0] Non-Secure Unlock Key When this bit group is written to the key value 0xA5, the write will be performed. If a value different from the key value is tried, the write will be discarded and INTFLAG.KEYE set. Bit 2 – DNS Data Flash Non-Secure Unlock Bit Note:  For SAM L10 devices, the Non-Secure Data Flash region corresponds to the entire Data Flash region. Value 0 1 Description The Non-Secure Data Flash region is locked. The Non-Secure Data Flash region is not locked. Bit 1 – ANS APPLICATION Non-Secure Unlock Bit Note:  For SAM L10 devices, the Non-Secure Flash (APPLICATION region) corresponds to the entire Flash (APPLICATION region). Value 0 1 Description The Non-Secure Flash (APPLICATION region) is locked. The Non-Secure Flash (APPLICATION region) is not locked. Bit 0 – BNS BOOT Non-Secure Unlock Bit Note:  For SAM L10 devices, the Non-Secure Flash (BOOT region) corresponds to the entire Flash (BOOT region). Value 0 1 Description The Non-Secure Flash (BOOT region) is locked. The Non-Secure Flash (BOOT region) is not locked. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 533 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.12 NVM Parameter Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset Bit Access Reset Bit Access Reset PARAM 0x24 x determined from (Data) Flash Memory Parameters tables Write-Secure 31 30 29 R/R/R 0 R/R/R 0 R/R/R 0 23 R/R/R 0 22 21 DFLASHP[3:0] R/R/R R/R/R 0 0 15 14 13 R/R/R x R/R/R x R/R/R x 7 6 5 R/R/R x R/R/R x R/R/R x 28 27 DFLASHP[11:4] R/R/R R/R/R 0 0 20 19 R/R/R 0 12 11 FLASHP[15:8] R/R/R R/R/R x x 4 3 FLASHP[7:0] R/R/R R/R/R x x 26 25 24 R/R/R 0 R/R/R 0 R/R/R 0 18 16 R/R/R x 17 PSZ[2:0] R/R/R x R/R/R x 10 9 8 R/R/R x R/R/R x R/R/R x 2 1 0 R/R/R x R/R/R x R/R/R x Bits 31:20 – DFLASHP[11:0] Data FLASH area Pages Indicates the number of pages in the Data FLASH array. Bits 18:16 – PSZ[2:0] Page Size Indicates the page size. Not all devices of the device families will provide all the page sizes indicated in the table. Value Name Description 0x0 8 8 bytes 0x1 16 16 bytes 0x2 32 32 bytes 0x3 64 64 bytes 0x4 128 128 bytes 0x5 256 256 bytes 0x6 512 512 bytes 0x7 1024 1024 bytes Bits 15:0 – FLASHP[15:0] FLASH Pages Indicates the number of pages in the FLASH array. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 534 SAM L10/L11 Family NVMCTRL – Nonvolatile Memory Controller 30.8.13 Data Scramble Control Name:  Offset:  Reset:  Property:  DSCC 0x30 0x00000000 PAC Write-Protection, Secure, Enable-Protected Important:  This register is only available for SAM L11 and has no effect for SAM L10. Bit 31 30 Access Reset Bit Access Reset Bit Access Reset Bit Access Reset 29 28 W/-/W 0 W/-/W 0 23 22 21 W/-/W 0 W/-/W 0 W/-/W 0 15 14 13 W/-/W 0 W/-/W 0 W/-/W 0 7 6 5 W/-/W 0 W/-/W 0 W/-/W 0 27 26 DSCKEY[29:24] W/-/W W/-/W 0 0 20 19 DSCKEY[23:16] W/-/W W/-/W 0 0 12 11 DSCKEY[15:8] W/-/W W/-/W 0 0 4 3 DSCKEY[7:0] W/-/W W/-/W 0 0 25 24 W/-/W 0 W/-/W 0 18 17 16 W/-/W 0 W/-/W 0 W/-/W 0 10 9 8 W/-/W 0 W/-/W 0 W/-/W 0 2 1 0 W/-/W 0 W/-/W 0 W/-/W 0 Bits 29:0 – DSCKEY[29:0] Data Scramble Key This key value is used for data scrambling of the Secure Data Flash. After reset the key is 0. When written, the new value in the register is an XOR of the value written and the previous value of DSCC.DSCKEY. This register is write only and will always read back as zero. This register is Enable-Protected with SECCTRL.DSCEN meaning that it can't be modified when DSCEN=1 otherwise a PAC error is generated. Updated DSCC.DSCKEY contents 2.0V) 0x3 VREFA External reference 0x4 VREFB External reference 0x5 INTVCC2 VDDANA 0x6 Reserved 0xF © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 877 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.4 Event Control Name:  Offset:  Reset:  Property:  Bit Access Reset 7 EVCTRL 0x03 0x00 PAC Write-Protection, Enable-Protected 6 5 4 WINMONEO RESRDYEO R/W R/W 0 0 3 STARTINV R/W 0 2 FLUSHINV R/W 0 1 STARTEI R/W 0 0 FLUSHEI R/W 0 Bit 5 – WINMONEO Window Monitor Event Out This bit indicates whether the Window Monitor event output is enabled or not and an output event will be generated when the window monitor detects something. Value Description 0 Window Monitor event output is disabled and an event will not be generated. 1 Window Monitor event output is enabled and an event will be generated. Bit 4 – RESRDYEO Result Ready Event Out This bit indicates whether the Result Ready event output is enabled or not and an output event will be generated when the conversion result is available. Value Description 0 Result Ready event output is disabled and an event will not be generated. 1 Result Ready event output is enabled and an event will be generated. Bit 3 – STARTINV Start Conversion Event Invert Enable Value Description 0 Start event input source is not inverted. 1 Start event input source is inverted. Bit 2 – FLUSHINV Flush Event Invert Enable Value Description 0 Flush event input source is not inverted. 1 Flush event input source is inverted. Bit 1 – STARTEI Start Conversion Event Input Enable Value Description 0 A new conversion will not be triggered on any incoming event. 1 A new conversion will be triggered on any incoming event. Bit 0 – FLUSHEI Flush Event Input Enable Value Description 0 A flush and new conversion will not be triggered on any incoming event. 1 A flush and new conversion will be triggered on any incoming event. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 878 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.5 Interrupt Enable Clear Name:  Offset:  Reset:  Property:  INTENCLR 0x04 0x00 PAC Write-Protection This register allows the user to disable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Set (INTENSET) register. Bit 7 6 5 4 3 Access Reset 2 WINMON R/W 0 1 OVERRUN R/W 0 0 RESRDY R/W 0 Bit 2 – WINMON Window Monitor Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Window Monitor Interrupt Enable bit, which disables the corresponding interrupt request. Value Description 0 The window monitor interrupt is disabled. 1 The window monitor interrupt is enabled, and an interrupt request will be generated when the Window Monitor interrupt flag is set. Bit 1 – OVERRUN Overrun Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Overrun Interrupt Enable bit, which disables the corresponding interrupt request. Value Description 0 The Overrun interrupt is disabled. 1 The Overrun interrupt is enabled, and an interrupt request will be generated when the Overrun interrupt flag is set. Bit 0 – RESRDY Result Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will clear the Result Ready Interrupt Enable bit, which disables the corresponding interrupt request. Value Description 0 The Result Ready interrupt is disabled. 1 The Result Ready interrupt is enabled, and an interrupt request will be generated when the Result Ready interrupt flag is set. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 879 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.6 Interrupt Enable Set Name:  Offset:  Reset:  Property:  INTENSET 0x05 0x00 PAC Write-Protection This register allows the user to enable an interrupt without doing a read-modify-write operation. Changes in this register will also be reflected in the Interrupt Enable Clear (INTENCLR) register. Bit 7 6 5 4 3 Access Reset 2 WINMON R/W 0 1 OVERRUN R/W 0 0 RESRDY R/W 0 Bit 2 – WINMON Window Monitor Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Window Monitor Interrupt bit, which enables the Window Monitor interrupt. Value Description 0 The Window Monitor interrupt is disabled. 1 The Window Monitor interrupt is enabled. Bit 1 – OVERRUN Overrun Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Overrun Interrupt bit, which enables the Overrun interrupt. Value Description 0 The Overrun interrupt is disabled. 1 The Overrun interrupt is enabled. Bit 0 – RESRDY Result Ready Interrupt Enable Writing a '0' to this bit has no effect. Writing a '1' to this bit will set the Result Ready Interrupt bit, which enables the Result Ready interrupt. Value Description 0 The Result Ready interrupt is disabled. 1 The Result Ready interrupt is enabled. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 880 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.7 Interrupt Flag Status and Clear Name:  Offset:  Reset:  Property:  Bit 7 INTFLAG 0x06 0x00 – 6 5 4 3 Access Reset 2 WINMON R/W 0 1 OVERRUN R/W 0 0 RESRDY R/W 0 Bit 2 – WINMON Window Monitor This flag is cleared by writing a '1' to the flag or by reading the RESULT register. This flag is set on the next GCLK_ADC cycle after a match with the window monitor condition, and an interrupt request will be generated if INTENCLR/SET.WINMON is '1'. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Window Monitor interrupt flag. Bit 1 – OVERRUN Overrun This flag is cleared by writing a '1' to the flag. This flag is set if RESULT is written before the previous value has been read by CPU, and an interrupt request will be generated if INTENCLR/SET.OVERRUN=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Overrun interrupt flag. Bit 0 – RESRDY Result Ready This flag is cleared by writing a '1' to the flag or by reading the RESULT register. This flag is set when the conversion result is available, and an interrupt will be generated if INTENCLR/ SET.RESRDY=1. Writing a '0' to this bit has no effect. Writing a '1' to this bit clears the Result Ready interrupt flag. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 881 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.8 Sequence Status Name:  Offset:  Reset:  Property:  Bit Access Reset 7 SEQBUSY R 0 SEQSTATUS 0x07 0x00 - 6 5 4 3 R 0 R 0 2 SEQSTATE[4:0] R 0 1 0 R 0 R 0 Bit 7 – SEQBUSY Sequence busy This bit is set when the sequence start. This bit is clear when the last conversion in a sequence is done. Bits 4:0 – SEQSTATE[4:0] Sequence State These bit fields are the pointer of sequence. This value identifies the last conversion done in the sequence. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 882 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.9 Input Control Name:  Offset:  Reset:  Property:  Bit 15 INPUTCTRL 0x08 0x0000 PAC Write-Protection, Write-Synchronized 14 13 Access Reset Bit 7 6 Access Reset 5 12 11 R/W 0 R/W 0 4 3 R/W 0 R/W 0 10 MUXNEG[4:0] R/W 0 2 MUXPOS[4:0] R/W 0 9 8 R/W 0 R/W 0 1 0 R/W 0 R/W 0 Bits 12:8 – MUXNEG[4:0] Negative MUX Input Selection These bits define the MUX selection for the negative ADC input. Value Name Description 0x00 AIN0 ADC AIN0 pin 0x01 AIN1 ADC AIN1 pin 0x02 AIN2 ADC AIN2 pin 0x03 AIN3 ADC AIN3 pin 0x04 AIN4 ADC AIN4 pin 0x05 AIN5 ADC AIN5 pin 0x06 AIN6 ADC AIN6 pin 0x07 AIN7 ADC AIN7 pin 0x08 Reserved 0x17 0x18 GND Internal ground 0x19 Reserved 0x1F Bits 4:0 – MUXPOS[4:0] Positive MUX Input Selection These bits define the MUX selection for the positive ADC input. If the internal bandgap voltage or temperature sensor input channel is selected, then the Sampling Time Length bit group in the Sampling Control register must be written with a corresponding value. Value Name Description 0x00 AIN0 ADC AIN0 pin 0x01 AIN1 ADC AIN1 pin 0x02 AIN2 ADC AIN2 pin 0x03 AIN3 ADC AIN3 pin 0x04 AIN4 ADC AIN4 pin 0x05 AIN5 ADC AIN5 pin 0x06 AIN6 ADC AIN6 pin 0x07 AIN7 ADC AIN7 pin 0x08 AIN8 ADC AIN8 pin 0x09 AIN9 ADC AIN9 pin 0x0A Reserved 0x17 0x18 TEMP Temperature Sensor 0x19 BANDGAP INTREF Voltage Reference 0x1A SCALEDVDDCORE 1/4 Scaled VDDCORE Supply 0x1B SCALEDVDDANA 1/4 Scaled VDDANA Supply © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 883 SAM L10/L11 Family ADC – Analog-to-Digital Converter Value 0x1C 0x1D 0x1E 0x1F Name DAC SCALEDVDDIO OPAMP01 OPAMP2 © 2020 Microchip Technology Inc. Description DAC Output 1/4 Scaled VDDIO Supply OPAMP0 or OPAMP1 output OPAMP2 output Datasheet DS60001513F-page 884 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.10 Control C Name:  Offset:  Reset:  Property:  Bit 15 CTRLC 0x0A 0x0000 PAC Write-Protection, Write-Synchronized 14 13 12 11 10 R/W 0 9 WINMODE[2:0] R/W 0 R/W 0 2 FREERUN R/W 0 1 LEFTADJ R/W 0 0 DIFFMODE R/W 0 Access Reset Bit 7 6 Access Reset 5 4 RESSEL[1:0] R/W R/W 0 0 3 CORREN R/W 0 8 Bits 10:8 – WINMODE[2:0] Window Monitor Mode These bits enable and define the window monitor mode. Value Name Description 0x0 DISABLE No window mode (default) 0x1 MODE1 RESULT > WINLT 0x2 MODE2 RESULT < WINUT 0x3 MODE3 WINLT < RESULT < WINUT 0x4 MODE4 WINUT < RESULT < WINLT 0x5 Reserved 0x7 Bits 5:4 – RESSEL[1:0] Conversion Result Resolution These bits define whether the ADC completes the conversion 12-, 10- or 8-bit result resolution. Value Name Description 0x0 12BIT 12-bit result 0x1 16BIT Accumulation or Oversampling and Decimation modes 0x2 10BIT 10-bit result 0x3 8BIT 8-bit result Bit 3 – CORREN Digital Correction Logic Enabled Value Description 0 Disable the digital result correction. 1 Enable the digital result correction. The ADC conversion result in the RESULT register is then corrected for gain and offset based on the values in the GAINCORR and OFFSETCORR registers. Conversion time will be increased by 13 cycles according to the value in the Offset Correction Value bit group in the Offset Correction register. Bit 2 – FREERUN Free Running Mode Value Description 0 The ADC run in single conversion mode. 1 The ADC is in free running mode and a new conversion will be initiated when a previous conversion completes. Bit 1 – LEFTADJ Left-Adjusted Result Value Description 0 The ADC conversion result is right-adjusted in the RESULT register. 1 The ADC conversion result is left-adjusted in the RESULT register. The high byte of the 12-bit result will be present in the upper part of the result register. Writing this bit to zero (default) will right-adjust the value in the RESULT register. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 885 SAM L10/L11 Family ADC – Analog-to-Digital Converter Bit 0 – DIFFMODE Differential Mode Value Description 0 The ADC is running in singled-ended mode. 1 The ADC is running in differential mode. In this mode, the voltage difference between the MUXPOS and MUXNEG inputs will be converted by the ADC. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 886 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.11 Average Control Name:  Offset:  Reset:  Property:  Bit Access Reset 7 AVGCTRL 0x0C 0x00 PAC Write-Protection, Write-Synchronized 6 R/W 0 5 ADJRES[2:0] R/W 0 4 3 R/W 0 R/W 0 2 1 SAMPLENUM[3:0] R/W R/W 0 0 0 R/W 0 Bits 6:4 – ADJRES[2:0] Adjusting Result / Division Coefficient These bits define the division coefficient in 2n steps. Bits 3:0 – SAMPLENUM[3:0] Number of Samples to be Collected These bits define how many samples are added together. The result will be available in the Result register (RESULT). Note: if the result width increases, CTRLC.RESSEL must be changed. Value Description 0x0 1 sample 0x1 2 samples 0x2 4 samples 0x3 8 samples 0x4 16 samples 0x5 32 samples 0x6 64 samples 0x7 128 samples 0x8 256 samples 0x9 512 samples 0xA 1024 samples 0xB Reserved 0xF © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 887 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.12 Sampling Time Control Name:  Offset:  Reset:  Property:  Bit 7 OFFCOMP Access R/W Reset 0 SAMPCTRL 0x0D 0x00 PAC Write-Protection, Write-Synchronized 6 5 4 R/W 0 R/W 0 3 2 SAMPLEN[5:0] R/W R/W 0 0 1 0 R/W 0 R/W 0 Bit 7 – OFFCOMP Comparator Offset Compensation Enable Setting this bit enables the offset compensation for each sampling period to ensure low offset and immunity to temperature or voltage drift. ADC sampling time is fixed to 4 ADC Clock cycles when OFFCOMP = 1. Bits 5:0 – SAMPLEN[5:0] Sampling Time Length These bits control the ADC sampling time in number of CLK_ADC cycles, depending of the prescaler value, thus controlling the ADC input impedance. Sampling time is set according to the equation: Sampling time = SAMPLEN+1 ⋅ CLKADC SAMPLEN is only available when OFFCOMP=0. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 888 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.13 Window Monitor Lower Threshold Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset WINLT 0x0E 0x0000 PAC Write-Protection, Write-Synchronized 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 12 11 WINLT[15:8] R/W R/W 0 0 4 3 WINLT[7:0] R/W R/W 0 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – WINLT[15:0] Window Lower Threshold If the window monitor is enabled, these bits define the lower threshold value. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 889 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.14 Window Monitor Upper Threshold Name:  Offset:  Reset:  Property:  Bit Access Reset Bit Access Reset WINUT 0x10 0x0000 PAV Write-Protection, Write-Synchronized 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 12 11 WINUT[15:8] R/W R/W 0 0 4 3 WINUT[7:0] R/W R/W 0 0 10 9 8 R/W 0 R/W 0 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – WINUT[15:0] Window Upper Threshold If the window monitor is enabled, these bits define the upper threshold value. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 890 SAM L10/L11 Family ADC – Analog-to-Digital Converter 41.8.15 Gain Correction Name:  Offset:  Reset:  Property:  Bit 15 GAINCORR 0x12 0x0000 PAC Write-Protection, Write-Synchronized 14 13 Access Reset Bit Access Reset 12 11 R/W 0 7 6 5 R/W 0 R/W 0 R/W 0 4 3 GAINCORR[7:0] R/W R/W 0 0 10 9 GAINCORR[11:8] R/W R/W 0 0 8 R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 11:0 – GAINCORR[11:0] Gain Correction Value If CTRLC.CORREN=1, these bits define how the ADC conversion result is compensated for gain error before being written to the result register. The gain correction is a fractional value, a 1-bit integer plus an 11-bit fraction, and therefore ½ IOBUS without jumping in an interrupt handler (Cortex M23 register PRIMASK = 1). The wake-up time is measured between the edge of the wake-up input signal and the edge of the GPIO pin. For Off mode, the exit of the mode is done through the reset pin, the time is measured between the falling edge of the RESETN signal (with the minimum reset pulse length), and the set of the I/O which is done by the first executed instructions after Reset. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 980 SAM L10/L11 Family Electrical Characteristics Table 46-10. Wake-Up Timing (1) Sleep Mode Condition Typ Unit Idle PL2 or PL0 1.5 μs Standby PL0 PL2 Voltage scaling at default values: SUPC >VREG.VSVSTEP=0 PDSW domain in retention 5.3 PDSW domain in active 2.6 PDSW domain in retention 76 PDSW domain in active 75 PDSW domain in retention 16 PDSW domain in active 15 SUPC > VREG.VSPER=0 PL2 Voltage scaling at fastest setting: SUPC > VREG.VSVSTEP=15 SUPC > VREG.VSPER=0 OFF L10 with BOOTOPT=0 3.2 ms L11 with BOOTOPT=0 4.1 L10 or L11 with BOOTOPT=1, BS = 0x40 210 L10 or L11 with BOOTOPT=1, BS = 0x80 410 L10 or L11 with BOOTOPT=2, BS = 0x40 210 L10 or L11 with BOOTOPT=2, BS = 0x80 410 Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. 46.9 I/O Pin Characteristics There are two different pin types with three different speeds: Normal and High Sink. The Drive Strength bit is located in the Pin Configuration register of the PORT (PORT.PINCFG.DRVSTR). Table 46-11. I/O Pins Common Characteristics Symbol Parameter Conditions Min. Typ. Max. VIL Input low-level voltage VIH Input high-level voltage VOL VDD=1.62V-2.7V - - 0.25*VDD VDD=2.7V-3.63V - - 0.3*VDD VDD=1.62V-2.7V 0.7*VDD - - VDD=2.7V-3.63V 0.55*VDD - - Output low-level voltage VDD>1.62V, IOL max - 0.1*VDD 0.2*VDD VOH Output high-level voltage VDD>1.62V, IOH max 0.75*VDD 0.85*VDD - RPULL Pull-up - Pull-down resistance 20 40 63 kΩ ILEAK Input leakage current -1 ±0.015 1 µA © 2020 Microchip Technology Inc. Pull-up resistors disabled Datasheet Units DS60001513F-page 981 V SAM L10/L11 Family Electrical Characteristics Table 46-12. I/O Pins Maximum Output Current Symbol Parameter Conditions Normal Pins High Sink Pins(2) Normal Pins DRVSTR=0 High Sink Pins(2) Units DRVSTR=1 IOL Maximum Output low-level current VDD=1.62V-3V 1 2 2 4 VDD=3V-3.63V 2.5 6 6 12 IOH Maximum Output high-level current VDD=1.62V-3V 0.7 1.5 1.5 3 VDD=3V-3.63V 2 5 5 10 Normal Pins High Sink Pins(2) Normal Pins High Sink Pins(2) mA Table 46-13. I/O Pins Dynamic Characteristics(1) Symbol Parameter Conditions DRVSTR=0 DRVSTR=1 tRISE Maximum Rise time VDD=3.3V, load=20 pF, 10%/90% 13 6 6 4.5 tFALL Maximum Fall time VDD=3.3V, load=20 pF, 10%/90% 12 7 7 4.5 ns The pins with I2C alternative mode available are compliant(2) with I2C norms. All I2C pins support Standard mode (Sm), Fast mode (Fm), Fast plus mode (Fm+), and High speed mode (Hs, up to 3.4 MHz). The available I2C pins are listed in the I/O Multiplexing section. Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. The following pins are High Sink pins and have different properties than normal pins: PA16, PA17, PA22,PA23, and PA31. 46.10 Injection Current Stresses beyond those listed in the table below may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Table 46-14. Injection Current(1) Symbol Description min max Unit (2) I/O pin injection current -1 +1 mA Iinj2 (3) I/O pin injection current -15 +15 mA Iinjtotal Sum of I/O pins injection current -45 +45 mA Iinj1 © 2020 Microchip Technology Inc. Units Datasheet DS60001513F-page 982 SAM L10/L11 Family Electrical Characteristics Notes:  1. Injecting current may have an effect on the accuracy of Analog blocks 2. Conditions for Vpin: Vpin < GND-0.6V or 3.6V 5kOhm Startup time Min. Typ. Max. Units Normal mode 350 ksps For DDATA=+/-1 1000 VDDANA > 2.6V VDDANA > 2.6V - - 2.85 µs VDDANA < 2.6V VDDANA < 2.6V - - 10 µs Note:  These values are based on simulation. These values are not covered by test limits in production or characterization. Table 46-28. Accuracy Characteristics (1)(2) Symbol Parameter RES Input resolution INL Integral non-linearity Conditions Min. Typ. Max. Units - - 10 Bits VDD = 1.62V ±0.2 ±0.5 ±1.4 LSB VDD = 3.63V ±0.2 ±0.4 ± 1.2 VDD = 1.62V ±0.2 ±0.6 ± 2.1 VDD = 3.63V ± 0.2 ±0.5 ± 1.9 VDD = 1.62V ± 0.4 ±0.7 ± 3.5 VDD = 3.63V ± 0.4 ±0.8 ±6 VDD = 1.62V ± 0.1 ±0.3 ± 1.5 VDD = 3.63V ± 0.1 ±0.3 ± 1.2 VDD = 1.62V ± 0.1 ±0.2 ± 1.7 VDD = 3.63V ± 0.1 ±0.2 ± 1.5 VDD = 1.62V ± 0.3 ±0.6 ±3 VDD = 3.63V ± 0.3 ±0.8 ±7 VREF= Ext 1.0V - ±4 ± 16 mV VREF= VDDANA - ±12 ± 60 mV VREF= INT1V - ±1 ± 22 mV VREF= Ext 1.0V - ±1 ± 13 mV VREF= VDDANA - ±2.5 ± 21 mV VREF= INT1V - ±1.5 ± 20 mV VREF= Ext 1.0V VREF = VDDANA VREF= INT1V DNL Differential non-linearity VREF= Ext 1.0V VREF= VDDANA VREF= INT1V Gain Offset Gain error Offset error © 2020 Microchip Technology Inc. Datasheet LSB DS60001513F-page 991 SAM L10/L11 Family Electrical Characteristics Notes:  1. Values are measured using a conversion rate of 350ksps. 2. These values are based on characterization. They are not covered in test limits in production. 