ATTINY426-SFR

ATtiny424/426/427 ATtiny824/826/827 tinyAVR® 2 Family Introduction The ATtiny424/426/427 and ATtiny824/826/827 microcontrollers of the tinyAVR® 2 family are using the AVR® CPU with hardware multiplier, running at up to 20 MHz, with 4/8 KB Flash, 512B/1 KB of SRAM, and 128B of EEPROM available in a 14-, 20-, and 24-pin package. The family uses the latest technologies from Microchip with a flexible and low-power architecture, including an Event System, advanced digital peripherals, and accurate analog features such as a 12-bit differential ADC with Programmable Gain Amplifier(PGA). tinyAVR® 2 Family Overview The figure below shows the tinyAVR® 2 family devices, laying out pin count variants and memory sizes. • Vertical migration is possible without code modification, as these devices are fully pin and feature compatible • Horizontal migration to the left reduces the pin count and, therefore, the available features Figure 1. tinyAVR® 2 Family Overview Devices described in this data sheet Devices described in other data sheets Flash 32 KB ATtiny3224 ATtiny3226 ATtiny3227 16 KB ATtiny1624 ATtiny1626 ATtiny1627 8 KB ATtiny824 ATtiny826 ATtiny827 4 KB ATtiny424 ATtiny426 ATtiny427 14 20 24 Pins Devices with different flash memory sizes typically also have different SRAM and EEPROM. The name of a device in the tinyAVR® 2 family is decoded as follows: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 1 ATtiny424/426/427 ATtiny824/826/827 Figure 2. tinyAVR® 2 Family Device Designations AT tiny 827 - MUR - VAO ® Variant Suffix AVR product family Flash size in KB Family number Pin count VAO = Automotive Blank = Standard Carrier Type R = Tape & Reel Blank = Tube or Tray 7=24 pins 6=20 pins 4=14 pins Temperature Range Package Type M=VQFN S=SOIC300 SS=SOIC150 X=TSSOP, SSOP U = -40°C to +85°C F = -40°C to +125°C Note:  Tape and Reel identifier only appears in the catalog part number description. This identifier is used for ordering purposes. Check with your Microchip Sales Office for package availability with the Tape and Reel option. Note:  The VAO variants have been designed, manufactured, tested, and qualified in accordance with AEC-Q100 requirements for automotive applications. These products may use a different package than non-VAO parts and can have additional specifications in their Electrical Characteristics. Memory Overview The following table shows the memory overview of the entire family, but further documentation describes only the ATtiny424/426/427 and ATtiny824/826/827 devices. Table 1. Memory Overview Device ATtiny424 ATtiny426 ATtiny427 ATtiny824 ATtiny826 ATtiny827 ATtiny1624 ATtiny1626 ATtiny1627 ATtiny3224 ATtiny3226 ATtiny3227 Flash Memory 4 KB 8 KB 16 KB 32 KB SRAM 512B 1 KB 2 KB 3 KB EEPROM 128B 128B 256B 256B User Row 32B 32B 32B 32B Peripheral Overview Table 2. Peripheral Overview Device ATtiny424 ATtiny824 ATtiny426 ATtiny826 ATtiny427 ATtiny827 Pins 14 20 24 Package SOIC, TSSOP SOIC, SSOP,VQFN VQFN Maximum frequency (MHz) 20 20 20 General purpose I/O 12 18 22 PORT PA[7:0] PB[3:0] PA[7:0] PB[5:0] PC[3:0] PA[7:0] PB[7:0] PC[5:0] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 2 ATtiny424/426/427 ATtiny824/826/827 ...........continued Device ATtiny424 ATtiny824 ATtiny426 ATtiny826 ATtiny427 ATtiny827 External interrupts 12 18 22 Event system channels 6 6 6 CCL LUTs 4 4 4 Real-Time Counter (RTC) 1 1 1 16-bit Timer/Counter type A (TCA) 1 1 1 16-bit Timer/Counter type B (TCB) 2 2 2 12-bit Timer/Counter type D (TCD) - - - USART/SPI host 2 2 2 SPI 1 1 1 TWI (I2C) 1 1 1 ADC (channels) 1 (9) 1 (15) 1 (15) DAC - - - Analog Comparators (inputs) 1 (2p/2n) 1 (3p/3n) 1 (4p/3n) Peripheral Touch Controller (PTC) (self cap/mutual cap channels) - - - Unified Program and Debug Interface (UPDI) activated by shared pin using high-voltage signal or fuse override 1 1 1 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 3 ATtiny424/426/427 ATtiny824/826/827 Features • High-Performance Low-Power AVR® CPU – Running at up to 20 MHz – Single-cycle I/O access – Two-level interrupt controller with vectored interrupts – Two-cycle hardware multiplier – Supply voltage range: 1.8V to 5.5V • Memories – 4/8 KB In-System self-programmable Flash memory – 512B/1 KB SRAM – 128B EEPROM – 32B of user row in nonvolatile memory that can keep data during chip-erase and be programmed while the device is locked – Write/erase endurance • Flash 10,000 cycles • EEPROM 100,000 cycles • • – Data retention: 40 years at 55°C System – Power-on Reset (POR) – Brown-out Detection (BOD) – Clock options • Lockable 20 MHz Low-Power internal oscillator • 32.768 kHz Ultra-Low Power (ULP) internal oscillator • 32.768 kHz external crystal oscillator • External clock input – Single-pin Unified Program and Debug Interface (UPDI) – Three sleep modes • Idle with all peripherals running and immediate wake-up time • Standby with configurable operation of selected peripherals • Power-Down with full data retention Peripherals – One 16-bit Timer/Counter type A (TCA) with a dedicated period register and three PWM channels – Two 16-bit Timer/Counters type B (TCB) with input capture and simple PWM functionality – One 16-bit Real-Time Counter (RTC) running from external 32.768 kHz crystal or internal 32.768 kHz ULP oscillator – Two Universal Synchronous Asynchronous Receiver Transmitters (USART) with fractional baud rate generator, auto-baud, and start-of-frame detection – Host/Client Serial Peripheral Interface (SPI) – Host/Client Two-Wire Interface (TWI) with dual address match • Standard mode (Sm, 100 kHz) • Fast mode (Fm, 400 kHz) • Fast mode plus (Fm+, 1 MHz) – Event System for CPU independent and predictable inter-peripheral signaling – Configurable Custom Logic (CCL) with four programmable Look-Up Tables (LUT) – One Analog Comparator (AC) with scalable reference input – One 12-bit differential 375 ksps Analog-to-Digital Converter (ADC) with Programmable Gain Amplifier (PGA) and up to 15 input channels – Multiple internal voltage references • 1.024V © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 4 ATtiny424/426/427 ATtiny824/826/827 • • • • • 2.048V • 2.500V • 4.096V • VDD – Automated Cyclic Redundancy Check (CRC) flash memory scan – Watchdog Timer (WDT) with Window Mode, with a separate on-chip oscillator – External interrupt on all general purpose pins I/O and Packages – Up to 22 programmable I/O pins – 14-pin • SOIC • TSSOP – 20-pin • SOIC • SSOP • VQFN 3x3 mm – 24-pin • VQFN 4x4 mm Temperature Ranges – -40°C to 85°C (industrial) – -40°C to 125°C (extended) Speed Grades (-40°C to 85°C) – 0-5 MHz @ 1.8V – 5.5V – 0-10 MHz @ 2.7V – 5.5V – 0-20 MHz @ 4.5V – 5.5V Speed Grades (-40°C to 125°C) – 0-8 MHz @ 2.7V - 5.5V – 0-16 MHz @ 4.5V - 5.5V © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 5 ATtiny424/426/427 ATtiny824/826/827 Table of Contents Introduction.....................................................................................................................................................1 tinyAVR® 2 Family Overview..........................................................................................................................1 1. 2. Memory Overview........................................................................................................................ 2 Peripheral Overview..................................................................................................................... 2 Features......................................................................................................................................................... 4 1. Block Diagram.......................................................................................................................................12 2. Pinout.................................................................................................................................................... 13 2.1. 2.2. 2.3. 2.4. 3. I/O Multiplexing and Considerations..................................................................................................... 17 3.1. 4. Numerical Notation.....................................................................................................................22 Memory Size and Type...............................................................................................................22 Frequency and Time...................................................................................................................22 Registers and Bits...................................................................................................................... 23 ADC Parameter Definitions........................................................................................................ 24 AVR® CPU............................................................................................................................................ 27 6.1. 6.2. 6.3. 6.4. 6.5. 6.6. 6.7. 7. General Guidelines.....................................................................................................................18 Connection for Power Supply.....................................................................................................18 Connection for RESET............................................................................................................... 19 Connection for UPDI Programming............................................................................................20 Connecting External Crystal Oscillators..................................................................................... 20 Connection for External Voltage Reference............................................................................... 21 Conventions.......................................................................................................................................... 22 5.1. 5.2. 5.3. 5.4. 5.5. 6. I/O Multiplexing...........................................................................................................................17 Hardware Guidelines.............................................................................................................................18 4.1. 4.2. 4.3. 4.4. 4.5. 4.6. 5. 14-Pin SOIC, TSSOP................................................................................................................. 13 20-Pin SOIC, SSOP................................................................................................................... 14 20-Pin VQFN.............................................................................................................................. 15 24-Pin VQFN.............................................................................................................................. 16 Features..................................................................................................................................... 27 Overview.................................................................................................................................... 27 Architecture................................................................................................................................ 27 Arithmetic Logic Unit (ALU)........................................................................................................ 29 Functional Description................................................................................................................29 Register Summary......................................................................................................................33 Register Description................................................................................................................... 33 Memories.............................................................................................................................................. 37 7.1. 7.2. 7.3. 7.4. Overview.................................................................................................................................... 37 Memory Map.............................................................................................................................. 37 In-System Reprogrammable Flash Program Memory................................................................37 SRAM Data Memory.................................................................................................................. 38 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 6 ATtiny424/426/427 ATtiny824/826/827 7.5. 7.6. 7.7. 7.8. 7.9. 7.10. 8. Peripherals and Architecture.................................................................................................................61 8.1. 8.2. 8.3. 9. EEPROM Data Memory............................................................................................................. 38 USERROW - User Row..............................................................................................................39 LOCKBIT - Memory Sections Access Protection....................................................................... 39 FUSE - Configuration and User Fuses.......................................................................................42 SIGROW - Signature Row..........................................................................................................50 I/O Memory.................................................................................................................................58 Peripheral Address Map.............................................................................................................61 Interrupt Vector Mapping............................................................................................................ 62 SYSCFG - System Configuration............................................................................................... 63 General Purpose I/O Registers............................................................................................................. 66 9.1. 9.2. Register Summary......................................................................................................................67 Register Description................................................................................................................... 67 10. NVMCTRL - Nonvolatile Memory Controller......................................................................................... 69 10.1. 10.2. 10.3. 10.4. 10.5. Features..................................................................................................................................... 69 Overview.................................................................................................................................... 69 Functional Description................................................................................................................70 Register Summary......................................................................................................................76 Register Description................................................................................................................... 76 11. CLKCTRL - Clock Controller................................................................................................................. 84 11.1. 11.2. 11.3. 11.4. 11.5. Features..................................................................................................................................... 84 Overview.................................................................................................................................... 84 Functional Description................................................................................................................86 Register Summary......................................................................................................................90 Register Description................................................................................................................... 90 12. SLPCTRL - Sleep Controller............................................................................................................... 100 12.1. 12.2. 12.3. 12.4. 12.5. Features................................................................................................................................... 100 Overview.................................................................................................................................. 100 Functional Description..............................................................................................................100 Register Summary....................................................................................................................104 Register Description................................................................................................................. 104 13. RSTCTRL - Reset Controller.............................................................................................................. 106 13.1. 13.2. 13.3. 13.4. 13.5. Features................................................................................................................................... 106 Overview.................................................................................................................................. 106 Functional Description..............................................................................................................107 Register Summary.................................................................................................................... 111 Register Description..................................................................................................................111 14. CPUINT - CPU Interrupt Controller..................................................................................................... 114 14.1. 14.2. 14.3. 14.4. Features................................................................................................................................... 114 Overview...................................................................................................................................114 Functional Description.............................................................................................................. 115 Register Summary ...................................................................................................................120 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 7 ATtiny424/426/427 ATtiny824/826/827 14.5. Register Description................................................................................................................. 120 15. EVSYS - Event System.......................................................................................................................125 15.1. 15.2. 15.3. 15.4. 15.5. Features................................................................................................................................... 125 Overview.................................................................................................................................. 125 Functional Description..............................................................................................................126 Register Summary....................................................................................................................132 Register Description................................................................................................................. 132 16. PORTMUX - Port Multiplexer.............................................................................................................. 138 16.1. Overview.................................................................................................................................. 138 16.2. Register Summary....................................................................................................................139 16.3. Register Description................................................................................................................. 139 17. PORT - I/O Pin Configuration..............................................................................................................146 17.1. 17.2. 17.3. 17.4. 17.5. 17.6. 17.7. Features................................................................................................................................... 146 Overview.................................................................................................................................. 146 Functional Description..............................................................................................................148 Register Summary - PORTx.....................................................................................................152 Register Description - PORTx.................................................................................................. 152 Register Summary - VPORTx.................................................................................................. 165 Register Description - VPORTx................................................................................................165 18. BOD - Brown-out Detector.................................................................................................................. 170 18.1. 18.2. 18.3. 18.4. 18.5. Features................................................................................................................................... 170 Overview.................................................................................................................................. 170 Functional Description..............................................................................................................171 Register Summary....................................................................................................................173 Register Description................................................................................................................. 173 19. VREF - Voltage Reference..................................................................................................................180 19.1. 19.2. 19.3. 19.4. 19.5. Features................................................................................................................................... 180 Overview.................................................................................................................................. 180 Functional Description..............................................................................................................180 Register Summary....................................................................................................................182 Register Description................................................................................................................. 182 20. WDT - Watchdog Timer ......................................................................................................................185 20.1. 20.2. 20.3. 20.4. 20.5. Features................................................................................................................................... 185 Overview.................................................................................................................................. 185 Functional Description..............................................................................................................186 Register Summary....................................................................................................................189 Register Description................................................................................................................. 189 21. TCA - 16-bit Timer/Counter Type A.....................................................................................................193 21.1. 21.2. 21.3. 21.4. Features................................................................................................................................... 193 Overview.................................................................................................................................. 193 Functional Description..............................................................................................................195 Register Summary - Normal Mode...........................................................................................207 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 8 ATtiny424/426/427 ATtiny824/826/827 21.5. Register Description - Normal Mode........................................................................................ 207 21.6. Register Summary - Split Mode............................................................................................... 226 21.7. Register Description - Split Mode.............................................................................................226 22. TCB - 16-Bit Timer/Counter Type B.................................................................................................... 242 22.1. 22.2. 22.3. 22.4. 22.5. Features................................................................................................................................... 242 Overview.................................................................................................................................. 242 Functional Description..............................................................................................................244 Register Summary....................................................................................................................254 Register Description................................................................................................................. 254 23. RTC - Real-Time Counter................................................................................................................... 265 23.1. Features................................................................................................................................... 265 23.2. Overview.................................................................................................................................. 265 23.3. Clocks.......................................................................................................................................266 23.4. RTC Functional Description..................................................................................................... 266 23.5. PIT Functional Description....................................................................................................... 267 23.6. Crystal Error Correction............................................................................................................269 23.7. Events...................................................................................................................................... 269 23.8. Interrupts.................................................................................................................................. 270 23.9. Sleep Mode Operation............................................................................................................. 271 23.10. Synchronization........................................................................................................................271 23.11. Debug Operation...................................................................................................................... 271 23.12. Register Summary................................................................................................................... 272 23.13. Register Description.................................................................................................................272 24. USART - Universal Synchronous and Asynchronous Receiver and Transmitter................................289 24.1. 24.2. 24.3. 24.4. 24.5. Features................................................................................................................................... 289 Overview.................................................................................................................................. 289 Functional Description..............................................................................................................290 Register Summary....................................................................................................................305 Register Description................................................................................................................. 305 25. SPI - Serial Peripheral Interface..........................................................................................................323 25.1. 25.2. 25.3. 25.4. 25.5. Features................................................................................................................................... 323 Overview.................................................................................................................................. 323 Functional Description..............................................................................................................324 Register Summary....................................................................................................................331 Register Description................................................................................................................. 331 26. TWI - Two-Wire Interface.................................................................................................................... 338 26.1. 26.2. 26.3. 26.4. 26.5. Features................................................................................................................................... 338 Overview.................................................................................................................................. 338 Functional Description..............................................................................................................339 Register Summary....................................................................................................................350 Register Description................................................................................................................. 350 27. CRCSCAN - Cyclic Redundancy Check Memory Scan...................................................................... 367 27.1. Features................................................................................................................................... 367 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 9 ATtiny424/426/427 ATtiny824/826/827 27.2. 27.3. 27.4. 27.5. Overview.................................................................................................................................. 367 Functional Description..............................................................................................................368 Register Summary....................................................................................................................371 Register Description................................................................................................................. 371 28. CCL - Configurable Custom Logic...................................................................................................... 375 28.1. 28.2. 28.3. 28.4. 28.5. Features................................................................................................................................... 375 Overview.................................................................................................................................. 375 Functional Description..............................................................................................................377 Register Summary ...................................................................................................................385 Register Description................................................................................................................. 385 29. AC - Analog Comparator.....................................................................................................................395 29.1. 29.2. 29.3. 29.4. 29.5. Features................................................................................................................................... 395 Overview.................................................................................................................................. 395 Functional Description..............................................................................................................396 Register Summary....................................................................................................................398 Register Description................................................................................................................. 398 30. ADC - Analog-to-Digital Converter...................................................................................................... 404 30.1. 30.2. 30.3. 30.4. 30.5. Features................................................................................................................................... 404 Overview.................................................................................................................................. 404 Functional Description..............................................................................................................405 Register Summary....................................................................................................................418 Register Description................................................................................................................. 418 31. UPDI - Unified Program and Debug Interface.....................................................................................438 31.1. 31.2. 31.3. 31.4. 31.5. Features................................................................................................................................... 438 Overview.................................................................................................................................. 438 Functional Description..............................................................................................................440 Register Summary....................................................................................................................460 Register Description................................................................................................................. 460 32. Instruction Set Summary.....................................................................................................................471 33. Electrical Characteristics.....................................................................................................................472 33.1. Disclaimer.................................................................................................................................472 33.2. Absolute Maximum Ratings .....................................................................................................472 33.3. General Operating Ratings ......................................................................................................473 33.4. Power Considerations.............................................................................................................. 474 33.5. Power Consumption ................................................................................................................ 475 33.6. Wake-Up Time..........................................................................................................................476 33.7. Peripherals Power Consumption..............................................................................................477 33.8. BOD and POR Characteristics................................................................................................. 478 33.9. External Reset Characteristics................................................................................................. 479 33.10. Oscillators and Clocks..............................................................................................................479 33.11. I/O Pin Characteristics..............................................................................................................481 33.12. USART..................................................................................................................................... 482 33.13. SPI........................................................................................................................................... 483 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 10 ATtiny424/426/427 ATtiny824/826/827 33.14. 33.15. 33.16. 33.17. 33.18. 33.19. 33.20. TWI...........................................................................................................................................484 VREF........................................................................................................................................487 ADC..........................................................................................................................................488 TEMPSENSE........................................................................................................................... 490 AC............................................................................................................................................ 491 UPDI.........................................................................................................................................492 Programming Time...................................................................................................................492 34. Typical Characteristics........................................................................................................................ 494 34.1. 34.2. 34.3. 34.4. 34.5. 34.6. 34.7. 34.8. 34.9. Power Consumption................................................................................................................. 494 GPIO........................................................................................................................................ 494 VREF Characteristics............................................................................................................... 501 BOD Characteristics.................................................................................................................501 ADC Characteristics................................................................................................................. 504 TEMPSENSE Characteristics.................................................................................................. 504 AC Characteristics....................................................................................................................504 OSC20M Characteristics..........................................................................................................505 OSCULP32K Characteristics................................................................................................... 507 35. Ordering Information........................................................................................................................... 508 36. Package Drawings.............................................................................................................................. 510 36.1. 36.2. 36.3. 36.4. 36.5. 36.6. 36.7. Online Package Drawings........................................................................................................ 