46.11.6 Analog Comparator (AC) Characteristics Table 46-29. Electrical and Timing Symbol Parameters Conditions Min. Typ Max. Unit V PNIVR Positive and Negative input range voltage 0 - VDDANA ICMR Input common mode range 0 - VDDANA-0.1 V Off Offset VHys Tpd(1) Tstart(1) Vscale Hysteresis Propagation Delay Vcm=VDDANA/2, Vin= +-100 mV overdrive from Vcm(Common Mode Voltage) Start-up time COMPCTRLn.SPEED=0x0 -70 -4.5/+1.5 70 COMPCTRLn.SPEED=0x1 -55 -4.5/+1.5 55 COMPCTRLn.SPEED=0x2 -48 -4.5/+1.5 48 COMPCTRLn.SPEED=0x3 -42 -4.5/+1.5 42 COMPCTRLn.HYST=0x0 10 45 74 COMPCTRLn.HYST=0x1 22 70 106 COMPCTRLn.HYST=0x2 37 90 129 COMPCTRLn.HYST=0x3 49 105 150 COMPCTRLn.SPEED=0x0 - 4 12.3 COMPCTRLn.SPEED=0x1 - 0.97 2.6 COMPCTRLn.SPEED=0x2 - 0.56 1.4 COMPCTRLn.SPEED=0x3 - 0.33 0.77 COMPCTRLn.SPEED=0x0 - 17 71 COMPCTRLn.SPEED=0x1 - 0.85 4.5 COMPCTRLn.SPEED=0x2 - 0.55 3.2 COMPCTRLn.SPEED=0x3 - 0.45 2.7 INL - 0.4 - DNL - 0.1 - Offset Error - 0.1 - Gain Error - 1.3 - mV mV µs µs LSB Note:  1. These values are based on characterization. They are not covered in test limits in production. Table 46-30. Power Consumption (1) Symbol Parameters Conditions Ta IDDANA COMPCTRLn.SPEED=0x0, VDDANA=3.3V COMPCTRLn.SPEED=0x1, VDDANA=3.3V Max.85°C Typ.25°C - 233 481 COMPCTRLn.SPEED=0x2, VDDANA=3.3V - 456 885 COMPCTRLn.SPEED=0x3, VDDANA=3.3V - 879 1604 VDDANA=3.3V - 13 Current consumption voltage scaler disabled. Current consumption voltage scaler only © 2020 Microchip Technology Inc. Datasheet Min. Typ Max. Unit 51 118 18 DS60001513F-page 992 nA µA SAM L10/L11 Family Electrical Characteristics Note:  1. These values are based on characterization. They are not covered in test limits in production. 46.11.7 DETREF Characteristics Table 46-31. Reference Voltage Characteristics Symbol Parameter Conditions Min. Typ. Max. Units ADC/DAC Ref ADC/DAC internal reference nom. 1.0V, VCC=3.0V, T= 25°C 0.976 1.0 1.022 V nom. 1.1V, VCC=3.0V, T= 25°C 1.077 1.1 1.127 nom. 1.2V, VCC=3.0V, T= 25°C 1.174 1.2 1.234 nom. 1.25V, VCC=3.0V, T= 25°C 1.221 1.25 1.287 nom. 2.0V, VCC=3.0V, T= 25°C 1.945 2.0 2.030 nom. 2.2V, VCC=3.0V, T= 25°C 2.143 2.2 2.242 nom. 2.4V, VCC=3.0V, T= 25°C 2.335 2.4 2.457 nom. 2.5V, VCC=3.0V, T= 25°C 2.428 2.5 2.563 drift over [-40, +25]°C - -0.01/+0.015 - drift over [+25, +85]°C - -0.01/+0.005 - Ref Supply coefficient(1) drift over [1.62, 3.63]V - +/-0.35 - %/V AC Ref Accuracy VCC=3.0V, T=25°C 1.086 1.1 1.128 V Ref Temperature coefficient(1) drift over [-40, +25]°C - +/-0.01 - %/°C drift over [+25, +85]°C - -0.005/+0.001 - %/°C drift over [1.62, 3.63]V - -0.35/+0.35 - %/V Ref Temperature coefficient(1) AC Ref Ref Supply coefficient(1) %/°C Note:  1. These values are based on characterization. They are not covered in test limits in production. 46.11.8 OPAMP Characteristics Table 46-32. Operating Conditions Symbol Parameters Conditions Min. Typ. Max. Unit VCC Power Supply All power modes 1.62 3 3.63 V Vin Input voltage range 0 - Vcc V Vout Output voltage range 0.15 - Vcc-0.15 V Maximum capacitance load - - 50 pF Output Range[0.15V;Vcc-0.15V] 3.5 - - kΩ Output Range[0.3V;Vcc-0.3V] 0.5 - - Output Range[0.15V;Vcc-0.15V] - - 1 Output Range[0.3V;Vcc-0.3V] - - 6.9 Cload Rload (1) Iload(1) Minimum resistive load DC output current load mA Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 993 SAM L10/L11 Family Electrical Characteristics Table 46-33. Power Consumption(1) Symbol Parameters Conditions Ta IDD Mode 3,VCC =3.3V Max 85°C Typ 25°C - Mode 2,VCC =3.3V DC supply current (Voltage Doubler OFF) Voltage Doubler consumption Min. Typ. Max. Unit 235 400 - 94 166 Mode 1,VCC =3.3V - 26 47 Mode 0 ,VCC =3.3V - 7 13 VCC =3.3V - 0.70 1.4 μA Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. Table 46-34. Static Characteristics in 1X Gain(1) Symbol Parameters Conditions Min. Typ. Max. Unit G0 Open loop gain Mode 3 - 114.5 - dB Mode 2 - 117.6 - Mode 1 - 116.8 - Mode 0 - 108.5 - Mode 3 - 7.1 - Mode 2 - 2.8 - Mode 1 - 0.85 - Mode 0 - 0.2 - Mode 3 - 71.5 - Mode 2 - 64 - Mode 1 - 56 - Mode 0 - 52 - Mode 3 - 1.3 - Mode 2 - 3.3 - Mode 1 - 13 - GBW фm Tr1 Gain Bandwidth Phase margin Response Time at 240µV (X1 gain) MHz deg µs Mode 0 - 52 - ∆Tr1 Response Time Variation for 10mV Mode 3 - 100 - ns Tstart Start-up time (Enable to Ready), (Voltage Doubler OFF) Mode 3 - 2.7 - µs Mode 2 - 6.35 - Mode 1 - 21.5 - Mode 0 - 88.5 - - - +-3.5 mV Mode 3 - - 2.8/2.6 - V/µs Mode 2 - -1.2/1.1 - Oe Input Offset Voltage SR Slew rate CMRR PSRR 1X gain 1X gain © 2020 Microchip Technology Inc. Datasheet Mode 1 - -0.3/0.3 - Mode 0 - -0.09/0.07 - Mode 3 - 83 - Mode 2 - 84 - Mode 1 - 84 - Mode 0 - 83 - Mode 3 - 76 - Mode 2 - 76 - Mode 1 - 76 - Mode 0 - 75 - dB dB DS60001513F-page 994 SAM L10/L11 Family Electrical Characteristics ...........continued Symbol Parameters Conditions Min. Typ. Max. Unit - Integrated Noise, BW=[0.1Hz-10kHz], x1 gain - VOUT=1V Mode 3 - 7.9 - µVRMS Mode 2 - 8.3 - Mode 1 - 9.9 - Mode 0 - 12.7 - Mode 3 - 18.2 - Mode 2 - 22.8 - Mode 1 - 36.7 - Mode 0 - 44.4 - - Integrated Noise, BW=[0.1Hz-1MHz], x1 gain - VOUT=1V µVRMS Note:  1.These values are based on simulation. They are not covered by production test limits or characterization. Table 46-35. PGA Electrical Characteristics(1) Symbol Parameters Conditions Min. Typ. Max. Unit - Gain accuracy 16X Gain - - +/-2.4 % 4X Gain - - +/-1.1 1X Gain - - +/-2.6 16X Gain - -77 - 4X Gain - -72.8 - 1X Gain - -82.6 - Mode 3 - 147 - Mode 2 - 147 - Mode 1 - 162 - Mode 0 - 191 - Mode 3 - 262 - Mode 2 - 247 - Mode 1 - 235 - Mode 0 - 235 - THD - - Total Harmonic Distortion @ 10kHz - mode 3 Integrated Noise, BW=[0.1Hz-10 kHz], 16X gain - VOUT=1V Integrated Noise, BW=[0.1Hz-1MHz], 16X gain - VOUT=1V dB µVrms µVrms Note:  1.These values are based on simulation. They are not covered by production test limits or characterization. 46.11.9 Peripheral Touch Controller (PTC) Characteristics Table 46-36. PTC Acquisition Clock Symbol Description Min Max Units FPTC_ACQ PTC Acquisition Clock - 8 Mhz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 995 SAM L10/L11 Family Electrical Characteristics Table 46-37. Sensor Load Capacitance (1) Symbol Cload Mode PTC channel Self-capacitance Mutual-capacitance Min PCB External (2) Y0 5 Y1 - Y2 - Y3 5 Y4 5 Y5 - Y6 5 Y7 5 Y8 5 Y9 5 Y10 - Y11 5 Y12 5 Y13 - Y14 - Y15 5 Y16 5 Y17 5 Y18 5 Y19 5 All - Max Sensor Load (3) Units 54 50 54 45 pF 54 50 54 31 Notes:  1. These values are based on characterization. They are not covered in test limits in production. 2. Minimum external capacitance must be added on PCB design per PTC channel. Ensure that the PCB and sensor design add enough parasitic capacitance on each PTC channel, otherwise, an external capacitor must be added. 3. Capacitance load, the PTC circuitry, can compensate for each channel. Table 46-38. Analog Gain Settings (1) (2) Symbol Gain © 2020 Microchip Technology Inc. Setting Average GAIN_1 1.0 GAIN_2 2.0 GAIN_4 3.9 GAIN_8 8.1 Datasheet DS60001513F-page 996 SAM L10/L11 Family Electrical Characteristics Notes:  1. Analog Gain is a parameter of the QTouch Library. Refer to the QTouch Library Peripheral Touch Controller User Guide. 2. These values are based on characterization. They are not covered in test limits in production. Power Consumption The values in the Power Consumption table below are measured values of power consumption under the following conditions: Operating Conditions • VDD = 3.3V Clocks • • • • OSC16M divided to 4MHz used as main clock source CPU is running on flash with 0 wait state, at 4MHz PTC Acquisition Clock (FPTC_ACQ) at 4MHz Voltage Regulator mode: LPEFF enabled PTC Configuration • • Mutual-capacitance mode One touch channel System Configuration • • • • Standby sleep mode enabled RTC running on OSCULP32K: used to define the PTC scan rate, through the event system Drift Calibration disabled: no interrupts, PTC scans are performed in standby mode Drift Calibration enabled: RTC interrupts (wakeup) the CPU to perform PTC scans. PTC drift calibration is performed every 1.5 sec. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 997 SAM L10/L11 Family Electrical Characteristics Table 46-39. Power Consumption (1) Symbol Parameters Drift Calibration PTC scan rate (msec) Oversamples Ta 10 50 Disabled 100 200 IDD Current Consumption 10 50 Enabled 100 200 Typ. Max. Units 4 6.2 16 12.7 58.1 4 2.3 43.7 16 3.7 45.5 4 1.7 43.2 16 2.4 43.9 4 1.4 42.8 1.8 43.2 8.3 51.7 16 Max. 85°C Typ. 25°C 4 49.2 16 14.2 60.5 4 3.0 44.8 16 4.8 47.0 4 2.3 44.5 16 2.8 45.4 4 1.9 43.9 16 2.4 44.2 µA Note:  1. These values are based on characterization. They are not covered in test limits in production. 46.12 NVM Characteristics Table 46-40. NVM Max Speed Characteristics (1) Conditions PL0 (-40/85°C) (-40/125°C) PL2 (-40/85°C) (-40/125°C) CPU Fmax (MHz) 0WS 1WS 2WS VDDIO>1.62 V 6 8 8 VDDIO>2.7 V 7.5 8 8 VDDIO>1.62 V 14 28 32 VDDIO>2.7 V 14 32 32 Table 46-41. NVM Timing Characteristics (1) Symbol Timings Max Units tFPP Page Write 2.5 ms tFRE Row erase 6 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 998 SAM L10/L11 Family Electrical Characteristics Note:  1. For this Flash technology, a maximum number of 8 consecutive writes is allowed per row. Once this number is reached, a row erase is mandatory. Table 46-42. Flash Erase and Programming Current Symbol Parameter Typ. Units IDDNVM Maximum current (peak) during whole programming or erase operation 10 mA Table 46-43. NVM Reliability Characteristics (2) Symbol Parameter Conditions Min. Typ. Units RetNVM25k Retention after up to 25k Average ambient 55°C 10 50 Years RetNVM2.5k Retention after up to 2.5k Average ambient 55°C 20 100 Years RetNVM100 Retention after up to 100 Average ambient 55°C 25 >100 Years CycNVM Cycling Endurance(1) -40°C < Ta < 85°C -40°C < Ta < 125°C 25K 100K Cycles 50 100 Cycles Cycling Endurance using Tamper Erase Notes:  1. An endurance cycle is a write and an erase operation. 2. Reliability characteristics are given when not using tamper erase operations except if noted. 46.13 Oscillators Characteristics 46.13.1 Crystal Oscillator (XOSC) Characteristics Digital Clock Characteristics The following table describes the characteristics for the oscillator when a digital clock is applied on XIN. Table 46-44. Digital Clock Characteristics Symbol Parameter Min. Typ. Max. Units FXIN XIN clock frequency - - 24 MHz DCXIN(1) XIN clock duty cycle 40 50 60 % Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. Crystal Oscillator Characteristics The following Table describes the characteristics for the oscillator when a crystal is connected between XIN and XOUT. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 999 SAM L10/L11 Family Electrical Characteristics Figure 46-3. Oscillator Connection DEVICE XIN Crystal CLEXT LM RM CSHUNT CM XOUT CLEXT The user must choose a crystal oscillator where the crystal load capacitance CL is within the range given in the Table. The exact value of CL can be found in the crystal data sheet. The capacitance of the external capacitors (CLEXT) can then be computed as follows: CLEXT = 2(CL - CPARA - CPCB - CSHUNT) Where: • • • CPARA is the internal load capacitor parasitic between XIN and XOUT (CPARA = (CXIN * CXOUT)/(CXIN + CXOUT)) CPCB is the capacitance of the PCB CSHUNT is the shunt capacity of the crystal. Table 46-45. Multi Crystal Oscillator Electrical Characteristics Symbol Parameter Fout Crystal oscillator frequency ESR(2) Crystal Equivalent Series Resistance - SF = 3 Cxin(2) Conditions Min. Typ. Max Units 0.4 - 32 MHz F = 0,4MHz - CL=100 pF XOSC,GAIN=0 - - 5.6K Ω F = 2MHz - CL=20 pF XOSC,GAIN=0, Cshunt=3.3pF - - 330 F = 4MHz - CL=20 pF XOSC,GAIN=1, Cshunt=2.5pF - - 240 F = 8MHz - CL=20 pF XOSC,GAIN=2, Cshunt=5.5pF - - 105 F = 16MHz - CL=20 pF XOSC,GAIN=3, Cshunt=4pF - - 60 F = 32MHz - CL=20 pF XOSC,GAIN=4, Cshunt=3.9pF - - 55 - 6.7 - pF - 4.2 - pF F = 2MHz - CL=20 pF XOSC,GAIN=0, Cshunt=3.3pF - 15.6K 81.6K Cycles F = 4MHz - CL=20 pF XOSC,GAIN=1, Cshunt=2.5pF - 6.3K 25.2K F = 8MHz - CL=20 pF XOSC,GAIN=2, Cshunt=5.5pF - 6.2K 27.2K F = 16MHz - CL=20 pF XOSC,GAIN=3, Cshunt=4pF - 7.7K 27.3K F = 32MHz - CL=20 pF XOSC,GAIN=4, Cshunt=3.9pF - 6.0K 21K 10 - 20 Parasitic load capacitor Cxout(2) Tstart(2) CL(1) Startup time Crystal load capacitance © 2020 Microchip Technology Inc. Datasheet pF DS60001513F-page 1000 SAM L10/L11 Family Electrical Characteristics ...........continued Symbol Parameter Conditions Min. Typ. Max Units Pon(1) AMPGC=ON - 100 uW Drive Level - Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These values are based on characterization. They are not covered in test limits in production. Table 46-46. Power Consumption (1) Symbol Parameter Conditions IDD F=2MHz - CL=20pF XOSC,GAIN=0, VCC=3.3V AMPGC=OFF Max 85°C Typ 25°C AMPGC=ON - 66 85 62 99 F=4MHz - CL=20pF XOSC,GAIN=1, VCC=3.3V AMPGC=OFF - 107 140 AMPGC=ON - 70 101 F=8MHz - CL=20pF XOSC,GAIN=2, VCC=3.3V AMPGC=OFF - 200 261 AMPGC=ON - 118 153 F=16MHz - CL=20pF XOSC,GAIN=3, VCC=3.3V AMPGC=OFF - 436 581 AMPGC=ON - 247 329 F=32MHz - CL=20pF XOSC,GAIN=4, VCC=3.3V AMPGC=OFF - 1303 1902 AMPGC=ON - 627 Current consumption Ta Min. Typ. Max. Units µA 940 Note:  1. These values are based on characterization. They are not covered in test limits in production. 46.13.2 External 32KHz Crystal Oscillator (XOSC32K) Characteristics Digital Clock Characteristics The following table describes the characteristics for the oscillator when a digital clock is applied on XIN32 pin. Table 46-47. Digital Clock Characteristics(1) Symbol Parameter fCPXIN32 XIN32 clock frequency DCXIN XIN32 clock duty cycle Min. 40 Typ. Max. Units 32.768 1000 kHz 50 60 % Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. Crystal Oscillator Characteristics The following section describes the characteristics for the oscillator when a crystal is connected between XIN32 and XOUT32 pins. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1001 SAM L10/L11 Family Electrical Characteristics Figure 46-4. Oscillator Crystal Connection DEVICE XIN32 Crystal CLEXT LM RM CSHUNT CM XOUT32 CLEXT The user must choose a crystal oscillator where the crystal load capacitance CL is within the range given in the table. The exact value of CL can be found in the crystal data sheet. The capacitance of the external capacitors (CLEXT) can then be computed as follows: CLEXT = 2(CL - CPARA - CPCB - CSHUNT) Where: • • • CPARA is the internal load capacitor parasitic between XIN and XOUT ( CPARA = (CXIN32K CXOUT32K)/(CXIN32K + CXOUT32K) ) CPCB is the capacitance of the PCB CSHUNT is the shunt capacity of the crystal. Table 46-48. 32 KHz Crystal Oscillator Electrical Characteristics Symbol Parameter Conditions Min. Typ. Max. Units FOUT Crystal oscillator frequency - - 32.768 - kHz Crystal load capacitance - 7 - 9 pF Crystal shunt capacitance - 0.6 - 2 pF CM(1) Motional capacitance - 0.6 - 3 fF ESR(2) Crystal Equivalent Series Resistance - SF=3 f=32.768kHz, CL= 9pF - - 70 kΩ CXIN32k(2) Parasitic load capacitor - - 3.2 - pF - - 3.4 - CL(1) CSHUNT (1) CXOUT32k(2) tSTARTUP(2) Startup time f=32.768kHz, CL= 9pF - 10 43 KCycles Pon(1) Drive Level - - - 0.1 µW Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These values are based on characterization. They are not covered in test limits in production. Table 46-49. Power Consumption (1) Symbol Parameter Conditions Ta Min. Typ. Max. Units IDD Current consumption VCC=3.3V Max 85°C Typ 25°C - 309 606 nA Note:  1. These values are based on characterization. They are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1002 SAM L10/L11 Family Electrical Characteristics 46.13.3 Ultra Low-Power Internal 32 kHz RC Oscillator (OSCULP32K) Characteristics Table 46-50. Ultra Low-Power Internal 32 kHz RC Oscillator Electrical Characteristics Symbol Parameter Conditions Min. Typ. Max. Units FOUT Output frequency at 25°C, at VDDIO=3.3V 30.84 32.768 34.51 kHz at 25°C, over [1.62, 3.63]V 30.84 32.768 34.74 kHz over[-40,+85]°C, over [1.62, 3.63]V 25.17 32.768 39.10 kHz - 50 - % Duty(1) Duty Cycle Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. 46.13.4 16 MHz RC Oscillator (OSC16M) Characteristics Table 46-51. Multi-RC Oscillator Electrical Characteristics Symbol Parameter Conditions Min. Typ. Max. Units FOUT Output frequency VDD=3.3V, T=25°C Calibrated against a 4/8/12/16 MHz reference 3.96 4.00 4.04 MHz 7.92 8.00 8.08 11.88 12.00 12.12 15.84 16.00 16.16 TempDrift Freq vs. temperature drift VDD=3.3V over temperature [-40°C-85°C], versus -5 calibration reference at 25°C - 5 SupplyDrift Freq vs. supply drift Temperature =25°C over voltage [1.62V-3.63V], versus calibration reference at 3.3V -1.5 - 1.5 TWUP(2) FOUT = 4MHz - 0.13 0.28 FOUT = 8MHz - 0.13 0.28 FOUT = 12MHz - 0.13 0.28 FOUT = 16MHz - 0.13 0.27 FOUT = 4MHz - 1.16 2.96 FOUT = 8MHz - 1.29 2.74 FOUT = 12MHz - 1.34 2.95 FOUT = 16MHz - 1.39 3.11 - 45 50 55 Wake up time - 1st clock edge after enable TSTARTUP(2) Startup time Duty(1) Duty Cycle Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These values are based on characterization. They are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1003 % µs µs % SAM L10/L11 Family Electrical Characteristics Table 46-52. Power Consumption (1) Symbol Parameter Conditions Ta Min. Typ. Max. Units IDD Current consumption Fout=4MHz, VCC=3.3V Max.85°C Typ.25°C - 73 139 µA Fout=8MHz, VCC=3.3V - 106 169 Fout=12MHz, VCC=3.3V - 135 195 Fout=16MHz, VCC=3.3V - 166 225 Note:  1. These values are based on characterization. They are not covered in test limits in production. 46.13.5 Digital Frequency Locked Loop (DFLLULP) Characteristics Table 46-53. Digital Frequency Locked Loop Characteristics (LDO Regulator) Symbol Parameter Min. Typ. Max. Unit FIN Input Clock Frequency 32 - 33 kHz FOUT Output Clock Frequency PL2 - - 32 MHz PL0 - - 8 FOUT drift Output Clock Frequency drift(2) PL0, Fin = 32768 Hz 50 ppm Fout = 8 MHz -3.8 - 3.2 PL2, Fin = 32768 Hz 50 ppm Fout = 32 MHz -3.2 - 3.4 Jp Period jitter (cycle to cycle jitter)(2) PL0, Fin= 32 kHz 50 ppm, Fout = 8 MHz -4 4 PL2, Fin= 32 kHz 50 ppm, Fout = 32 MHz -4.3 - 4.3 Lock Time After startup, time to get lock signal Fin = 32768 Hz, Fout = 8MHz, PL0 Binary Search mode enabled - 362 - µs After startup, time to get lock signal Fin = 32768 Hz, Fout = 32 MHz, PL2 Binary Search mode enabled - 362 - µs 40 50 60 % tLOCK Duty Duty cycle(1) - % % Notes:  1. These values are based on simulation, and are not covered by test or characterization. 2. Core running on OSC16M, no peripheral activity. Table 46-54. Digital Frequency Locked Loop Characteristics (Buck Regulator) Symbol Parameter FIN Input Clock Frequency FOUT Output Clock Frequency FOUT drift Output Clock Frequency drift (2) © 2020 Microchip Technology Inc. Conditions Min. Typ. Max. 32 33 PL0 - - 4.88 PL2 - - 26.78 PL0, FIN = 32 kHz, FOUT = 4.88 MHz -16.3 38.9 PL2, FIN = 32 kHz, FOUT = 26.78 MHz -8.7 16.3 Datasheet Unit kHz MHz % DS60001513F-page 1004 SAM L10/L11 Family Electrical Characteristics ...........continued Symbol Jp Parameter Conditions Min. Typ. Max. Unit Period Jitter(2)(3) PL0, FIN = 32 kHz, FOUT = 4.88 MHz -7.8 - 8.1 (cycle to cycle jitter) PL2, FIN = 32 kHz, FOUT = 26.78 MHz -5.0 - 4.6 - 362 - µs - 362 - µs 40 50 60 % % After startup, time to get lock signal FIN = 32 kHz, FOUT = 4.88 MHz, PL0 Binary Search mode enabled Lock Time tLOCK After startup, time to get lock signal FIN = 32 kHz, FOUT = 26.78 MHz, PL2 Binary Search mode enabled Duty Cycle (1) Duty Notes:  1. These values are based on simulation, and are not covered by test or characterization. 2. Asynchronous peripherals and accurate ADC measurement must not use DFLLULP with Buck Converter, alternatively use a clock configuration and source providing required accuracy. Synchronous-based peripherals must also consider frequency drift to ensure proper inter-device communications. 3. Core running on OSC16M, no peripheral activity. Table 46-55. Power Consumption(1) (2) Symbol Parameters IDD Conditions Ta Current Consumption Fout = 8 MHz (PL0) - VCC = 3.3V Min. Typ. Max. Units Max 85°C Typ 25°C - Fout = 32 MHz (PL2) - VCC = 3.3V - 33 93 144 223 µA Notes:  1. These characteristics are only applicable in LDO regulator mode. 2. These values are based on characterization, and are not covered in test limits in production. 46.13.6 Digital Phase Lock Loop (DPLL) Characteristics Table 46-56. Fractional Digital Phase Lock Loop Characteristics(2) Symbol Parameter Min. Typ. Max. Unit FIN Input Clock Frequency 32 - 2000 kHz FOUT Output Clock Frequency PL2 32 - 96 MHz PL0 32 - 48 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1005 SAM L10/L11 Family Electrical Characteristics ...........continued Symbol Parameter Jp Min. Typ. Max. Unit Period jitter PL0, Fin = 32 kHz, Fout = 32 MHz - PL2, Fin = 32 kHz, Fout = 32 MHz PL0, Fin = 32 kHz, Fout = 48 MHz - PL2, Fin = 32 kHz, Fout = 48 MHz 5 3 4 2 6 3 4 PL0, Fin = 32 kHz, Fout = 32 MHz - 3 5 3 6 5 7 3 6 4 10 After startup, time to get lock signal Fin = 32 kHz, Fout = 96 MHz 1.1 1.5 ms After startup, time to get lock signal Fin = 2 MHz, Fout = 96 MHz - 24 35 µs 40 50 60 % - PL2, Fin = 2 MHz, Fout = 48 MHz PL2, Fin = 2 MHz, Fout = 96 MHz Duty 2 % - PL0, Fin = 2 MHz, Fout = 48 MHz Lock Time 6 PL2, Fin = 32 kHz, Fout = 96 MHz PL2, Fin = 32 kHz, Fout = 32 MHz tLOCK 3 - Duty cycle(1) Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These characteristics are applicable only in LDO regulator mode and with a XOSC or XOSC32K reference. Table 46-57. Power Consumption(1)(2) Symbol Parameter Conditions TA Min. Typ. Max. Units IDD Current Consumption Fout = 48 MHz (PL0) - VDD=3.3V Max. 85°C Typ. 25°C - 339 432 µA - 678 777 Fout = 96 MHz (PL2) - VDD=3.3V Notes:  1. These characteristics are only applicable in LDO regulator mode. 2. These values are based on characterization. They are not covered in test limits in production. 46.14 Timing Characteristics 46.14.1 External Reset Pin Table 46-58. External Reset Characteristics(1) Symbol Parameter tEXT Minimum reset pulse width Conditions Min. Typ. Max. Units 1 - - µs Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1006 SAM L10/L11 Family Electrical Characteristics 46.14.2 SERCOM in SPI Mode in PL0 Table 46-59. SPI Timing Characteristics and Requirements (1) Symbol Parameter Conditions tSCK SCK period when Master tSOV=0 on the slave side Master Min. Typ. Max. Units Reception 2*(tMIS +tSLAVE_OUT) (3) - - ns Transmission 2*(tMOV +tSLAVE_IN) (4) - - tSCKW SCK high/low width Master - 0,5*tSCK tSCKR SCK rise time(2) Master - 0,25*tSCK - Master - 0,25*tSCK - Master, VDD>2,70V 90 - - Master, VDD>1,62V 98.1 - - MISO hold after SCK Master, VDD>2,70V 0 - - Master, VDD>1,62V 0 - - MOSI output valid after SCK Master, VDD>2,70V - - 34.5 Master, VDD>1,62V - - 38.6 MOSI hold after SCK Master, VDD>2,70V 9.7 - - Master, VDD>1,62V 9.7 - - Slave SCK Period when tMIS=0 on the master side Slave Reception 2*(tSIS +tMASTER_OUT) (5) - - Slave Transmission 2*(tSOV +tMASTER_IN) (6) - - Slave - 0,5*tSCK - Slave - 0,25*tSCK - Slave - 0,25*tSCK - time(2) tSCKF SCK fall tMIS MISO setup to SCK tMIH tMOV tMOH tSSCK tSSCKW SCK high/low width tSSCKR SCK rise tSSCKF time(2) SCK fall time(2) © 2020 Microchip Technology Inc. Datasheet ns DS60001513F-page 1007 SAM L10/L11 Family Electrical Characteristics ...........continued Symbol Parameter Conditions Min. Typ. Max. Units tSIS MOSI setup to SCK Slave, VDD>2,70V 25.6 - - ns Slave, VDD>1,62V 26.2 - - MOSI hold after SCK Slave, VDD>2,70V 13.2 - - Slave, VDD>1,62V 13.9 - - SS setup to SCK Slave PRELOADEN=1 tSOSS+tEXT_MIS +2*tAPBC (8) (9) - - PRELOADEN=0 tSOSS+tEXT_MIS (8) - - tSIH tSSS tSSH SS hold after SCK Slave 0.5*tSSCK - - tSOV MISO output valid after SCK Slave, VDD>2,70V - - 69 Slave, VDD>1,62V - - 78.4 MISO hold after SCK Slave, VDD>2,70V 20.2 - - Slave, VDD>1,62V 20.2 - - MISO setup after SS Slave, VDD>2,70V low Slave, VDD>1,62V - - 1* tSCK - - 1* tSCK MISO hold after SS high Slave, VDD>2,70V 15 - - Slave, VDD>1,62V 15 - - tSOH tSOSS tSOSH Notes:  1. These values are based on simulation. These values are not covered by test limits in production. 