510 14-Pin SOIC............................................................................................................................. 511 14-Pin TSSOP..........................................................................................................................514 20-Pin SOIC............................................................................................................................. 517 20-Pin SSOP............................................................................................................................ 520 20-Pin VQFN............................................................................................................................ 522 24-Pin VQFN............................................................................................................................ 525 37. Data Sheet Revision History............................................................................................................... 528 37.1. Rev. A - 03/2021.......................................................................................................................528 The Microchip Website...............................................................................................................................529 Product Change Notification Service..........................................................................................................529 Customer Support...................................................................................................................................... 529 Product Identification System.....................................................................................................................530 Microchip Devices Code Protection Feature.............................................................................................. 530 Legal Notice............................................................................................................................................... 530 Trademarks................................................................................................................................................ 531 Quality Management System..................................................................................................................... 531 Worldwide Sales and Service.....................................................................................................................532 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 11 ATtiny424/426/427 ATtiny824/826/827 Block Diagram 1. Block Diagram UPDI UPDI / RESET CRC CPU OCD Flash SRAM BUS Matrix EEPROM AINm ADCn PORTS PGA PORTMUX AINPm AINNm OUT ACn VREFA VREF EVOUTx LUTn_INm LUTn_OUT WOm WO EVSYS CCL TCAn TCBn E V E N T R O U T I N G N E T W O R K D A T A B U S GPIOR CPUINT I N / O U T NVMCTRL Pxn D A T A B U S Detectors/power control System Management RSTCTRL POR VREG BOD VLM VDD CLKCTRL SLPCTRL Clock generation CLKOUT RXD TXD XCK XDIR OSC20M USARTn OSCULP32K RTC MISO MOSI SCK SS SPIn SDA SCL TWIn EXTCLK WDT TOSC1 XOSC32K TOSC2 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 12 ATtiny424/426/427 ATtiny824/826/827 Pinout 2. Pinout 2.1 14-Pin SOIC, TSSOP VDD 1 14 GND PA4 2 13 PA3 (EXTCLK) PA5 3 12 PA2 PA6 4 11 PA1 PA7 5 10 PA0 (UPDI/RESET) (TOSC1) PB3 6 9 PB0 (TOSC2) PB2 7 8 PB1 Power Functionality Power Supply Programming/Debug Ground Clock/Crystal Pin on VDD Power Domain Analog Function © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 13 ATtiny424/426/427 ATtiny824/826/827 Pinout 2.2 20-Pin SOIC, SSOP VDD 1 20 GND PA4 2 19 PA3 (EXTCLK) PA5 3 18 PA2 PA6 4 17 PA1 PA7 5 16 PA0 (UPDI/RESET) PB5 6 15 PC3 PB4 7 14 PC2 (TOSC1) PB3 8 13 PC1 (TOSC2) PB2 9 12 PC0 PB1 10 11 PB0 Power Functionality Power Supply Programming/Debug Ground Clock/Crystal Pin on VDD Power Domain Analog Function © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 14 ATtiny424/426/427 ATtiny824/826/827 Pinout PA1 PA0 (UPDI/RESET) PC3 PC2 PC1 20 19 18 17 16 20-Pin VQFN 3 13 PB1 VDD 4 12 PB2 (TOSC2) PA4 5 11 PB3 (TOSC1) 10 GND PB4 PB0 9 14 PB5 2 8 (EXTCLK) PA3 PA7 PC0 7 15 PA6 1 6 PA2 PA5 2.3 Power Functionality Power Supply Programming/Debug Ground Clock/Crystal Pin on VDD Power Domain Analog Function © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 15 ATtiny424/426/427 ATtiny824/826/827 Pinout PA1 PA0 (UPDI/RESET) PC5 PC4 PC3 PC2 24 23 22 21 20 19 24-Pin VQFN PB0 VDD 4 15 PB1 PA4 5 14 PB2 (TOSC2) PA5 6 13 PB3 (TOSC1) 12 16 PB4 3 11 GND PB5 PC0 10 17 PB6 2 9 (EXTCLK) PA3 PB7 PC1 8 18 PA7 1 7 PA2 PA6 2.4 Power Functionality Power Supply Programming/Debug Ground Clock/Crystal Pin on VDD Power Domain Analog Function Digital Function Only © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 16 ATtiny424/426/427 ATtiny824/826/827 I/O Multiplexing and Considerations 3. I/O Multiplexing and Considerations 3.1 I/O Multiplexing VQFN 20-pin TSSOP/SOIC 14-pin 19 16 10 Pin Other/Special ADC0(3) Name (1,2) AC0 USART0 USART1 SPI0 TWI0 TCA0 TCBn CCL VQFN 24-pin SSOP/SOIC 20-pin Table 3-1. PORT Function Multiplexing 23 24 20 17 11 PA1 AIN1 TXD(4) TXD MOSI LUT0-IN1 1 1 18 12 PA2 EVOUTA AIN2 RxD(4) RXD MISO LUT0-IN2 2 2 19 13 PA3 EXTCLK AIN3 XCK(4) XCK SCK WO3 3 3 20 14 GND 4 4 1 1 VDD 5 5 2 2 PA4 AIN4 XDIR(4) XDIR SS WO4 6 6 3 3 PA5 7 7 4 4 PA6 8 8 5 5 9 10 PA0 RESET UPDI VREFA PA7 EVOUTA(4) PB7 EVOUTB(4) LUT0-IN0 AIN5 OUT AIN6 AINN0 AIN7 AINP0 PB6 WO5 1,WO LUT0-OUT 0,WO LUT3-OUT(4) LUT1-OUT LUT2-OUT(4) AINP3 11 9 6 PB5 CLKOUT AIN8 AINP1 WO2(4) 12 10 7 PB4 RESET(4) AIN9 AINN1 WO1(4) 13 11 8 6 PB3 TOSC1 RxD WO0(4) LUT2-OUT 14 12 9 7 PB2 TOSC2 EVOUTB TxD WO2 LUT2-IN2 15 13 10 8 PB1 AIN10 AINP2 XCK SDA WO1 LUT2-IN1 16 14 11 9 PB0 AIN11 AINN2 XDIR SCL WO0 LUT2-IN0 17 15 12 PC0 AIN12 XCK(4) SCK(4) AIN13 RxD(4) MISO(4) AIN14 TxD(4) MOSI(4) AIN15 XDIR(4) SS(4) 18 16 13 PC1 19 17 14 PC2 20 18 15 PC3 EVOUTC LUT0-OUT 0,WO(4) LUT3-IN0 LUT1-OUT(4) LUT3-IN1 LUT3-IN2 WO3(4) 21 PC4 WO4(4) 22 PC5 WO5(4) LUT1-IN0 1,WO(4) LUT1-IN1 LUT3-OUT LUT1-IN2 Notes:  1. Pin names are of type Pxn with x being the PORT instance (A, B) and n the pin number. Notation for signals is PORTx_PINn. 2. All pins can be used for external interrupt where pins Px2 and Px6 of each port have full asynchronous detection. All pins can be used as event input. 3. AIN[15:8] can not be used as negative ADC input for differential measurements. 4. Alternative pin location. For selecting an alternative pin location, refer to the PORTMUX section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 17 ATtiny424/426/427 ATtiny824/826/827 Hardware Guidelines 4. Hardware Guidelines This section contains guidelines for designing or reviewing electrical schematics using AVR 8-bit microcontrollers. The information presented here is a brief overview of the most common topics. More detailed information can be found in application notes, listed in this section where applicable. This section covers the following topics: • • • • • • 4.1 General guidelines Connection for power supply Connection for RESET Connection for UPDI (Unified Program and Debug Interface) Connection for external crystal oscillators Connection for VREF (external voltage reference) General Guidelines Unused pins must be soldered to their respective soldering pads. The soldering pads must not be connected to the circuit. The PORT pins are in their default state after Reset. Follow the recommendations in the PORT section to reduce power consumption. All values are given as typical values and serve only as a starting point for circuit design. Refer to the following application notes for further information: • • 4.1.1 AVR040 - EMC Design Considerations AVR042 - AVR Hardware Design Considerations Special Consideration for Packages with Center Pad Flat packages often come with an exposed pad located on the bottom, often referred to as the center pad or the thermal pad. This pad is not electrically connected to the internal circuit of the chip, but it is mechanically bonded to the internal substrate and serves as a thermal heat sink as well as providing added mechanical stability. This pad must be connected to GND since the ground plane is the best heat sink (largest copper area) of the printed circuit board (PCB). 4.2 Connection for Power Supply The basics and details regarding the design of the power supply itself lie beyond the scope of these guidelines. For more detailed information about this subject, see the application notes mentioned at the beginning of this section. A decoupling capacitor must be placed close to the microcontroller for each supply pin pair (VDD, AVDD, or other power supply pin and its corresponding GND pin). If the decoupling capacitor is placed too far from the microcontroller, a high-current loop might form that will result in increased noise and increased radiated emission. Each supply pin pair (power input pin and ground pin) must have separate decoupling capacitors. It is recommended to place the decoupling capacitor on the same side of the PCB as the microcontroller. If space does not allow it, the decoupling capacitor may be placed on the other side through a via, but make sure the distance to the supply pin is kept as short as possible. If the board is experiencing high-frequency noise (upward of tens of MHz), add a second ceramic type capacitor in parallel to the decoupling capacitor described above. Place this second capacitor next to the primary decoupling capacitor. On the board layout from the power supply circuit, run the power and return traces to the decoupling capacitors first, and then to the device pins. This ensures that the decoupling capacitors are first in the power chain. Equally important is to keep the trace length between the capacitor and the power pins to a minimum, thereby reducing PCB trace inductance. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 18 ATtiny424/426/427 ATtiny824/826/827 Hardware Guidelines As mentioned at the beginning of this section, all values used in examples are typical values. The actual design may require other values. 4.2.1 Digital Power Supply For larger pin count package types, there are several VDD and corresponding GND pins. All the VDD pins in the microcontroller are internally connected. The same voltage must be applied to each of the VDD pins. The following figure shows the recommendation for connecting a power supply to the VDD pin(s) of the device. Figure 4-1. Recommended VDD Connection Circuit Schematic VDD Typical values (recommended): C1: 100 nF (primary decoupling capacitor) C2: 1-10 nF (HF decoupling capacitor) C3(*): 1 μF (decouplingcapacitor - optional) VDD C3 C1 C2 GND Important:  For systems that frequently cycle VDD or experience fast VDD transients, it is recommended to add an additional decoupling capacitor (C3) if the power supply slew rate exceeds the slew rate limits. Refer to the Supply Voltage section in the Electrical Characteristics for details about power supply slew rate limits. 4.3 Connection for RESET The RESET pin on the device is active-low, and setting the pin low externally will result in a Reset of the device. AVR devices feature an internal pull-up resistor on the RESET pin, and an external pull-up resistor is usually not required. The following figure shows the recommendation for connecting an external Reset switch to the device. Figure 4-2. Recommended External Reset Circuit Schematic RESET R1 SW1 Typical values (Recommended): C1: 100 nF (filtering capacitor) R1: 330 Ω (switch series resistance) C1 GND A resistor in series with the switch can safely discharge the filtering capacitor. This prevents a current surge when shorting the filtering capacitor, as this may cause a noise spike that can harm the system. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 19 ATtiny424/426/427 ATtiny824/826/827 Hardware Guidelines 4.4 Connection for UPDI Programming The standard connection for UPDI programming is a 100-mil 6-pin 2x3 header. Even though three pins are sufficient for programming most AVR devices, it is recommended to use a 2x3 header since most programming tools are delivered with 100-mil 6-pin 2x3 connectors. The following figure shows the recommendation for connecting a UPDI connector to the device. Figure 4-3. Recommended UPDI Programming Circuit Schematic VDD UPDI Typical values (recommended): C1: 100 nF (primary decoupling capacitor) C2: 1-10 nF (HF decoupling capacitor) NC = Not Connected VDD UPDI 1 NC 3 NC 5 2 VDD 4 NC 6 GND C2 C1 GND 100-mil 6-pin 2x3 connector The decoupling capacitor between VDD and GND must be placed as close to the pin pair as possible. The decoupling capacitor must be included even if the UPDI connector is not included in the circuit. 4.5 Connecting External Crystal Oscillators The use of external oscillators and the design of oscillator circuits are not trivial. This is because there are many variables: VDD, operating temperature range, crystal type and manufacture, loading capacitors, circuit layout, and PCB material. In this section, some typical guidelines to help with the basic oscillator circuit design are presented. • • • • • • • Even the best performing oscillator circuits and high-quality crystals will not perform well if the layout and materials used during the assembly are not carefully considered The crystal circuit must be placed on the same side of the board as the device. Place the crystal circuit as close to the respective oscillator pins as possible and avoid long traces. This will reduce parasitic capacitance and increase immunity against noise and crosstalk. The load capacitors must be placed next to the crystal itself, on the same side of the board. Any kind of sockets must be avoided. Place a grounded copper area around the crystal circuit to isolate it from surrounding circuits. If the circuit board has two sides, the copper area on the bottom layer must be a solid area covering the crystal circuit. The copper area on the top layer must surround the crystal circuit and be tied to the bottom layer area using via(s). Do not run any signal traces or power traces inside the grounded copper area. Avoid routing digital lines, especially clock lines, close to the crystal lines. If using a two-sided PCB, avoid any traces beneath the crystal. For a multilayer PCB, avoid routing signals below the crystal lines. Dust and humidity will increase parasitic capacitance and reduce signal isolation. A protective coating is recommended. Successful oscillator design requires good specifications of operating conditions, a component selection phase with initial testing, and testing in actual operating conditions to ensure that the oscillator performs as desired For more detailed information about oscillators and oscillator circuit design, see the following application notes: • AN2648 - Selecting and Testing 32 kHz Crystal Oscillators for AVR® Microcontrollers • AN949 - Making Your Oscillator Work 4.5.1 Connection for XOSC32K (External 32.768 kHz Crystal Oscillator) Ultra-low power 32.768 kHz oscillators typically dissipate significantly below 1 μW, and the current flowing in the circuit is, therefore, extremely small. The crystal frequency is highly dependent on the capacitive load. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 20 ATtiny424/426/427 ATtiny824/826/827 Hardware Guidelines The following figure shows how to connect an external 32.768 kHz crystal oscillator. Figure 4-4. Recommended External 32.768 kHz Oscillator Connection Circuit Schematic TOSC1 C1 32.768 kHz Crystal Oscillator TOSC2 C2 4.6 Connection for External Voltage Reference If the design includes the use of an external voltage reference, the general recommendation is to use a suitable capacitor connected in parallel with the reference. The value of the capacitor depends on the nature of the reference and the type of electrical noise that needs to be filtered out. Additional filtering components may be needed. This depends on the type of external voltage reference used. Figure 4-5. Recommended External Voltage Reference Connection + Voltage Reference C1 - © 2021 Microchip Technology Inc. VREFA GND Preliminary Datasheet DS40002311A-page 21 ATtiny424/426/427 ATtiny824/826/827 Conventions 5. Conventions 5.1 Numerical Notation Table 5-1. Numerical Notation 5.2 Symbol Description 165 Decimal number 0b0101 Binary number ‘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 5-2. Memory Size and Bit Rate 5.3 Symbol Description KB kilobyte (210B = 1024B) MB megabyte (220B = 1024 KB) GB gigabyte (230B = 1024 MB) b bit (binary ‘0’ or ‘1’) B byte (8 bits) 1 kbit/s 1,000 bit/s rate 1 Mbit/s 1,000,000 bit/s rate 1 Gbit/s 1,000,000,000 bit/s rate word 16-bit Frequency and Time Table 5-3. Frequency and Time Symbol Description kHz 1 kHz = 103 Hz = 1,000 Hz MHz 1 MHz = 106 Hz = 1,000,000 Hz GHz 1 GHz = 109 Hz = 1,000,000,000 Hz ms 1 ms = 10-3s = 0.001s µs 1 µs = 10-6s = 0.000001s ns 1 ns = 10-9s = 0.000000001s © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 22 ATtiny424/426/427 ATtiny824/826/827 Conventions 5.4 Registers and Bits Table 5-4. 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. BITFIELD Bitfield names are shown in uppercase. Example: INTMODE. BITFIELD[n:m] A set of bits from bit n down to m. Example: PINA[3:0] = {PINA3, PINA2, PINA1, PINA0}. Reserved Reserved bits, bit fields, and bit field values are unused and reserved for future use. For compatibility with future devices, always write reserved bits to ‘0’ when the register is written. Reserved bits will always return zero when read. PERIPHERALn If several instances of the peripheral exist, the peripheral name is followed by a single number to identify one instance. Example: USARTn is the collection of all instances of the USART module, while USART3 is one specific instance of the USART module. PERIPHERALx If several instances of the peripheral exist, the peripheral name is followed by a single capital letter (A-Z) to identify one instance. Example: PORTx is the collection of all instances of the PORT module, while PORTB is one specific instance of the PORT module. 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/TGL Registers with SET/CLR/TGL suffix allow the user to clear and set bits in a register without doing a read-modify-write operation. Each SET/CLR/TGL register is paired with the register it is affecting. Both registers in a register pair return the same value when read. Example: In the PORT peripheral, the OUT and OUTSET registers form such a register pair. The contents of OUT will be modified by a write to OUTSET. Reading OUT and OUTSET will return the same value. Writing a ‘1’ to a bit in the CLR register will clear the corresponding bit in both registers. Writing a ‘1’ to a bit in the SET register will set the corresponding bit in both registers. Writing a ‘1’ to a bit in the TGL register will toggle the corresponding bit in both registers. 5.4.1 Addressing Registers from Header Files In order to address registers in the supplied C header files, the following rules apply: 1. 2. 3. 4. A register is identified by ., e.g., CPU.SREG, USART2.CTRLA, or PORTB.DIR. The peripheral name is given in the “Peripheral Address Map” in the “Peripherals and Architecture” section. is obtained by substituting any n or x in the peripheral name with the correct instance identifier. When assigning a predefined value to a peripheral register, the value is constructed following the rule: ___gc is , but remove any instance identifier. can be found in the “Name” column in the tables in the Register Description sections describing the bit fields of the peripheral registers. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 23 ATtiny424/426/427 ATtiny824/826/827 Conventions Example 5-1. Register Assignments // EVSYS channel 0 is driven by TCB3 OVF event EVSYS.CHANNEL0 = EVSYS_CHANNEL0_TCB3_OVF_gc; // USART0 RXMODE uses Double Transmission Speed USART0.CTRLB = USART_RXMODE_CLK2X_gc; Note:  For peripherals with different register sets in different modes, and must be followed by a mode name, for example: // TCA0 in Normal Mode (SINGLE) uses waveform generator in frequency mode TCA0.SINGLE.CTRL=TCA_SINGLE_WGMODE_FRQ_gc; 5.5 ADC Parameter Definitions An ideal n-bit single-ended ADC converts a voltage linearly between GND and VREF in 2n steps (LSb). The lowest code is read as ‘0’, and the highest code is read as ‘2n-1’. Several parameters describe the deviation from the ideal behavior: Offset Error The deviation of the first transition (0x000 to 0x001) compared to the ideal transition (at 0.5 LSb). Ideal value: 0 LSb. Figure 5-1. Offset Error Output Code Ideal ADC Actual ADC Offset Error Gain Error VREF Input Voltage After adjusting for offset, the gain error is found as the deviation of the last transition (e.g., 0x3FE to 0x3FF for a 10-bit ADC) compared to the ideal transition (at 1.5 LSb below maximum). Ideal value: 0 LSb. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 24 ATtiny424/426/427 ATtiny824/826/827 Conventions Figure 5-2. Gain Error Gain Error Output Code Ideal ADC Actual ADC VREF Integral Nonlinearity (INL) Input Voltage After adjusting for offset and gain error, the INL is the maximum deviation of an actual transition compared to an ideal transition for any code. Ideal value: 0 LSb. Figure 5-3. Integral Nonlinearity Output Code INL Ideal ADC Actual ADC VREF Differential Nonlinearity (DNL) Input Voltage The maximum deviation of the actual code width (the interval between two adjacent transitions) from the ideal code width (1 LSb). Ideal value: 0 LSb. Figure 5-4. Differential Nonlinearity Output Code 0x3FF 1 LSb DNL 0x000 0 © 2021 Microchip Technology Inc. VREF Preliminary Datasheet Input Voltage DS40002311A-page 25 ATtiny424/426/427 ATtiny824/826/827 Conventions Quantization Error Due to the quantization of the input voltage into a finite number of codes, a range of input voltages (1 LSb wide) will code to the same value. Always ±0.5 LSb. Absolute Accuracy The maximum deviation of an actual (unadjusted) transition compared to an ideal transition for any code. This is the compound effect of all errors mentioned before. Ideal value: ±0.5 LSb. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 26 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6. AVR® CPU 6.1 Features • • • • • • • • 6.2 8-Bit, High-Performance AVR RISC CPU: – 135 instructions – Hardware multiplier 32 8-Bit Registers Directly Connected to the ALU Stack in RAM Stack Pointer Accessible in I/O Memory Space Direct Addressing of up to 64 KB of Unified Memory Efficient Support for 8-, 16-, and 32-Bit Arithmetic Configuration Change Protection for System-Critical Features Native On-Chip Debugging (OCD) Support: – Two hardware breakpoints – Change of flow, interrupt, and software breakpoints – Run-time read-out of Stack Pointer (SP) register, Program Counter (PC), and Status Register (SREG) – Register file read- and writable in Stopped mode Overview The AVR CPU can access memories, perform calculations, control peripherals, execute instructions from the program memory, and handle interrupts. 6.3 Architecture To maximize performance and parallelism, the AVR CPU uses a Harvard architecture with separate buses for program and data. The instructions in the program memory are executed with a single-level pipeline. While one instruction is being executed, the next instruction is prefetched from the program memory. This enables instructions to be executed on every clock cycle. Refer to the Instruction Set Summary section for a summary of all AVR instructions. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 27 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU Figure 6-1. AVR® CPU Architecture Register file R31 (ZH) R29 (YH) R27 (XH) R25 R23 R21 R19 R17 R15 R13 R11 R9 R7 R5 R3 R1 R30 (ZL) R28 (YL) R26 (XL) R24 R22 R20 R18 R16 R14 R12 R10 R8 R6 R4 R2 R0 Program Counter Flash Program Memory Instruction Register Instruction Decode Data Memory Stack Pointer Status Register © 2021 Microchip Technology Inc. ALU Preliminary Datasheet DS40002311A-page 28 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6.4 Arithmetic Logic Unit (ALU) The Arithmetic Logic Unit (ALU) supports arithmetic and logic operations between working registers or between a constant and a working register. Also, single-register operations can be executed. The ALU operates in a direct connection with all the 32 general purpose working registers in the register file. The arithmetic operations between working registers or between a working register and an immediate operand are executed in a single clock cycle, and the result is stored in the register file. After an arithmetic or logic operation, the Status Register (CPU.SREG) is updated to reflect information about the result of the operation. ALU operations are divided into three main categories – arithmetic, logical, and bit functions. Both 8- and 16-bit arithmetic are supported, and the instruction set allows for an efficient implementation of the 32-bit arithmetic. The hardware multiplier supports signed and unsigned multiplication and fractional formats. 6.4.1 Hardware Multiplier The multiplier is capable of multiplying two 8-bit numbers into a 16-bit result. The hardware multiplier supports different variations of signed and unsigned integer and fractional numbers: • • • • Multiplication of signed/unsigned integers Multiplication of signed/unsigned fractional numbers Multiplication of a signed integer with an unsigned integer Multiplication of a signed fractional number with an unsigned fractional number A multiplication takes two CPU clock cycles. 6.5 6.5.1 Functional Description Program Flow After being reset, the CPU will execute instructions from the lowest address in the Flash program memory, 0x0000. The Program Counter (PC) addresses the next instruction to be fetched. The CPU supports instructions that can change the program flow conditionally or unconditionally and are capable of addressing the whole address space directly. Most AVR instructions use a 16-bit word format, and a limited number use a 32-bit format. During interrupts and subroutine calls, the return address PC is stored on the stack as a word pointer. The stack is allocated in the general data SRAM, and consequently, the stack size is only limited by the total SRAM size and the usage of the SRAM. After the Stack Pointer (SP) is reset, it points to the highest address in the internal SRAM. The SP is read/write accessible in the I/O memory space, enabling easy implementation of multiple stacks or stack areas. The data SRAM can easily be accessed through the five different Addressing modes supported by the AVR CPU. See the Instruction Set Summary section for details. 6.5.2 Instruction Execution Timing The AVR CPU is clocked by the CPU clock, CLK_CPU. No internal clock division is applied. The figure below shows the parallel instruction fetches and executions enabled by the Harvard architecture and the fast-access register file concept. This is the basic pipelining concept enabling up to 1 MIPS/MHz performance with high efficiency. Figure 6-2. The Parallel Instruction Fetches and Executions T1 T2 T3 T4 CLK_CPU Fetch Execute © 2021 Microchip Technology Inc. Instruction 1 Instruction 2 Instruction 3 Instruction 1 Instruction 2 Preliminary Datasheet Instruction 4 Instruction 3 DS40002311A-page 29 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU The following figure shows the internal timing concept for the register file. In a single clock cycle, an ALU operation using two register operands is executed, and the result is stored in the destination register. Figure 6-3. Single Cycle ALU Operation T1 T2 T3 T4 clkCPU Total Execution Time Register Operands Fetch ALU Operation Execute Result Write Back 6.5.3 Status Register The Status Register (CPU.SREG) contains information about the result of the most recently executed arithmetic or logic instructions. This information can be used for altering the program flow to perform conditional operations. CPU.SREG is updated after all ALU operations, as specified in the Instruction Set Summary section, which will, in many cases, remove the need for using the dedicated compare instructions, resulting in a faster and more compact code. CPU.SREG is not automatically stored or restored when entering or returning from an Interrupt Service Routine (ISR). Therefore, maintaining the Status Register between context switches must be handled by user-defined software. CPU.SREG is accessible in the I/O memory space. 6.5.4 Stack and Stack Pointer The stack is used for storing return addresses after interrupts and subroutine calls. Also, it can be used for storing temporary data. The Stack Pointer (SP) always points to the top of the stack. The address pointed to by the SP is stored in the Stack Pointer (CPU.SP) register. The CPU.SP is implemented as two 8-bit registers that are accessible in the I/O memory space. Data are pushed and popped from the stack using the instructions given in Table 6-1, or by executing interrupts. The stack grows from higher to lower memory locations. This means that when pushing data onto the stack, the SP decreases, and when popping data off the stack, the SP increases. The SP is automatically set to the highest address of the internal SRAM after being reset. If the stack is changed, it must be set to point above the SRAM start address (see the SRAM Data Memory topic in the Memories section for the SRAM start address), and it must be defined before any subroutine calls are executed and before interrupts are enabled. See the table below for SP details. Table 6-1. Stack Pointer Instructions Instruction Stack Pointer Description PUSH Decremented by 1 Data are pushed onto the stack CALL ICALL RCALL Decremented by 2 A return address is pushed onto the stack with a subroutine call or interrupt POP Incremented by 1 Data are popped from the stack RET RETI Incremented by 2 A return address is popped from the stack with a return from subroutine or return from interrupt During interrupts or subroutine calls, the return address is automatically pushed on the stack as a word, and the SP is decremented by two. The return address consists of two bytes and the Least Significant Byte (LSB) is pushed on the stack first (at the higher address). As an example, a byte pointer return address of 0x0006 is saved on the stack as 0x0003 (shifted one bit to the right), pointing to the fourth 16-bit instruction word in the program memory. The return address is popped off the stack with RETI (when returning from interrupts) and RET (when returning from subroutine calls), and the SP is incremented by two. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 30 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU The SP is decremented by one when data are pushed on the stack with the PUSH instruction, and incremented by one when data are popped off the stack using the POP instruction. To prevent corruption when updating the SP from software, a write to SPL will automatically disable interrupts for up to four instructions or until the next I/O memory write, whichever comes first. 6.5.5 Register File The register file consists of 32 8-bit general purpose working registers used by the CPU. The register file is located in a separate address space from the data memory. All CPU instructions that operate on working registers have direct and single-cycle access to the register file. Some limitations apply to which working registers can be accessed by an instruction, like the constant arithmetic and logic instructions SBCI, SUBI, CPI, ANDI, ORI and LDI. These instructions apply to the second half of the working registers in the register file, R16 to R31. See the AVR Instruction Set Manual for further details. Figure 6-4. AVR® CPU General Purpose Working Registers 0 Addr. 7 0x00 R0 0x01 R1 0x02 R2 ... R13 R14 R15 R16 R17 0x0D 0x0E 0x0F 0x10 0x11 R26 R27 R28 R29 R30 R31 0x1A 0x1B 0x1C 0x1D 0x1E 0x1F ... 6.5.5.1 X-register Low Byte X-register High Byte Y-register Low Byte Y-register High Byte Z-register Low Byte Z-register High Byte The X-, Y-, and Z-Registers Working registers R26...R31 have added functions besides their general purpose usage. These registers can form 16-bit Address Pointers for indirect addressing of data memory. These three address registers are called the X-register, Y-register, and Z-register. The Z-register can also be used as Address Pointer for program memory. Figure 6-5. The X-, Y-, and Z-Registers Bit (individually) 7 X-register 15 Bit (individually) 7 Y-register Bit (individually) 7 8 7 R29 0 7 15 7 R31 0 0 R28 0 YL 8 7 0 7 ZH 15 R26 XL YH Z-register Bit (Z-register) 0 XH Bit (X-register) Bit (Y-register) R27 0 R30 0 ZL 8 7 0 The lowest register address holds the Least Significant Byte (LSB), and the highest register address holds the Most Significant Byte (MSB). These address registers can function as fixed displacement, automatic increment, and automatic decrement, with different LD*/ST* instructions. See the Instruction Set Summary section for details. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 31 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6.5.6 Configuration Change Protection (CCP) System critical I/O register settings are protected from accidental modification. Flash self-programming is protected from accidental execution. This is handled globally by the Configuration Change Protection (CCP) register. Changes to the protected I/O registers or bits, or execution of protected instructions, are only possible after the CPU writes a signature to the CCP register. The different signatures are listed in the description of the CCP register (CPU.CCP). Once the correct signature is written by the CPU, interrupts will be ignored for the duration of the configuration change enable period. Any interrupt request (including non-maskable interrupts) during the CCP period will set the corresponding Interrupt flag as normal, and the request is kept pending. After the CCP period is completed, any pending interrupts are executed according to their level and priority. There are two modes of operation: One for protected I/O registers, and one for protected self-programming. 6.5.6.1 Sequence for Write Operation to Configuration Change Protected I/O Registers To write to registers protected by CCP, the following steps are required: 1. 2. The software writes the signature that enables change of protected I/O registers to the CCP bit field in the CPU.CCP register. Within four instructions, the software must write the appropriate data to the protected register. Most protected registers also contain a Write Enable/Change Enable/Lock bit. This bit must be written to ‘1’ in the same operation as the data are written. The protected change is immediately disabled if the CPU performs write operations to the I/O register or data memory, if load or store accesses to Flash, NVMCTRL, or EEPROM are conducted, or if the SLEEP instruction is executed. 6.5.6.2 Sequence for Execution of Self-Programming To execute self-programming (the execution of writes to the NVM controller’s command register), the following steps are required: 1. 2. 6.5.7 The software temporarily enables self-programming by writing the SPM signature to the CCP register (CPU.CCP). Within four instructions, the software must execute the appropriate instruction. The protected change is immediately disabled if the CPU performs accesses to the Flash, NVMCTRL, or EEPROM, or if the SLEEP instruction is executed. On-Chip Debug Capabilities The AVR CPU includes native On-Chip Debug (OCD) support. It contains some powerful debug capabilities to enable profiling and detailed information about the CPU state. It is possible to alter the CPU state and resume code execution. Also, normal debug capabilities like hardware Program Counter breakpoints, breakpoints on change of flow instructions, breakpoints on interrupts, and software breakpoints (BREAK instruction) are present. Refer to the Unified Program and Debug Interface section for details about OCD. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 32 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6.6 Offset 0x00 ... 0x03 0x04 0x05 ... 0x0C Register Summary Name 7 6 5 4 3 2 1 0 V N Z C Reserved CCP 7:0 CCP[7:0] 7:0 15:8 7:0 SP[7:0] SP[15:8] Reserved 0x0D SP 0x0F SREG 6.7 Bit Pos. I T H S Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 33 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6.7.1 Configuration Change Protection Name:  Offset:  Reset:  Property:  Bit 7 CCP 0x04 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 CCP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – CCP[7:0] Configuration Change Protection Writing the correct signature to this bit field allows changing protected I/O registers or executing protected instructions within the next four CPU instructions executed. All interrupts are ignored during these cycles. After these cycles are completed, the interrupts will automatically be handled by the CPU, and any pending interrupts will be executed according to their level and priority. When the protected I/O register signature is written, CCP[0] will read ‘1’ as long as the CCP feature is enabled. When the protected self-programming signature is written, CCP[1] will read ‘1’ as long as the CCP feature is enabled. CCP[7:2] will always read ‘0’. Value Name Description 0x9D SPM Allow self-programming 0xD8 IOREG Unlock protected I/O registers © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 34 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6.7.2 Stack Pointer Name:  Offset:  Reset:  Property:  SP 0x0D Top of stack - The CPU.SP register holds the Stack Pointer (SP) that points to the top of the stack. After being reset, the SP points to the highest internal SRAM address. Only the number of bits required to address the available data memory, including external memory (up to 64 KB), is implemented for each device. Unused bits will always read ‘0’. The CPU.SPL and CPU.SPH register pair represents the 16-bit value, CPU.SP. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. To prevent corruption when updating the SP from software, a write to CPU.SPL will automatically disable interrupts for the next four instructions or until the next I/O memory write, whichever comes first. Bit 15 14 13 12 11 10 9 8 R/W R/W R/W R/W 3 2 1 0 R/W R/W R/W R/W SP[15:8] Access Reset Bit R/W R/W R/W R/W 7 6 5 4 SP[7:0] Access Reset R/W R/W R/W R/W Bits 15:8 – SP[15:8] Stack Pointer High Byte These bits hold the MSB of the 16-bit register. Bits 7:0 – SP[7:0] Stack Pointer Low Byte These bits hold the LSB of the 16-bit register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 35 ATtiny424/426/427 ATtiny824/826/827 AVR® CPU 6.7.3 Status Register Name:  Offset:  Reset:  Property:  SREG 0x0F 0x00 - The Status Register contains information about the result of the most recently executed arithmetic or logic instructions. For details about the bits in this register and how they are influenced by different instructions, see the Instruction Set Summary section. Bit Access Reset 7 I R/W 0 6 T R/W 0 5 H R/W 0 4 S R/W 0 3 V R/W 0 2 N R/W 0 1 Z R/W 0 0 C R/W 0 Bit 7 – I Global Interrupt Enable Bit Writing a ‘1’ to this bit enables interrupts on the device. Writing a ‘0’ to this bit disables interrupts on the device, independent of the individual interrupt enable settings of the peripherals. This bit is not cleared by hardware while entering an Interrupt Service Routine (ISR) or set when the RETI instruction is executed. This bit can be set and cleared by software with the SEI and CLI instructions. Changing the I bit through the I/O register results in a one-cycle Wait state on the access. Bit 6 – T Transfer Bit The bit copy instructions, Bit Load (BLD) and Bit Store (BST), use the T bit as source or destination for the operated bit. Bit 5 – H Half Carry Flag This flag is set when there is a half carry in arithmetic operations that support this, and is cleared otherwise. Half carry is useful in BCD arithmetic. Bit 4 – S Sign Flag This flag is always an Exclusive Or (XOR) between the Negative flag (N) and the Two’s Complement Overflow (V) flag. Bit 3 – V Two’s Complement Overflow Flag This flag is set when there is an overflow in arithmetic operations that support this, and is cleared otherwise. Bit 2 – N Negative Flag This flag is set when there is a negative result in an arithmetic or logic operation, and is cleared otherwise. Bit 1 – Z Zero Flag This flag is set when there is a zero result in an arithmetic or logic operation, and is cleared otherwise. Bit 0 – C Carry Flag This flag is set when there is a carry in an arithmetic or logic operation, and is cleared otherwise. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 36 ATtiny424/426/427 ATtiny824/826/827 Memories 7. Memories 7.1 Overview The main memories of the ATtiny424/426/427 and ATtiny824/826/827 devices are SRAM data memory space, EEPROM data memory space, and Flash program memory space. Also, the peripheral registers are located in the I/O memory space. 7.2 Memory Map The figure below shows the memory map for the largest memory derivative in the tinyAVR 2 family. Refer to the subsequent sections and the Peripheral Address Map table for further details. Figure 7-1.  Memory Map: Flash 32 KB, Internal SRAM 3 KB, EEPROM 256B Code Space Data Space Single Cycle I/O Registers 0x0000-0x003F Extended I/O Registers 0x0040-0x107F 0x00000 Flash Code 32 KB 7.3 I/O Memory 0x0000-0x107F SIGROW 0x1100-0x11FF FUSE 0x1280-0x1289 LOCKBIT 0x128A-0x12FF USERROW 0x1300-0x137F EEPROM 256 Bytes 0x1400-0x14FF (Reserved) SRAM 3 KB 0x3400-0x3FFF (Reserved) 0x4000-0x7FFF In-System Reprogrammable Flash 32 KB 0x8000-0xFFFF In-System Reprogrammable Flash Program Memory The ATtiny424/426/427 and ATtiny824/826/827 contains 4/8 KB on-chip in-system reprogrammable Flash memory for program storage. Since all AVR instructions are 16 or 32 bits wide, the Flash is organized as 4K x 16-bit pages. For write protection, the Flash program memory space can be divided into three sections (Figure 7-2): Boot section, Application Code section, and Application Data section. Code placed in one section may be restricted from writing to addresses in other sections. See the Nonvolatile Memory Controller (NVMCTRL) section for more details. The Program Counter (PC) can address the whole program memory. The procedure for writing Flash memory is described in detail in the NVMCTRL section. The Flash memory is mapped into the data space and is accessible with normal LD/ST instructions. For LD/ST instructions, the Flash is mapped from address 0x8000. The Flash memory can be read with the LPM instruction. For the LPM instruction, the Flash start address is 0x0000. The ATtiny424/426/427 and ATtiny824/826/827 has a CRC module that is a host on the bus. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 37 ATtiny424/426/427 ATtiny824/826/827 Memories Table 7-1. Physical Properties of Flash Memory Property ATtiny42x ATtiny82x Size 4 KB 8 KB Page size 64B 64B Number of pages 64 128 Start address in data space 0x8000 0x8000 Start address in code space 0x0 0x0 Figure 7-2. Flash Areas FLASHSTART: 0x0000 BOOTSIZE fuse Boot BOOTEND: (BOOTSIZE*256)-1 CODESIZE fuse Flash Application Code APPEND: (CODESIZE*256)-1 Application Data FLASHEND 7.4 SRAM Data Memory The primary task of the SRAM memory is to store application data. Also, the program stack is located at the end of SRAM. It is not possible to execute code from SRAM. Table 7-2. Physical Properties of SRAM 7.5 Property ATtiny42x ATtiny82x Size 512B 1 KB Start address 0x3E00 0x3C00 EEPROM Data Memory The primary task of the EEPROM memory is to store nonvolatile application data. The EEPROM memory supports single- and multi-byte read and write. The EEPROM is controlled by the Nonvolatile Memory Controller (NVMCTRL). Table 7-3. Physical Properties of EEPROM Property ATtiny42x ATtiny82x Size 128B 128B Page size 32B 32B © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 38 ATtiny424/426/427 ATtiny824/826/827 Memories ...........continued 7.6 Property ATtiny42x ATtiny82x Number of pages 4 4 Start address 0x1400 0x1400 USERROW - User Row The ATtiny424/426/427 and ATtiny824/826/827 has one extra page of EEPROM memory that can be used for firmware settings, the User Row (USERROW). This memory supports single-byte read and write as the normal EEPROM. The CPU can write and read this memory as normal EEPROM, and the UPDI can write and read it as a normal EEPROM memory if the part is unlocked. The User Row can be written by the UPDI when the part is locked. USERROW is not affected by a chip erase. 7.7 LOCKBIT - Memory Sections Access Protection The device can be locked so that the memories cannot be read using the UPDI. The locking protects both the Flash (all Boot, Application Code, and Application Date sections), SRAM, and the EEPROM, including the FUSE data. This prevents successful reading of application data or code using the debugger interface. Regular memory access from within the application is still enabled. The device is locked by writing a non-valid key to the LOCKBIT bit field in FUSE.LOCKBIT. Table 7-4. Memory Access Unlocked (FUSE.LOCKBIT Valid Key)(1) Memory Section CPU Access UPDI Access Read Write Read Write SRAM Yes Yes Yes Yes Registers Yes Yes Yes Yes Flash Yes Yes Yes Yes EEPROM Yes Yes Yes Yes USERROW Yes Yes Yes Yes SIGROW Yes No Yes No Other fuses including Yes LOCK No Yes Yes Table 7-5. Memory Access Locked (FUSE.LOCKBIT Invalid Key)(1) Memory Section CPU Access UPDI Access Read Write Read Write SRAM Yes Yes No No Registers Yes Yes No No Flash Yes Yes No No EEPROM Yes Yes No No USERROW Yes Yes No Yes(2) SIGROW Yes No No No © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 39 ATtiny424/426/427 ATtiny824/826/827 Memories ...........continued Memory Section CPU Access Read Other fuses including Yes LOCK UPDI Access Write Read Write No No No Notes:  1. Read operations marked No in the tables may appear to be successful, but the data is not valid. Hence, any attempt of code validation through the UPDI will fail on these memory sections. 2. In the Locked mode, the USERROW can be written using the Fuse Write command, but the current USERROW values cannot be read out. Important:  The only way to unlock a device is CHIPERASE. No application data is retained. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 40 ATtiny424/426/427 ATtiny824/826/827 Memories 7.7.1 Lock Bit Summary Offset Name Bit Pos. 0x00 LOCKBIT 7:0 7.7.2 7 6 5 4 3 2 1 0 LOCKBIT[7:0] Lock Bit Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 41 ATtiny424/426/427 ATtiny824/826/827 Memories 7.7.2.1 Lock Bits Name:  Offset:  Default:  Property:  LOCKBIT 0x00 0xC5 - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit Access Default 7 6 5 R/W 1 R/W 1 R/W 0 4 3 LOCKBIT[7:0] R/W R/W 0 0 2 1 0 R/W 1 R/W 0 R/W 1 Bits 7:0 – LOCKBIT[7:0] Lock Bits When the part is locked, UPDI cannot access the system bus, so it cannot read out anything but CS-space. Value Description 0xC5 Valid key - the device is open other Invalid - the device is locked 7.8 FUSE - Configuration and User Fuses Fuses are part of the nonvolatile memory and hold the device configuration. The fuses can be read by the CPU or the UPDI, but can only be programmed or cleared by the UPDI. The configuration values stored in the fuses are written to their respective target registers at the end of the start-up sequence. The fuses for peripheral configuration (FUSE) are pre-programmed but can be altered by the user. Altered values in the configuration fuse will be effective only after a Reset. Note:  When writing the fuses, all reserved bits must be written to ‘1’. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 42 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.1 Fuse Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 ... 0x04 0x05 0x06 0x07 0x08 WDTCFG BODCFG OSCCFG 7:0 7:0 7:0 7.8.2 7 6 5 WINDOW[3:0] LVL[2:0] 4 3 2 1 0 PERIOD[3:0] SAMPFREQ ACTIVE[1:0] TOUTDIS RSTPINCFG[1:0] OSCLOCK SLEEP[1:0] FREQSEL[1:0] Reserved SYSCFG0 SYSCFG1 APPEND BOOTEND 7:0 7:0 7:0 7:0 CRCSRC[1:0] EESAVE SUT[2:0] APPEND[7:0] BOOTEND[7:0] Fuse Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 43 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.1 Watchdog Configuration Name:  Offset:  Default:  Property:  WDTCFG 0x00 0x00 - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit 7 6 5 4 3 2 WINDOW[3:0] Access Default R 0 R 0 1 0 R 0 R 0 PERIOD[3:0] R 0 R 0 R 0 R 0 Bits 7:4 – WINDOW[3:0] Watchdog Window Time-out Period This value is loaded into the WINDOW bit field of the Watchdog Control A (WDT.CTRLA) register during reset. Bits 3:0 – PERIOD[3:0] Watchdog Time-out Period This value is loaded into the PERIOD bit field of the Watchdog Control A (WDT.CTRLA) register during reset. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 44 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.2 BOD Configuration Name:  Offset:  Default:  Property:  BODCFG 0x01 0x00 - The settings of the BOD will be loaded from this Fuse after a Reset. The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit Access Default 7 R 0 6 LVL[2:0] R 0 5 R 0 4 SAMPFREQ R 0 3 2 1 ACTIVE[1:0] R 0 0 SLEEP[1:0] R 0 R 0 R 0 Bits 7:5 – LVL[2:0] BOD Level This value is loaded into the LVL bit field of the BOD Control B (BOD.CTRLB) register during Reset. Value Name Description 0x0 BODLEVEL0 1.8V 0x1 BODLEVEL1 2.15V 0x2 BODLEVEL2 2.60V 0x3 BODLEVEL3 2.95V 0x4 BODLEVEL4 3.30V 0x5 BODLEVEL5 3.70V 0x6 BODLEVEL6 4.00V 0x7 BODLEVEL7 4.30V Bit 4 – SAMPFREQ BOD Sample Frequency This value is loaded into the SAMPFREQ bit of the BOD Control A (BOD.CTRLA) register during Reset. Value Description 0x0 The sample frequency is 1 kHz 0x1 The sample frequency is 125 Hz Bits 3:2 – ACTIVE[1:0] BOD Operation Mode in Active and Idle This value is loaded into the ACTIVE bit field of the BOD Control A (BOD.CTRLA) register during Reset. Value Description 0x0 Disabled 0x1 Enabled 0x2 Sampled 0x3 Enabled with wake-up halted until BOD is ready Bits 1:0 – SLEEP[1:0] BOD Operation Mode in Sleep This value is loaded into the SLEEP bit field of the BOD Control A (BOD.CTRLA) register during Reset. Value Description 0x0 Disabled 0x1 Enabled 0x2 Sampled 0x3 Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 45 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.3 Oscillator Configuration Name:  Offset:  Default:  Property:  OSCCFG 0x02 0x7E - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit Access Default 7 OSCLOCK R 0 6 5 4 3 2 1 0 FREQSEL[1:0] R R 1 0 Bit 7 – OSCLOCK Oscillator Lock This fuse bit is loaded to LOCK in CLKCTRL.OSC20MCALIBB during reset. Value Description 0 Calibration registers of the 20 MHz oscillator are accessible 1 Calibration registers of the 20 MHz oscillator are locked Bits 1:0 – FREQSEL[1:0] Frequency Select These bits select the operation frequency of the 20 MHz internal oscillator (OSC20M) and determine the respective factory calibration values to be written to CAL20M in CLKCTRL.OSC20MCALIBA and TEMPCAL20M in CLKCTRL.OSC20MCALIBB. Value Description 0x0 Reserved 0x1 Run at 16 MHz 0x2 Run at 20 MHz 0x3 Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 46 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.4 System Configuration 0 Name:  Offset:  Default:  Property:  SYSCFG0 0x05 0xF6 - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit 7 6 5 CRCSRC[1:0] Access Default R 1 R 1 4 TOUTDIS R 1 3 2 RSTPINCFG[1:0] R R 0 1 1 0 EESAVE R 0 Bits 7:6 – CRCSRC[1:0] CRC Source See the CRC description for more information about the functionality. Value Name Description 0x0 FLASH CRC of full Flash (boot, application code and application data) 0x1 BOOT CRC of the boot section 0x2 BOOTAPP CRC of application code and boot sections 0x3 NOCRC No CRC Bit 4 – TOUTDIS Time-Out Disable This bit can disable the blocking of NVM writes after POR. When the TOUTDIS bit in FUSE.SYSCFG0 is ‘0’ and the RSTPINCFG bit field in FUSE.SYSCFG0 is configured to GPIO or RESET, there will be a time-out period after POR that blocks NVM writes. The NVM write block will last for 768 OSC32K cycles after POR. The EEBUSY and FBUSY bits in the NVMCTRL.STATUS register must read ‘0’ before the page buffer can be filled or NVM commands can be issued. Value Description 0 NVM write block is enabled 1 NVM write block is disabled Bits 3:2 – RSTPINCFG[1:0] Reset Pin Configuration This bit selects the pin configuration for the Reset pin. Note:  When configuring the Reset pin as GPIO, there is a potential conflict between the GPIO actively driving the output, and a high-voltage UPDI enable sequence initiation. To avoid this, the GPIO output driver is disabled for 768 OSC32K cycles after a System Reset. Enable any interrupts for this pin only after this period. Value 0x0 0x1 0x2 0x3 Description GPIO UPDI RESET UPDI w/alternate RESET pin Bit 0 – EESAVE EEPROM Save Across Chip Erase This bit controls if the EEPROM is being erased during a Chip Erase. If enabled, only the Flash memory will be erased by the Chip Erase. If the device is locked, the EEPROM is always erased by a Chip Erase regardless of this bit. Value Description 0 EEPROM erased during Chip Erase 1 EEPROM not erased under Chip Erase © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 47 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.5 System Configuration 1 Name:  Offset:  Default:  Property:  SYSCFG1 0x06 0xFF - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit 7 6 5 4 3 Access Default 2 R 1 1 SUT[2:0] R 1 0 R 1 Bits 2:0 – SUT[2:0] Start-up Time Setting These bits select the start-up time between power-on and code execution. Value Description 0x0 0 ms 0x1 1 ms 0x2 2 ms 0x3 4 ms 0x4 8 ms 0x5 16 ms 0x6 32 ms 0x7 64 ms © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 48 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.6 Application Code End Name:  Offset:  Default:  Property:  APPEND 0x07 0x00 - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit 7 6 5 4 3 2 1 0 R 0 R 0 R 0 R 0 APPEND[7:0] Access Default R 0 R 0 R 0 R 0 Bits 7:0 – APPEND[7:0] Application Code Section End This bit field controls the combined size of the Boot Code section and Application Code section in blocks of 256 bytes. For more details, refer to the Nonvolatile Memory Controller section. Note:  If FUSE.BOOTEND is 0x00, the entire Flash is the Boot Code section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 49 ATtiny424/426/427 ATtiny824/826/827 Memories 7.8.2.7 Boot End Name:  Offset:  Default:  Property:  BOOTEND 0x08 0x00 - The default value given in this fuse description is the factory-programmed value, and should not be mistaken for the Reset value. Bit 7 6 5 Access Default R 0 R 0 R 0 4 3 BOOTEND[7:0] R R 0 0 2 1 0 R 0 R 0 R 0 Bits 7:0 – BOOTEND[7:0] Boot Section End This bit field controls the size of the boot section in blocks of 256 bytes. A value of 0x00 defines the entire Flash as Boot Code section. For more details, refer to the Nonvolatile Memory Controller section. 7.9 SIGROW - Signature Row The content of the Signature Row (SIGROW) fuses is pre-programmed and cannot be altered. SIGROW holds information such as device ID, serial number, and calibration values. All AVR microcontrollers have a three-byte device ID that identifies the device. This device ID can be read using the UPDI interface, also when the device is locked. The three bytes reside in the Signature Row. The signature bytes are given in the following table. Table 7-6. Device ID Device Name Signature Bytes Address 0x00 0x01 0x02 ATtiny427 0x1E 0x92 0x2A ATtiny426 0x1E 0x92 0x2B ATtiny424 0x1E 0x92 0x2C ATtiny827 0x1E 0x93 0x27 ATtiny826 0x1E 0x93 0x28 ATtiny824 0x1E 0x93 0x29 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 50 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.1 Signature Row Summary Offset Name Bit Pos. 0x00 DEVICEID0 7:0 DEVICEID[7:0] 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D ... 0x17 0x18 0x19 0x1A 0x1B 0x1C ... 0x1F 0x20 0x21 DEVICEID1 DEVICEID2 SERNUM0 SERNUM1 SERNUM2 SERNUM3 SERNUM4 SERNUM5 SERNUM6 SERNUM7 SERNUM8 SERNUM9 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 DEVICEID[7:0] DEVICEID[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] SERNUM[7:0] 7.9.2 7 6 5 4 3 2 1 0 Reserved OSCCAL16M0 OSCCAL16M1 OSCCAL20M0 OSCCAL20M1 7:0 7:0 7:0 7:0 OSCCAL16M[6:0] OSCCAL16MTCAL[3:0] OSCCAL20M[6:0] OSCCAL20MTCAL[3:0] Reserved TEMPSENSE0 TEMPSENSE1 7:0 7:0 TEMPSENSE[7:0] TEMPSENSE[7:0] Signature Row Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 51 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.1 Device ID n Name:  Offset:  Reset:  Property:  DEVICEIDn 0x00 + n*0x01 [n=0..2] [Device ID] - Each device has a device ID identifying the device and its properties such as memory sizes, pin count, and die revision. This can be used to identify a device and hence, the available features by software. The Device ID consists of three bytes: SIGROW.DEVICEID[2:0]. Bit 7 6 5 Access Reset R x R x R x 4 3 DEVICEID[7:0] R R x x 2 1 0 R x R x R x Bits 7:0 – DEVICEID[7:0] Byte n of the Device ID © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 52 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.2 Serial Number Byte n Name:  Offset:  Reset:  Property:  SERNUMn 0x03 + n*0x01 [n=0..9] [Byte n of device serial number] - Each device has an individual serial number representing a unique ID. This can be used to identify a specific device in the field. The serial number consists of ten bytes: SIGROW.SERNUM[9:0]. Bit 7 6 5 4 3 2 1 0 R x R x R x R x SERNUM[7:0] Access Reset R x R x R x R x Bits 7:0 – SERNUM[7:0] Serial Number Byte n © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 53 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.3 OSC16 Calibration byte Name:  Offset:  Reset:  Property:  Bit Access Reset 7 OSCCAL16M0 0x18 [Factory oscillator calibration value] - 6 5 4 R x R x R x 3 OSCCAL16M[6:0] R x 2 1 0 R x R x R x Bits 6:0 – OSCCAL16M[6:0] OSC16 Calibration These bits contains factory calibration values for the internal 16 MHz oscillator. If the OSCCFG fuse is configured to run the device at 16 MHz, this byte is automatically copied to the OSC20MCALIBA register during Reset to calibrate the internal 16 MHz RC Oscillator. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 54 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.4 OSC16 Temperature Calibration byte Name:  Offset:  Reset:  Property:  Bit 7 OSCCAL16M1 0x19 [Factory oscillator temperature calibration value] - 6 Access Reset 5 4 3 R x 2 1 OSCCAL16MTCAL[3:0] R R x x 0 R x Bits 3:0 – OSCCAL16MTCAL[3:0] OSC16 Temperature Calibration These bits contain factory temperature calibration values for the internal 16 MHz oscillator. If the OSCCFG fuse is configured to run the device at 16 MHz, this byte is automatically written into the OSC20MCALIBB register during Reset to ensure correct frequency of the calibrated RC Oscillator. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 55 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.5 OSC20 Calibration byte Name:  Offset:  Reset:  Property:  Bit Access Reset 7 OSCCAL20M0 0x1A [Factory oscillator calibration value] - 6 5 4 R x R x R x 3 OSCCAL20M[6:0] R x 2 1 0 R x R x R x Bits 6:0 – OSCCAL20M[6:0] OSC20 Calibration These bits contain factory calibration values for the internal 20 MHz oscillator. If the OSCCFG fuse is configured to run the device at 20 MHz, this byte is automatically written into the OSC20MCALIBA register during Reset to ensure correct frequency of the calibrated RC Oscillator. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 56 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.6 OSC20 Temperature Calibration byte Name:  Offset:  Reset:  Property:  Bit 7 OSCCAL20M1 0x1B [Factory oscillator temperature calibration value] - 6 Access Reset 5 4 3 R x 2 1 OSCCAL20MTCAL[3:0] R R x x 0 R x Bits 3:0 – OSCCAL20MTCAL[3:0] OSC20 Temperature Calibration These bits contain factory temperature calibration values for the internal 20 MHz oscillator. If the OSCCFG fuse is configured to run the device at 20 MHz, this byte is automatically written into the OSC20MCALIBB register during Reset to ensure correct frequency of the calibrated RC Oscillator. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 57 ATtiny424/426/427 ATtiny824/826/827 Memories 7.9.2.7 Temperature Sensor Calibration n Name:  Offset:  Reset:  Property:  TEMPSENSEn 0x20 + n*0x01 [n=0..1] [Temperature sensor calibration value] - The Temperature Sensor Calibration registers contain correction factors for temperature measurements from the on-chip sensor. SIGROW.TEMPSENSE0 is a correction factor for the gain/slope (unsigned) and SIGROW.TEMPSENSE1 is a correction factor for the offset (signed). Bit 7 6 5 Access Reset R x R x R x 4 3 TEMPSENSE[7:0] R R x x 2 1 0 R x R x R x Bits 7:0 – TEMPSENSE[7:0] Temperature Sensor Calibration Byte n Refer to the ADC - Analog-to-Digital Converter section for a description of how to use this register. 