2. See I/O Pin Characteristics. 3. Where tSLAVE_OUT is the slave external device output response time, generally tEXT_SOV+tLINE_DELAY. (7) 4. 5. 6. 7. 8. 9. Where tSLAVE_IN is the slave external device input constraint, generally tEXT_SIS+tLINE_DELAY. (7) Where tMASTER_OUT is the master external device output response time, generally tEXT_MOV +tLINE_DELAY. (7) Where tMASTER_IN is the master external device input constraint, generally tEXT_MIS+tLINE_DELAY. (7) tLINE_DELAY is the transmission line time delay. tEXT_MIS is the input constraint for the master external device. tAPBC is the APB period for SERCOM. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1008 SAM L10/L11 Family Electrical Characteristics Figure 46-5. SPI Timing Requirements in Master Mode SS tSSCKF tSSCKR SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSB LSB tMOV tMOH tMOH MOSI (Data Output) MSB LSB Figure 46-6. SPI Timing Requirements in Slave Mode SS tSSS tSSCKF tSSCKR tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS MOSI (Data Input) tSIH MSB LSB tSOSH tSOSS MISO (Data Output) tSSCK tSOV tSOH MSB LSB Maximum SPI Frequency • Master Mode fSCKmax = 1/2*(tMIS + tSLAVE_OUT) • Slave Mode fSCKmax = 1/2*(tSOV + tMASTER_IN) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1009 SAM L10/L11 Family Electrical Characteristics 46.14.3 SERCOM in SPI Mode in PL2 Table 46-60. SPI Timing Characteristics and Requirements (1) Symbol Parameter Conditions tSCK SCK period when Master tSOV=0 on the slave side Master Min. Typ. Max. Units Reception 2*(tMIS +tSLAVE_OUT) (3) - - ns Transmission 2*(tMOV +tSLAVE_IN) (4) - - tSCKW SCK high/low width Master - 0,5*tSCK tSCKR SCK rise time(2) Master - 0,25*tSCK - Master - 0,25*tSCK - Master, VDD>2,70V 42.5 - - Master, VDD>1,62V 52.5 - - MISO hold after SCK Master, VDD>2,70V 0 - - Master, VDD>1,62V 0 - - MOSI output valid after SCK Master, VDD>2,70V - - 17.1 Master, VDD>1,62V - - 21.2 MOSI hold after SCK Master, VDD>2,70V 6.3 - - Master, VDD>1,62V 6.3 - - Reception 2*(tSIS +tMASTER_OUT) (5) - - Transmission 2*(tSOV +tMASTER_IN) (6) - - time(2) tSCKF SCK fall tMIS MISO setup to SCK tMIH tMOV tMOH tSSCK Slave SCK Period Slave when tMIS =0 on the master side Slave © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1010 SAM L10/L11 Family Electrical Characteristics ...........continued Symbol Parameter tSSCKW SCK high/low width tSSCKR SCK rise time(2) Conditions Min. Typ. Max. Units Slave - 0,5*tSCK - ns Slave - 0,25*tSCK - tSSCKF SCK fall time(2) Slave - 0,25*tSCK - tSIS MOSI setup to SCK Slave, VDD>2,70V 10.3 - - Slave, VDD>1,62V 11.1 - - MOSI hold after SCK Slave, VDD>2,70V 6.1 - - Slave, VDD>1,62V 6.9 - - SS setup to SCK Slave PRELOADEN=1 tSOSS+tEXT_MIS +2*tAPBC (8) (9) - - PRELOADEN=0 tSOSS+tEXT_MIS (8) - - tSIH tSSS tSSH SS hold after SCK Slave 0.5*tSSCK - - tSOV MISO output valid after SCK Slave, VDD>2,70V - - 35 Slave, VDD>1,62V - - 44.8 MISO hold after SCK Slave, VDD>2,70V 13.4 - - Slave, VDD>1,62V 13.4 - - MISO setup after SS Slave, VDD>2,70V low Slave, VDD>1,62V - - 1* tSCK - - 1* tSCK MISO hold after SS high Slave, VDD>2,70V 8.6 - - Slave, VDD>1,62V 8.6 - - tSOH tSOSS tSOSH ns Notes:  1. These values are based on simulation. These values are not covered by test limits in production. 2. See I/O Pin Characteristics. 3. Where tSLAVE_OUT is the slave external device output response time, generally tEXT_SOV+tLINE_DELAY. (7) 4. 5. 6. 7. 8. 9. Where tSLAVE_IN is the slave external device input constraint, generally tEXT_SIS+tLINE_DELAY. (7) Where tMASTER_OUT is the master external device output response time, generally tEXT_MOV +tLINE_DELAY. (7) Where tMASTER_IN is the master external device input constraint, generally tEXT_MIS+tLINE_DELAY. (7) tLINE_DELAY is the transmission line time delay. tEXT_MIS is the input constraint for the master external device. tAPBC is the APB period for SERCOM. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1011 SAM L10/L11 Family Electrical Characteristics Figure 46-7. SPI Timing Requirements in Master Mode SS tSSCKF tSSCKR SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSB LSB tMOV tMOH tMOH MOSI (Data Output) MSB LSB Figure 46-8. SPI Timing Requirements in Slave Mode SS tSSS tSSCKF tSSCKR tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS MOSI (Data Input) tSIH MSB LSB tSOSH tSOSS MISO (Data Output) tSSCK tSOV tSOH MSB LSB Maximum SPI Frequency • Master Mode fSCKmax = 1/2*(tMIS + tSLAVE_OUT) • Slave Mode fSCKmax = 1/2*(tSOV + tMASTER_IN) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1012 SAM L10/L11 Family 125°C Electrical Characteristics 47. 125°C Electrical Characteristics This section provides an overview of the SAM L10 and SAM L11 electrical characteristics, which are specific for devices running up to 125°C (excluding AEC-Q100 Grade 1 qualified devices characteristics which are provided in chapter AEC-Q100 Grade 1 (-40°C to 125°C) Electrical Characteristics.) For all other values or other characteristics, refer to Electrical Characteristics. 47.1 Disclaimer All typical values are measured at T = 25°C unless otherwise specified. All minimum and maximum values are valid across operating temperature and voltage unless otherwise specified. 47.2 General Operating Ratings The device must operate within the ratings listed in the following table for all other electrical characteristics and typical characteristics of the device to be valid. Table 47-1. General Operating Conditions Symbol Description Min. Typ. Max. Units VDDIO IO Supply Voltage 1.62 3.3 3.63 V VDDANA Analog supply voltage 1.62 3.3 3.63 V TA Temperature range -40 25 125 °C TJ Junction temperature - - 145 °C 47.3 Power Consumption The values in this section are measured values of power consumption under the following conditions, except where noted: • Operating Conditions – VDDIO = 3.3V or 1.8V – CPU is running on Flash with required Wait states, as recommended in the NVM Characteristics section. – Low power cache is enabled – BOD33 is disabled – I/Os are configured with digital input trigger disabled (default Reset configuration) • Oscillators – XOSC (crystal oscillator) stopped – XOSC32K (32.768 kHz crystal oscillator) running with external 32.768 kHz crystal – When in active PL2 mode on FDPLL96M at 32 MHZ, DPLL is using XOSC32K as reference clock and running at 32 MHz – When in Active mode on DFLLULP, the DFLLULP is configured in Closed Loop mode using XOSC32K as reference clock and MCLK.CTRLA.CKSEL = 1 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1013 SAM L10/L11 Family 125°C Electrical Characteristics Table 47-2. Active Current Consumption Mode Conditions Regulator PL CPU Clock Vcc Ta Typ. Max. 1.8V 64.1 129 3.3V 64.4 131 1.8V 66.6 130 3.3V 70.3 132 1.8V 74.1 203 3.3V 77.8 206 1.8V 82.0 98 3.3V 82.5 99 1.8V 75.8 109 3.3V 75.8 107 1.8V 44 103 3.3V 29.9 69 1.8V 43.8 84 3.3V 32.1 58 50.3 131 3.3V 38.9 92 1.8V 59.9 70 3.3V 35.3 43 1.8V 55.8 80 3.3V 33.7 48 1.8V 44.3 110 3.3V 44.4 111 1.8V 47.6 111 3.3V 50.1 113 1.8V 54.6 184 3.3V 57.7 187 1.8V 56.9 79 3.3V 57.2 80 1.8V 50.8 72 3.3V 51.0 72 Units DFLLUP at 8 MHz PL0 LDO OSC 8 MHz OSC 4 MHz FDPLL96 at 32 MHz PL2 DFLLULP at 32 MHz COREMARK / FIBONACCI DFLLUP at 4.88 MHz PL0 OSC 8 MHz 1.8V OSC 4 MHz BUCK ACTIVE Max at 125°C Typ at 25°C uA/MHz FDPLL96 at 32 MHz PL2 DFLLULP at 26.78 MHz DFLLUP at 8 MHz PL0 WHILE1 LDO OSC 8 MHz OSC 4 MHz FDPLL96 at 32 MHz PL2 DFLLULP at 32 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1014 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Mode Conditions Regulator PL CPU Clock Vcc Ta Typ. Max. 1.8V 32.4 90 3.3V 22.8 62 1.8V 32.2 73 3.3V 25.3 51 1.8V 38.4 121 3.3V 31.9 86 1.8V 41.5 55 3.3V 24.6 34 1.8V 38.3 58 3.3V 23.1 36 1.8V 16.0 81 3.3V 16.2 82 1.8V 19.8 82 3.3V 22.0 85 26.2 152 3.3V 29.2 157 1.8V 20.3 54 3.3V 20.4 54 1.8V 14.3 32 3.3V 14.4 33 1.8V 15.1 68 3.3V 12.3 48 1.8V 15.5 55 3.3V 15.2 40 1.8V 21.3 100 3.3V 21.6 73 1.8V 14.9 30 3.3V 9.1 19 1.8V 11.2 26 3.3V 7.2 17 Units DFLLUP at 4.88 MHz WHILE1 PL0 ACTIVE BUCK OSC 8 MHz OSC 4 MHz WHILE1 FDPLL96 at 32 MHz PL2 DFLLULP at 26.78 MHz DFLLUP at 8 MHz PL0 OSC 8 MHz 1.8V LDO OSC 4 MHz Max at 125°C Typ at 25°C uA/MHz FDPLL96 at 32 MHz PL2 DFLLULP at 32 MHz IDLE -DFLLUP at 4.88 MHz PL0 BUCK OSC 8 MHz OSC 4 MHz FDPLL96 at 32 MHz PL2 DFLLULP at 26.78 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1015 SAM L10/L11 Family 125°C Electrical Characteristics Table 47-3. Standby and Off Mode Current Consumption Mode Conditions Regulator Mode Vcc LPEFF Disable 1,8V LPEFF Enable Ta Typ. Max. 25°C 1.3 3.5 125°C 121.7 304.8 25°C 1.1 3.0 125°C 74.5 282.6 25°C 1.2 2.9 125°C 78.0 188.7 25°C 1.1 2.2 125°C 50.9 122.9 25°C 0.6 1.1 125°C 27.1 81.0 25°C 0.5 1.0 125°C 23.1 52.8 25°C 0.8 1.1 125°C 23.0 53.7 25°C 0.8 1.5 125°C 17.3 37.6 25°C 0.6 1.1 125°C 25.5 73.7 25°C 0.5 1.0 125°C 21.6 48.8 25°C 0.7 1.1 125°C 21.5 50.5 25°C 0.8 1.5 125°C 16.4 35.4 25°C 0.5 1.0 125°C 23.8 67.1 25°C 0.5 0.9 125°C 20.2 45.4 25°C 0.7 1.0 125°C 19.9 46.5 25°C 0.7 1.4 125°C 15.5 33.2 Units 3,3V All 16kB RAM retained, PDSW domain in active state BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) LPEFF Disable LPEFF Enable STANDBY 1,8V 3,3V 1,8V 3,3V All 16kB RAM retained, PDSW domain in retention µA BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) LPEFF Disable LPEFF Enable 1,8V 3,3V 1,8V 3,3V 12 kB RAM retained,PDSW domain in retention Buck in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) LPEFF Disable LPEFF Enable STANDBY 1,8V 3,3V 1,8V 3,3V 8kB RAM retained,PDSW domain in retention µA BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) © 2020 Microchip Technology Inc. Datasheet 1,8V 3,3V DS60001513F-page 1016 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Mode Conditions Regulator Mode Vcc LPEFF Disable 1,8V LPEFF Enable Ta Typ. Max. 25°C 0.5 0.9 125°C 22.0 58.9 25°C 0.5 0.9 125°C 18.7 41.5 25°C 0.7 1.0 125°C 18.4 42.7 25°C 0.8 1.5 125°C 14.6 31.0 25°C 0.9 1.3 125°C 22.6 59.8 25°C 0.8 1.2 125°C 19.3 42.1 25°C 1.0 1.3 125°C 19.0 43.3 25°C 1.1 1.7 125°C 15.2 31.6 25°C 34.6 54.4 Units 3,3V 4kB RAM retained,PDSW domain in retention BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) 1,8V 3,3V STANDBY μA LPEFF Disable LPEFF Enable 1,8V 3,3V 4kB RAM retained,PDSW domain in retention and RTC running on XOSC32k BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) 1,8V 3,3V 1,8V 125°C 4385.0 8291.5 OFF nA 25°C 61.2 89.1 3,3V 125°C 5489.5 10564.7 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1017 SAM L10/L11 Family 125°C Electrical Characteristics 47.4 47.4.1 Analog Characteristics Brown-Out Detectors (BOD) Characteristics Table 47-4. BOD33 Characteristics with BOD33.VREFSEL = 0 Symbol Parameters Conditions Min. Typ. Max. Unit VBOD+ (2) BOD33 high threshold level BOD33.LEVEL = 6 1.66 1.68 1.70 V BOD33.LEVEL = 7 1.70 1.72 1.74 BOD33.LEVEL = 39 2.79 2.84 2.89 BOD33.LEVEL = 48 3.11 3.18 3.20 BOD33.LEVEL = 6 1.61 1.64 1.65 BOD33.LEVEL = 7 1.65 1.67 1.68 BOD33.LEVEL = 39 2.74 2.78 2.80 BOD33.LEVEL = 48 3.04 3.09 3.11 VBOD- / VBOD(2) BOD33 low threshold level - Step size 34 mV VHys Hysteresis (VBOD+ VBOD-) BOD33.LEVEL = 0x0 to 0x3F 30 - 180 mV Tstart Startup time(1) time from enable to RDY - 3.2 - us Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. With BOD33.VREF_SEL = 0 and no hysteresis configured, BOD levels can be given as: VBOD+ = VBOD- = 1.43 + BOD Setting * Step_size Table 47-5. BOD33 Characteristics with BOD33.VREFSEL = 1 Symbol Parameters Conditions Min. Typ. Max. Unit VBOD+ (2) - BOD33.LEVEL = 17 1.62 1.70 1.79 V BOD33.LEVEL = 18 1.65 1.73 1.81 BOD33.LEVEL = 59 2.86 2.96 3.09 BOD33.LEVEL = 63 2.97 3.08 3.20 BOD33.LEVEL = 17 1.59 1.65 1.72 BOD33.LEVEL = 18 1.62 1.68 1.75 BOD33.LEVEL = 59 2.73 2.83 2.94 BOD33.LEVEL = 63 2.83 2.94 3.06 VBOD- / VBOD(2) - © 2020 Microchip Technology Inc. Datasheet V DS60001513F-page 1018 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Symbol Parameters Conditions - Step size VHys Hysteresis (VBOD+ - VBOD-) BOD33.LEVEL = 0x0 to 0x3F Tstart Startup time(1) Min. Typ. Max. Unit 28 30 Time from enable to RDY mV - 150 mV 3.2 - us Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. With BOD33.VREF_SEL = 0 and no hysteresis configured, BOD levels can be given as: Vbod+ = Vbod- = 1.17 + Bod setting * Step_size Table 47-6. Power Consumption (1) Symbo Parameters l Conditions Ta Min. Typ. Max. Units IDD IDLE, Mode CONT VCC = 1.8V - 17.4 21.8 µA - 28.5 37.5 IDLE, Mode SAMPL VCC = 1.8V Max 125°C Typ 25°C - 0.02 0.17 VCC = 3.3V - 0.04 0.13 STANDBY, Mode SAMPL VCC = 1.8V - 0.11 0.17 VCC = 3.3V - 0.23 0.29 VCC = 3.3V Note:  1. These values are based on characterization. They are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1019 SAM L10/L11 Family 125°C Electrical Characteristics 47.4.2 Analog-to-Digital (ADC) Characteristics Table 47-7. Differential Mode (1)(2) Symbol Parameters Conditions ENOB Effective Number of bits Fadc = 1Msps Measurements Min. Typ. Max. Vref = 2.0V Vddana = 3.0V 9.1 10.2 10.8 Vref = 1.0V Vddana = 1.62V to 3.6V 9.0 10.1 10.6 Vref = Vddana = 1.62V to 3.6V 8.9 9.9 11.0 Bandgap Reference, Vddana = 1.62V to 3.6V 9.0 9.8 10.6 Unit bits TUE Total Unadjusted Error without offset and gain compensatio n Vref = Vddana = 1.62V to 3.6V - 7 32 INL Integral Non Linearity without offset and gain compensatio n Vref = Vddana = 1.62V to 3.6V - +/-1.9 +/-4.8 DNL Differential Non Linearity without offset and gain compensatio n Vref = Vddana = 1.62V to 3.6V - +0.94/-1 +1.85/-1 Gain Gain Error without gain Vref = 1V compensatio Vddana = n 1.62V to 3.6V - +/-0.38 +/-1.9 Vref = 3V Vddana = 1.62V to 3.6V - +/-0.14 +/-0.9 Bandgap Reference - +/-0.64 +/-5.4 Vref = Vddana = 1.62V to 3.6V - +/-0.15 +/-0.9 © 2020 Microchip Technology Inc. Datasheet LSB % DS60001513F-page 1020 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Symbol Parameters Conditions Offset Offset Error without offset compensatio n Typ. Max. Vref = 1V Vddana = 1.62V to 3.6V - +/-0.13 +/-15.8 Vref = 3V Vddana = 1.62V to 3.6V - +/-1.82 +/-14.9 Bandgap Reference - +/-2.07 +/-15.8 Vref = Vddana = 1.62V to 3.6V - +/-1.82 +/-15.3 Vref = 2.0V Vddana = 3.0V 58.1 70.5 77.5 56.7 63.4 66.5 Spurious Free Dynamic Range SINAD Signal to Noise and Distortion ratio SNR Signal to Noise ratio 56.5 64.4 67.1 THD Total Harmonic Distortion -74.7 -68.7 -57.7 - 0.42 - External Reference voltage Unit Min. SFDR Noise RMS Fs = 1MHz/Fin = 13 kHz/Full range Input signal Measurements External Reference voltage mV dB mV Notes:  1. These values are given without any ADC oversampling and decimation features enabled. 2. These values are based on characterization, and are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1021 SAM L10/L11 Family 125°C Electrical Characteristics Table 47-8. Single- Ended Mode (1)(2) Symbol Parameters Conditions ENOB Effective Number of bits Fadc = 1Msps Measurements Min. Typ. Max. Vref = 2.0V Vddana = 3.0V 8.0 9.3 9.7 Vref = 1.0V Vddana = 1.62V to 3.6V 7.9 8.2 9.4 Vref = Vddana = 1.62V to 3.6V 8.6 9.2 9.9 Bandgap Reference, Vddana = 1.62V to 3.6V 7.8 8.4 8.9 Unit bits TUE Total Unadjusted Error without Vref = 2.0V offset and Vddana = gain 3.0V compensatio n - 12 66 INL Integral Non Linearity without Vref = 2.0V offset and Vddana = gain 3.0V compensatio n - +/-3.4 +/-9.1 DNL Differential Non Linearity without Vref = 2.0V offset and Vddana = gain 3.0V compensatio n - +0.9/-1 +1.8/-1 Gain Gain Error without gain Vref = 1V compensatio Vddana = n 1.62V to 3.6V - +/-0.3 +/-5.1 Vref = 3V Vddana = 1.62V to 3.6V - +/-0.3 +/-5.1 Bandgap Reference - +/-0.4 +/-5.1 Vref = Vddana = 1.62V to 3.6V - +/-0.2 +/-0.8 © 2020 Microchip Technology Inc. Datasheet LSB % DS60001513F-page 1022 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Symbol Parameters Conditions Offset Offset Error without offset compensatio n Min. Typ. Max. Vref = 1V Vddana = 1.62V to 3.6V - +/-2.6 +/-48 Vref = 3V Vddana = 1.62V to 3.6V - +/-2.6 +/-48 Bandgap Reference - +/-1.3 +/-35 Vref = Vddana = 1.62V to 3.6V - +/-1.8 +/-38 Vref = 2.0V Vddana = 3.0V 56.1 63.8 72.6 50.0 57.7 60.1 SFDR Spurious Free Dynamic Range SINAD Signal to Noise and Distortion ratio SNR Signal to Noise ratio 51.9 58.3 59.8 THD Total Harmonic Distortion -72.5 -62.4 -52.3 - 0.80 - Noise RMS Fs = 1 MHz/Fin = 13 kHz/Full range Input signal Measurements External Reference voltage External Reference voltage Unit mV dB mV Notes:  1. These values are given without any ADC oversampling and decimation features enabled. 2. These values are based on characterization, and are not covered in test limits in production. Figure 47-1. ADC Analog Input AINx The minimum sampling time tsamplehold for a given Rsource can be found using this formula: �samplehold ≥ �sample + �source × �sample × � + 2 × ln 2 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1023 SAM L10/L11 Family 125°C Electrical Characteristics For 12-bit accuracy: 47.4.3 �samplehold ≥ �sample + �source × �sample × 9.7 Digital-to-Analog Converter (DAC) Characteristics Table 47-9. Operating Conditions (1) Symbol Parameters AVREF IDD Min Typ Max Unit External reference voltage 1 - VDDANA-0.6 V Internal reference voltage 1 - 1 - V Internal reference voltage 2 - VDDANA - V Linear output voltage range 0.05 - VDDANA-0.05 V Minimum resistive load 5 - - kOhm Maximum capacitance load - - 100 pF - 175 270 µA DC supply current(2) Conditions Voltage pump disabled Notes:  1. These values are based on simulation otherwise noted. 2. These values are based on characterization. These values are not covered in test limits in production. Table 47-10. Accuracy Characteristics (1)(2) Symbol Parameter RES Input resolution INL Integral non-linearity Conditions Min. Typ. Max. Units - - 10 Bits VDD = 1.62V +/-0,2 +/-0,5 +/-1.4 LSB VDD = 3.63V +/-0,2 +/-0,4 +/-1,2 VDD = 1.62V +/-0,2 +/-0,6 +/-2.1 VDD = 3.63V +/-0,2 +/-0,5 +/-1,9 VDD = 1.62V +/-0,4 +/-0,7 +/-4.2 VDD = 3.63V +/-0,4 +/-0,8 +/-6 VDD = 1.62V +/-0,1 +/-0,3 +/-2 VDD = 3.63V +/-0,1 +/-0,3 +/-1.5 VDD = 1.62V +/-0,1 +-0,2 +/-3.0 VDD = 3.63V +/-0,1 +/-0,2 +/-1.6 VDD = 1.62V +/-0,3 +/-0,6 +/-4.3 VDD = 3.63V +/-0,3 +/-0,8 +/-7 VREF= Ext 1.0V - +/-4 +/-16 mV VREF= VDDANA - +/-12 +/-60 mV VREF= INT1V - +/-1 +/-23 mV VREF= Ext 1.0V - +/-1 +/-13 mV VREF= VDDANA - +/-2.5 +/-32 mV VREF= INT1V - +/-1.5 +/-30 mV VREF= Ext 1.0V VREF = VDDANA VREF= INT1V DNL Differential non-linearity VREF= Ext 1.0V VREF= VDDANA VREF= INT1V Gain error Offset error © 2020 Microchip Technology Inc. Datasheet LSB DS60001513F-page 1024 SAM L10/L11 Family 125°C Electrical Characteristics Notes:  1. All values measured using a conversion rate of 350ksps. 2. These values are based on characterization. They are not covered in test limits in production. 47.4.4 Analog Comparator Characteristics Table 47-11. Electrical and Timing Symbol Parameters Conditions Min. Typ Max. Unit V PNIVR Positive and Negative input range voltage 0 - VDDANA ICMR Input common mode range 0 - VDDANA-0.1 V Off Offset VHys Tpd(1) Tstart(1) Vscale Hysteresis COMPCTRLn.SPEED=0x0 -70 -4.5/+1.5 70 COMPCTRLn.SPEED=0x1 -55 -4.5/+1.5 55 COMPCTRLn.SPEED=0x2 -48 -4.5/+1.5 48 COMPCTRLn.SPEED=0x3 -42 -4.5/+1.5 42 COMPCTRLn.HYST=0x0 10 45 79 COMPCTRLn.HYST=0x1 22 70 115 COMPCTRLn.HYST=0x2 37 90 138 COMPCTRLn.HYST=0x3 49 105 159 4 12.3 0.97 2.6 0.56 1.4 COMPCTRLn.SPEED=0x3 - 0.33 0.77 COMPCTRLn.SPEED=0x0 - 17 71 COMPCTRLn.SPEED=0x1 - 0.85 4.5 COMPCTRLn.SPEED=0x2 - 0.55 3.2 COMPCTRLn.SPEED=0x3 - 0.45 2.7 Propagation Delay COMPCTRLn.SPEED=0x0 Vcm=Vddana/2, Vin= +-100mV overdrive from VCM (Common COMPCTRLn.SPEED=0x1 Mode Voltage) COMPCTRLn.SPEED=0x2 - Start-up time INL - 0.4 - DNL - 0.1 - Offset Error - 0.1 - Gain Error - 1.3 - mV mV µs µs LSB Note:  1. These values are based on characterization. They are not covered in test limits in production. Table 47-12. Power Consumption (1) Symbol Parameters Conditions Ta IDDANA COMPCTRLn.SPEED=0x0, VDDANA=3.3V COMPCTRLn.SPEED=0x1, VDDANA=3.3V Max.125°C Typ.25°C - COMPCTRLn.SPEED=0x2, VDDANA=3.3V - 456 1009 COMPCTRLn.SPEED=0x3, VDDANA=3.3V - 879 1756 VDDANA=3.3V - 13 Current consumption VCM=VDDANA/2, +/-100mV overdrive from VCM, Voltage scaler disabled Current consumption Voltage Scaler only © 2020 Microchip Technology Inc. Datasheet Min. Typ Max. Unit 51 232 nA 233 604 19 DS60001513F-page 1025 µA SAM L10/L11 Family 125°C Electrical Characteristics Note:  1. These values are based on characterization. They are not covered in test limits in production. 47.4.5 DETREF Characteristics Table 47-13. Reference Voltage Characteristics Symbol Parameter Conditions Min. Typ. Max. Units ADC/DAC Ref ADC/DAC internal reference nom. 1.0V, VCC=3.0V, T= 25°C 0.976 1.0 1.022 V nom. 1.1V, VCC=3.0V, T= 25°C 1.077 1.1 1.127 nom. 1.2V, VCC=3.0V, T= 25°C 1.174 1.2 1.234 nom. 1.25V, VCC=3.0V, T= 25°C 1.221 1.25 1.287 nom. 2.0V, VCC=3.0V, T= 25°C 1.945 2.0 2.030 nom. 2.2V, VCC=3.0V, T= 25°C 2.143 2.2 2.242 nom. 2.4V, VCC=3.0V, T= 25°C 2.335 2.4 2.457 nom. 2.5V, VCC=3.0V, T= 25°C 2.428 2.5 2.563 drift over [-40, +25]°C - -0.01/+0.015 - drift over [+25, +125]°C - -0.006/+0.003 - Ref Supply coefficient drift over [1.62, 3.63]V - +/-0.35 - %/V AC Ref Accuracy VCC=3.0V, T=25°C 1.086 1.1 1.128 V Ref Temperature coefficient drift over [-40, +25]°C - +/-0.01 - %/°C drift over [+25, +125]°C - -0.005/+0.001 - %/°C drift over [1.62, 3.63]V - -0.35/+0.35 - %/V Ref Temperature coefficient AC Ref Ref Supply coefficient 47.4.6 %/°C OPAMP Characteristics Table 47-14. Power Consumption(1) Symbol Parameters Conditions Ta IDD Mode 3,VCC =3.3V Max 125°C Typ 25°C - Mode 2,VCC =3.3V DC supply current (Voltage Doubler OFF) Voltage Doubler consumption Min. Typ. Max. Unit 235 415 - 94 173 Mode 1,VCC =3.3V - 26 50 Mode 0 ,VCC =3.3V - 7 14 VCC =3.3V - 0.70 1.5 μA Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. 47.4.7 Peripheral Touch Controller (PTC) Characteristics Power Consumption The values in the Power Consumption table below are measured values of power consumption under the following conditions: Operating Conditions • VDD = 3.3V Clocks • OSC16M divided to 4MHz used as main clock source © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1026 SAM L10/L11 Family 125°C Electrical Characteristics • • • CPU is running on Flash with 0 wait state, at 4MHz PTC Acquisition Clock (FPTC_ACQ) at 4MHz Voltage Regulator mode: LPEFF enabled PTC Configuration • • Mutual-Capacitance mode One touch channel System Configuration • • • • Standby Sleep mode enabled RTC running on OSCULP32K: used to define the PTC scan rate, through the event system Drift Calibration disabled: no interrupts, PTC scans are performed in Standby mode Drift Calibration enabled: RTC interrupts (wake-up) the CPU to perform PTC scans. PTC drift calibration is performed every 1.5 sec. Table 47-15. Power Consumption (1) Symbol Parameters Drift Calibration PTC scan rate (msec) Oversamples Ta 10 50 Disabled 100 200 IDD 4 6.2 16 12.7 300.5 4 2.3 286.1 16 3.7 290.3 4 1.7 286.1 16 2.4 286.2 4 1.4 285.5 1.8 286.2 8.3 293.9 16 Current Consumption 4 10 50 Enabled 100 200 Typ. Max. Max 125°C Typ 25°C Units 292.0 16 14.2 304.9 4 3.0 289.2 16 4.8 290.5 4 2.3 289.2 16 2.8 289.5 4 1.9 287.9 16 2.4 289.0 µA Note:  1. These values are based on characterization. They are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1027 SAM L10/L11 Family 125°C Electrical Characteristics 47.5 47.5.1 Oscillators Characteristics Crystal Oscillator (XOSC) Characteristics Table 47-16. Power Consumption (1) Symbol Parameter Conditions IDD F=2MHz - CL=20pF XOSC,GAIN=0, VCC=3.3V AMPGC=OFF Max 125°C Typ 25°C AMPGC=ON - 66 106 62 107 F=4MHz - CL=20pF XOSC,GAIN=1, VCC=3.3V AMPGC=OFF - 107 164 AMPGC=ON - 70 132 F=8MHz - CL=20pF XOSC,GAIN=2, VCC=3.3V AMPGC=OFF - 200 307 AMPGC=ON - 118 180 F=16MHz - CL=20pF XOSC,GAIN=3, VCC=3.3V AMPGC=OFF - 436 630 AMPGC=ON - 247 382 F=32MHz - CL=20pF XOSC,GAIN=4, VCC=3.3V AMPGC=OFF - 1303 2251 AMPGC=ON - 627 Current consumption Ta Min. Typ. Max. Units µA 1116 Note:  1. These values are based on characterization. They are not covered in test limits in production. 47.5.2 External 32KHz Crystal Oscillator (XOSC32K) Characteristics Table 47-17. Power Consumption(1) Symbol Parameter Conditions Ta Min. Typ. Max. Units IDD Current consumption VCC=3.3V Max 125°C Typ 25°C - 309 767 nA Note:  1. These values are based on characterization. They are not covered in test limits in production. 47.5.3 Ultra Low-Power Internal 32 kHz RC Oscillator (OSCULP32K) Characteristics Table 47-18. Ultra Low-Power Internal 32 kHz RC Oscillator Electrical Characteristics Symbol Parameter Conditions Min. Typ. Max. Units FOUT Output frequency at 25°C, at VDDIO=3.3V 30.84 32.768 34.51 kHz at 25°C, over [1.62, 3.63]V 30.84 32.768 34.74 kHz over[-40,+125]°C, over [1.62, 3.63]V 25.17 32.768 41.76 kHz - 50 - % Duty(1) Duty Cycle Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1028 SAM L10/L11 Family 125°C Electrical Characteristics 47.5.4 16 MHz RC Oscillator (OSC16M) Characteristics Table 47-19. Multi-RC Oscillator Electrical Characteristics Symbol Parameter Conditions Min. Typ. Max. Units FOUT Output frequency VDD=3.3V, T=25°C Calibrated against a 4/8/12/16 MHz reference 3.96 4.00 4.04 MHz 7.92 8.00 8.08 11.88 12.00 12.12 15.84 16.00 16.16 TempDrift Freq vs. temperature drift VDD=3.3V over temperature [-40°C-125°C], versus calibration reference at 25°C -5 5 SupplyDrift Freq vs. supply drift Temperature =25°C over voltage [1.62V-3.63V], versus calibration reference at 3.3V -1.5 1.5 TWUP(2) FOUT = 4MHz - 0.13 0.32 FOUT = 8MHz - 0.13 0.31 FOUT = 12MHz - 0.13 0.31 FOUT = 16MHz - 0.13 0.31 FOUT = 4MHz - 1.16 2.96 FOUT = 8MHz - 1.29 2.74 FOUT = 12MHz - 1.34 2.95 FOUT = 16MHz - 1.39 3.11 - 45 50 55 Wake up time - 1st clock edge after enable TSTARTUP(2) Startup time Duty(1) Duty Cycle Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These values are based on characterization. These values are not covered in test limits in production. Table 47-20. Power Consumption (1) Symbol Parameter Conditions Ta Min. Typ. Max. Units IDD Current consumption Fout=4MHz, VCC=3.3V Max.125°C Typ.25°C - 73 370 µA Fout=8MHz, VCC=3.3V - 106 400 Fout=12MHz, VCC=3.3V - 135 425 Fout=16MHz, VCC=3.3V - 166 455 Note:  1. These values are based on characterization. They are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1029 % µs µs % SAM L10/L11 Family 125°C Electrical Characteristics 47.5.5 Digital Frequency Locked Loop (DFLLULP) Characteristics Table 47-21. Power Consumption(1)(2) Symbol Parameters IDD Conditions Ta Min. Typ. Max Units Current Consumption Fout = 8 MHz (PL0) - VCC = 3.3V Max 125°C Typ 25°C Fout = 32 MHz (PL2) - VCC=3.3V - 33 284 144 458 µA Notes:  1. These characteristics are only applicable in LDO Regulator mode. 2. These values are based on characterization. They are not covered in test limits in production. 47.5.6 Digital Phase Lock Loop (DPLL) Characteristics Table 47-22. Fractional Digital Phase Lock Loop(2) Symbol Parameter Min. Typ. Max. Unit FIN Input Clock Frequency 32 - 2000 kHz FOUT Output Clock Frequency PL2 32 - 96 MHz PL0 32 - 48 MHz PL0, Fin = 32 kHz, Fout = 32 MHz - 3 6 % PL2, = 32 kHz, Fout = 32 MHz - 2 6 PL0, Fin = 32 kHz, Fout = 48 MHz - 3 4 PL2, Fin = 32 kHz, Fout = 48 MHz - 2 6 PL2, Fin = 32 kHz, Fout = 96 MHz - 3 4 PL0, Fin = 32 kHz, Fout = 32 MHz - 3 5 PL2, Fin = 32 kHz, Fout = 32 MHz - 3 6 PL0, Fin = 2 MHz, Fout = 48 MHz - 5 7 PL2, Fin = 2 MHz, Fout = 48 MHz - 3 6 PL2, Fin= 2 MHz, Fout= 96 MHz - 4 10 After startup, time to get lock signal Fin = 32 kHz, Fout = 96 MHz 1.1 1.5 ms After startup, time to get lock signal Fin = 2 MHz, Fout = 96 MHz - 24 35 µs 40 50 60 % Jp tLOCK Duty Period jitter Lock Time Duty cycle (1) Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These characteristics are applicable only in LDO Regulator mode and with a XOSC or XOSC32K reference. Table 47-23. Power Consumption(1)(2) Symbol Parameter Conditions TA Min. Typ. Max. Units IDD Current Consumption Fout = 48 MHz (PL0) - VDD = 3.3V Max. 125°C Typ. 25°C - 339 618 µA - 678 1005 Fout = 96 MHz (PL2) - VDD = 3.3V © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1030 SAM L10/L11 Family 125°C Electrical Characteristics Notes:  1. These characteristics are only applicable in LDO regulator mode. 2. These values are based on characterization. They are not covered in test limits in production. 47.6 Timing Characteristics 47.6.1 SERCOM in SPI Mode in PL0 Table 47-24. SPI Timing Characteristics and Requirements (1) Symbol Parameter Conditions Min. tSCK SCK period when tSOV=0 on the slave side Master Reception tSCKW SCK high/low width time(2) Typ. Max. Units 2*(tMIS+tSLAVE_OUT) - - ns Master Transmission 2*(tMOV+tSLAVE_IN) - - Master - 0,5*tSCK - Master - 0,25*tSCK - (3) (4) tSCKR SCK rise tSCKF SCK fall time(2) Master - 0,25*tSCK - tMIS MISO setup to SCK Master, VDD>2,70V 86 - - Master, VDD>1,62V 95 - - Master, VDD>2,70V 0 - - Master, VDD>1,62V 0 - - MOSI output valid after SCK Master, VDD>2,70V - - 33.3 Master, VDD>1,62V - - 49.6 tMOH MOSI hold after SCK Master, VDD>2,70V 9.7 - - tMOH MOSI hold after SCK Master, VDD>1,62V 9.7 - - tSSCK Slave SCK Period when Slave tMIS=0 on the master side Slave Reception 2*(tSIS +tMASTER_OUT) (5) - - Transmission 2*(tSOV +tMASTER_IN) (6) - - tMIH tMOV MISO hold after SCK tSSCKW SCK high/low width Slave - 0,5*tSCK tSSCKR SCK rise time(2) Slave - 0,25*tSCK - tSSCKF SCK fall time(2) Slave - 0,25*tSCK - tSIS MOSI setup to SCK Slave, VDD>2,70V 24.2 - - Slave, VDD>1,62V 24.9 - - Slave, VDD>2,70V 12.9 - - Slave, VDD>1,62V 13.5 - - tSIH MOSI hold after SCK © 2020 Microchip Technology Inc. Datasheet ns DS60001513F-page 1031 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Symbol Parameter Conditions tSSS SS setup to SCK Slave Min. Typ. Max. Units PRELOADEN=1 tSOSS+tEXT_MIS +2*tAPBC (8) (9) - - ns PRELOADEN=0 tSOSS+tEXT_MIS (8) - - tSSH SS hold after SCK Slave 0.5*tSSCK - - tSOV MISO output valid after SCK Slave, VDD>2,70V - - 66.9 Slave, VDD>1,62V - - 76.6 MISO hold after SCK Slave, VDD>2,70V 22.7 - - Slave, VDD>1,62V 20.3 - - MISO setup after SS low Slave, VDD>2,70V - - 1* tSCK Slave, VDD>1,62V - - 1* tSCK MISO hold after SS high Slave, VDD>2,70V 15 - - Slave, VDD>1,62V 15 - - tSOH tSOSS tSOSH Notes:  1. These values are based on simulation. These values are not covered by test limits in production. 2. See I/O Pin Characteristics. 3. Where tSLAVE_OUT is the slave external device output response time, generally tEXT_SOV+tLINE_DELAY (See Note 7). 4. Where tSLAVE_IN is the slave external device input constraint, generally tEXT_SIS+tLINE_DELAY (See Note 7). 5. Where tMASTER_OUT is the master external device output response time, generally tEXT_MOV +tLINE_DELAY (See Note 7). 6. Where tMASTER_IN is the master external device input constraint, generally tEXT_MIS+tLINE_DELAY (See Note 7). 7. tLINE_DELAY is the transmission line time delay. 8. tEXT_MIS is the input constraint for the master external device. 9. tAPBC is the APB period for SERCOM. Figure 47-2. SPI Timing Requirements in Master Mode SS tSSCKF tSSCKR SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSB LSB tMOV tMOH tMOH MOSI (Data Output) © 2020 Microchip Technology Inc. MSB LSB Datasheet DS60001513F-page 1032 SAM L10/L11 Family 125°C Electrical Characteristics Figure 47-3. SPI Timing Requirements in Slave Mode SS tSSS tSSCKF tSSCKR tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS tSIH MOSI (Data Input) tSSCK MSB LSB tSOSH tSOSS tSOV MISO (Data Output) tSOH MSB LSB Maximum SPI Frequency • Master mode: fSCKmax = 1/2*(tMIS + tSLAVE_OUT) • Slave mode: fSCKmax = 1/2*(tSOV + tMASTER_IN) 47.6.2 SERCOM in SPI Mode in PL2 Table 47-25. SPI Timing Characteristics and Requirements (1) Symbol Parameter tSCK SCK period when Master tSOV=0 on the slave side Master tSCKW SCK high/low width time(2) Conditions Min. Typ. Max. Units Reception 2*(tMIS +tSLAVE_OUT) (3) - - ns Transmission 2*(tMOV +tSLAVE_IN) (4) - - Master - 0,5*tSCK - Master - 0,25*tSCK - tSCKR SCK rise tSCKF SCK fall time(2) Master - 0,25*tSCK - tMIS MISO setup to SCK Master, VDD>2,70V 43.8 - - Master, VDD>1,62V 54.1 - - © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1033 SAM L10/L11 Family 125°C Electrical Characteristics ...........continued Symbol Parameter Conditions Min. Typ. Max. Units tMIH MISO hold after SCK Master, VDD>2,70V 0 - - ns Master, VDD>1,62V 0 - - MOSI output valid after SCK Master, VDD>2,70V - - 17.5 Master, VDD>1,62V - - 21.2 MOSI hold after SCK Master, VDD>2,70V 6.32 - - Master, VDD>1,62V 6.32 - - Slave SCK Period when tMIS=0 on the master side Slave Reception 2*(tSIS +tMASTER_OUT) (5) - - Slave Transmission 2*(tSOV +tMASTER_IN) (6) - - tMOV tMOH tSSCK tSSCKW SCK high/low width Slave - 0,5*tSCK tSSCKR SCK rise time(2) Slave - 0,25*tSCK - tSSCKF SCK fall time(2) Slave - 0,25*tSCK - tSIS MOSI setup to SCK Slave, VDD>2,70V 10.7 - - Slave, VDD>1,62V 11.4 - - MOSI hold after SCK Slave, VDD>2,70V 6.4 - - Slave, VDD>1,62V 7.1 - - SS setup to SCK Slave - - PRELOADEN=0 tSOSS+tEXT_MIS (8) - - tSIH tSSS PRELOADEN=1 tSOSS+tEXT_MIS +2*tAPBC (8) (9) tSSH SS hold after SCK Slave 0.5*tSSCK - - tSOV MISO output valid after SCK Slave, VDD>2,70V - - 36.1 Slave, VDD>1,62V - - 46.4 MISO hold after SCK Slave, VDD>2,70V 13.4 - - Slave, VDD>1,62V 13.4 - - - 1* tSCK - 1* tSCK tSOH tSOSS tSOSH MISO setup after SS Slave, VDD>2,70V low Slave, VDD>1,62V MISO hold after SS high © 2020 Microchip Technology Inc. Slave, VDD>2,70V 8.7 - - Slave, VDD>1,62V 8.7 - - Datasheet ns DS60001513F-page 1034 SAM L10/L11 Family 125°C Electrical Characteristics Notes:  1. These values are based on simulation. These values are not covered by test limits in production. 2. See I/O Pin Characteristics. 3. Where tSLAVE_OUT is the slave external device output response time, generally tEXT_SOV+tLINE_DELAY (See Note 7). 4. Where tSLAVE_IN is the slave external device input constraint, generally tEXT_SIS+tLINE_DELAY (See Note 7). 5. Where tMASTER_OUT is the master external device output response time, generally tEXT_MOV +tLINE_DELAY (See Note 7). 6. Where tMASTER_IN is the master external device input constraint, generally tEXT_MIS+tLINE_DELAY (See Note 7). 7. tLINE_DELAY is the transmission line time delay. 8. tEXT_MIS is the input constraint for the master external device. 9. tAPBC is the APB period for SERCOM. Figure 47-4. SPI Timing Requirements in Master Mode SS tSSCKF tSSCKR SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSB LSB tMOV tMOH tMOH MOSI (Data Output) MSB LSB Figure 47-5. SPI Timing Requirements in Slave Mode SS tSSS tSSCKF tSSCKR tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS MOSI (Data Input) tSIH MSB LSB tSOSH tSOSS MISO (Data Output) tSSCK tSOV tSOH MSB LSB Maximum SPI Frequency • Master Mode fSCKmax = 1/2*(tMIS + tSLAVE_OUT) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1035 SAM L10/L11 Family 125°C Electrical Characteristics • Slave Mode fSCKmax = 1/2*(tSOV + tMASTER_IN) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1036 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48. AEC-Q100 Grade (-40°C to 125°C) Electrical Characteristics This section provides an overview of the SAM L10 and SAM L11 electrical characteristics which are specific for devices qualified for AEC-Q100 Grade 1 (-40°C to 125°C). For all other values or other characteristics, refer to Electrical Characteristics. 48.1 Disclaimer All typical values are measured at T = 25°C unless otherwise specified. All minimum and maximum values are valid across operating temperature and voltage unless otherwise specified. 48.2 General Operating Ratings The device must operate within the ratings listed in the following table for all other electrical characteristics and typical characteristics of the device to be valid. Table 48-1. General Operating Conditions 48.3 Symbol Description Min. Typ. Max. Units VDDIO I/O supply voltage 1.8 3.3 3.63 V VDDANA Analog supply voltage 1.8 3.3 3.63 V TA Temperature range -40 25 125 °C TJ Junction temperature - - 145 °C Supply Characteristics Table 48-2. Supply Characteristics Symbol 48.4 Voltage Min. Max. Units VDDIO 1.8 3.63 V VDDANA 1.8 3.63 V Power Consumption The values in this section are measured values of power consumption under the following conditions, except where noted: • Operating Conditions – VDDIO = 3.3V or 1.8V – CPU is running on Flash with required Wait states, as recommended in the NVM Characteristics section. – Low-power cache is enabled – BOD33 is disabled – I/Os are configured with digital input trigger disabled (default Reset configuration) • Oscillators – XOSC (crystal oscillator) stopped – XOSC32K (32.768 kHz crystal oscillator) running with external 32.768 kHz crystal – When in active PL2 mode on FDPLL96M at 32 MHZ, DPLL is using XOSC32K as reference clock and running at 32 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1037 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... – When in Active mode on DFLLULP, the DFLLULP is configured in Closed Loop mode using XOSC32K as reference clock and MCLK.CTRLA.CKSEL = 1 Table 48-3. Active Current Consumption Mode Conditions Regulator PL CPU Clock Vcc Ta Typ. Max. 1.8V 64.1 129 3.3V 64.4 131 1.8V 66.6 130 3.3V 70.3 132 1.8V 74.1 203 3.3V 77.8 206 1.8V 82.0 98 3.3V 82.5 99 1.8V 75.8 109 3.3V 75.8 107 1.8V 44 103 3.3V 29.9 69 1.8V 43.8 84 3.3V 32.1 58 50.3 131 3.3V 38.9 92 1.8V 59.9 70 3.3V 35.3 43 1.8V 55.8 80 3.3V 33.7 48 1.8V 44.3 110 3.3V 44.4 111 1.8V 47.6 111 3.3V 50.1 113 1.8V 54.6 184 3.3V 57.7 187 1.8V 56.9 79 3.3V 57.2 80 1.8V 50.8 72 3.3V 51.0 72 Units DFLLUP at 8 MHz PL0 LDO OSC 8 MHz OSC 4 MHz FDPLL96 at 32 MHz PL2 DFLLULP at 32 MHz COREMARK/FIBONACCI DFLLUP at 4.88 MHz PL0 OSC 8 MHz 1.8V OSC 4 MHz BUCK ACTIVE Max. at 125°C, Typ. at 25°C uA/MHz FDPLL96 at 32 MHz PL2 DFLLULP at 26.78 MHz DFLLUP at 8 MHz PL0 WHILE1 LDO OSC 8 MHz OSC 4 MHz FDPLL96 at 32 MHz PL2 DFLLULP at 32 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1038 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Mode Conditions Regulator PL CPU Clock Vcc Ta Typ. Max. 1.8V 32.4 90 3.3V 22.8 62 1.8V 32.2 73 3.3V 25.3 51 1.8V 38.4 121 3.3V 31.9 86 1.8V 41.5 55 3.3V 24.6 34 1.8V 38.3 58 3.3V 23.1 36 1.8V 16.0 81 3.3V 16.2 82 1.8V 19.8 82 3.3V 22.0 85 26.2 152 3.3V 29.2 157 1.8V 20.3 54 3.3V 20.4 54 1.8V 14.3 32 3.3V 14.4 33 1.8V 15.1 68 3.3V 12.3 48 1.8V 15.5 55 3.3V 15.2 40 1.8V 21.3 100 3.3V 21.6 73 1.8V 14.9 30 3.3V 9.1 19 1.8V 11.2 26 3.3V 7.2 17 Units DFLLUP at 4.88 MHz WHILE1 PL0 ACTIVE BUCK OSC 8 MHz OSC 4 MHz WHILE1 FDPLL96 at 32 MHz PL2 DFLLULP at 26.78 MHz DFLLUP at 8 MHz PL0 OSC 8 MHz 1.8V LDO OSC 4 MHz Max. at 125°C, Typ. at 25°C uA/MHz FDPLL96 at 32 MHz PL2 DFLLULP at 32 MHz IDLE -DFLLUP at 4.88 MHz PL0 BUCK OSC 8 MHz OSC 4 MHz FDPLL96 at 32 MHz PL2 DFLLULP at 26.78 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1039 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-4. Standby and Off Mode Current Consumption Mode Conditions Regulator Mode Vcc LPEFF Disable 1,8V LPEFF Enable Ta Typ. Max. 25°C 1.3 3.5 125°C 121.7 304.8 25°C 1.1 3.0 125°C 74.5 282.6 25°C 1.2 2.9 125°C 78.0 188.7 25°C 1.1 2.2 125°C 50.9 122.9 25°C 0.6 1.1 125°C 27.1 81.0 25°C 0.5 1.0 125°C 23.1 52.8 25°C 0.8 1.1 125°C 23.0 53.7 25°C 0.8 1.5 125°C 17.3 37.6 25°C 0.6 1.1 125°C 25.5 73.7 25°C 0.5 1.0 125°C 21.6 48.8 25°C 0.7 1.1 125°C 21.5 50.5 25°C 0.8 1.5 125°C 16.4 35.4 25°C 0.5 1.0 125°C 23.8 67.1 25°C 0.5 0.9 125°C 20.2 45.4 25°C 0.7 1.0 125°C 19.9 46.5 25°C 0.7 1.4 125°C 15.5 33.2 Units 3,3V All 16kB RAM retained, PDSW domain in active state BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) LPEFF Disable LPEFF Enable STANDBY 1,8V 3,3V 1,8V 3,3V All 16kB RAM retained, PDSW domain in retention µA BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) LPEFF Disable LPEFF Enable 1,8V 3,3V 1,8V 3,3V 12 kB RAM retained, PDSW domain in retention Buck in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) LPEFF Disable LPEFF Enable STANDBY 1,8V 3,3V 1,8V 3,3V 8kB RAM retained, PDSW domain in retention µA BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) © 2020 Microchip Technology Inc. Datasheet 1,8V 3,3V DS60001513F-page 1040 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Mode Conditions Regulator Mode Vcc LPEFF Disable 1,8V LPEFF Enable Ta Typ. Max. 25°C 0.5 0.9 125°C 22.0 58.9 25°C 0.5 0.9 125°C 18.7 41.5 25°C 0.7 1.0 125°C 18.4 42.7 25°C 0.8 1.5 125°C 14.6 31.0 25°C 0.9 1.3 125°C 22.6 59.8 25°C 0.8 1.2 125°C 19.3 42.1 25°C 1.0 1.3 125°C 19.0 43.3 25°C 1.1 1.7 125°C 15.2 31.6 25°C 34.6 54.4 Units 3,3V 4kB RAM retained, PDSW domain in retention 1,8V BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) 3,3V STANDBY μA LPEFF Disable 1,8V LPEFF Enable 3,3V 4kB RAM retained, PDSW domain in retention and RTC running on XOSC32k 1,8V BUCK in standby PL0 (VREG.RUNSTDBY=1 and VREG.STDBYPL0=1) 3,3V 1,8V 125°C 4385.0 8291.5 OFF nA 25°C 61.2 89.1 3,3V 125°C 5489.5 10564.7 48.5 I/O Pin Characteristics The following are two I/O pin types with three different speeds: Normal and High Sink. The Drive Strength bit is located in the Pin Configuration register of the PORT (PORT.PINCFG.DRVSTR). Table 48-5. I/O Pins Common Characteristics Symbol Parameter Conditions Min. Typ. Max. Units VIL Input low-level voltage VDD=1.8V-2.7V - - 0.25*VDD V VDD=2.7V-3.63V - - 0.3*VDD VDD=1.8V-2.7V 0.7*VDD - - VDD=2.7V-3.63V 0.55*VDD - - VIH Input high-level voltage VOL Output low-level voltage VDD>1.8V, IOL max. - 0.1*VDD 0.2*VDD VOH Output high-level voltage VDD>1.8V, IOH max. 0.7*VDD 0.8*VDD - RPULL Pull-up - Pull-down resistance 20 40 63 kΩ ILEAK Input leakage current -1 ±0.015 1 µA © 2020 Microchip Technology Inc. Pull-up resistors disabled Datasheet DS60001513F-page 1041 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-6. I/O Pins Maximum Output Current Symbol Parameter Conditions Normal Pins High Sink Pins(1) Normal Pins DRVSTR=0 IOL IOH Maximum Output low-level current Maximum Output high-level current High Sink Pins(1) Units DRVSTR=1 VDD=1.8V-3V 1 2 2 4 VDD=3V-3.63V 2.5 6 6 12 VDD=1.8V-3V 0.7 1.5 1.5 3 VDD=3V-3.63V 2 5 5 10 mA Note:  1. The following pins are High Sink pins and have different properties than the normal pins: PA16, PA17, PA22, PA23, and PA31. 48.6 48.6.1 Analog Characteristics Brown-Out Detectors (BOD) Characteristics Table 48-7. BOD33 Characteristics with BOD33.VREFSEL = 0 Symbol VBOD+ (2) VBOD- / VBOD (2) Parameters Conditions BOD33 high-threshold level BOD33 low-threshold Level - Step size VHys Hysteresis (VBOD+ - VBOD-) BOD33.LEVEL = 0x0 to 0x3F Tstart Startup time (1) Min. Typ. Max. Unit BOD33.LEVEL = 8 1.74 1.76 1.78 V BOD33.LEVEL = 9 1.77 1.79 1.81 V BOD33.LEVEL = 39 2.79 2.84 2.89 V BOD33.LEVEL = 48 3.11 3.18 3.20 V BOD33.LEVEL = 8 1.67 1.70 1.71 V BOD33.LEVEL = 9 1.71 1.74 1.75 V BOD33.LEVEL = 39 2.74 2.78 2.80 V BOD33.LEVEL = 48 3.04 3.09 3.11 V 34 mV time from enable to RDY 30 - 180 mV - 3.2 - us Notes:  1. The values are based on simulation, and are not covered by test or characterization. 2. With BOD33.VREFSEL = 0 and no hysteresis configured, BOD levels can be given as: Vbod+=Vbod-=1.43+Bod setting*Step_size. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1042 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-8. BOD33 Characteristics with BOD33.VREFSEL = 1 Symbol Parameters Conditions VBOD+ (2) VBOD- / VBOD (2) - Step size VHys Hysteresis (VBOD+ - VBOD-) BOD33.LEVEL = 0x0 to 0x3F Tstart Startup time (1) Min. Typ. Max. Unit BOD33.LEVEL = 19 1.68 1.75 1.85 V BOD33.LEVEL = 20 1.71 1.78 1.88 V BOD33.LEVEL = 59 2.86 2.96 3.09 V BOD33.LEVEL = 63 2.97 3.08 3.20 V BOD33.LEVEL = 19 1.64 1.70 1.78 V BOD33.LEVEL = 20 1.67 1.74 1.81 V BOD33.LEVEL = 59 2.73 2.83 2.94 V BOD33.LEVEL = 63 2.83 2.94 3.06 V 28 mV time from enable to RDY 30 - 150 mV - 3.2 - us Notes:  1. These are based on simulation. These values are not covered by test or characterization. 2. With BOD33.VREFSEL = 1 and no hysteresis configured, BOD levels can be given as: Vbod+=Vbod-=1.17+Bod setting*Step_size. Table 48-9. Power Consumption (1) Symbol Parameters IDLE, Mode CONT IDD Idle, Mode SAMPL Stand-by, Mode SAMPL Conditions Min. Typ. Max. VCC = 1.8V - 17.4 21.8 VCC = 3.3V - 28.5 37.5 - 0.02 0.17 - 0.04 0.13 VCC = 1.8V - 0.11 0.17 VCC = 3.3V - 0.23 0.29 VCC = 1.8V VCC = 3.3V Ta Max. 125°C, Typ. 25°C Units µA Note:  1. These values are based on characterization, and are not covered by the test. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1043 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48.6.2 Analog-to-Digital Converter (ADC) Characteristics Table 48-10. Differential Mode (1,2) Symbol Parameters ENOB Effective Number of bits Measurements Conditions Fadc = 1Msps Min. Typ. Max. Vref=2.0V Vddana=3.0 V 9.1 10.2 10.8 Vref=1.0V Vddana=1.8 V to 3.6V 9.0 10.1 10.6 Vref=Vddan a=1.8V to 3.6V 8.9 9.9 11.0 Bandgap Reference, Vddana=1.8 V to 3.6V 9.0 9.8 10.6 TUE Total Unadjusted Error without offset and gain compensatio n Vref=Vddan a=1.8V to 3.6V - 7 38 INL Integral Non Linearity without offset and gain compensatio n Vref=Vddan a=1.8V to 3.6V - +/-1.9 +/-4.8 DNL Differential Non Linearity without offset and gain compensatio n Vref=Vddan a=1.8V to 3.6V - +0.94/-1 +1.85/-1 Gain Gain Error without gain Vref=1V compensatio Vddana=1.8 n V to 3.6V - +/-0.38 +/-2.2 Vref=3V Vddana=1.8 V to 3.6V - +/-0.14 +/-1 Bandgap Reference - +/-0.64 +/-6.6 Vref=Vddan a=1.8V to 3.6V - +/-0.15 +/-1 © 2020 Microchip Technology Inc. Datasheet Unit bits LSB % DS60001513F-page 1044 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Measurements Symbol Parameters Conditions Offset Offset Error without Vref=1V offset Vddana=1.8 compensatio V to 3.6V n Vref=3V Vddana=1.8 V to 3.6V Typ. Max. - +/-0.13 +/-19.5 - +/-1.82 +/-18.3 Bandgap Reference - +/-2.07 +/-19.4 Vref=Vddan a=1.8V to 3.6V - +/-1.82 +/-18.6 Vref=2.0V Vddana=3.0 V 58.1 70.5 77.5 56.7 63.4 66.5 SFDR Spurious Free Dynamic Range SINAD Signal-toNoise and Distortion ratio SNR Signal-toNoise ratio 56.5 64.4 67.1 THD Total Harmonic Distortion -74.7 -68.7 -57.7 - 0.42 - Noise RMS Fs = 1MHz / Fin = 13 kHz / Full range Input signal Min. External Reference voltage External Reference voltage Unit mV dB mV Notes:  1. These values are given without any ADC oversampling and decimation features enabled. 