7.10 I/O Memory All ATtiny424/426/427 and ATtiny824/826/827 devices’ I/O and peripheral registers are located in the I/O memory space. Refer to the Peripheral Address Map table for further details. For compatibility with a future device, if a register containing reserved bits is written, the reserved bits should be written to ‘0’. Reserved I/O memory addresses should never be written. Single-Cycle I/O Registers The I/O memory ranging from 0x00 to 0x3F can be accessed by a single-cycle CPU instruction using the IN or OUT instructions. The peripherals available in the single-cycle I/O registers are as follows: • • • VPORTx – Refer to the I/O Configuration section for further details GPIO – Refer to the I/O Configuration section for further details CPU – Refer to the AVR CPU section for further details The single-cycle I/O registers ranging from 0x00 to 0x1F (VPORTx and GPIO) are also directly bit-accessible using the SBI or CBI instruction. In these single-cycle I/O registers, single bits can be checked by using the SBIS or SBIC instruction. Refer to the Instruction Set Summary for further details. 7.10.1 Accessing 16-Bit Registers Most of the registers for the ATtiny424/426/427 and ATtiny824/826/827 devices are 8-bit registers, but the devices also feature a few 16-bit registers. As the AVR data bus has a width of eight bits, accessing the 16-bit requires two read or write operations. All the 16-bit registers of the ATtiny424/426/427 and ATtiny824/826/827 devices are connected to the 8-bit bus through a temporary (TEMP) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 58 ATtiny424/426/427 ATtiny824/826/827 Memories Figure 7-3. 16-Bit Register Write Operation DATAH TEMP DATAL A V R D A T A B U S DATAH TEMP DATAL A V R D A T A B U S Write High Byte Write Low Byte For a 16-bit write operation, the low byte register (e.g., DATAL) of the 16-bit register must be written before the high byte register (e.g., DATAH). Writing the low byte register will result in a write to the temporary (TEMP) register instead of the low byte register, as shown in the left side of the figure above. When the high byte register of the 16-bit register is written, TEMP will be copied into the low byte of the 16-bit register in the same clock cycle, as shown on the right side of the same figure. Figure 7-4. 16-Bit Register Read Operation DATAH TEMP DATAL Read Low Byte A V R D A T A B U S DATAH TEMP DATAL A V R D A T A B U S Read High Byte For a 16-bit read operation, the low byte register (e.g., DATAL) of the 16-bit register must be read before the high byte register (e.g., DATAH). When the low byte register is read, the high byte register of the 16-bit register is copied © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 59 ATtiny424/426/427 ATtiny824/826/827 Memories into the temporary (TEMP) register in the same clock cycle, as shown on the left side of the figure above. Reading the high byte register will result in a read from TEMP instead of the high byte register, as shown on the right side of the same figure. The described mechanism ensures that the low and high bytes of 16-bit registers are always accessed simultaneously when reading or writing the registers. Interrupts can corrupt the timed sequence if an interrupt is triggered during a 16-bit read/write operation, and a 16-bit register within the same peripheral is accessed in the interrupt service routine. To prevent this, interrupts should be disabled when writing or reading 16-bit registers. Alternatively, the temporary register can be read before and restored after the 16-bit access in the interrupt service routine. 7.10.2 Accessing 32-Bit Registers For 32-bit registers, the read and write access is done in the same way as described for 16-bit registers, except there are three temporary registers for 32-bit registers. The Most Significant Byte (MSB) must be written last when writing to the register, and the Least Significant Byte (LSB) must be read first when reading the register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 60 ATtiny424/426/427 ATtiny824/826/827 Peripherals and Architecture 8. Peripherals and Architecture 8.1 Peripheral Address Map The address map shows the base address for each peripheral. For complete register description and summary for each peripheral, refer to the respective peripheral sections. Table 8-1. Peripheral Address Map Base Address Name Description 0x0000 VPORTA Virtual Port A 0x0004 VPORTB Virtual Port B 0x0008 VPORTC Virtual Port C 0x001C GPIO General Purpose I/O registers 0x0030 CPU CPU 0x0040 RSTCTRL Reset Controller 0x0050 SLPCTRL Sleep Controller 0x0060 CLKCTRL Clock Controller 0x0080 BOD Brown-out Detector 0x00A0 VREF Voltage Reference 0x0100 WDT Watchdog Timer 0x0110 CPUINT Interrupt Controller 0x0120 CRCSCAN Cyclic Redundancy Check Memory Scan 0x0140 RTC Real-Time Counter 0x0180 EVSYS Event System 0x01C0 CCL Configurable Custom Logic 0x0400 PORTA Port A Configuration 0x0420 PORTB Port B Configuration 0x0440 PORTC Port C Configuration 0x05E0 PORTMUX Port Multiplexer 0x0600 ADC0 Analog-to-Digital Converter 0x0680 AC0 Analog Comparator 0 0x0800 USART0 Universal Synchronous Asynchronous Receiver Transmitter 0 0x0820 USART1 Universal Synchronous Asynchronous Receiver Transmitter 1 0x08A0 TWI0 Two-Wire Interface 0x08C0 SPI0 Serial Peripheral Interface 0x0A00 TCA0 Timer/Counter Type A instance 0 0x0A80 TCB0 Timer/Counter Type B instance 0 0x0A90 TCB1 Timer/Counter Type B instance 1 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 61 ATtiny424/426/427 ATtiny824/826/827 Peripherals and Architecture ...........continued Base Address Name Description 0x0F00 SYSCFG System Configuration 0x1000 NVMCTRL Nonvolatile Memory Controller Table 8-2. System Memory Address Map 8.2 Base Address Name Description 0x1100 SIGROW Signature Row 0x1280 FUSE Device specific fuses 0x128A LOCKBIT Lock bits 0x1300 USERROW User Row Interrupt Vector Mapping Each of the interrupt vectors is connected to one peripheral instance, as shown in the table below. A peripheral can have one or more interrupt sources. For more details on the available interrupt sources, see the 'Interrupt' section in the 'Functional Description' of the respective peripheral. An Interrupt Flag is set in the Interrupt Flags register of the peripheral (peripheral.INTFLAGS) when the interrupt condition occurs, even if the interrupt is not enabled. An interrupt is enabled or disabled by writing to the corresponding Interrupt Enable bit in the peripheral's Interrupt Control (peripheral.INTCTRL) register. An interrupt request is generated when the corresponding interrupt is enabled, and the Interrupt Flag is set. The interrupt request remains active until the Interrupt Flag is cleared. See the peripheral's INTFLAGS register for details on how to clear Interrupt Flags. Note:  Interrupts must be enabled globally for interrupt requests to be generated. Table 8-3. Interrupt Vector Mapping Vector Program Peripheral Number Address Source (Word) (Name) Description 0 0x00 1 0x01 NMI Non-Maskable Interrupt available for CRCSCAN 2 0x02 BOD_VLM Voltage Level Monitor interrupt 3 0x03 RTC_CNT Real Time Counter Overflow or compare match interrupt 4 0x04 RTC_PIT Real Time Counter Periodic Interrupt 5 0x05 CCL_CCL Configurable Custom Logic interrupt 6 0x06 PORTA_PORT PORT A External interrupt 7 0x07 PORT_PORTB PORT B External interrupt 8 0x08 TCA0_OVF TCA_LUNF Normal: Timer/Counter Type A Overflow interrupt Split: Timer/Counter Type A Low Underflow interrupt 9 0x09 TCA0_HUNF Normal: Unused Split: Timer/Counter Type A High Underflow interrupt RESET © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 62 ATtiny424/426/427 ATtiny824/826/827 Peripherals and Architecture ...........continued Vector Program Peripheral Number Address Source (Word) (Name) 8.3 Description 10 0x0A TCA0_CMP0 TCA0_LCMP0 Normal: Timer/Counter Type A Compare channel 0 interrupt Split: Timer/Counter Type A Low Compare channel 0 interrupt 11 0x0B TCA0_CMP1 TCA0_LCMP1 Normal: Timer/Counter Type A Compare channel 1 interrupt Split: Timer/Counter Type A Low Compare channel 1 interrupt 12 0x0C TCA0_CMP2 TCA0_LCMP2 Normal: Timer/Counter Type A Compare channel 2 interrupt Split: Timer/Counter Type A Low Compare channel 2 interrupt 13 0x0D TCB0_INT Timer/Counter Type B Capture interrupt 14 0x0E TWI0_TWIS Two Wire Interface Client interrupt 15 0x0F TWI0_TWIM Two Wire Interface Host interrupt 16 0x10 SPI0_INT Serial Peripheral Interface 0 interrupt 17 0x11 USART0_RCX Universal Synchronous and Asynchronous Receiver and Transmitter 0 Receive Complete interrupt 18 0x12 USART0_DRE Universal Synchronous and Asynchronous Receiver and Transmitter 0 Data Register Empty interrupt 19 0x13 USART0_TXC Universal Synchronous and Asynchronous Receiver and Transmitter 0 Transmit Complete interrupt 20 0x14 AC0_AC Analog Comparator Compare interrupt 21 0x15 ADC0_ERROR Analog-to-Digital Converter Error interrupt 22 0x16 ADC0_RESRDY Analog-to-Digital Converter Result interrupt 23 0x17 ADC0_SAMPRDY Analog-to-Digital Converter Sample interrupt 24 0x18 PORTC_PORT PORT C External interrupt 25 0x19 TCB1_INT Timer/Counter Type B Capture interrupt 26 0x1A USART1_RCX Universal Synchronous and Asynchronous Receiver and Transmitter 1 Receive Complete interrupt 27 0x1B USART1_DRE Universal Synchronous and Asynchronous Receiver and Transmitter 1 Data Register Empty interrupt 28 0x1C USART1_TXC Universal Synchronous and Asynchronous Receiver and Transmitter 1 Transmit Complete interrupt 29 0x1D NVMCTRL_EE Non-Volatile Memory Controller Ready interupt SYSCFG - System Configuration The system configuration contains the revision ID of the part. The revision ID is readable from the CPU, making it useful for implementing application changes between part revisions. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 63 ATtiny424/426/427 ATtiny824/826/827 Peripherals and Architecture 8.3.1 Register Summary Offset Name Bit Pos. 0x00 0x01 Reserved REVID 7:0 8.3.2 7 6 5 4 3 2 1 0 REVID[7:0] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 64 ATtiny424/426/427 ATtiny824/826/827 Peripherals and Architecture 8.3.2.1 Device Revision ID Register Name:  Offset:  Reset:  Property:  REVID 0x01 [revision ID] - This register is read-only and displays the device revision ID. Bit 7 6 5 4 3 2 1 0 R R R R REVID[7:0] Access Reset R R R R Bits 7:0 – REVID[7:0] Revision ID This bit field contains the device revision. 0x00 = A, 0x01 = B, and so on. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 65 ATtiny424/426/427 ATtiny824/826/827 General Purpose I/O Registers 9. General Purpose I/O Registers The ATtiny424/426/427 and ATtiny824/826/827 devices provide four general purpose I/O registers. These registers can be used for storing any information, and they are particularly useful for storing global variables and interrupt flags. General purpose I/O registers, which reside in the address range 0x1C-0x1F, are directly bit-accessible using the SBI, CBI, SBIS, and SBIC instructions. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 66 ATtiny424/426/427 ATtiny824/826/827 General Purpose I/O Registers 9.1 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 GPIOR0 GPIOR1 GPIOR2 GPIOR3 7:0 7:0 7:0 7:0 9.2 7 6 5 4 3 2 1 0 GPIOR[7:0] GPIOR[7:0] GPIOR[7:0] GPIOR[7:0] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 67 ATtiny424/426/427 ATtiny824/826/827 General Purpose I/O Registers 9.2.1 General Purpose I/O Register n Name:  Offset:  Reset:  Property:  GPIORn 0x00 + n*0x01 [n=0..3] 0x00 - These are general purpose registers that can be used to store data, such as global variables and flags, in the bit accessible I/O memory space. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 GPIOR[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – GPIOR[7:0] General Purpose I/O Register Byte © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 68 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10. NVMCTRL - Nonvolatile Memory Controller 10.1 Features • • • • • • 10.2 Unified Memory In-System Programmable Self-Programming and Boot Loader Support Configurable Sections for Write Protection: – Boot section for boot loader code or application code – Application code section for application code – Application data section for application code or data storage Signature Row for Factory-Programmed Data: – ID for each device type – Serial number for each device – Calibration bytes for factory-calibrated peripherals User Row for Application Data: – Can be read and written from software – Can be written from UPDI on a locked device – Content is kept after chip erase Overview The NVM Controller (NVMCTRL) is the interface between the CPU and Nonvolatile Memories (Flash, EEPROM, Signature Row, User Row, and fuses). These are reprogrammable memory blocks that retain their values when they are not powered. The Flash is mainly used for program storage and can also be used for data storage, while the EEPROM, Signature Row, User Row, and fuses are used for data storage. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 69 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.2.1 Block Diagram Figure 10-1. NVMCTRL Block Diagram Nonvolatile Memory Block Program Memory Bus ` Flash EEPROM Data Memory Bus Signature Row User Row Fuses Register access NVMCTRL 10.3 Functional Description 10.3.1 Memory Organization 10.3.1.1 Flash The Flash is divided into a set of pages. A page is the basic unit addressed when programming the Flash. It is only possible to write or erase a whole page at a time. One page consists of several words. The Flash can be divided into three sections in blocks of 256 bytes for different security. The three different sections are BOOT, Application Code (APPCODE), and Application Data (APPDATA). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 70 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller Figure 10-2. Flash Sections FLASHSTART : 0x8000 BOOT BOOTEND>0: 0x8000+BOOTEND*256 APPLICATION CODE APPEND>0: 0x8000+APPEND*256 APPLICATION DATA FLASHEND Section Sizes The sizes of these sections are set by the Boot Section End (FUSE.BOOTEND) fuse and the Application Code Section End (FUSE.APPEND) fuse. The fuses select the section sizes in blocks of 256 bytes. The BOOT section stretches from the start of the Flash until BOOTEND. The APPCODE section runs from BOOTEND until APPEND, and the remaining area is the APPDATA section. Table 10-1. Setting Up Flash Sections BOOTEND APPEND BOOT Section 0 — 0 to FLASHEND > 0 0 0 to 256*BOOTEND > 0 ≤ BOOTEND 0 to 256*BOOTEND > 0 > BOOTEND 0 to 256*BOOTEND APPCODE Section APPDATA Section — — 256*BOOTEND to FLASHEND — 256*BOOTEND to 256*APPEND — 256*BOOTEND to FLASHEND 256*APPEND to FLASHEND If BOOTEND is written to ‘0’, the entire Flash is regarded as the BOOT section. If APPEND is written to ‘0’ and BOOTEND > 0, the APPCODE section runs from BOOTEND to the end of Flash (no APPDATA section). When APPEND ≤ BOOTEND, the APPCODE section is removed, and the APPDATA runs from BOOTEND to the end of Flash. When APPEND > BOOTEND, the APPCODE section spreads from BOOTEND until APPEND. The remaining area is the APPDATA section. If there is no boot loader software, it is recommended to use the BOOT section for Application Code. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 71 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller Notes:  1. After Reset, the default vector table location is at the start of the APPCODE section. The peripheral interrupts can be used in the code running in the BOOT section by relocating the interrupt vector table at the beginning of this section. That is done by setting the IVSEL bit in the CPUINT.CTRLA register. Refer to the CPUINT section for details. 2. If BOOTEND/APPEND, as resulted from BOOTEND and APPEND fuse setting, exceed the device FLASHEND, the corresponding fuse setting is ignored, and the default value is used. Refer to “Fuse” in the Memories section for default values. Example 10-1. Size of Flash Sections If FUSE.BOOTEND is written to 0x04 and FUSE.APPEND is written to 0x08, the first 4*256 bytes will be BOOT, the next 4*256 bytes will be APPCODE, and the remaining Flash will be APPDATA. Inter-Section Write Protection Between the three Flash sections, directional write protection is implemented: • The code in the BOOT section can write to APPCODE and APPDATA • The code in APPCODE can write to APPDATA • The code in APPDATA cannot write to Flash or EEPROM Boot Section Lock and Application Code Section Write Protection Additional to the inter-section write protection, the NVMCTRL provides a security mechanism to avoid unwanted access to the Flash memory sections. Even if the CPU can never write to the BOOT section, a Boot Section Lock (BOOTLOCK) bit in the Control B (NVMCTRL.CTRLB) register is provided to prevent the read and execution of code from the BOOT section. This bit can be set only from the code executed in the BOOT section and has effect only when leaving the BOOT section. The Application Code Section Write Protection (APCWP) bit in the Control B (NVMCTRL.CTRLB) register can be set to prevent further updates of the APPCODE section. 10.3.1.2 EEPROM The EEPROM is divided into a set of pages where one page consists of multiple bytes. The EEPROM has byte granularity on the erase/write. Within one page, only the bytes marked to be updated will be erased/written. The byte is marked by writing a new value to the page buffer for that address location. 10.3.1.3 User Row The User Row is one extra page of EEPROM. This page can be used to store various data, such as calibration/ configuration data and serial numbers. This page is not erased by a chip erase. The User Row is written as normal EEPROM, but also, it can be written through UPDI on a locked device. 10.3.2 Memory Access 10.3.2.1 Read Reading of the Flash and EEPROM is done by using load instructions with an address according to the memory map. Reading any of the arrays while a write or erase is in progress will result in a bus wait, and the instruction will be suspended until the ongoing operation is complete. 10.3.2.2 Page Buffer Load The page buffer is loaded by writing directly to the memories as defined in the memory map. The Flash, EEPROM, and User Row share the same page buffer, so only one section can be programmed at a time. The Least Significant bits (LSb) of the address are used to select where in the page buffer data are written. The resulting data will be a binary AND operation between the new and the previous content of the page buffer. The page buffer will automatically be erased (all bits set) after: • A device Reset • Any page write or erase operation • A Clear Page Buffer command © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 72 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller • A device wake-up from any sleep mode 10.3.2.3 Programming For page programming, filling the page buffer and writing the page buffer into Flash, User Row, and EEPROM are two separate operations. Before programming a Flash page with the data in the page buffer, the Flash page must be erased. The page buffer is also erased when the device enters a sleep mode. Programming an unerased Flash page will corrupt its content. The Flash can either be written with the erase and write separately, or one command handling both: Alternative 1: 1. Fill the page buffer. 2. Write the page buffer to Flash with the Erase and Write Page (ERWP) command. Alternative 2: 1. Write to a location on the page to set up the address. 2. Perform an Erase Page (ER) command. 3. Fill the page buffer. 4. Perform a Write Page (WP) command. The NVM command set supports both a single erase and write operation, and split Erase Page (ER) and Write Page (WP) commands. This split commands enable shorter programming time for each command, and the erase operations can be done during non-time-critical programming execution. The EEPROM programming is similar, but only the bytes updated in the page buffer will be written or erased in the EEPROM. 