2. These values are based on characterization, and are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1045 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-11. Single- Ended Mode (1)(2) Symbol Parameters ENOB Effective Number of bits Measurements Conditions Fadc = 1Msps Min. Typ. Max. Vref=2.0V Vddana=3.0 V 8.0 9.3 9.7 Vref=1.0V Vddana=1.8 V to 3.6V 7.9 8.2 9.4 Vref=Vddan a=1.8V to 3.6V 8.6 9.2 9.9 Bandgap Reference, Vddana=1.8 V to 3.6V 7.8 8.4 8.9 TUE Total Unadjusted Error without Vref=2.0V offset and Vddana=3.0 gain V compensatio n - 12 77 INL Integral Non Linearity without Vref=2.0V offset and Vddana=3.0 gain V compensatio n - +/-3.4 +/-9.1 DNL Differential Non Linearity without Vref=2.0V offset and Vddana=3.0 gain V compensatio n - +0.9/-1 +1.8/-1 Gain Gain Error without gain Vref=1V compensatio Vddana=1.8 n V to 3.6V - +/-0.3 +/-6.3 Vref=3V Vddana=1.8 V to 3.6V - +/-0.3 +/-6.3 Bandgap Reference - +/-0.4 +/-6.3 Vref=Vddan a=1.8V to 3.6V - +/-0.2 +/-0.9 © 2020 Microchip Technology Inc. Datasheet Unit bits LSB % DS60001513F-page 1046 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Measurements Symbol Parameters Conditions Offset Offset Error without Vref=1V offset Vddana=1.8 compensatio V to 3.6V n Vref=3V Vddana=1.8 V to 3.6V Min. Typ. Max. - +/-2.6 +/-58 - +/-2.6 +/-58 Bandgap Reference - +/-1.3 +/-42.4 Vref=Vddan a=1.8V to 3.6V - +/-1.8 +/-46.6 56.1 63.8 72.6 50.0 57.7 60.1 SFDR Spurious Free Dynamic Range SINAD Signal-toNoise and Distortion ratio SNR Signal-toNoise ratio 51.9 58.3 59.8 THD Total Harmonic Distortion -72.5 -62.4 -52.3 - 0.80 - Noise RMS Fs = 1 MHz / Vref=2.0V Fin = 13 Vddana=3.0 kHz / Full V range Input signal External Reference voltage External Reference voltage Unit mV dB mV Notes:  1. These values are given without any ADC oversampling and decimation features enabled. 2. These values are based on characterization, and are not covered in the test limits in production. Figure 48-1. ADC Analog Input AINx The minimum sampling time tsamplehold for a given Rsource can be calculated using the following formula: �samplehold ≥ �sample + �source × �sample × � + 2 × ln 2 For 12-bit accuracy: �samplehold ≥ �sample + �source × �sample × 9.7 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1047 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48.6.3 Digital-to-Analog Converter (DAC) Characteristics Table 48-12. Operating Conditions (1) Symbol Parameters AVREF IDD Conditions Min. Typ. Max. Unit External reference voltage 1 - VDDANA-0.6 V Internal reference voltage 1 - 1 - V Internal reference voltage 2 - VDDANA - V Linear output voltage range 0.05 - VDDANA-0.05 V Minimum resistive load 5 - - kOhm Maximum capacitance load - - 100 pF - 175 290 µA DC supply current(2) Voltage pump disabled Notes:  1. These values are based on simulation otherwise noted. 2. These values are based on characterization, and are not covered in test limits in production. Table 48-13. Accuracy Characteristics (1,2) Symbol Parameter RES Input resolution INL Integral non-linearity Conditions Min. Typ. Max. Units - - 10 Bits VDD = 1.8V +/-0,2 +/-0,5 +/-1.4 LSB VDD = 3.63V +/-0,2 +/-0,4 +/-1,2 VDD = 1.8V +/-0,2 +/-0,6 +/-2.1 VDD = 3.63V +/-0,2 +/-0,5 +/-1,9 VDD = 1.8V +/-0,4 +/-0,7 +/-4.2 VDD = 3.63V +/-0,4 +/-0,8 +/-6 VDD = 1.8V +/-0,1 +/-0,3 +/-2 VDD = 3.63V +/-0,1 +/-0,3 +/-1.5 VDD = 1.8V +/-0,1 +/-0,2 +/-3.0 VDD = 3.63V +/-0,1 +/-0,2 +/-1.6 VDD = 1.8V +/-0,3 +/-0,6 +/-4.3 VDD = 3.63V +/-0,3 +/-0,8 +/-7 VREF= Ext 1.0V - +/-4 +/-16 mV VREF= VDDANA - +/-12 +/-60 mV VREF= INT1V - +/-1 +/-23 mV VREF= Ext 1.0V - +/-1 +/-13 mV VREF= VDDANA - +/-2.5 +/-32 mV VREF= INT1V - +/-1.5 +/-30 mV VREF= Ext 1.0V VREF = VDDANA VREF= INT1V DNL Differential non-linearity VREF= Ext 1.0V VREF= VDDANA VREF= INT1V Gain error Offset error LSB Notes:  1. All values are measured using a conversion rate of 350 ksps. 2. These values are based on characterization, and are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1048 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48.6.4 Analog Comparator Characteristics Table 48-14. Electrical and Timing Symbol Parameters PNIVR Min. Typ. Max. Unit Positive and Negative input range voltage 0 - VDDANA V ICMR Input common mode range 0 - VDDANA-0.1 V Off Offset COMPCTRLn.SPEED=0x0 -70 -4.5/+1.5 70 mV COMPCTRLn.SPEED=0x1 -55 -4.5/+1.5 55 COMPCTRLn.SPEED=0x2 -48 -4.5/+1.5 48 COMPCTRLn.SPEED=0x3 -42 -4.5/+1.5 42 VHys Tpd(1) Tstart(1) Hysteresis Conditions COMPCTRLn.HYST=0x0 10 45 84 COMPCTRLn.HYST=0x1 22 70 120 COMPCTRLn.HYST=0x2 37 90 142 COMPCTRLn.HYST=0x3 49 105 164 Propagation Delay COMPCTRLn.SPEED=0x0 Vcm=Vddana/2, Vin= +-100mV overdrive from VCM (Common COMPCTRLn.SPEED=0x1 Mode Voltage) COMPCTRLn.SPEED=0x2 - 4 13.8 - 0.97 2.9 - 0.56 1.6 COMPCTRLn.SPEED=0x3 - 0.33 0.84 COMPCTRLn.SPEED=0x0 - 17 81 COMPCTRLn.SPEED=0x1 - 0.85 4.7 COMPCTRLn.SPEED=0x2 - 0.55 3.2 COMPCTRLn.SPEED=0x3 - 0.45 2.7 INL - 0.4 - DNL - 0.1 - Offset Error - 0.1 - Gain Error - 1.3 - Start-up time Vscale mV µs µs LSB Note:  1. These values are based on characterization, and are not covered in test limits in the production. Table 48-15. Power Consumption (1) Symbol Parameters IDDANA Current consumption VCM=VDDANA/2, +/-100mV overdrive from VCM, Voltage scaler disabled Current consumption Voltage Scaler only Conditions Ta Min. Typ Max. Unit COMPCTRLn.SPEED=0x0, VDDANA=3.3V Max.125°C Typ. 25°C COMPCTRLn.SPEED=0x1, VDDANA=3.3V - 51 232 - 233 604 COMPCTRLn.SPEED=0x2, VDDANA=3.3V - 456 1009 COMPCTRLn.SPEED=0x3, VDDANA=3.3V - 879 1756 VDDANA=3.3V - 13 19 Note:  1. These values are based on characterization, and are not covered in test limits in the production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1049 nA µA SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48.6.5 DETREF Characteristics Table 48-16. Reference Voltage Characteristics Symbol Parameter Conditions Min. Typ. Max. nom. 1.0V, VCC=3.0V, T= 25°C 0.976 1.0 1.022 nom. 1.1V, VCC=3.0V, T= 25°C 1.077 1.1 1.127 nom. 1.2V, VCC=3.0V, T= 25°C 1.174 1.2 1.234 nom. 1.25V, VCC=3.0V, T= 25°C 1.221 1.25 1.287 nom. 2.0V, VCC=3.0V, T= 25°C 1.945 2.0 2.030 nom. 2.2V, VCC=3.0V, T= 25°C 2.143 2.2 2.242 nom. 2.4V, VCC=3.0V, T= 25°C 2.335 2.4 2.457 nom. 2.5V, VCC=3.0V, T= 25°C 2.428 2.5 2.563 drift over [-40, +25]°C - -0.01/+0.015 - drift over [+25, +125]°C - -0.006/+0.003 - Ref Supply coefficient drift over [1.8, 3.63]V - +/-0.35 - %/V AC Ref Accuracy VCC=3.0V, T=25°C 1.086 1.1 1.128 V drift over [-40, +25]°C - +/-0.01 - %/°C drift over [+25, +125]°C - -0.005/+0.001 - %/°C drift over [1.8, 3.63]V - -0.35/+0.35 - %/V ADC/DAC internal reference ADC/DAC Ref Ref Temperature coefficient AC Ref Ref Temperature coefficient Ref Supply coefficient 48.6.6 Units V %/°C OPAMP Characteristics Table 48-17. Operating Conditions Symbol Parameters Conditions Min. Typ. Max. Unit VCC Power Supply All power modes 1.8 3 3.63 V Vin Input voltage range 0 - Vcc V Vout Output voltage range 0.15 - Vcc-0.15 V Cload Maximum capacitance load - - 50 pF Rload (1) Minimum resistive load Output Range[0.15V;Vcc-0.15V] 3.5 - - kΩ Output Range[0.3V;Vcc-0.3V] 0.5 - - Output Range[0.15V;Vcc-0.15V] - - 1 Output Range[0.3V;Vcc-0.3V] - - 6.9 Iload (1) DC output current load Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1050 mA SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-18. Power Consumption(1) Symbol Parameters Conditions Ta IDD Mode 3,VCC =3.3V Max 125°C Typ 25°C - Mode 2,VCC =3.3V DC supply current (Voltage Doubler OFF) Voltage Doubler consumption Min. Typ. Max. Unit 235 415 - 94 173 Mode 1,VCC =3.3V - 26 50 Mode 0 ,VCC =3.3V - 7 14 VCC =3.3V - 0.70 1.5 μA Note:  1. These values are based on simulation. They are not covered by production test limits or characterization. 48.6.7 Peripheral Touch Controller (PTC) Characteristics Power Consumption The values provided in the table below are measured values of power consumption, and the values are based on these conditions: Operating Conditions • VDD = 3.3V Clocks • • • • OSC16M divided to 4 MHz used as main clock source CPU is running on Flash with 0 wait state, at 4 MHz PTC Acquisition Clock (FPTC_ACQ) at 4 MHz Voltage Regulator mode: LPEFF-enabled PTC Configuration • • Mutual-Capacitance mode One touch channel System Configuration • • • • Standby Sleep mode enabled RTC running on OSCULP32K: used to define the PTC scan rate, through the event system Drift Calibration disabled: no interrupts, PTC scans are performed in Standby mode Drift Calibration enabled: RTC interrupts (wake up) the CPU to perform PTC scans. PTC drift calibration is performed every 1.5 seconds. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1051 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-19. Power Consumption (1) Symbol Parameters Drift Calibration PTC scan rate (msec) Oversamples Ta 10 50 Disabled 100 200 IDD 4 6.2 16 12.7 300.5 4 2.3 286.1 16 3.7 290.3 4 1.7 286.1 16 2.4 286.2 4 1.4 285.5 1.8 286.2 8.3 293.9 16 Current Consumption 4 10 50 Enabled 100 200 Typ. Max. Max 125°C, Typ 25°C Units 292.0 16 14.2 304.9 4 3.0 289.2 16 4.8 290.5 4 2.3 289.2 16 2.8 289.5 4 1.9 287.9 16 2.4 289.0 µA Note:  1. These values are based on characterization, and are not covered in test limits in the production. 48.7 NVM Characteristics Table 48-20. NVM Maximum Speed Characteristics (1) Conditions PL0 (-40/85°C) (-40/125°C) PL2 (-40/85°C) (-40/125°C) CPU Fmax (MHz) 0WS 1WS 2WS VDDIO>1.8 V 6 8 8 VDDIO>2.7 V 7.5 8 8 VDDIO>1.8 V 14 28 32 VDDIO>2.7 V 14 32 32 Note:  1. An endurance cycle is a write and an erase operation. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1052 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Table 48-21. Flash Erase and Programming Current Symbol Parameter Typ. Units IDDNVM Maximum current (peak) during whole programming or erase operation 10 mA Table 48-22. NVM Reliability Characteristics (1) Symbol Parameter Conditions Min. Typ. Units RetNVM25k Retention after up to 25k Average ambient 55°C 10 50 Years RetNVM2.5k Retention after up to 2.5k Average ambient 55°C 20 100 Years RetNVM100 Retention after up to 100 Average ambient 55°C 25 >100 Years -40°C < Ta < 85°C -40°C < Ta < 125°C 25K 100K Cycles 50 100 Cycles CycNVM Cycling Endurance(2) Cycling Endurance using Tamper Erase Notes:  1. Reliability characteristics are given when not using tamper erase operations except if noted. 2. An endurance cycle is a write and an erase operation. 48.8 Oscillators Characteristics 48.8.1 Crystal Oscillator (XOSC) Characteristics Table 48-23. Power Consumption (1) Symbol Parameter Conditions IDD F=2 MHz - CL=20 pF XOSC,GAIN=0, VCC=3.3V AMPGC=OFF Max 125°C, Typ 25°C AMPGC=ON - 66 106 62 107 F=4 MHz - CL=20 pF XOSC,GAIN=1, VCC=3.3V AMPGC=OFF - 107 164 AMPGC=ON - 70 132 F=8 MHz - CL=20 pF XOSC,GAIN=2, VCC=3.3V AMPGC=OFF - 200 307 AMPGC=ON - 118 180 F=16 MHz - CL=20 pF XOSC,GAIN=3, VCC=3.3V AMPGC=OFF - 436 630 AMPGC=ON - 247 382 F=32 MHz - CL=20 pF XOSC,GAIN=4, VCC=3.3V AMPGC=OFF - 1303 2251 AMPGC=ON - 627 Current consumption Ta Min. Typ. Max. Units µA 1116 Note:  1. These values are based on characterization, and are not covered in test limits in production. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1053 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48.8.2 External 32 KHz Crystal Oscillator (XOSC32K) Characteristics Table 48-24. Power Consumption(1) Symbol Parameter Conditions Ta Min. Typ. Max. Units IDD Current consumption VCC=3.3V Max 125°C Typ 25°C - 309 767 nA Note:  1. These values are based on characterization, and are not covered in test limits in production. 48.8.3 Ultra Low-Power Internal 32 kHz RC Oscillator (OSCULP32K) Characteristics Table 48-25. Ultra Low-Power Internal 32 kHz RC Oscillator Electrical Characteristics Symbol Parameter Conditions Min. Typ. Max. Units FOUT Output frequency at 25°C, at VDDIO=3.3V 30.84 32.768 34.51 kHz at 25°C, over [1.8, 3.63]V 30.84 32.768 34.74 kHz over[-40,+125]°C, over [1.8, 3.63]V 25.17 32.768 41.76 kHz - 50 - % Duty(1) Duty Cycle Note:  1. These values are based on simulation, and are not covered by production test limits or characterization. 48.8.4 16 MHz RC Oscillator (OSC16M) Characteristics Table 48-26. Multi-RC Oscillator Electrical Characteristics Symbol FOUT Parameter Output frequency Conditions VDD= 3.3V, T = 25°C Calibrated against a 4/8/12/16 MHz reference Min. Typ. Max. Units 3.96 4.00 4.04 7.92 8.00 8.08 11.88 12.00 12.12 MHz 15.84 16.00 16.16 TempDrift SupplyDrift TWUP(2) TSTARTUP(2) Duty(1) Freq vs. temperature drift VDD = 3.3V over temperature [-40°C-125°C], versus calibration reference at 25°C -6 Freq vs. supply drift Temperature =25°C over voltage [1.8V-3.63V], versus calibration reference at 3.3V -1.5 FOUT = 4 MHz - 0.13 0.32 FOUT = 8 MHz - 0.13 0.31 FOUT = 12 MHz - 0.13 0.31 FOUT = 16 MHz - 0.13 0.31 FOUT = 4 MHz - 1.16 2.96 FOUT = 8 MHz - 1.29 2.74 FOUT = 12 MHz - 1.34 2.95 FOUT = 16 MHz - 1.39 3.11 - 45 50 55 Wake up time - 1st clock edge after enable Startup time Duty Cycle © 2020 Microchip Technology Inc. Datasheet 6 % 1.5 DS60001513F-page 1054 µs µs % SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These values are based on characterization. These values are not covered in test limits in production. Table 48-27. Power Consumption (1) Symbol Parameter Conditions Ta Fout=4MHz, VCC=3.3V Current consumption IDD Fout=8MHz, VCC=3.3V Fout=12MHz, VCC=3.3V Max.125°C, Typ.25°C Fout=16MHz, VCC=3.3V Min. Typ. Max. - 73 370 - 106 400 - 135 425 - 166 455 Units µA Note:  1. These values are based on characterization, and are not covered in test limits in production. 48.8.5 Digital Frequency Locked Loop (DFLLULP) Characteristics Table 48-28. Power Consumption(1)(2) Symbol Parameters IDD Conditions Ta Min. Typ. Max Units Current Consumption Fout = 8 MHz (PL0) - VCC = 3.3V Max 125°C Typ 25°C Fout = 32 MHz (PL2) - VCC=3.3V - 33 284 144 458 µA Notes:  1. These characteristics are only applicable in LDO Regulator mode. 2. These values are based on characterization. They are not covered in test limits in production. 48.8.6 Digital Phase Lock Loop (DPLL) Characteristics Table 48-29. Fractional Digital Phase Lock Loop(2) Symbol Parameter Min. Typ. Max. Unit FIN Input Clock Frequency 32 - 2000 kHz FOUT Output Clock Frequency PL2 32 - 96 MHz PL0 32 - 48 MHz © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1055 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Symbol Parameter Jp tLOCK Duty Min. Typ. Max. Unit Period jitter Lock Time PL0, Fin = 32 kHz, Fout = 32 MHz - 3 6 PL2, = 32 kHz, Fout = 32 MHz - 2 6 PL0, Fin = 32 kHz, Fout = 48 MHz - 3 4 PL2, Fin = 32 kHz, Fout = 48 MHz - 2 6 PL2, Fin = 32 kHz, Fout = 96 MHz - 3 4 PL0, Fin = 32 kHz, Fout = 32 MHz - 3 5 PL2, Fin = 32 kHz, Fout = 32 MHz - 3 6 PL0, Fin = 2 MHz, Fout = 48 MHz - 5 7 PL2, Fin = 2 MHz, Fout = 48 MHz - 3 6 PL2, Fin= 2 MHz, Fout= 96 MHz - 4 10 After startup, time to get lock signal Fin = 32 kHz, Fout = 96 MHz 1.1 1.5 ms After startup, time to get lock signal Fin = 2 MHz, Fout = 96 MHz - 24 35 µs 40 50 60 % Duty cycle (1) % Notes:  1. These values are based on simulation. They are not covered by production test limits or characterization. 2. These characteristics are applicable only in LDO Regulator mode and with a XOSC or XOSC32K reference. Table 48-30. Power Consumption(1)(2) Symbol Parameter Conditions TA Min. Typ. Max. Units IDD Current Consumption Fout = 48 MHz (PL0) - VDD = 3.3V Max. 125°C Typ. 25°C - 339 618 µA - 678 1005 Fout = 96 MHz (PL2) - VDD = 3.3V Notes:  1. These characteristics are only applicable in LDO regulator mode. 2. These values are based on characterization. They are not covered in test limits in production. 48.9 Timing Characteristics Enter a short description of your concept here (optional). This is the start of your concept. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1056 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... 48.9.1 SERCOM in SPI Mode in PL0 Table 48-31. SPI Timing Characteristics and Requirements (1) Symbol Parameter tSCK SCK period when tSOV=0 on the slave side Conditions Min. Master Reception Master Transmission Typ. Max. - - (4) - - 2*(tMIS+tSLAVE_OUT) (3) 2*(tMOV+tSLAVE_IN) tSCKW SCK high/low width Master - 0,5*tSCK - tSCKR SCK rise time(2) Master - 0,25*tSCK - tSCKF time(2) Master - 0,25*tSCK - Master, VDD>2.70V 86 - - Master, VDD>1.8V 95 - - Master, VDD>2.70V 0 - - Master, VDD>1.8V 0 - - SCK fall tMIS MISO setup to SCK tMIH MISO hold after SCK tMOV MOSI output valid after SCK Master, VDD>2.70V - - 33.3 Master, VDD>1.8V - - 49.6 tMOH MOSI hold after SCK Master, VDD>2.70V 9.7 - - tMOH MOSI hold after SCK Master, VDD>1.8V 9.7 - - tSSCK Slave SCK Period when tMIS=0 on the master side Slave Reception 2*(tSIS +tMASTER_OUT) (5) - - Slave Transmission 2*(tSOV +tMASTER_IN) (6) - - SCK high/low width Slave - 0,5*tSCK - tSSCKR SCK rise time(2) Slave - 0,25*tSCK - tSSCKF SCK fall time(2) Slave - 0,25*tSCK - tSIS MOSI setup to SCK Slave, VDD>2.70V 24.2 - - Slave, VDD>1.8V 24.9 - - tSIH MOSI hold after SCK Slave, VDD>2.70V 12.9 - - Slave, VDD>1.8V 13.5 - - Datasheet ns ns tSSCKW © 2020 Microchip Technology Inc. Units DS60001513F-page 1057 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Symbol Parameter Conditions tSSS SS setup to SCK Slave Min. Typ. Max. PRELOADEN=1 tSOSS+tEXT_MIS +2*tAPBC (8) (9) - - PRELOADEN=0 tSOSS+tEXT_MIS (8) - - tSSH SS hold after SCK Slave 0.5*tSSCK - - tSOV MISO output valid after SCK Slave, VDD>2.70V - - 66.9 Slave, VDD>1.8V - - 76.6 tSOH MISO hold after SCK Slave, VDD>2.70V 22.7 - - Slave, VDD>1.8V 20.3 - - tSOSS MISO setup after SS low Slave, VDD>2.70V - - 1* tSCK Slave, VDD>1.8V - - 1* tSCK tSOSH MISO hold after SS high Slave, VDD>2.70V 15 - - Slave, VDD>1.8V 15 - - Units ns Notes:  1. These values are based on simulation. These values are not covered by test limits in production. 2. See I/O Pin Characteristics. 3. Where tSLAVE_OUT is the slave external device output response time, generally tEXT_SOV+tLINE_DELAY (See Note 7). 4. Where tSLAVE_IN is the slave external device input constraint, generally tEXT_SIS+tLINE_DELAY (See Note 7). 5. Where tMASTER_OUT is the master external device output response time, generally tEXT_MOV +tLINE_DELAY (See Note 7). 6. Where tMASTER_IN is the master external device input constraint, generally tEXT_MIS+tLINE_DELAY (See Note 7). 7. tLINE_DELAY is the transmission line time delay. 8. tEXT_MIS is the input constraint for the master external device. 9. tAPBC is the APB period for SERCOM. Figure 48-2. SPI Timing Requirements in Master Mode SS tSSCKF tSSCKR SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSB LSB tMOV tMOH tMOH MOSI (Data Output) © 2020 Microchip Technology Inc. MSB LSB Datasheet DS60001513F-page 1058 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Figure 48-3. SPI Timing Requirements in Slave Mode SS tSSS tSSCKF tSSCKR tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS tSIH MOSI (Data Input) tSSCK MSB LSB tSOSH tSOSS tSOV MISO (Data Output) tSOH MSB LSB Maximum SPI Frequency • Master mode: fSCKmax = 1/2*(tMIS + tSLAVE_OUT) • Slave mode: fSCKmax = 1/2*(tSOV + tMASTER_IN) 48.9.2 SERCOM in SPI Mode in PL2 Table 48-32. SPI Timing Characteristics and Requirements (1) Symbol Parameter tSCK SCK period when Master tSOV=0 on the slave side Master tSCKW SCK high/low width time(2) Conditions Min. Typ. Max. Units Reception 2*(tMIS +tSLAVE_OUT) (3) - - ns Transmission 2*(tMOV +tSLAVE_IN) (4) - - Master - 0,5*tSCK - Master - 0,25*tSCK - tSCKR SCK rise tSCKF SCK fall time(2) Master - 0,25*tSCK - tMIS MISO setup to SCK Master, VDD>2.70V 43.8 - - Master, VDD>1.8V 54.1 - - © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1059 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... ...........continued Symbol Parameter Conditions Min. Typ. Max. Units tMIH MISO hold after SCK Master, VDD>2.70V 0 - - ns Master, VDD>1.8V 0 - - MOSI output valid after SCK Master, VDD>2.70V - - 17.5 Master, VDD>1.8V - - 21.2 Master, VDD>2.70V 6.32 - - Master, VDD>1.8V 6.32 - - Slave Reception 2*(tSIS +tMASTER_OUT) (5) - - Slave Transmission 2*(tSOV +tMASTER_IN) (6) - - tMOV tMOH tSSCK MOSI hold after SCK Slave SCK Period when tMIS=0 on the master side tSSCKW SCK high/low width Slave - 0,5*tSCK tSSCKR SCK rise time(2) Slave - 0,25*tSCK - tSSCKF SCK fall time(2) Slave - 0,25*tSCK - tSIS MOSI setup to SCK Slave, VDD>2.70V 10.7 - - Slave, VDD>1.8V 11.4 - - MOSI hold after SCK Slave, VDD>2.70V 6.4 - - Slave, VDD>1.8V 7.1 - - SS setup to SCK Slave - - PRELOADEN=0 tSOSS+tEXT_MIS (8) - - tSIH tSSS PRELOADEN=1 tSOSS+tEXT_MIS +2*tAPBC (8) (9) tSSH SS hold after SCK Slave 0.5*tSSCK - - tSOV MISO output valid after SCK Slave, VDD>2.70V - - 36.1 Slave, VDD>1.8V - - 46.4 MISO hold after SCK Slave, VDD>2.70V 13.4 - - Slave, VDD>1.8V 13.4 - - - 1* tSCK - 1* tSCK tSOH tSOSS tSOSH MISO setup after SS Slave, VDD>2.70V low Slave, VDD>1.8V MISO hold after SS high © 2020 Microchip Technology Inc. Slave, VDD>2.70V 8.7 - - Slave, VDD>1.8V 8.7 - - Datasheet ns DS60001513F-page 1060 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... Notes:  1. These values are based on simulation. These values are not covered by test limits in production. 2. See I/O Pin Characteristics. 3. Where tSLAVE_OUT is the slave external device output response time, generally tEXT_SOV+tLINE_DELAY (See Note 7). 4. Where tSLAVE_IN is the slave external device input constraint, generally tEXT_SIS+tLINE_DELAY (See Note 7). 5. Where tMASTER_OUT is the master external device output response time, generally tEXT_MOV +tLINE_DELAY (See Note 7). 6. Where tMASTER_IN is the master external device input constraint, generally tEXT_MIS+tLINE_DELAY (See Note 7). 7. tLINE_DELAY is the transmission line time delay. 8. tEXT_MIS is the input constraint for the master external device. 