10.3.2.4 Commands Reading the Flash/EEPROM and writing the page buffer is handled with normal load/store instructions. Other operations, such as writing and erasing the memory arrays, are handled by commands in the NVM. To execute a command in the NVM: 1. Confirm that any previous operation is completed by reading the Busy (EEBUSY and FBUSY) Flags in the NVMCTRL.STATUS register. 2. Write the appropriate key to the Configuration Change Protection (CPU.CCP) register to unlock the NVM Control A (NVMCTRL.CTRLA) register. 3. Write the desired command value to the CMD bit field in the Control A (NVMCTRL.CTRLA) register within the next four instructions. 10.3.2.4.1 Write Page Command The Write Page (WP) command of the Flash controller writes the content of the page buffer to the Flash or EEPROM. If the write is to the Flash, the CPU will stop executing code as long as the Flash is busy with the write operation. If the write is to the EEPROM, the CPU can continue to execute code while the operation is ongoing. The page buffer will automatically be cleared after the operation is finished. 10.3.2.4.2 Erase Page Command The Erase Page (ER) command erases the current page. There must be one byte written in the page buffer for the Erase Page (ER) command to take effect. For erasing the Flash, first, write to one address on the desired page, then execute the command. The whole page in the Flash will then be erased. The CPU will be halted while the erase is ongoing. For the EEPROM, only the bytes written in the page buffer will be erased when the command is executed. To erase a specific byte, write to its corresponding address before executing the command. To erase a whole page, all the bytes in the page buffer have to be updated before executing the command. The CPU can continue running code while the operation is ongoing. The page buffer will automatically be cleared after the operation is finished. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 73 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.3.2.4.3 Erase/Write Page Command The Erase and Write Page (ERWP) command is a combination of the Erase Page and Write Page commands, but without clearing the page buffer after the Erase Page command: The erase/write operation first erases the selected page, then it writes the content of the page buffer to the same page. When executed on the Flash, the CPU will be halted when the operations are ongoing. When executed on EEPROM, the CPU can continue to execute code. The page buffer will automatically be cleared after the operation is finished. 10.3.2.4.4 Page Buffer Clear Command The Page Buffer Clear (PBC) command clears the page buffer. The contents of the page buffer will be all ‘1’s after the operation. The CPU will be halted when the operation executes (seven CPU cycles). 10.3.2.4.5 Chip Erase Command The Chip Erase (CHER) command erases the Flash and the EEPROM. The EEPROM is unaltered if the EEPROM Save During Chip Erase (EESAVE) fuse in FUSE.SYSCFG0 is set. The Flash will not be protected by Boot Section Lock (BOOTLOCK) bit or Application Code Section Write Protection (APCWP) bit in NVMCTRL.CTRLB register. The memory will be all ‘1’s after the operation. 10.3.2.4.6 EEPROM Erase Command The EEPROM Erase (EEER) command erases the EEPROM. The EEPROM will be all ‘1’s after the operation. The CPU will be halted while the EEPROM is being erased. 10.3.2.4.7 Write Fuse Command The Write Fuse (WFU) command writes the fuses. It can only be used by the UPDI; the CPU cannot start this command. Follow this procedure to use the Write Fuse command: 1. Write the address of the fuse to the Address (NVMCTRL.ADDR) register. 2. Write the data to be written to the fuse to the Data (NVMCTRL.DATA) register. 3. Execute the Write Fuse command. 4. After the fuse is written, a Reset is required for the updated value to take effect. For reading fuses, use a regular read on the memory location. 10.3.2.5 Write Access after Reset After a Power-on Reset (POR), the NVMCTRL rejects any write attempts to the NVM for a given time. During this period, the Flash Busy (FBUSY) and the EEPROM Busy (EEBUSY) bit field in the NVMCTRL.STATUS register will read ‘1’. EEBUSY and FBUSY bit field must read ‘0’ before the page buffer can be filled, or NVM commands can be issued. This time-out period is disabled either by writing the Time-Out Disable (TOUTDIS) bit in the System Configuration 0 (FUSE.SYSCFG0) fuse to ‘0’ or by configuring the RSTPINCFG bit field in FUSE.SYSCFG0 fuse to UPDI. 10.3.3 Preventing Flash/EEPROM Corruption A Flash/EEPROM write or erase can cause memory corruption if the supply voltage is too low for the CPU and the Flash/EEPROM to operate correctly. These issues are the same on-board level systems using Flash/EEPROM, and it is recommended to use the internal or an external Brown-out Detector (BOD) to ensure that the device is not operating at too low voltage. When the voltage is too low, a Flash/EEPROM corruption may be caused by two circumstances: 1. A regular write sequence to the Flash, which requires a minimum voltage to operate correctly. 2. The CPU itself can execute instructions incorrectly when the supply voltage is too low. The chip erase does not clear fuses. If the BOD is enabled by fuses before starting the Chip Erase command, it is automatically enabled at its previous configured level during the chip erase. Refer to the Electrical Characteristics section for Maximum Frequency vs. VDD. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 74 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller Attention:  Flash/EEPROM corruption can be avoided by taking the following measures: 1. Keep the device in Reset during periods of an insufficient power supply voltage. Do this by enabling the internal BOD. 2. The Voltage Level Monitor (VLM) in the BOD can be used to prevent starting a write to the EEPROM close to the BOD level. 3. If the detection levels of the internal BOD do not match the required detection level, an external VDD Reset protection circuit can be used. If a Reset occurs while a write operation is ongoing, the write operation will be aborted. 10.3.4 Interrupts Table 10-2. Available Interrupt Vectors and Sources Name Vector Description Conditions EEREADY NVM The EEPROM is ready for new write/erase operations. When an interrupt condition occurs, the corresponding interrupt flag is set in the Interrupt Flags (NVMCTRL.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding bit in the Interrupt Control (NVMCTRL.INTCTRL) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the NVMCTRL.INTFLAGS register for details on how to clear interrupt flags. 10.3.5 Sleep Mode Operation If there is no ongoing write operation, the NVMCTRL will enter a sleep mode when the system enters a sleep mode. If a write operation is ongoing when the system enters a sleep mode, the NVM block, the NVM Controller, and the system clock will remain ON until the write is finished. This is valid for all sleep modes, including Power-Down sleep mode. The EEPROM Ready interrupt will wake up the device only from Idle sleep mode. The page buffer is cleared when waking up from sleep. 10.3.6 Configuration Change Protection This peripheral has registers that are under Configuration Change Protection (CCP). To write to these registers, a certain key must first be written to the CPU.CCP register, followed by a write access to the protected bits within four CPU instructions. Attempting to write to a protected register without following the appropriate CCP unlock sequence leaves the protected register unchanged. The following registers are under CCP: Table 10-3. NVMCTRL - Registers under Configuration Change Protection Register Key NVMCTRL.CTRLA SPM NVMCTRL.CTRLB IOREG © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 75 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 0x04 0x05 CTRLA CTRLB STATUS INTCTRL INTFLAGS Reserved 7:0 7:0 7:0 7:0 7:0 0x06 DATA 0x08 ADDR 10.5 7 7:0 15:8 7:0 15:8 6 5 4 3 2 1 WRERROR CMD[2:0] BOOTLOCK EEBUSY 0 APCWP FBUSY EEREADY EEREADY DATA[7:0] DATA[15:8] ADDR[7:0] ADDR[15:8] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 76 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.1 Control A Name:  Offset:  Reset:  Property:  Bit 7 CTRLA 0x00 0x00 Configuration Change Protection 6 5 4 3 Access Reset 2 R/W 0 1 CMD[2:0] R/W 0 0 R/W 0 Bits 2:0 – CMD[2:0] Command Write this bit field to issue a command. The Configuration Change Protection key for self-programming (SPM) has to be written within four instructions before this write. Value Name Description 0x0 No command 0x1 WP Write page buffer to memory (NVMCTRL.ADDR selects which memory) 0x2 ER Erase page (NVMCTRL.ADDR selects which memory) 0x3 ERWP Erase and write page (NVMCTRL.ADDR selects which memory) 0x4 PBC Page buffer clear 0x5 CHER Chip erase: Erase Flash and EEPROM (unless EESAVE in FUSE.SYSCFG is ‘1’) 0x6 EEER EEPROM Erase 0x7 WFU Write fuse (only accessible through UPDI) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 77 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.2 Control B Name:  Offset:  Reset:  Property:  Bit 7 CTRLB 0x01 0x00 Configuration Change Protection 6 5 4 3 Access Reset 2 1 BOOTLOCK R/W 0 0 APCWP R/W 0 Bit 1 – BOOTLOCK Boot Section Lock Writing this bit to ‘1’ locks the BOOT section from reading and instruction fetching. If this bit is ‘1’, a read from the BOOT section will return ‘0’. A fetch from the BOOT section will also return ‘0’ as instruction. This bit can be written from the BOOT section only. It can only be cleared to ‘0’ by a Reset. This bit will take effect only when the BOOT section is left the first time after the bit is written. Bit 0 – APCWP Application Code Section Write Protection Writing this bit to ‘1’ prevents further updates to the Application Code section. This bit can only be written to ‘1’. It is cleared to ‘0’ only by Reset. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 78 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.3 Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x02 0x00 - 6 5 4 3 Access Reset 2 WRERROR R 0 1 EEBUSY R 0 0 FBUSY R 0 Bit 2 – WRERROR Write Error This bit will read ‘1’ when a write error has happened. A write error could be writing to different sections before doing a page write or writing to a protected area. This bit is valid for the last operation. Bit 1 – EEBUSY EEPROM Busy This bit will read ‘1’ when the EEPROM is busy with a command. Bit 0 – FBUSY Flash Busy This bit will read ‘1’ when the Flash is busy with a command. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 79 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.4 Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 INTCTRL 0x03 0x00 - 6 5 4 3 Access Reset 2 1 0 EEREADY R/W 0 Bit 0 – EEREADY EEPROM Ready Interrupt Writing a ‘1’ to this bit enables the interrupt, which indicates that the EEPROM is ready for new write/erase operations. This is a level interrupt that will be triggered only when the EEREADY flag in the INTFLAGS register is set to ‘0’. Thus, the interrupt must not be enabled before triggering an NVM command, as the EEREADY flag will not be set before the NVM command is issued. The interrupt may be disabled in the interrupt handler. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 80 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.5 Interrupt Flags Name:  Offset:  Reset:  Property:  Bit 7 INTFLAGS 0x04 0x00 - 6 5 4 3 2 1 0 EEREADY R/W 0 Access Reset Bit 0 – EEREADY EEREADY Interrupt Flag This flag is set continuously as long as the EEPROM is not busy. This flag is cleared by writing a ‘1’ to it. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 81 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.6 Data Name:  Offset:  Reset:  Property:  DATA 0x06 0x00 - The NVMCTRL.DATAL and NVMCTRL.DATAH register pair represents the 16-bit value, NVMCTRL.DATA. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit 15 14 13 12 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 DATA[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 DATA[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – DATA[15:0] Data Register This register is used by the UPDI for fuse write operations. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 82 ATtiny424/426/427 ATtiny824/826/827 NVMCTRL - Nonvolatile Memory Controller 10.5.7 Address Name:  Offset:  Reset:  Property:  ADDR 0x08 0x00 - The NVMCTRL.ADDRL and NVMCTRL.ADDRH register pair represents the 16-bit value, NVMCTRL.ADDR. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit 15 14 13 12 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 ADDR[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 ADDR[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:0 – ADDR[15:0] Address The Address register contains the address to the last memory location that has been updated. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 83 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11. CLKCTRL - Clock Controller 11.1 Features • • • • 11.2 All Clocks and Clock Sources are Automatically Enabled when Requested by Peripherals Internal Oscillators: – 20 MHz oscillator (OSC20M) – 32.768 kHz ultra low-power oscillator (OSCULP32K) External Clock Options: – 32.768 kHz crystal oscillator (XOSC32K) – External clock Main Clock Features: – Safe run-time switching – Prescaler with 1x to 64x division in 12 different settings Overview The Clock Controller (CLKCTRL) controls, distributes and prescales the clock signals from the available oscillators and supports internal and external clock sources. The CLKCTRL is based on an automatic clock request system implemented in all peripherals on the device. The peripherals will automatically request the clocks needed. The request is routed to the correct clock source if multiple clock sources are available. The Main Clock (CLK_MAIN) is used by the CPU, RAM, and all peripherals connected to the I/O bus. The main clock source can be selected and prescaled. Some peripherals can share the same clock source as the main clock or run asynchronously to the main clock domain. 11.2.1 Block Diagram - CLKCTRL © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 84 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller NVM RAM CPU CLK_CPU RTC Other Peripherals CLKOUT CLK_PER WDT INT BOD PRESCALER CLK_RTC CLK_WDT CLK_BOD Main Clock Prescaler CLK_MAIN RTC CLKSEL Main Clock Switch DIV32 XOSC32K OSCULP32K OSC20M XOSC32K SEL OSC20M Int. Oscillator 32.768 kHz ULP Int. Oscillator 32.768 kHz Ext. Crystal Oscillator TOSC2 TOSC1 EXTCLK The clock system consists of the main clock and other asynchronous clocks: • Main Clock This clock is used by the CPU, RAM, Flash, the I/O bus, and all peripherals connected to the I/O bus. It is always running in Active and Idle Sleep mode and can be running in Standby Sleep mode if requested. • The main clock CLK_MAIN is prescaled and distributed by the clock controller: • CLK_CPU is used by the CPU, SRAM, and the NVMCTRL peripheral to access the nonvolatile memory • CLK_PER is used by all peripherals that are not listed under asynchronous clocks Clocks running asynchronously to the main clock domain: – CLK_RTC is used by the RTC/PIT. It will be requested when the RTC/PIT is enabled. The clock source for CLK_RTC may only be changed if the peripheral is disabled. – CLK_WDT is used by the WDT. It will be requested when the WDT is enabled. – CLK_BOD is used by the BOD. It will be requested when the BOD is enabled in Sampled mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 85 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller The clock source for the for the main clock domain is configured by writing to the Clock Select bits (CLKSEL) in the Main Clock Control A register (CLKCTRL.MCLKCTRLA). The asynchronous clock sources are configured by registers in the respective peripheral. 11.2.2 Signal Description Signal Type Description CLKOUT Digital output CLK_PER output 11.3 Functional Description 11.3.1 Sleep Mode Operation When a clock source is not used or requested, it will stop. It is possible to request a clock source directly by writing a ‘1’ to the Run Standby (RUNSTDBY) bit in the respective oscillator’s Control A (CLKCTRL.[osc]CTRLA) register. This will cause the oscillator to run constantly, except for Power-Down sleep mode. Additionally, when this bit is written to ‘1’, the oscillator start-up time is eliminated when the clock source is requested by a peripheral. The main clock will always run in Active and Idle sleep modes. In Standby sleep mode, the main clock will run only if any peripheral is requesting it, or the Run in Standby (RUNSTDBY) bit in the respective oscillator’s Control A (CLKCTRL.[osc]CTRLA) register is written to ‘1’. In Power-Down sleep mode, the main clock will stop after all NVM operations are completed. Refer to the Sleep Controller section for more details on sleep mode operation. 11.3.2 Main Clock Selection and Prescaler All internal oscillators can be used as the main clock source for CLK_MAIN. The main clock source is selectable from software and can be safely changed during normal operation. Built-in hardware protection prevents unsafe clock switching: Upon selection of an external clock source, a switch to the chosen clock source will only occur if edges are detected. Until a sufficient number of clock edges are detected the switch will not occur, and it will not be possible to change to another clock source again without executing a Reset. An ongoing clock source switch is indicated by the System Oscillator Changing (SOSC) flag in the Main Clock Status (CLKCTRL.MCLKSTATUS) register. The stability of the external clock sources is indicated by the respective status (EXTS and XOSC32KS in CLKCTRL.MCLKSTATUS) flags. CAUTION 1. 2. If an external clock source fails while used as the CLK_MAIN source, only the WDT can provide a mechanism to switch back via System Reset. Do not alter the properties of the external clock source while used as the CLK_MAIN source. This can be interpreted as a clock failure. CLK_MAIN is fed into a prescaler before it is used by the peripherals (CLK_PER) in the device. The prescaler divide CLK_MAIN by a factor from 1 to 64. Figure 11-1. Main Clock and Prescaler OSC20M 32.768 kHz Osc. 32.768 kHz crystal Osc. External clock © 2021 Microchip Technology Inc. CLK_MAIN Main Clock Prescaler (Div 1, 2, 4, 8, 16, 32, 64, 6, 10, 24, 48) Preliminary Datasheet CLK_PER DS40002311A-page 86 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller The Main Clock and Prescaler configuration (CLKCTRL.MCLKCTRLA, CLKCTRL.MCLKCTRLB) registers are protected by the Configuration Change Protection Mechanism, employing a timed write procedure for changing these registers. 11.3.3 Main Clock After Reset After any Reset, CLK_MAIN is provided by the 20 MHz Oscillator (OSC20M) and with a prescaler division factor of 6. The actual frequency of the OSC20M is determined by the Frequency Select bits (FREQSEL) of the Oscillator Configuration fuse (FUSE.OSCCFG). Refer to the description of FUSE.OSCCFG for details of the possible frequencies after Reset. 11.3.4 Clock Sources The clock sources are divided into two main groups: internal oscillators and external clock sources. All the internal clock sources are automatically enabled when they are requested by a peripheral. The crystal oscillator must be enabled by writing a ‘1’ to the ENABLE bit in the 32.768 kHz Crystal Oscillator Control A (CLKCTRL.XOSC32KCTRLA) register before it can serve as a clock source. After Reset, the device starts running from the internal high-frequency oscillator or the internal 32.768 kHz oscillator. The respective Oscillator Status bits in the Main Clock Status (CLKCTRL.MCLKSTATUS) register indicate if the clock source is running and stable. 11.3.4.1 Internal Oscillators The internal oscillators do not require any external components to run. See the related links for accuracy and electrical characteristics. 