9. tAPBC is the APB period for SERCOM. Figure 48-4. SPI Timing Requirements in Master Mode SS tSSCKF tSSCKR SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSB LSB tMOV tMOH tMOH MOSI (Data Output) MSB LSB Figure 48-5. SPI Timing Requirements in Slave Mode SS tSSS tSSCKF tSSCKR tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS MOSI (Data Input) tSIH MSB LSB tSOSH tSOSS MISO (Data Output) tSSCK tSOV tSOH MSB LSB Maximum SPI Frequency • Master Mode fSCKmax = 1/2*(tMIS + tSLAVE_OUT) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1061 SAM L10/L11 Family AEC-Q100 Grade (-40°C to 125°C) Electrical ... • Slave Mode fSCKmax = 1/2*(tSOV + tMASTER_IN) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1062 SAM L10/L11 Family AC and DC Characteristics Graphs 49. AC and DC Characteristics Graphs 49.1 Typical Power Consumption over Temperature in Sleep Modes - 85°C Power Consumption in Standby Sleep Mode with PDSW in Active state Operating conditions: • VDDIO = 3.3V or 1.8V • No RTC running • BOD33 is disabled • LPVREG with LPEFF Enable • All 16 kB SRAM retained • PDSW Domain in Active state Figure 49-1. Power Consumption over Temperature in Standby Sleep Mode with PDSW in Active state Power Consumption in Standby Sleep Mode with PDSW in Retention state Operating conditions: • VDDIO = 3.3V or 1.8V • No RTC running • BOD33 is disabled • LPVREG with LPEFF Enable • All 16 kB SRAM retained • PDSW Domain in Retention state © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1063 SAM L10/L11 Family AC and DC Characteristics Graphs Figure 49-2. Power Consumption over Temperature in Standby Sleep Mode with PDSW in Retention state Power Consumption in Off Sleep Mode Operating conditions: • VDDIO = 3.3V or 1.8V Figure 49-3. Power Consumption over Temperature in Off Sleep Mode © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1064 SAM L10/L11 Family AC and DC Characteristics Graphs 49.2 Typical Power Consumption over Temperature in Sleep Modes - 125°C Power Consumption in Standby Sleep mode with PDSW in Active state Operating conditions: • VDDIO = 3.3V or 1.8V • No RTC running • BOD33 is disabled • LPVREG with LPEFF Enable • All 16 kB SRAM retained • PDSW Domain in Active state Figure 49-4. Power Consumption over Temperature in Standby Sleep Mode with PDSW in Active state Power Consumption in Standby Sleep Mode with PDSW in Retention state Operating conditions: • VDDIO = 3.3V or 1.8V • No RTC running • BOD33 is disabled • LPVREG with LPEFF Enable • All 16 kB SRAM retained • PDSW Domain in Retention state © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1065 SAM L10/L11 Family AC and DC Characteristics Graphs Figure 49-5. Power Consumption over Temperature in Standby Sleep Mode with PDSW in Retention state Power Consumption in Off Sleep Mode Operating conditions: • VDDIO = 3.3V or 1.8V Figure 49-6. Power Consumption over Temperature in Off Sleep Mode © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1066 SAM L10/L11 Family Packaging Information 50. Packaging Information 50.1 Package Marking Information All devices are marked with the Atmel logo, a shortened ordering code and additional marking (the two last lines) YYWW R ARM XXXXXX CC Where: • "Y" or "YY": Manufacturing year (last or last two digits) • "WW": Manufacturing week • "R": Revision • "XXXXXX": Lot number • "CC": Internal Code 50.2 Package Drawings Note:  For current package drawings, refer to the Microchip Packaging Specification, which is available at http:// www.microchip.com/packaging. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1067 SAM L10/L11 Family Packaging Information 50.2.1 32-pin TQFP Table 50-1. Device and Package Maximum Weight 100 mg Table 50-2. Package Characteristics Moisture Sensitivity Level © 2020 Microchip Technology Inc. MSL3 Datasheet DS60001513F-page 1068 SAM L10/L11 Family Packaging Information Table 50-3. Package Reference 50.2.2 JEDEC Drawing Reference MS-026 JESD97 Classification E3 24-Pin VQFN Table 50-4. Device and Package Maximum Weight 36 © 2020 Microchip Technology Inc. mg Datasheet DS60001513F-page 1069 SAM L10/L11 Family Packaging Information Table 50-5. Package Characteristics Moisture Sensitivity Level MSL1 Table 50-6. Package Reference JEDEC Drawing Reference MO-220 JESD97 Classification E3 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1070 SAM L10/L11 Family Packaging Information 50.2.3 24-pin VQFN with Stepped Wettable Flanks (AEC-Q100 Grade 1) 24-Lead Very Thin Plastic Quad Flat, No Lead Package (U3B) - 4x4 mm Body [VQFN] With 2.6mm Exposed Pad and Stepped Wettable Flanks; Atmel Legacy ZLH Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging 24X 0.08 C D NOTE 1 A 0.10 C B N 1 2 E (DATUM B) (DATUM A) 2X 0.10 C 2X TOP VIEW 0.10 C A1 (A3) 0.10 C A B A SEATING C PLANE D2 SIDE VIEW 0.10 DETAIL A C A B E2 A4 e 2 2 A A 1 D3 K N L e BOTTOM VIEW 24X b 0.10 0.05 SECTION A-A STEPPED WETTABLE FLANK C A B C Microchip Technology Drawing C04-21483 Rev A Sheet 1 of 2 © 2018 Microchip Technology Inc. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1071 SAM L10/L11 Family Packaging Information 24-Lead Very Thin Plastic Quad Flat, No Lead Package (U3B) - 4x4 mm Body [VQFN] With 2.6mm Exposed Pad and Stepped Wettable Flanks; Atmel Legacy ZLH Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging DETAIL 1 ALTERNATE TERMINAL CONFIGURATIONS Notes: Units Dimension Limits N Number of Terminals e Pitch Overall Height A Standoff A1 Terminal Thickness A3 Overall Length D Exposed Pad Length D2 E Overall Width Exposed Pad Width E2 b Terminal Width L Terminal Length Terminal-to-Exposed-Pad K D3 Wettable Flank Step Length Wettable Flank Step Height A4 MIN 0.80 0.00 2.50 2.50 0.20 0.35 0.20 0.10 MILLIMETERS NOM MAX 24 0.50 BSC 0.85 0.90 0.035 0.05 0.203 REF 4.00 BSC 2.60 2.70 4.00 BSC 2.60 2.70 0.25 0.30 0.40 0.45 0.085 0.19 1. Pin 1 visual index feature may vary, but must be located within the hatched area. 2. Package is saw singulated 3. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. REF: Reference Dimension, usually without tolerance, for information purposes only. Microchip Technology Drawing C04-21483 Rev A Sheet 2 of 2 Table 50-7. Device and Package Maximum Weight © 2018 Microchip Technology Inc. 41.4 © 2020 Microchip Technology Inc. mg Datasheet DS60001513F-page 1072 SAM L10/L11 Family Packaging Information Table 50-8. Package Characteristics Moisture Sensitivity Level MSL1 Table 50-9. Package Reference 50.2.4 JEDEC Drawing Reference N/A JESD97 Classification E3 32-pin VQFN © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1073 SAM L10/L11 Family Packaging Information Table 50-10. Device and Package Maximum Weight 90 mg Table 50-11. Package Characteristics Moisture Sensitivity Level MSL3 Table 50-12. Package Reference JEDEC Drawing Reference MO-220 JESD97 Classification E3 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1074 SAM L10/L11 Family Packaging Information 50.2.5 32-pin VQFN with Stepped Wettable Flanks (AEC-Q100 Grade 1) 32-Lead Very Thin Plastic Quad Flat, No Lead Package (RTB) - 5x5 mm Body [VQFN] With 3.6x3.6 mm Exposed Pad and Stepped Wettable Flanks; Atmel Legacy ZBS Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging D NOTE 1 A B N 1 2 E (DATUM B) (DATUM A) 2X 0.10 C 2X TOP VIEW 0.10 C A1 0.10 C C SEATING PLANE A 32X (A3) 0.08 C SIDE VIEW 0.10 C A B D2 A4 DETAIL A PARTIALLY PLATED D3 A A E2 e 2 SECTION A–A K 2 1 NOTE 1 0.10 C A B N 32X b 0.10 0.05 L e C A B C BOTTOM VIEW Microchip Technology Drawing C04-21391 Rev D Sheet 1 of 2 © 2017 Microchip Technology Inc. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1075 SAM L10/L11 Family Packaging Information 32-Lead Very Thin Plastic Quad Flat, No Lead Package (RTB) - 5x5 mm Body [VQFN] With 3.6x3.6 mm Exposed Pad and Stepped Wettable Flanks; Atmel Legacy ZBS Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging DETAIL 1 ALTERNATE TERMINAL CONFIGURATIONS Units Dimension Limits Number of Terminals N e Pitch Overall Height A Standoff A1 A3 Terminal Thickness Overall Length D Exposed Pad Length D2 Overall Width E Exposed Pad Width E2 b Terminal Width Terminal Length L Terminal-to-Exposed-Pad K D3 Wettable Flank Step Cut Width Wettable Flank Step Cut Depth A4 MIN 0.80 0.00 3.50 3.50 0.20 0.35 0.20 0.10 MILLIMETERS MAX NOM 32 0.50 BSC 0.85 0.90 0.035 0.05 0.203 REF 5.00 BSC 3.60 3.70 5.00 BSC 3.60 3.70 0.25 0.30 0.40 0.45 0.085 0.19 Dimensions D3 and A4 above apply to all new products released after November 1, and all products shipped after January 1, 2019, and supersede dimensions D3 and A4 below. No physical changes are being made to any package; this update is to align cosmetic and tolerance variations from existing suppliers. Notes: Wettable Flank Step Length Wettable Flank Step Height D3 A4 0.035 0.10 0.06 - 0.085 0.19 1. Pin 1 visual index feature may vary, but must be located within the hatched area. 2. Package is saw singulated 3. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. REF: Reference Dimension, usually without tolerance, for information purposes only. Microchip Technology Drawing C04-21391 Rev D Sheet 2 of 2 Table 50-13. Device and Package Maximum Weight © 2017 Microchip Technology Inc. 68.7 © 2020 Microchip Technology Inc. mg Datasheet DS60001513F-page 1076 SAM L10/L11 Family Packaging Information Table 50-14. Package Characteristics Moisture Sensitivity Level MSL3 Table 50-15. Package Reference JEDEC Drawing Reference N/A JESD97 Classification E3 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1077 SAM L10/L11 Family Packaging Information 50.2.6 24-pin SSOP © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1078 SAM L10/L11 Family Packaging Information Table 50-16. Device and Package Maximum Weight 187.322 mg Table 50-17. Package Characteristics Moisture Sensitivity Level MSL3 Table 50-18. Package Reference JEDEC Drawing Reference MO-150 JESD97 Classification E3 © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1079 SAM L10/L11 Family Packaging Information 50.2.7 32-pin WLCSP Table 50-19. Device and Package Maximum Weight 6.04 mg Table 50-20. Package Characteristics Moisture Sensitivity Level © 2020 Microchip Technology Inc. MSL1 Datasheet DS60001513F-page 1080 SAM L10/L11 Family Packaging Information Table 50-21. Package Reference 50.3 JEDEC Drawing Reference N/A JESD97 Classification E1 Soldering Profile The following table gives the recommended soldering profile from J-STD-20. Table 50-22. Recommended Soldering Profile Profile Feature Green Package Average Ramp-up Rate (217°C to peak) 3°C/s max. Preheat Temperature 175°C ±25°C 150-200°C Time Maintained Above 217°C 60-150s Time within 5°C of Actual Peak Temperature 30s Peak Temperature Range 260°C Ramp-down Rate 6°C/s max. Time 25°C to Peak Temperature 8 minutes max. A maximum of three reflow passes is allowed per component. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1081 SAM L10/L11 Family Schematic Checklist 51. Schematic Checklist 51.1 Introduction This chapter describes a common checklist which should be used when starting and reviewing the schematics for a SAM L10/L11 design. This chapter illustrates the recommended power supply connections, how to connect external analog references, programmer, debugger, oscillator and crystal. CAUTION 51.2 AEC-Q100 Grade 1 qualified devices have different operating conditions. Refer to AEC-Q100 Grade (-40°C to 125°C) Electrical Characteristics chapter for more details. Power Supply The SAM L10/L11 supports a single or dual power supply from 1.62V to 3.63V. The same voltage must be applied to both VDDIO and VDDANA. The internal voltage regulator has four different modes: • • • Linear mode: This mode does not require any external inductor. This is the default mode when CPU and peripherals are running Switching mode (Buck): The most efficient mode when the CPU and peripherals are running Low-Power (LP) mode: This is the default mode used when the device is in Standby mode Selecting between Switching mode and Linear mode can be done by software on the fly, but the power supply must be designed according to which mode to be used. 51.2.1 Power Supply Connections The following figures shows the recommended power supply connections for Switched/Linear mode and Linear mode only. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1082 SAM L10/L11 Family Schematic Checklist Figure 51-1. Power Supply Connection for Switching/Linear Mode SAM L11 SAML10 Main Supply Close to device (for every pin) (1.62V — 3.63V) VDDANA VDDIO 10µH 100nF 100nF 10µF VDDOUT 10µF VDDCORE 1µF 100nF GND GNDANA Figure 51-2. Power Supply Connection for Linear Mode Only SAM L11 SAML10 Main Supply Close to device (for every pin) (1.62V — 3.63V) VDDANA VDDIO 100nF 10µF 10µF VDDOUT 100nF VDDCORE 1µF 100nF GND GNDANA © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1083 SAM L10/L11 Family Schematic Checklist Table 51-1. Power Supply Connections Signal Name Recommended Pin Connection Description VDDIO Digital supply voltage 1.62V to 3.63V Decoupling/filtering capacitors 100 nF(1,2) and 10 µF(1) Decoupling/filtering inductor 10 μH(1,3) VDDANA 1.62V to 3.63V Decoupling/filtering capacitors 100 nF(1,2) and 10 µF(1) Analog supply voltage Ferrite bead(4) prevents the VDD noise interfering with VDDANA VDDCORE 0.9V to 1.2V typical Decoupling/filtering capacitors 100 nF(1,2) and 1µF(1) Linear regulator mode: Core supply voltage output/external decoupling pin Switched regulator mode: Core supply voltage input, must be connected to VDDOUT via inductor (5) VDDOUT Switching regulator mode: 10 µH inductor (5) Linear regulator mode: Not connected On-chip Switching mode regulator output GND Ground GNDANA Ground for the analog power domain Notes:  1. These values are only given as a typical example. 2. Decoupling capacitors should be placed close to the device for each supply pin pair in the signal group, low ESR capacitors should be used for better decoupling. 3. An inductor should be added between the external power and the VDD for power filtering. 4. A ferrite bead has better filtering performance compared to standard inductor at high frequencies. A ferrite bead can be added between the main power supply and VDDANA to prevent digital noise from entering the analog power domain. The bead should provide enough impedance (for example, 50Ω at 20 MHz and 220Ω at 100 MHz) to separate the digital and analog power domains. Make sure to select a ferrite bead designed for filtering applications with a low DC resistance to avoid a large voltage drop across the ferrite bead. 5. Refer to the Buck Converter section in the Electrical Characteristics chapter. 51.2.2 Special Considerations for QFN Packages The QFN package has an exposed paddle that must be connected to GND. 51.3 External Analog Reference Connections The following schematic checklist is only necessary if the application is using one or more of the external analog references. If the internal references are used instead, the circuits in the following two figures are not necessary. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1084 SAM L10/L11 Family Schematic Checklist Figure 51-3. External Analog Reference Schematic With Two References Close to device (for every pin) VREFA EXTERNAL REFERENCE 1 4.7μF 100nF GND VREFB EXTERNAL REFERENCE 2 4.7μF 100nF GND Figure 51-4. External Analog Reference Schematic With One Reference Close to device (for every pin) VREFA EXTERNAL REFERENCE 4.7μF 100nF GND VREFB GND Table 51-2. External Analog Reference Connections Signal Name Recommended Pin Connection Description VREFx 1.0V to (VDDANA - 0.6V) for ADC 1.0V to (VDDANA - 0.15V) for DAC Decoupling/filtering capacitors 100nF(1)(2) and 4.7µF(1) External reference VREFx for the analog port GND Ground 1. These values are only given as a typical example. 2. Decoupling capacitor should be placed close to the device for each supply pin pair in the signal group. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1085 SAM L10/L11 Family Schematic Checklist 51.4 External Reset Circuit The external Reset circuit is connected to the RESET pin when the external Reset function is used. The circuit is not necessary when the RESET pin is not driven low externally by the application circuitry. The reset switch can also be removed, if a manual reset is not desired. The RESET pin itself has an internal pull-up resistor, hence it is optional to add any external pull-up resistor. A pull-up resistor makes sure that the reset does not go low and unintentionally causing a device reset. An additional resistor has been added in series with the switch to safely discharge the filtering capacitor, that is, preventing a current surge when shorting the filtering capacitor which again can cause a noise spike that can have a negative effect on the system. Figure 51-5.  External Reset Circuit Schematic VDD 10kΩ 330Ω 100nF RESET GND Figure 51-6. External Reset Circuit Schematic (EFT Immunity Enhancement) VDD 2.2kΩ 330Ω 100pF RESET GND Note:  This reset circuit is intended to improve EFT immunity but does not filter low-frequency glitches which makes it not suitable as an example for applications requiring debouncing on a reset button. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1086 SAM L10/L11 Family Schematic Checklist Table 51-3. Reset Circuit Connections Signal Name Recommended Pin Connection Description RESET Reset low-level threshold voltage VDDIO = 1.62V - 2.0V: Below 0.33 * VDDIO Reset pin VDDIO = 2.7V - 3.63V: Below 0.36 * VDDIO Decoupling/filter capacitor 100pF(1) Pull-up resistor (2) Resistor in series with the switch 330Ω(1) 1. These values are only given as a typical example. 2. The SAM L10/L11 features an internal pull-up resistor on the RESET pin, hence an external pull-up is optional. 51.5 Unused or Unconnected Pins For unused pins the default state of the pins will give the lowest current leakage. Thus there is no need to do any configuration of the unused pins in order to lower the power consumption. 51.6 Clocks and Crystal Oscillators The SAM L10/L11 can be run from internal or external clock sources, or a mix of internal and external sources. An example of usage can be to use the internal 16 MHz oscillator as source for the system clock and an external 32.768 kHz watch crystal as clock source for the Real-Time counter (RTC). 51.6.1 External Clock Source Figure 51-7. External Clock Source Schematic External Clock XIN XOUT/GPIO NC/GPIO Table 51-4. External Clock Source Connections Signal Name Recommended Pin Connection Description XIN XIN is used as input for an external clock signal Input for inverting oscillator pin XOUT/GPIO Can be left unconnected or used as normal GPIO NC/GPIO © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1087 SAM L10/L11 Family Schematic Checklist 51.6.2 Crystal Oscillator Figure 51-8. Crystal Oscillator Schematic XIN 15pF XOUT 15pF The crystal should be located as close to the device as possible. Long signal lines may cause too high load to operate the crystal, and cause crosstalk to other parts of the system. Table 51-5. Crystal Oscillator Checklist Signal Name Recommended Pin Connection Description pF(1)(2) XIN Load capacitor 15 XOUT Load capacitor 15 pF(1)(2) External crystal between 0.4 to 32 MHz 1. These values are only given as a typical example. 2. The capacitors should be placed close to the device for each supply pin pair in the signal group. 51.6.3 External Real Time Oscillator The low-frequency crystal oscillator is optimized for use with a 32.768 kHz watch crystal. When selecting crystals, load capacitance and the crystal’s Equivalent Series Resistance (ESR) must be taken into consideration. Both the values are specified by the crystal vendor. SAM L10/L11 oscillator is optimized for very low power consumption, hence close attention should be made when selecting crystals. The typical parasitic load capacitance values are available in the Electrical Characteristics chapters. This capacitance and PCB capacitance can allow using a crystal inferior to 12.5 pF load capacitance without external capacitors as shown in the following figure. Figure 51-9. External Real Time Oscillator without Load Capacitor XIN32 32.768kHz XOUT32 To improve accuracy and safety, it has recommended to add external capacitors, as recommend in the crystal data sheet. See figure below for additional information. To find suitable load capacitance for a 32.768 kHz crystal, consult the crystal data sheet. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1088 SAM L10/L11 Family Schematic Checklist Figure 51-10. External Real Time Oscillator with Load Capacitor XIN32 12pF 32.768kHz XOUT32 12pF Table 51-6. External Real Time Oscillator Checklist Signal Name Recommended Pin Connection Description XIN32 Load capacitor 12 pF(1,2) Timer oscillator input XOUT32 Load capacitor 12 pF(1,2) Timer oscillator output 1. These values are only given as typical examples. 2. The capacitors should be placed close to the device for each supply pin pair in the signal group. Note:  To minimize the cycle-to-cycle jitter of the external oscillator, keep the neighboring pins as steady as possible. For neighboring pin details, refer to 4.2 Oscillators Pinout. Calculating the Correct Crystal Decoupling Capacitor The model shown in the following figure can be used to calculate correct load capacitor for a given crystal. This model includes internal capacitors CLn, external parasitic capacitance CELn and external load capacitance CPn. Figure 51-11. Crystal Circuit With Internal, External and Parasitic Capacitance CL1 XIN CEL1 CL2 XOUT CP1 CP2 External Internal 51.6.4 CEL2 Using this model the total capacitive load for the crystal can be calculated as shown in the equation below: �tot = ��1 + ��1 + �EL1 ��2 + ��2 + �EL2 ��1 + ��1 + �EL1 + ��2 + ��2 + �EL2 where Ctot is the total load capacitance seen by the crystal. This value should be equal to the load capacitance value found in the crystal manufacturer datasheet. The parasitic capacitance CELn can in most applications be disregarded as these are usually very small. If accounted for, these values are dependent on the PCB material and PCB layout. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1089 SAM L10/L11 Family Schematic Checklist For some crystal the internal capacitive load provided by the device itself can be enough. To calculate the total load capacitance in this case. CELn and CPn are both zero, CL1 = CL2 = CL, and the equation reduces to the following: �tot = �� 2 See the related links for equivalent internal pin capacitance values. 51.7 Programming and Debug Ports For programming and/or debugging the SAM L10/L11, the device should be connected using the Serial Wire Debug, SWD, interface. Currently the SWD interface is supported by several Microchip and third party programmers and debuggers, like the Atmel-ICE, SAM-ICE or SAM L10/L11 Xplained Pro (SAM L10/L11 evaluation kit) Embedded Debugger. Refer to the Atmel-ICE, SAM-ICE or SAM L10/L11 Xplained Pro user guides for details on debugging and programming connections and options. For connecting to any other programming or debugging tool, refer to that specific programmer or debugger’s user guide. The SAM L10/L11 Xplained Pro evaluation board supports programming and debugging through the on-board embedded debugger so no external programmer or debugger is needed. The SWDIO pin should be pulled up on the target. It is recommended that the SWCLK pin is pulled to a defined state of the target board. 51.7.1 Cortex Debug Connector (10-pin) For debuggers and/or programmers that support the Cortex Debug Connector (10-pin) interface the signals should be connected as shown in the following figure, with details described in the following table. Figure 51-12. Cortex Debug Connector (10-pin) VDD Cortex Debug Connector (10-pin) VTref SWDIO 1 GND GND NC NC SWDCLK NC NC RESET RESET SWCLK SWDIO GND © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1090 SAM L10/L11 Family Schematic Checklist Table 51-7. Cortex Debug Connector (10-pin) 51.7.2 Header Signal Name Description SWDCLK Serial wire clock pin SWDIO Serial wire bidirectional data pin RESET Target device reset pin, active low VTref Target voltage sense, should be connected to the device VDD GND Ground 10-pin JTAGICE3 Compatible Serial Wire Debug Interface The JTAGICE3 debugger and programmer does not support the Cortex Debug Connector (10-pin) directly, hence a special pinout is needed to directly connect the SAM L10/L11 to the JTAGICE3, alternatively one can use the JTAGICE3 squid cable and manually match the signals between the JTAGICE3 and SAM L10/L11. The following figure describes how to connect a 10-pin header that support connecting the JTAGICE3 directly to the SAM L10/L11 without the need for a squid cable. This can also be used for the Atmel-ICE AVR connector port. The JTAGICE3 squid cable or the JTACICE3 50mil cable can be used to connect the JTAGICE3 programmer and debugger to the SAM L10/L11. The figure illustrates the correct pinout for the JTAGICE3 50 mil, and details are given in the following table. Figure 51-13. 10-pin JTAGICE3 Compatible Serial Wire Debug Interface 10-pin JTAGICE3 Compatible Serial Wire Debug Header SWDCLK 1 VDD GND RESET VTG NC SWDIO RESET NC NC NC NC SWCLK SWDIO GND Table 51-8. 10-pin JTAGICE3 Compatible Serial Wire Debug Interface Header Signal Name Description SWDCLK Serial wire clock pin SWDIO Serial wire bidirectional data pin RESET Target device reset pin, active low VTG Target voltage sense, should be connected to the device VDD GND Ground © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1091 SAM L10/L11 Family Schematic Checklist 51.7.3 20-pin IDC JTAG Connector For debuggers and/or programmers that support the 20-pin IDC JTAG Connector, e.g., the SAM-ICE, the signals should be connected, as shown in the following figure, with details described in the following table. Figure 51-14. 20-pin IDC JTAG Connector VDD 20-pin IDC JTAG Connector VCC NC NC SWDIO 1 NC GND RESET GND GND SWDCLK GND NC GND NC GND* RESET GND* NC GND* NC GND* SWCLK SWDIO GND Table 51-9. 20-pin IDC JTAG Connector Header Signal Name Description 51.8 SWDCLK Serial wire clock pin SWDIO Serial wire bidirectional data pin RESET Target device reset pin, active low VCC Target voltage sense, should be connected to the device VDD GND Ground GND* These pins are reserved for firmware extension purposes. They can be left unconnected or connected to GND in normal debug environment. They are not essential for SWD in general. Peripherals Considerations ADC Accuracy The ADC accuracy may depend on different parameters, such as its input sources, as well as its conversion speed. Please refer to the Analog-to-Digital Converter (ADC) Characteristics section in the Electrical Characteristics chapters for more details. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1092 SAM L10/L11 Family Conventions 52. Conventions 52.1 Numerical Notation Table 52-1. Numerical Notation 52.2 Symbol Description 165 Decimal number 0b0101 Binary number (example 0b0101 = 5 decimal) '0101' Binary numbers are given without prefix if unambiguous 0x3B24 Hexadecimal number X Represents an unknown or do not care value Z Represents a high-impedance (floating) state for either a signal or a bus Memory Size and Type Table 52-2. Memory Size and Bit Rate 52.3 Symbol Description KB (kbyte) kilobyte (210 = 1024) MB (Mbyte) megabyte (220 = 1024*1024) GB (Gbyte) gigabyte (230 = 1024*1024*1024) b bit (binary '0' or '1') B byte (8 bits) 1kbit/s 1,000 bit/s rate (not 1,024 bit/s) 1Mbit/s 1,000,000 bit/s rate 1Gbit/s 1,000,000,000 bit/s rate word 32 bit half-word 16 bit Frequency and Time Table 52-3. Frequency and Time Symbol Description kHz 1 kHz = 103 Hz = 1,000 Hz KHz 1 KHz = 1,024 Hz, 32 KHz = 32,768 Hz MHz 1 MHz = 106 Hz = 1,000,000 Hz GHz 1 GHz = 109 Hz = 1,000,000,000 Hz s second © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1093 SAM L10/L11 Family Conventions ...........continued 52.4 Symbol Description ms millisecond µs microsecond ns nanosecond Registers and Bits Table 52-4. Register and Bit Mnemonics Symbol Description R/W Read/Write accessible register bit. The user can read from and write to this bit. R Read-only accessible register bit. The user can only read this bit. Writes will be ignored. W Write-only accessible register bit. The user can only write this bit. Reading this bit will return an undefined value. BIT Bit names are shown in uppercase. (Example ENABLE) FIELD[n:m] A set of bits from bit n down to m. (Example: PINA[3:0] = {PINA3, PINA2, PINA1, PINA0} Reserved Reserved bits are unused and reserved for future use. For compatibility with future devices, always write reserved bits to zero when the register is written. Reserved bits will always return zero when read. Reserved bit field values must not be written to a bit field. A reserved value will not be read from a read-only bit field. Do not write any value to reserved bits of a fuse. PERIPHERALi If several instances of a peripheral exist, the peripheral name is followed by a number to indicate the number of the instance in the range 0-n. PERIPHERAL0 denotes one specific instance. Reset Value of a register after a Power-on Reset. This is also the value of registers in a peripheral after performing a software Reset of the peripheral, except for the Debug Control registers. SET/CLR Registers with SET/CLR suffix allows the user to clear and set bits in a register without doing a read-modify-write operation. These registers always come in pairs. Writing a ‘1’ to a bit in the CLR register will clear the corresponding bit in both registers, while writing a ‘1’ to a bit in the SET register will set the corresponding bit in both registers. Both registers will return the same value when read. If both registers are written simultaneously, the write to the CLR register will take precedence. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1094 SAM L10/L11 Family Acronyms and Abbreviations 53. Acronyms and Abbreviations The below table contains acronyms and abbreviations used in this document. Table 53-1. Acronyms and Abbreviations Abbreviation Description AC Analog Comparator ADC Analog-to-Digital Converter ADDR Address AES Advanced Encryption Standard AHB Advanced High-performance Bus AMBA Advanced Microcontroller Bus Architecture APB AMBA Advanced Peripheral Bus AREF Analog Reference Voltage BOD Brown-out Detector CAL Calibration CC Compare/Capture CCL Configurable Custom Logic CLK Clock CRC Cyclic Redundancy Check CTRL Control DAC Digital-to-Analog Converter DAP Debug Access Port DFLL Digital Frequency Locked Loop DPLL Digital Phase Locked Loop DMAC DMA (Direct Memory Access) Controller DSU Device Service Unit EEPROM Electrically Erasable Programmable Read-Only Memory EIC External Interrupt Controller EVSYS Event System FDPLL Fractional Digital Phase Locked Loop, also DPLL FREQM Frequency Meter GCLK Generic Clock Controller GND Ground GPIO General Purpose Input/Output I2C Inter-Integrated Circuit IF Interrupt Flag INT Interrupt © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1095 SAM L10/L11 Family Acronyms and Abbreviations ...........continued Abbreviation Description MBIST Memory Built-In Self-Test MEM-AP Memory Access Port MTB Micro Trace Buffer NMI Non-maskable Interrupt NVIC Nested Vector Interrupt Controller NVM Nonvolatile Memory NVMCTRL Nonvolatile Memory Controller OPAMP Operation Amplifier OSC Oscillator PAC Peripheral Access Controller PC Program Counter PER Period PM Power Manager POR Power-on Reset PORT I/O Pin Controller PTC Peripheral Touch Controller PWM Pulse-Width Modulation RAM Random-Access Memory REF Reference RTC Real-Time Counter RX Receiver/Receive SEEP SmartEEPROM Page SERCOM Serial Communication Interface SMBus System Management Bus SP Stack Pointer SPI Serial Peripheral Interface SRAM Static Random Access Memory SUPC Supply Controller SWD Serial Wire Debug TC Timer/Counter TRNG True Random Number Generator TX Transmitter/Transmit ULP Ultra Low-Power USART Universal Synchronous and Asynchronous Serial Receiver and Transmitter VDD Common voltage to be applied to VDDIO and VDDANA © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1096 SAM L10/L11 Family Acronyms and Abbreviations ...........continued Abbreviation Description VDDIO Digital Supply Voltage VDDANA Analog Supply Voltage VREF Voltage Reference WDT Watchdog Timer XOSC Crystal Oscillator © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1097 SAM L10/L11 Family Appendix A: Migrating From SAM L21 to SAM ... 54. Appendix A: Migrating From SAM L21 to SAM L10/L11 (32-pin Package) This appendix provides an overview of pinout I/O and pinout multiplexing considerations for migrating from SAM L21 32-pin package devices to the SAM L10/L11 family of devices. It does not compare the characteristics of each peripheral and does not refer to software considerations. Pinout Differences SAM L10/L11 and SAM L21 families have a full pin-to-pin compatibility on the 32-pin packages. The only differences are in the following pin names: Table 54-1. Pin-to-Pin Comparison Table Pinout Comparison PIN# SAM L10/L11 SAM L21 29 VDDOUT VSW 30 VDDIO VDDIN 32 31 30 29 28 27 26 27 32 31 30 29 28 27 26 27 PA31 PA30 VDDIO VDDOUT GND VDDCORE RESET PA27 PA31 PA30 VDDIN VSW GND VDDCORE RESET PA27 Figure 54-1. TQFP-32 and QFN-32 Pin-to-Pin Comparison SAML10/L11Ex 24 23 22 21 20 19 18 17 PA25 PA24 PA23 PA22 PA19 PA18 PA17 PA16 PA00 PA01 PA02 PA03 PA04 PA05 PA06 PA07 1 2 3 4 5 6 7 8 24 23 22 21 20 19 18 17 SAML21Ex PA25 PA24 PA23 PA22 PA19 PA18 PA17 PA16 9 10 11 12 13 14 15 16 1 2 3 4 5 6 7 8 VDDANA GNDANA PA08 PA09 PA10 PA11 PA14 PA15 9 10 11 12 13 14 15 16 PA00 PA01 PA02 PA03 PA04 PA05 PA06 PA07 VDDANA GNDANA PA08 PA09 PA10 PA11 PA14 PA15 54.1 DIGITAL PIN ANALOG PIN OSCILLATORS GROUND INPUT SUPPLY REGULATED INPUT/OUTPUT SUPPLY RESET PIN © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1098 SAM L10/L11 Family Appendix A: Migrating From SAM L21 to SAM ... 54.2 Pinout Multiplexing Differences This section highlights the pinout multiplexing differences which have an impact on the peripherals features compatibility. Important:  The loss of features when migrating from SAM L21 to SAM L10/L11 are the only features highlighted. 54.2.1 SERCOM Table 54-2. Pinout Multiplexing Comparison (Peripheral Function C and D) Peripheral Functions C (SERCOM) D (SERCOM ALT) Pin# SAM L10/L11 SAM L21 SAM L10/L11 SAM L21 SAM L10/L11 SAM L21 1 PA00/Xin32 PA00/Xin32 SERCOM1/PAD[0] SERCOM1/PAD[0] 2 PA01/XOUT32 PA01/XOUT32 SERCOM1/PAD[1] SERCOM1/PAD[1] 5 PA04 PA04 SERCOM0/PAD[0] SERCOM0/PAD[0] 6 PA05 PA05 SERCOM0/PAD[1] SERCOM0/PAD[1] 7 PA06 PA06 SERCOM0/PAD[2] SERCOM0/PAD[2] 8 PA07 PA07 SERCOM0/PAD[3] SERCOM0/PAD[3] 11 PA08 PA08 SERCOM1/PAD[0] SERCOM0/PAD[0] SERCOM2/PAD[0] SERCOM2/PAD[0] 12 PA09 PA09 SERCOM1/PAD[1] SERCOM0/PAD[1] SERCOM2/PAD[1] SERCOM2/PAD[1] 13 PA10 PA10 SERCOM1/PAD[2] SERCOM0/PAD[2] SERCOM2/PAD[2] SERCOM2/PAD[2] 14 PA11 PA11 SERCOM1/PAD[3] SERCOM0/PAD[3] SERCOM2/PAD[3] SERCOM2/PAD[3] 15 PA14/XIN PA14/XIN SERCOM2/PAD[2] SERCOM2/PAD[2] SERCOM0/PAD[2] SERCOM4/PAD[2] 16 PA15/XOUT PA15/XOUT SERCOM2/PAD[3] SERCOM2/PAD[3] SERCOM0/PAD[3] SERCOM4/PAD[3] 17 PA16 PA16 SERCOM1/PAD[0] SERCOM1/PAD[0] SERCOM0/PAD[0] SERCOM3/PAD[0] 18 PA17 PA17 SERCOM1/PAD[1] SERCOM1/PAD[1] SERCOM0/PAD[1] SERCOM3/PAD[1] 19 PA18 PA18 SERCOM1/PAD[2] SERCOM1/PAD[2] SERCOM0/PAD[2] SERCOM3/PAD[2] 20 PA19 PA19 SERCOM1/PAD[3] SERCOM1/PAD[3] SERCOM0/PAD[3] SERCOM3/PAD[3] 21 PA22 PA22 SERCOM0/PAD[0] SERCOM3/PAD[0] SERCOM2/PAD[0] SERCOM5/PAD[0] 22 PA23 PA23 SERCOM0/PAD[1] SERCOM3/PAD[1] SERCOM2/PAD[1] SERCOM5/PAD[1] 23 PA24 PA24 SERCOM0/PAD[2] SERCOM3/PAD[2] SERCOM2/PAD[2] SERCOM5/PAD[2] 24 PA25 PA25 SERCOM0/PAD[3] SERCOM3/PAD[3] SERCOM2/PAD[3] SERCOM5/PAD[3] SERCOM Features Comparison The following tables highlight SERCOM features differences with respect to the Pinout Multiplexing. Table 54-3. SERCOM Features Comparison with SAM L21 (Peripheral Function C) PA08, PA09 Pin Name Features / SERCOM Instances I2C USART PA10, PA11 PA16, PA17 PA18, PA19 SAM L10/L11 SERCOM1 SAM L21 SERCOM0 SAM L10/L11 SERCOM1 SAM L21 SERCOM0 Full Speed No Yes No No Yes Yes No Fast Mode Plus No Yes No No Yes Yes No High Speed No Yes No No No Yes Auto-baud mode No Yes No Yes No Yes LIN Slave No Yes No Yes No Yes No © 2020 Microchip Technology Inc. SAM L10/L11 - SAM L21 SAM L10/L11 - SAM L21 SERCOM1 SERCOM1 Datasheet PA22, PA23 PA24, PA25 SAM L10/L11 SERCOM0 SAM L21 SERCOM3 SAM L10/L11 SERCOM0 SAM L21 SERCOM3 No Yes Yes No No No Yes Yes No No No No Yes Yes No No No Yes No Yes No Yes Yes No Yes No Yes DS60001513F-page 1099 SAM L10/L11 Family Appendix A: Migrating From SAM L21 to SAM ... Table 54-4. SERCOM Features Comparison with SAM L21 (Peripheral Function D) Pin Name PA00, PA01 PA04, PA05, PA06, PA07 PA08, PA09 Features / SERCOM Instances SAM L10/L11 - SAM L21 SERCOM1 SAM L10/L11 - SAM L21 SERCOM0 SAM L10/L11 - SAM L21 SERCOM2 I2C PA14, PA15 PA16, PA17 PA18, PA19 PA22,PA23 SAM L10/L11 SERCOM0 SAM L21 SERCOM4 SAM L10/L11 SERCOM0 SAM L21 SERCOM3 SAM L10/L11 SERCOM0 SAM L21 SERCOM3 SAM L10/L11 SERCOM2 SAM L21 SERCOM5 Full Speed No No No No No Yes No No Yes Yes No No No Yes Fast Mode Plus No No No No No Yes No No Yes Yes No No No No High Speed No No No No No Yes No No Yes Yes No No No No Auto-baud mode No Yes No Yes Yes Yes No Yes No Yes No Yes Yes No LIN Slave No Yes No Yes Yes Yes No Yes No Yes No Yes Yes No USART 54.2.2 CCL Table 54-5. Pinout Multiplexing Comparison (Peripheral Function I) Pin # Pin Name SAM L10/L11 SAM L21 21 PA22 - IN[0] 22 PA23 - IN[1] 23 PA24 - IN[2] 24 PA25 - OUT[0] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1100 SAM L10/L11 Family Appendix B: Migrating From SAM D20/D21 to SAM ... 55. Appendix B: Migrating From SAM D20/D21 to SAM L10/L11 (32-pin Package) This appendix provides an overview of pinout I/O and pinout multiplexing considerations for migrating from SAM D20/D21 32-pin package devices to the SAM L10/L11 family of devices. It does not compare the characteristics of each peripheral and does not refer to software considerations. Note:  Only SAM D21ExA/B/C/D Series are considered as SAM D21ExL Series have major differences in term of pinout. 55.1 Pinout Differences The only exceptions are in the following pin functions: Table 55-1. Pin to Pin Comparison Table Pinout Comparison Features Difference PIN# SAM L10/L11 SAM D20/D21 10 GNDANA GND None (Naming Change) 27 VDDCORE PA28 Yes 29 VDDOUT VDDCORE Yes 30 VDDIO VDDIN None (Naming Change) © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1101 SAM L10/L11 Family Appendix B: Migrating From SAM D20/D21 to SAM ... Figure 55-1. TQFP-32 and QFN-32 Pin-to-Pin Comparison 55.2 Pinout Multiplexing Differences This section highlights the pinout multiplexing differences which have an impact on the peripherals features compatibility. Important:  The loss of features when migrating from SAM D20/D21 to SAM L10/L11 are the only features highlighted. 55.2.1 EIC Table 55-2. Pinout Multiplexing Comparison (Peripheral Function A) Peripheral Functions A (EIC) Pin# SAM L10/L11 SAM D20/D21 SAM L10/L11 SAM D20/D21 27 VDDCORE PA28 - EXTINT[8] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1102 SAM L10/L11 Family Appendix B: Migrating From SAM D20/D21 to SAM ... 55.2.2 SERCOM (SAM D20) Table 55-3. SAM D20 Pinout Multiplexing Comparison (Peripheral Function D) Peripheral Functions D (SERCOM ALT) Pin# SAM L10/L11 SAM D20 SAM L10/L11 SAM D20 5 PA04 PA04 - SERCOM0/PAD[0] 6 PA05 PA05 - SERCOM0/PAD[1] 7 PA06 PA06 - SERCOM0/PAD[2] 8 PA07 PA07 - SERCOM0/PAD[3] The following tables highlight SERCOM features differences with respect to the Pinout Multiplexing. Table 55-4. SERCOM Features Comparison with SAM D20 (Peripheral Function C) Pin Name PA08, PA09 Features / SERCOM Instances I2C SAM L10/L11 SERCOM1 SAM D20 SERCOM0 No Yes Full Speed Table 55-5. SERCOM Features Comparison with SAM D20 (Peripheral Function D) Pin Name PA08, PA09 Features / SERCOM Instances SAM L10/L11 - SAM D20 SERCOM2 I2C 55.2.3 Full Speed No PA22, PA23 SAM L10/L11 SERCOM2 SAM D20 SERCOM5 No Yes Yes SERCOM (SAM D21) The following tables highlight SERCOM features differences with respect to the Pinout Multiplexing. Table 55-6. SAM D21 Pinout Multiplexing Comparison (Peripheral Function C and D) Peripheral Functions C (SERCOM) D (SERCOM ALT) Pin# SAM L10/L11 SAM D21 SAM L10/L11 SAM D21 SAM L10/L11 SAM D21 1 PA00/Xin32 PA00/Xin32 - - SERCOM0/PAD[2] SERCOM1/PAD[0] 2 PA01/XOUT32 PA01/XOUT32 - - SERCOM0/PAD[3] SERCOM1/PAD[1] 5 PA04 PA04 - - - SERCOM0/PAD[0] 6 PA05 PA05 - - - SERCOM0/PAD[1] 7 PA06 PA06 - - - SERCOM0/PAD[2] 8 PA07 PA07 - - - SERCOM0/PAD[3] 11 PA08 PA08 SERCOM1/PAD[0] SERCOM0/PAD[0] SERCOM2/PAD[0] SERCOM2/PAD[0] 12 PA09 PA09 SERCOM1/PAD[1] SERCOM0/PAD[1] SERCOM2/PAD[1] SERCOM2/PAD[1] 13 PA10 PA10 SERCOM1/PAD[2] SERCOM0/PAD[2] SERCOM2/PAD[2] SERCOM2/PAD[2] 14 PA11 PA11 SERCOM1/PAD[3] SERCOM0/PAD[3] SERCOM2/PAD[3] SERCOM2/PAD[3] 15 PA14/XIN PA14/XIN SERCOM2/PAD[2] SERCOM2/PAD[2] SERCOM0/PAD[2] SERCOM4/PAD[2] 16 PA15/XOUT PA15/XOUT SERCOM2/PAD[3] SERCOM2/PAD[3] SERCOM0/PAD[3] SERCOM4/PAD[3] 17 PA16 PA16 SERCOM1/PAD[0] SERCOM1/PAD[0] SERCOM0/PAD[0] SERCOM3/PAD[0] 18 PA17 PA17 SERCOM1/PAD[1] SERCOM1/PAD[1] SERCOM0/PAD[1] SERCOM3/PAD[1] 19 PA18 PA18 SERCOM1/PAD[2] SERCOM1/PAD[2] SERCOM0/PAD[2] SERCOM3/PAD[2] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1103 SAM L10/L11 Family Appendix B: Migrating From SAM D20/D21 to SAM ... ...........continued Peripheral Functions C (SERCOM) D (SERCOM ALT) Pin# SAM L10/L11 SAM D21 SAM L10/L11 SAM D21 SAM L10/L11 SAM D21 20 PA19 PA19 SERCOM1/PAD[3] SERCOM1/PAD[3] SERCOM0/PAD[3] SERCOM3/PAD[3] 21 PA22 PA22 SERCOM0/PAD[0] SERCOM3/PAD[0] SERCOM2/PAD[0] SERCOM5/PAD[0] 22 PA23 PA23 SERCOM0/PAD[1] SERCOM3/PAD[1] SERCOM2/PAD[1] SERCOM5/PAD[1] 23 PA24 PA24 SERCOM0/PAD[2] SERCOM3/PAD[2] SERCOM2/PAD[2] SERCOM5/PAD[2] 24 PA25 PA25 SERCOM0/PAD[3] SERCOM3/PAD[3] SERCOM2/PAD[3] SERCOM5/PAD[3] 31 PA30 PA30 - - SERCOM1/PAD[2] SERCOM1/PAD[2] 32 PA31 PA31 - - SERCOM1/PAD[3] SERCOM1/PAD[3] Table 55-7. SERCOM Features Comparison with SAM D21 (Peripheral Function C) Pin Name PA08, PA09 Features / SERCOM Instances PA10, PA11 PA16, PA17 PA18, PA19 SAM L10/L11 SAM D21 SERCOM1 SAM L10/L11 SAM D21 SERCOM1 SAM L10/L11 SERCOM1 SAM D21 SERCOM0 SAM L10/L11 SERCOM1 SAM D21 SERCOM0 Full Speed No Yes No No Yes Yes No Fast Mode Plus No Yes No No Yes Yes High Speed No Yes No No No Auto-baud mode No Yes No Yes LIN Slave No Yes No Yes I2C USART PA22, PA23 PA24, PA25 SAM L10/L11 SERCOM0 SAM D21 SERCOM3 SAM L10/L11 SERCOM0 SAM D21 SERCOM3 No Yes Yes No No No No Yes Yes No No Yes No No Yes Yes No No No Yes No Yes No Yes No Yes No Yes No Yes No Yes No Yes Table 55-8. SERCOM Features Comparison with SAM D21 (Peripheral Function D) Pin Name Features / SERCOM Instances I2C USART PA04, PA05, PA06, PA07 PA00, PA01 SAM L10/L11 - SAM D21 SERCOM0 PA08, PA09 PA14, PA15 SAM L10/L11 - SAM SAM L10/L11 D21 SERCOM2 SERCOM0 PA16, PA17 SAM D21 SERCOM4 SAM L10/L11 SERCOM0 PA18, PA19 SAM D21 SERCOM3 SAM L10/L11 SERCOM0 PA22, PA23 SAM D21 SERCOM3 SAM L10/L11 SERCOM2 PA30, PA31 SAM L10/L11 SERCOM0 SAM D21 SERCOM1 SAM D21 SERCOM5 SAM L10/L11 SERCOM1 SAM D21 SERCOM5 Full Speed No No No No No Yes No No Yes Yes No No No Yes No No Fast Mode Plus No No No No No Yes No No Yes Yes No No No Yes No No High Speed No No No No No Yes No No Yes Yes No No No Yes No No Auto-baud mode No Yes No Yes Yes Yes No Yes No Yes No Yes Yes Yes No Yes LIN Slave No Yes No Yes Yes Yes No Yes No Yes No Yes Yes Yes No Yes 55.2.4 TC Table 55-9. Pinout Multiplexing Comparison (Peripheral Function E/F) Peripheral Functions E/F (TC) Pin# SAM L10/L11 D20Exx SAM L10/L11 D20 11 PA08 PA08 - TC0/WO[0] 12 PA09 PA09 - TC0/WO[1] 13 PA10 PA10 - TC1/WO[0] 14 PA11 PA11 - TC1/WO[1] 17 PA16 PA16 - TC2/WO[0] 18 PA17 PA17 - TC2/WO[1] Note:  SAM D21 has similar TCC functions which do not have an equivalent on the SAM L10/L11 for the above pins. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1104 SAM L10/L11 Family Appendix B: Migrating From SAM D20/D21 to SAM ... 55.2.5 GCLK Table 55-10. Pinout Multiplexing Comparison (Peripheral Function H) Peripheral Functions H (GCLK) Pin# SAM L10/L11 SAM D20/D21 SAM L10/L11 SAM D20/D21 27 VDDCORE PA28 - GCLK_IO[0] © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1105 SAM L10/L11 Family Data Sheet Revision History 56. Data Sheet Revision History Note:  The data sheet revision is independent of the die revision (Revision bit in the Device Identification register of the Device Service Unit, DSU.DID.REVISION) and the device variant (last letter of the ordering number). 56.1 Revision F - 06/2020 In addition to the changes listed in the following table, there were numerous typographical updates that were made throughout the document. The following additions or updates were done during this revision: Section Features Description • • Configuration Summary Updated Silent access entries for Data Flash and TrustRAM Updated ISO7816, RS-485, and LIN Slave entries for Communication Interfaces Added a new note to Table 1-1, SAM L10/L11 DeviceSpecific Features Pinout • Moved the SERCOM related tables to the SERCOM Chapters Memories • Updated the NVM Software Calibration Row Mapping table with new names for the 0x00 Offset SAM L11 Specific Security Features • • • • Updated the Note in Features Replaced NVM text in Data Flash Replaced NVM text in SRAM Added new second paragraph to Peripherals Security Attribution Removed Hardfault Generation text from Table 13-9 SAM L11 Memory Space Security Attributions Replaced the word hash with digest throughout the Crypto Acceleration chapter • • Boot ROM • • DSU • • Updated SAM L11 Boot ROM Flow Diagram and replaced OK with Not OK Replaced the word hash with digest throughout the Boot ROM chapter Replaced the text in SAM L11 TrustZone-Specific Register Access Updated the Register Description with new text for SAM L11 devices MCLK Updated the offset for the CPUDIV register FREQM Updated the Block Diagram and changed CLK_REF_MUX to CLK_REF DMAC • • © 2020 Microchip Technology Inc. Added new bit field description to the SRCADDR bit of the SRCADDR Register Added new bit field description to the DSTADDR bit of the DSTADDR Register Datasheet DS60001513F-page 1106 SAM L10/L11 Family Data Sheet Revision History ...........continued Section Description NVMCTRL Updated the Silent Access section with new text and table TRAM • • Updated the first paragraph in Overview Updated the Silent Access section with new text and table SERCOM • Added in the Pinout from the Pinout chapter to the Features section Added Secure Pin Multiplexing (on SERCOM) Pins (SAM L11 Only) • SERCOM I2C TC Updated the Signal Description with a new note and Pinout tables • • • • • • TRNG ADC Updated the DATA register with a new register property • • OPAMP Electrical Characteristics at 85℃ • • © 2020 Microchip Technology Inc. Updated Calibration with new Register references of ADC BIASCOMP and BIASREFBUF Updated the BIASREFBUF and BIASCOMP bits of the CALIB register with new bit descriptions Added in a new topic, Reference Buffer (REFBUF) • Electrical Characteristics at 125℃ Added new paragraph with information regarding the PER and PERBUF registers to Principle of Operation Replaced the NPWM and NFRQ paragraph with new text in Waveform Output Operations Updated the register property to PAC WriteProtection, Read-Synchronized, WriteSynchronized for the CTRLBSET register in 8-bit mode Updated the bit description for the PER bit for the PER Register in 8-bit mode Updated the bit description for the PER bit for the PER Register in 16-bit mode Updated the bit description for the PER bit for the PER Register in 32-bit mode Removed the last Equation in Analog-to-Digital Converter (ADC) Characteristics Updated Table 46-43 NVM Reliability Characteristics with a new note in NVM Characteristics Updated the FOUT drift rows converting kHz to Hz in Table 46-53 Digital Frequency Locked Loop Characteristics (LDO Regulator) Removed the last Equation in Analog-to-Digital Converter (ADC) Characteristics Datasheet DS60001513F-page 1107 SAM L10/L11 Family Data Sheet Revision History ...........continued Section AEC-Q100 Grade Electrical Characteristics Description • • 56.2 Removed the last Equation in Analog-to-Digital Converter (ADC) Characteristics Updated Table 48-22 NVM Reliability Characteristics with a new note in NVM Characteristics Revision E - 08/2019 The following additions or updates were done during this revision: Section Description Features Added the AEC-Q100 qualifications. Multiplexed Signals Corrected typographical errors for note designations in the Pinout Multiplexing Table. Peripherals Configuration Summary Corrected typographical errors in the table. Electrical Specifications at 85°C • • Electrical Specifications at 125°C • • 56.3 Updated SERCOM in SPI Mode in PL0 with new images and new equations Updated SERCOM in SPI Mode in PL2 with new images and new equations Updated SERCOM in SPI Mode in PL0 with new images and new equations Updated SERCOM in SPI Mode in PL2 with new images and new equations AEC-Q100 Electrical Specifications This section is newly added for this release. 50.2 Package Drawings 50.2.3 24-pin VQFN with Stepped Wettable Flanks (AEC-Q100 Grade 1) and 50.2.5 32-pin VQFN with Stepped Wettable Flanks (AEC-Q100 Grade 1) Rev D - 04/2019 Section Updates Features • Updated Security features Ordering Information • Added new Ordering Information diagram to include new information for SAM L11 Securely Key Provisioned Memories • Created new TrustRAM topic • Updated NVM Software Calibration Row title from NVM Software Calibration Area. All references inside the topic have corrected the word ‘area’ to ‘row.’ Processor and Architecture • Corrected XOSCFAIL to CLKFAIL in the Interrupt Line Mapping table in Interrupt Line Mapping Peripherals Configuration Summary • Corrected XOSCFAIL in the Peripherals Configuration Summary table to CLKFAIL • Updated bit names in the User and Generator columns of the table. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1108 SAM L10/L11 Family Data Sheet Revision History ...........continued Section SAM L11 Specific Security Features Peripheral Access Controller GCLK MCLK Updates • Updated chapter title • Corrected typographical and minor content errors in Features • Updated Secure Pin Multiplexing on SERCOM with new content for feature enabling • Updated Data Flash Scrambling Chapter title from Data Flash, replaced the existing text with Data Flash scrambling information, and added a cross reference to the NVMCTRL. • Updated Clocks with new CLK_PAC_AHB text • The following registers were updated with corrections to register properties and bitfields: – WRCTRL – EVCTRL – STATUSA – STATUSB – STATUSC – NONSECA – NONSECB – NONSECC • Updated Synchronization with new polling text • Updated the Generator Selection table in the PCHCTRLm register • Updated the Peripheral Clock Default State table in Peripheral Clock Masking with new Peripheral Clock names: – CLK_APBA_AHB – CLK_APBB_AHB – CLK_APBC_AHB – CLK_HMATRIXHS_APB FREQM • Updated the enable-protected references in the CTRLA register PM • Updated the Register Property for the STDBYCFG Register to PAC WriteProtection OSCCTRL • Updated Register Access Protection with DFLLULP information • Corrected erroneous text in Clock Failure Detection Operation • Updated the OSC16MRDY text in Interrupts and for the DPLL reference the bit names were updated with DPLLLCKR, DPLLLCKF, and DPLLLTO • Updated bit names in Events, CFDEO was changed to CLKFAILEO • Corrected typographical errors in Synchronization • The following registers had bit names corrected,or properties updated: OSC32KCTRL © 2020 Microchip Technology Inc. – EVCTRL – XOSCCTRL – DFLLULPCTRL • Updated the CFD text references in Clock Failure Detection Operation • Updated the EVCTRL.CLKFAILEO bit name in Events • Updated CLKFAILEO in the EVCTRL register Datasheet DS60001513F-page 1109 SAM L10/L11 Family Data Sheet Revision History ...........continued Section SUPC WDT RTC DMAC EIC © 2020 Microchip Technology Inc. Updates • Corrected terminology under Features • Updated title for Voltage Regulators System Operation • Updated ‘Selecting a Voltage Regulator’ to read Selecting the Main Voltage Regulator • Added new text ‘Enable-Protected (excluding BOD33.ENABLE bit)’ to the Initialization chapter • Added a new bulleted item, ‘DFLLULP Low Power Voltage Reference Ready (ULPVREFRDY), asynchronous’ to Interrupts • Removed BOD12 Detection reference in Events • The following registers were updated to correct Register properties, bitfield names, and enable-protected text: • – BOD33 – EVCTRL Updated Register Access Protection with a new reference to the CLEAR register • Updated ENABLE bit text in Initialization • Added Watchdog Clear Register (CLEAR) reference to Synchronization • The following registers had updates to bitfields, properties, and enableprotection text: – CTRLA – CONFIG – EWCTRL • Updated TAMPERID information in Register Access Protection • Added new information for GP registers in Initialization • Corrected bit names for CMP0-1, ALARM0, and PER0-7 in Interrupts • Corrected bit names for CMP0-1, ALARM0, and PER0-7 in Events • Updated the table in General Purpose Registers • Updated TAMPCTRL text in Tamper Detection • Added new Register Description topic • Removed redundant text in Register Description - Mode 0 - 32-Bit Counter • Removed redundant text in Register Description - Mode 1 - 16-Bit Counter • Removed redundant text in Register Description - Mode 2 - Clock/ Calendar • The following 32 bit, 16 bit and Clock registers were updated with enableprotection text, new properties and typographical corrections: – CTRLA – EVCTRL – SYNCBUSY – GP – TIMESTAMP • Corrected bit names in Events • The Not Enable-Protected attribute was updated for the CTRL register • The CHCTRLB register was updated to correct a bit offset • Changed the name of the EXTINTx bit in Events to EXTINT0-7 • Updated the CTRLA Register with a new Register Property • Corrected a typographical error in the following registers changing Enabled-Protected to Enable-Protected: – EVCTRL – ASYNCH – CONFIG – DEBOUNCEN Datasheet DS60001513F-page 1110 SAM L10/L11 Family Data Sheet Revision History ...........continued Section NVMCTRL TRAM PORT - I/O Pin Controller EVSYS SERCOM SERCOM - USART SERCOM - SPI © 2020 Microchip Technology Inc. Updates • Updated Overview with new bit names in the text for FLASH, Data Flash and NVM rows • Removed an erroneous Note from Features • Removed erroneous STATUS register reference from Register Access Protection • Updated Memory Organization with new bit names in the text for FLASH, Data Flash and NVM rows • Updated NVM User Row (UROW) References in Region Unlock Bits • Updated Command and Data Interface with new bit names in the text for FLASH, Data Flash and NVM rows • Updated NVM Rows data in NVM Rows Operations • Updated the Memory Regions and Attribute table in SAM L11 Trustzone Protections Considerations • Updated text for FLASH and NVM references in Lock Regions • Added a new note to the Register Description • The following registers were updated with corrections to properties, enable-protected text, FLASH, or bitfields: – CTRLA – CTRLC – SCFGB – SCFGAD • References to the Data Scramble Control (DSCC) register, Permutation Write (PERMW) register, and the RAM (RAM[0:63]) addresses were removed from Register Access Protection • Corrected typographical errors in Initialization • The following registers had their properties updated: – CTRLA – STATUS – SYNCBUSY – PERMR • Updated the Cross Reference for the Nested Vector Interrupt Controller in Interrupts • Updated Register Access Protection with new introductory text and a reference to the INTFLAG register • Corrected typographical errors in Events • Added an Event Input Pin reference to the EVCTRL register • Added reference to the CHINTFLAGn register in Register Access Protection • Updated the register reset value on the READYUSR register • Corrected multiple bit names in the Event Generators table in the CHANNELn register • Corrected multiple values in the User Multiplexer Number m table of the USERm register • Introductory text in Register Access Protection was rephrased, and text referring to the INTFLAG, STATUS, DATA, and ADDR registers was removed • Corrected typographical errors in Initialization • Added new line item information for the CTRLC register and the RXPL register to Initialization • Updated the Register property for the CTRLA Register • Updated the Register properties and added “these bits are not synchronized” text to the following registers: – CTRLA – CTRLB Datasheet DS60001513F-page 1111 SAM L10/L11 Family Data Sheet Revision History ...........continued Section SERCOM I2C TC Updates • Updated Register Access Protection to remove the reference to the ADDR Register • The Slave CTRLA Register was updated with a new Register property and the text “this bit is not synchronized” for the LOWTOUT bit • The Slave CTRLB Register has the register property corrected, and the text “These bits are not write synchronized,” removed • The Master CTRLA Register was updated with a new Register Property • Removed COUNT register information from Register Access Protection. • Corrected the name of the Match or Capture Channel Bit from MCx to MCO-1 in Interrupts • Corrected the name of the Match or Capture Channel Bit from MC0-1 to MCXO-1 in Events • Added new information for Control B Clear and Control B Set Registers, and Channel x Compare/Capture Value in Synchronization • Added new topics: – • Register Description - 16-bit Mode – Register Description - 32-bit Mode The following registers were updated: – Added “This bit is not synchronized” to the COPENx bit of the CTRLA Register – Updated the Register Property for the Status Register TRNG • Updated Register Access Protection with new information for INTFLAG and DATA Registers. CCL • Updated Events with new information, replacing OUTx with “LUT_n where n=0-1” • Updated the Enable bit of the LUTCTRL Register with new text, “This bit is not Enable-Protected” • Updated the name of the bus clock in Clocks to CLK_ADC_APB • SEQCTRLwas updated to remove an erroneous ‘n’ from the name of the Register. • Updated Events to display the bit name COMP0-1, and removed information for START0 and START1 • The following registers had their register properties updated: ADC AC – DAC 56.4 Register Description - 8-bit Mode – CTRLB – STATUSA – STATUSB – SYNCBUSY • Removed EVCTRL references from Initialization • Updated the Register Property for the INTFLAG Register Rev C - 02/2019 Section Updates Configuration Summary Updated SAML10/L11 Family Features Oscillators Pinout Updated XOSC32 Jitter Minimization Memories 13.1 Features © 2020 Microchip Technology Inc. • Updated NVM Software Calibration Bitfields Definition • Updated SAM L11 BOCOR Bitfields Definition • Updated SAM L11 BOCOR Mapping • Updated Features • Updated CRYA APIs Addresses with a note Datasheet DS60001513F-page 1112 SAM L10/L11 Family Data Sheet Revision History ...........continued Section Boot ROM Device Service Unit (DSU) Power Manager (PM) Oscillators Controller (OSCCTRL) Updates • Updated Secure Boot Options • Updated Accessible Memory Range by Read Auxiliary Row Command, and added a note Updated STATUSB Register • Updated PLCFG Register • Corrected missing Block Diagram • Updated the reset value for the STATUS Register 32KHz Oscillators Controller (OSC32KCTRL) Updated the ULP32KSW bit in the OSCULP32K Register Supply Controller (SUPC) Corrected erroneous text and added a note to Low Power VREF in Active Mode Real Time Counter (RTC) • Updated RTC Block Diagram (Tamper Detection Use Case) • Updated Active Layer Protection • Updated TAMPCTRL Register with new notes for the DEBNC and TAMLVL bits • Updated TAMPCTRLB Register with a note for the ALSI bits • Updated the text for the DMAC Clocks section • Updated the LVLEN bits for the CRTL Register • Updated the LVLEX bits for the ACTIVE Register • Updated the NMIFLAG Register • Updated the CONFIG Register to reflect changes to the FILTEN and SENSE bits • Corrected erroneous text in Cache • Corrected table entries in Memory Regions AHB Access Limitations and an updated a note. • Updated Data Flash Scrambling • Corrected Erroneous text in Overview • Updated Features I/O Pin Controller (PORT) • Updated the PORTEI, EVACT, and PID bits in the EVCTRL Register Event System (EVSYS) • Corrected text in Initialization SERCOM USART • Updated the BAUD Register • Updated the equation in the RXPL Register • Updated Signal Description Direct Memory Access Controller (DMAC) External Interrupt Controller (EIC) Nonvolatile Memory Controller (NVMCTRL) TrustRAM (TRAM) SERCOM I2C Timer/Counter (TC) Configurable Custom Logic (CCL) © 2020 Microchip Technology Inc. • Updated the property for the slave DATA Register • Updated the master DATA Register • Updated the MCEO bits in the EVCTRL Register for 8-bit, 16-bit and 32bit Modes • Updated The MC Bits in the INTENCLR, INTENSET, and INTFLAG Registers for 8-bit, 16-bit and 32-bit Modes • Updated the CCBUFV bit in the STATUS Register for 8-bit, 16-bit and 32bit Modes • Updated the INVEN Bit in the DRVCTRL Register for 8-bit, 16-bit and 32bit Modes • Updated text in Overview • Updated the Block Diagram • Updated the table in Signal Description • Updated Linked LUT • Updated Analog Comparator Inputs • Removed erroneous TCC text • Updated the INSEL bits in the LUTCTRL0 Register • Updated the INSEL bits in the LUTCTRL1 Register Datasheet DS60001513F-page 1113 SAM L10/L11 Family Data Sheet Revision History ...........continued Section Analog-to-Digital Converter (ADC) Analog Comparators (AC) • Updated Features • Updated the Block Diagram • Updated the text in ADC Resolution • Added a note in Oversampling and Decimation • Updated the CTRLC Register • Updated the text in VDD Scaler • Updated the START bits in the CTRLB Register • Updated the COMPEO, COMPEI, and INVEI bits in the EVCTRL Register • Updated the COMP bits in the INTENCLR, INTENSET, and INTFLAG Registers • Updated the STATE bits in the STATUSA Register • Updated the READY bits in the STATUSB Register • Updated the COMPCTRL bits in the SYNCBUSY Register • Updated Features • Updated Dithering Mode • Updated the diagram in 44.6.11.3 Offset Compensation • Updated the READY bits of the STATUS Register • Updated the note in Absolute Maximum Ratings • Removed erroneous data from the External Components Requirements in Switching Mode Table • Updated the Operating Conditions Table • Updated Active Current Consumption • Updated Digital frequency Locked Loop Characteristics Electrical Characteristics at 125°C • Updated “Operating Conditions Table” . Schematic Checklist • Updated “External Analog Reference Schematic with one reference”. Digital-to-Analog Converter (DAC) Operational Amplifier Controller (OPAMP) Electrical Characteristics 56.5 Updates Appendix A New Section for Migrating From SAM L21 to SAM L10/L11 (32-pin Package) Appendix B New Section for Migrating From SAM D20/D21 to SAM L10/L11 (32-pin Package) Rev B - 06/2018 Added new documentation for Electrical Characteristics -125°C. 56.6 Rev A - 09/2017 This is the initial released version of the document. © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1114 SAM L10/L11 Family The Microchip Web Site Microchip provides online support via our web site at www.microchip.com/. This web site is used as a means to make files and information easily available to customers. Accessible by using your favorite Internet browser, the web site contains the following information: • • • Product Support – Data sheets and errata, application notes and sample programs, design resources, user’s guides and hardware support documents, latest software releases and archived software General Technical Support – Frequently Asked Questions (FAQ), technical support requests, online discussion groups, Microchip consultant program member listing Business of Microchip – Product selector and ordering guides, latest Microchip press releases, listing of seminars and events, listings of Microchip sales offices, distributors and factory representatives Customer Change Notification Service Microchip’s customer notification service helps keep customers current on Microchip products. Subscribers will receive e-mail notification whenever there are changes, updates, revisions or errata related to a specified product family or development tool of interest. To register, access the Microchip web site at www.microchip.com/. Under “Support”, click on “Customer Change Notification” and follow the registration instructions. Customer Support Users of Microchip products can receive assistance through several channels: • • • • Distributor or Representative Local Sales Office Field Application Engineer (FAE) Technical Support Customers should contact their distributor, representative or Field Application Engineer (FAE) for support. Local sales offices are also available to help customers. A listing of sales offices and locations is included in the back of this document. Technical support is available through the web site at: www.microchip.com/support © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1115 SAM L10/L11 Family Product Identification System To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office. ATSAML 11 D 14 A M U T KPH Securely Key Provisioned SAML = Ultra Low Power Microcontroller No character = Tray or Tube 10 = Cortex-M23 CPU 11 = Cortex-M23 CPU with TrustZone Enabled U = -40 - +85°C Matte Sn Plating F = -40 - +125°C Matte Sn Plating Z = -40 - +125°C Matte Sn Plating (AEC-Q100 Qualified) D = 24 Pins E = 32 Pins (Flash) 16 = 64 KB 15 = 32 KB 14 = 16 KB A = TQFP M = VQFN Y = SSOP U = WLCSP Microchip Devices Code Protection Feature Note the following details of the code protection feature on Microchip devices: • • • • • Microchip products meet the specification contained in their particular Microchip Data Sheet. Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the intended manner and under normal conditions. There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data Sheets. Most likely, the person doing so is engaged in theft of intellectual property. Microchip is willing to work with the customer who is concerned about the integrity of their code. Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not mean that we are guaranteeing the product as “unbreakable.” Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act. Legal Notice Information contained in this publication regarding device applications and the like is provided only for your convenience and may be superseded by updates. It is your responsibility to ensure that your application meets with your specifications. MICROCHIP MAKES NO REPRESENTATIONS OR WARRANTIES OF ANY KIND WHETHER EXPRESS OR IMPLIED, WRITTEN OR ORAL, STATUTORY OR OTHERWISE, RELATED TO THE INFORMATION, INCLUDING BUT NOT LIMITED TO ITS CONDITION, QUALITY, PERFORMANCE, MERCHANTABILITY OR FITNESS FOR PURPOSE. Microchip disclaims all liability arising from this information and its use. Use of Microchip devices in life support and/or safety applications is entirely at the buyer’s risk, and the buyer agrees to defend, © 2020 Microchip Technology Inc. Datasheet DS60001513F-page 1116 SAM L10/L11 Family indemnify and hold harmless Microchip from any and all damages, claims, suits, or expenses resulting from such use. No licenses are conveyed, implicitly or otherwise, under any Microchip intellectual property rights unless otherwise stated. Trademarks The Microchip name and logo, the Microchip logo, AnyRate, AVR, AVR logo, AVR Freaks, BeaconThings, BitCloud, CryptoMemory, CryptoRF, dsPIC, FlashFlex, flexPWR, Heldo, JukeBlox, KeeLoq, KeeLoq logo, Kleer, LANCheck, LINK MD, maXStylus, maXTouch, MediaLB, megaAVR, MOST, MOST logo, MPLAB, OptoLyzer, PIC, picoPower, PICSTART, PIC32 logo, Prochip Designer, QTouch, RightTouch, SAM-BA, SpyNIC, SST, SST Logo, SuperFlash, tinyAVR, UNI/O, and XMEGA are registered trademarks of Microchip Technology Incorporated in the U.S.A. and other countries. ClockWorks, The Embedded Control Solutions Company, EtherSynch, Hyper Speed Control, HyperLight Load, IntelliMOS, mTouch, Precision Edge, and Quiet-Wire are registered trademarks of Microchip Technology Incorporated in the U.S.A. Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any Capacitor, AnyIn, AnyOut, BodyCom, chipKIT, chipKIT logo, CodeGuard, CryptoAuthentication, CryptoCompanion, CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average Matching, DAM, ECAN, EtherGREEN, In-Circuit Serial Programming, ICSP, Inter-Chip Connectivity, JitterBlocker, KleerNet, KleerNet logo, Mindi, MiWi, motorBench, MPASM, MPF, MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach, Omniscient Code Generation, PICDEM, PICDEM.net, PICkit, PICtail, PureSilicon, QMatrix, RightTouch logo, REAL ICE, Ripple Blocker, SAM-ICE, Serial Quad I/O, SMART-I.S., SQI, SuperSwitcher, SuperSwitcher II, Total Endurance, TSHARC, USBCheck, VariSense, ViewSpan, WiperLock, Wireless DNA, and ZENA are trademarks of Microchip Technology Incorporated in the U.S.A. and other countries. SQTP is a service mark of Microchip Technology Incorporated in the U.S.A. Silicon Storage Technology is a registered trademark of Microchip Technology Inc. in other countries. GestIC is a registered trademark of Microchip Technology Germany II GmbH & Co. KG, a subsidiary of Microchip Technology Inc., in other countries. All other trademarks mentioned herein are property of their respective companies. © 2017, Microchip Technology Incorporated, Printed in the U.S.A., All Rights Reserved. ISBN: 978-1-5224-6296-5 Quality Management System Certified by DNV ISO/TS 16949 Microchip received ISO/TS-16949:2009 certification for its worldwide headquarters, design and wafer fabrication facilities in Chandler and Tempe, Arizona; Gresham, Oregon and design centers in California and India. The Company’s quality system processes and procedures are for its PIC® MCUs and dsPIC® DSCs, KEELOQ® code hopping devices, Serial EEPROMs, microperipherals, nonvolatile memory and analog products. In addition, Microchip’s quality system for the design and manufacture of development systems is ISO 9001:2000 certified. © 2020 Microchip Technology Inc. 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Datasheet DS60001513F-page 1118
ATSAML11D14A-MUT 价格&库存

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ATSAML11D14A-MUT
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  • 1+21.424941+2.65776
  • 25+19.6522125+2.43785
  • 100+17.79314100+2.20723
  • 1000+16.930021000+2.10016

库存:5884