11.3.4.1.1 20 MHz Oscillator (OSC20M) This oscillator can operate at multiple frequencies, selected by the value of the Frequency Select bits (FREQSEL) in the Oscillator Configuration Fuse (FUSE.OSCCFG). After a system Reset, FUSE.OSCCFG determines the initial frequency of CLK_MAIN. During Reset, the calibration values for the OSC20M are loaded from fuses. There are two different calibration bit fields. The Calibration bit field (CAL20M) in the Calibration A register (CLKCTRL.OSC20MCALIBA) enables calibration around the current center frequency. The Oscillator Temperature Coefficient Calibration bit field (TEMPCAL20M) in the Calibration B register (CLKCTRL.OSC20MCALIBB) enables adjustment of the slope of the temperature drift compensation. For applications requiring more fine-tuned frequency than provided by the oscillator calibration, the remaining oscillator frequency error measured during calibration is available in the Signature Row (SIGROW) for additional compensation. The oscillator calibration can be locked by the Oscillator Lock (OSCLOCK) Fuse (FUSE.OSCCFG). When this fuse is ‘1’, it is not possible to change the calibration. The calibration is locked if this oscillator is used as the main clock source and the Lock Enable bit (LOCKEN) in the Control B register (CLKCTRL.OSC20MCALIBB) is ‘1’. The calibration bits are protected by the Configuration Change Protection Mechanism, requiring a timed write procedure for changing the main clock and prescaler settings. Refer to the Electrical Characteristics section for the start-up time. OSC20M Stored Frequency Error Compensation This oscillator can operate at multiple frequencies, selected by the value of the Frequency Select bits (FREQSEL) in the Oscillator Configuration fuse (FUSE.OSCCFG) at Reset. As previously mentioned, appropriate calibration values are loaded to adjust to center frequency (OSC20M), and temperature drift compensation (TEMPCAL20M), meeting the specifications defined in the internal oscillator characteristics. For applications requiring a wider operating range, the relative factory stored frequency error after calibrations can be used. The four errors are measured at different settings and are available in the signature row as signed byte values. • • • SIGROW.OSC16ERR3V is the frequency error from 16 MHz measured at 3V SIGROW.OSC16ERR5V is the frequency error from 16 MHz measured at 5V SIGROW.OSC20ERR3V is the frequency error from 20 MHz measured at 3V © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 87 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller • SIGROW.OSC20ERR5V is the frequency error from 20 MHz measured at 5V The error is stored as a compressed Q1.10 fixed point 8-bit value in order not to lose resolution, where the MSb is the sign bit and the seven LSb the lower bits of the Q1.10. BAUDactual = BAUDideal + BAUDideal * SigRowError 1024 The minimum legal BAUD register value is 0x40. The target BAUD register value may therefore not be lower than 0x4A to ensure that the compensated BAUD value stays within the legal range, even for parts with negative compensation values. The example code below demonstrates how to apply this value for a more accurate USART baud rate: #include /* Baud rate compensated with factory stored frequency error */ /* Asynchronous communication without Auto-baud (Sync ) */ /* 16MHz Clock, 3V and 600 BAUD */ int8_t sigrow_val int32_t baud_reg_val = SIGROW.OSC16ERR3V; = 600; assert (baud_reg_val >= 0x4A); value with max neg comp baud_reg_val *= (1024 + sigrow_val); baud_reg_val /= 1024; USART0.BAUD = (int16_t) baud_reg_val; // read signed error // ideal BAUD register value // Verify legal min BAUD register // sum resolution + error // divide by resolution // set adjusted baud rate 11.3.4.1.2 32.768 kHz Oscillator (OSCULP32K) The 32.768 kHz oscillator is optimized for Ultra Low-Power (ULP) operation. Power consumption is decreased at the cost of decreased accuracy compared to an external crystal oscillator. This oscillator provides the 1.024 kHz signal for the Real-Time Counter (RTC), the Watchdog Timer (WDT), and the Brown-out Detector (BOD). The start-up time of this oscillator is the oscillator start-up time plus four oscillator cycles. Refer to section Electrical Characteristics for the start-up time. 11.3.4.2 External Clock Sources These external clock sources are available: • External Clock from a pin (EXTCLK). • The TOSC1 and TOSC2 pins are dedicated to driving a 32.768 kHz crystal oscillator (XOSC32K). • Instead of a crystal oscillator, TOSC1 can be configured to accept an external clock source. 11.3.4.2.1 32.768 kHz Crystal Oscillator (XOSC32K) This oscillator supports two input options: Either a crystal is connected to the pins TOSC1 and TOSC2, or an external clock running at 32.768 kHz is connected to TOSC1. The input option must be configured by writing the Source Select (SEL) bit in the XOSC32K Control A (CLKCTRL.XOSC32KCTRLA) register. The XOSC32K is enabled by writing a ‘1’ to its ENABLE bit in CLKCTRL.XOSC32KCTRLA. When enabled, the configuration of the GPIO pins used by the XOSC32K is overridden as TOSC1 and TOSC2 pins. The Enable bit needs to be set for the oscillator to start running when requested. The start-up time of a given crystal oscillator can be accommodated by writing to the Crystal Start-up Time bits (CSUT) in CLKCTRL.XOSC32KCTRLA. When XOSC32K is configured to use an external clock on TOSC1, the start-up time is fixed to two cycles. 11.3.4.2.2 External Clock (EXTCLK) The EXTCLK is taken directly from the pin. This GPIO pin is automatically configured for EXTCLK if any peripheral is requesting this clock. This clock source has a start-up time of two cycles when first requested. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 88 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.3.5 Configuration Change Protection This peripheral has registers that are under Configuration Change Protection (CCP). To write to these registers, a certain key must first be written to the CPU.CCP register, followed by a write access to the protected bits within four CPU instructions. Attempting to write to a protected register without following the appropriate CCP unlock sequence leaves the protected register unchanged. The following registers are under CCP: Table 11-1. CLKCTRL - Registers Under Configuration Change Protection Register Key CLKCTRL.MCLKCTRLB IOREG CLKCTRL.MCLKLOCK IOREG CLKCTRL.XOSC32KCTRLA IOREG CLKCTRL.MCLKCTRLA IOREG CLKCTRL.OSC20MCTRLA IOREG CLKCTRL.OSC20MCALIBA IOREG CLKCTRL.OSC20MCALIBB IOREG CLKCTRL.OSC32KCTRLA IOREG © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 89 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.4 Register Summary Offset Name Bit Pos. 7 0x00 0x01 0x02 0x03 0x04 ... 0x0F 0x10 0x11 0x12 0x13 ... 0x17 0x18 0x19 ... 0x1B 0x1C MCLKCTRLA MCLKCTRLB MCLKLOCK MCLKSTATUS 7:0 7:0 7:0 7:0 CLKOUT 11.5 6 5 4 3 2 XOSC32KS OSC32KS 0 CLKSEL[1:0] PEN LOCKEN SOSC PDIV[3:0] EXTS 1 OSC20MS Reserved OSC20MCTRLA OSC20MCALIBA OSC20MCALIBB 7:0 7:0 7:0 RUNSTDBY CAL20M[6:0] LOCK TEMPCAL20M[3:0] Reserved OSC32KCTRLA 7:0 RUNSTDBY Reserved XOSC32KCTRLA 7:0 CSUT[1:0] SEL RUNSTDBY ENABLE Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 90 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.1 Main Clock Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CLKOUT R/W 0 MCLKCTRLA 0x00 0x00 Configuration Change Protection 6 5 4 3 2 1 0 CLKSEL[1:0] R/W R/W 0 0 Bit 7 – CLKOUT System Clock Out When this bit is written to ‘1’, the system clock is output to the CLKOUT pin. When the device is in a Sleep mode, there is no clock output unless a peripheral is using the system clock. Bits 1:0 – CLKSEL[1:0] Clock Select This bit field selects the source for the Main Clock (CLK_MAIN). Value Name Description 0x0 OSC20M 20 MHz internal oscillator 0x1 OSCULP32K 32.768 kHz internal ultra low-power oscillator 0x2 XOSC32K 32.768 kHz external crystal oscillator 0x3 EXTCLK External clock © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 91 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.2 Main Clock Control B Name:  Offset:  Reset:  Property:  Bit 7 MCLKCTRLB 0x01 0x11 Configuration Change Protection 6 5 4 3 2 1 R/W 0 R/W 0 PDIV[3:0] Access Reset R/W 1 R/W 0 0 PEN R/W 1 Bits 4:1 – PDIV[3:0] Prescaler Division If the Prescaler Enable (PEN) bit is written to ‘1’, these bits define the division ratio of the main clock prescaler. These bits can be written during run-time to vary the clock frequency of the system to suit the application requirements. The user software must ensure a correct configuration of the input frequency (CLK_MAIN) and prescaler settings, so that the resulting frequency of CLK_PER never exceeds the allowed maximum (see Electrical Characteristics). Value Name Description 0x0 DIV2 CLK_MAIN divided by 2 0x1 DIV4 CLK_MAIN divided by 4 0x2 DIV8 CLK_MAIN divided by 8 0x3 DIV16 CLK_MAIN divided by 16 0x4 DIV32 CLK_MAIN divided by 32 0x5 DIV64 CLK_MAIN divided by 64 0x6-0x7 Reserved 0x8 DIV6 CLK_MAIN divided by 6 0x9 DIV10 CLK_MAIN divided by 10 0xA DIV12 CLK_MAIN divided by 12 0xB DIV24 CLK_MAIN divided by 24 0xC DIV48 CLK_MAIN divided by 48 other Reserved Bit 0 – PEN Prescaler Enable This bit must be written to ‘1’ to enable the prescaler. When enabled, the division ratio is selected by the PDIV bit field. When this bit is written to ‘0’, the main clock will pass through undivided (CLK_PER = CLK_MAIN), regardless of the value of PDIV. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 92 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.3 Main Clock Lock Name:  Offset:  Reset:  Property:  Bit 7 MCLKLOCK 0x02 Based on OSCLOCK in FUSE.OSCCFG Configuration Change Protection 6 5 4 3 Access Reset 2 1 0 LOCKEN R/W x Bit 0 – LOCKEN Lock Enable Writing this bit to ‘1’ will lock the CLKCTRL.MCLKCTRLA and CLKCTRL.MCLKCTRLB registers, and, if applicable, the calibration settings for the current main clock source from further software updates. Once locked, the CLKCTRL.MCLKLOCK registers cannot be accessed until the next hardware Reset. This provides protection for the CLKCTRL.MCLKCTRLA and CLKCTRL.MCLKCTRLB registers and calibration settings for the main clock source from unintentional modification by software. At Reset, the LOCKEN bit is loaded based on the OSCLOCK bit in FUSE.OSCCFG. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 93 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.4 Main Clock Status Name:  Offset:  Reset:  Property:  Bit Access Reset 7 EXTS R 0 MCLKSTATUS 0x03 0x00 - 6 XOSC32KS R 0 5 OSC32KS R 0 4 OSC20MS R 0 3 2 1 0 SOSC R 0 Bit 7 – EXTS External Clock Status Value Description 0 EXTCLK has not started 1 EXTCLK has started Bit 6 – XOSC32KS XOSC32K Status The Status bit will only be available if the source is requested as the main clock or by another module. If the oscillator RUNSTDBY bit is set and the oscillator is unused/not requested, this bit will be ‘0’. Value Description 0 XOSC32K is not stable 1 XOSC32K is stable Bit 5 – OSC32KS OSCULP32K Status The Status bit will only be available if the source is requested as the main clock or by another module. If the oscillator RUNSTDBY bit is set and the oscillator is unused/not requested, this bit will be ‘0’. Value Description 0 OSCULP32K is not stable 1 OSCULP32K is stable Bit 4 – OSC20MS OSC20M Status The Status bit will only be available if the source is requested as the main clock or by another module. If the oscillator RUNSTDBY bit is set and the oscillator is unused/not requested, this bit will be ‘0’. Value Description 0 OSC20M is not stable 1 OSC20M is stable Bit 0 – SOSC Main Clock Oscillator Changing Value Description 0 The clock source for CLK_MAIN is not undergoing a switch 1 The clock source for CLK_MAIN is undergoing a switch and will change as soon as the new source is stable © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 94 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.5 20 MHz Oscillator Control A Name:  Offset:  Reset:  Property:  Bit 7 OSC20MCTRLA 0x10 0x00 Configuration Change Protection 6 5 4 3 Access Reset 2 1 RUNSTDBY R/W 0 0 Bit 1 – RUNSTDBY Run Standby This bit forces the oscillator ON in all modes, even when unused by the system. In Standby sleep mode this can be used to ensure immediate wake-up and not waiting for oscillator start-up time. When not requested by peripherals, no oscillator output is provided. It takes four oscillator cycles to open the clock gate after a request but the oscillator analog start-up time will be removed when this bit is set. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 95 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.6 20 MHz Oscillator Calibration A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 OSC20MCALIBA 0x11 Based on FREQSEL in FUSE.OSCCFG Configuration Change Protection 6 5 4 R/W x R/W x R/W x 3 CAL20M[6:0] R/W x 2 1 0 R/W x R/W x R/W x Bits 6:0 – CAL20M[6:0] Calibration These bits change the frequency around the current center frequency of the OSC20M for fine-tuning. At Reset, the factory-calibrated values are loaded based on the FREQSEL bit in FUSE.OSCCFG. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 96 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.7 20 MHz Oscillator Calibration B Name:  Offset:  Reset:  Property:  Bit Access Reset 7 LOCK R x OSC20MCALIBB 0x12 Based on FUSE.OSCCFG Configuration Change Protection 6 5 4 3 R/W x 2 1 TEMPCAL20M[3:0] R/W R/W x x 0 R/W x Bit 7 – LOCK Oscillator Calibration Locked by Fuse When this bit is set, the calibration settings in CLKCTRL.OSC20MCALIBA and CLKCTRL.OSC20MCALIBB cannot be changed. The Reset value is loaded from the OSCLOCK bit in the Oscillator Configuration (FUSE.OSCCFG) fuse. Bits 3:0 – TEMPCAL20M[3:0] Oscillator Temperature Coefficient Calibration These bits tune the slope of the temperature compensation. At Reset, the factory-calibrated values are loaded based on the FREQSEL bits in FUSE.OSCCFG. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 97 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.8 32.768 kHz Oscillator Control A Name:  Offset:  Reset:  Property:  Bit 7 OSC32KCTRLA 0x18 0x00 Configuration Change Protection 6 5 4 3 Access Reset 2 1 RUNSTDBY R/W 0 0 Bit 1 – RUNSTDBY Run Standby This bit forces the oscillator ON in all modes, even when unused by the system. In Standby sleep mode this can be used to ensure immediate wake-up and not waiting for the oscillator start-up time. When not requested by peripherals, no oscillator output is provided. It takes four oscillator cycles to open the clock gate after a request but the oscillator analog start-up time will be removed when this bit is set. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 98 ATtiny424/426/427 ATtiny824/826/827 CLKCTRL - Clock Controller 11.5.9 32.768 kHz Crystal Oscillator Control A Name:  Offset:  Reset:  Property:  XOSC32KCTRLA 0x1C 0x00 Configuration Change Protection The SEL and CSUT bits cannot be changed as long as the ENABLE bit is set or the XOSC32K Stable (XOSC32KS) bit in CLKCTRL.MCLKSTATUS is high. To change settings safely: Write a ‘0’ to the ENABLE bit and wait until XOSC32KS is ‘0’ before re-enabling the XOSC32K with new settings. Bit 7 6 5 4 3 CSUT[1:0] Access Reset R/W 0 R/W 0 2 SEL R/W 0 1 RUNSTDBY R/W 0 0 ENABLE R/W 0 Bits 5:4 – CSUT[1:0] Crystal Start-Up Time These bits select the start-up time for the XOSC32K. It is write-protected when the oscillator is enabled (ENABLE = 1). If SEL = 1, the start-up time will not be applied. Value Name Description 0x0 1K 1k cycles 0x1 16K 16k cycles 0x2 32K 32k cycles 0x3 64K 64k cycles Bit 2 – SEL Source Select This bit selects the external source type. It is write-protected when the oscillator is enabled (ENABLE = 1). Value Description 0 External crystal 1 External clock on TOSC1 pin Bit 1 – RUNSTDBY Run Standby Writing this bit to ‘1’ starts the crystal oscillator and forces the oscillator ON in all modes, even when unused by the system if the ENABLE bit is set. In Standby sleep mode, this can be used to ensure immediate wake-up and not waiting for oscillator start-up time. When this bit is ‘0’, the crystal oscillator is only running when requested and the ENABLE bit is set. The output of XOSC32K is not sent to other peripherals unless it is requested by one or more peripherals. When the RUNSTDBY bit is set, there will only be a delay of two to three crystal oscillator cycles after a request until the oscillator output is received, if the initial crystal start-up time has already completed. According to RUNSTDBY bit, the oscillator will be turned ON all the time if the device is in Active, Idle, or Standby sleep mode, or only be enabled when requested. This bit is I/O protected to prevent any unintentional enabling of the oscillator. Bit 0 – ENABLE Enable When this bit is written to ‘1’, the configuration of the respective input pins is overridden to TOSC1 and TOSC2. Also, the Source Select (SEL) bit and Crystal Start-Up Time (CSUT) become read-only. This bit is I/O protected to prevent any unintentional enabling of the oscillator. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 99 ATtiny424/426/427 ATtiny824/826/827 SLPCTRL - Sleep Controller 12. SLPCTRL - Sleep Controller 12.1 Features • • • 12.2 Power Management for Adjusting Power Consumption and Functions Three Sleep Modes: – Idle – Standby – Power-Down Configurable Standby Mode where Peripherals Can Be Configured as ON or OFF Overview Sleep modes are used to shut down peripherals and clock domains in the device in order to save power. The Sleep Controller (SLPCTRL) controls and handles the transitions between Active and sleep modes. There are four modes available: One Active mode in which software is executed, and three sleep modes. The available sleep modes are Idle, Standby and Power-Down. All sleep modes are available and can be entered from the Active mode. In Active mode, the CPU is executing application code. When the device enters sleep mode, the program execution is stopped. The application code decides which sleep mode to enter and when. Interrupts are used to wake the device from sleep. The available interrupt wake-up sources depend on the configured sleep mode. When an interrupt occurs, the device will wake up and execute the Interrupt Service Routine before continuing normal program execution from the first instruction after the SLEEP instruction. Any Reset will take the device out of sleep mode. The content of the register file, SRAM and registers, is kept during sleep. If a Reset occurs during sleep, the device will reset, start and execute from the Reset vector. 12.2.1 Block Diagram Figure 12-1. Sleep Controller in the System SLEEP Instruction SLPCTRL Interrupt Request CPU Sleep State Interrupt Request Peripheral 12.3 12.3.1 Functional Description Initialization To put the device into a sleep mode, follow these steps: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 100 ATtiny424/426/427 ATtiny824/826/827 SLPCTRL - Sleep Controller 1. Configure and enable the interrupts that are able to wake the device from sleep. Also, enable global interrupts. WARNING 2. If there are no interrupts enabled when going to sleep, the device cannot wake up again. Only a Reset will allow the device to continue operation. Select which sleep mode to enter and enable the Sleep Controller by writing to the Sleep Mode (SMODE) bit field and the Enable (SEN) bit in the Control A (SLPCTRL.CTRLA) register. The SLEEP instruction must be executed to make the device go to sleep. 12.3.2 Operation 12.3.2.1 Sleep Modes In addition to Active mode, there are three different sleep modes with decreasing power consumption and functionality. Idle Standby PowerDown The CPU stops executing code. No peripherals are disabled, and all interrupt sources can wake the device. The user can configure peripherals to be enabled or not, using the respective RUNSTBY bit. This means that the power consumption is highly dependent on what functionality is enabled, and thus may vary between the Idle and Power-Down levels. SleepWalking is available for the ADC module. BOD, WDT, and PIT (a component of the RTC) are active. The only wake-up sources are the pin change interrupt, PIT, VLM, TWI address match, and CCL. Table 12-1. Sleep Mode Activity Overview for Peripherals Clock Peripheral Active in Sleep Mode Idle Standby Power-Down CLK_CPU CPU CLK_RTC RTC X X(1,2) X(2) CLK_WDT WDT X X X CLK_BOD(3) BOD X X X (4) CCL X X(1) CLK_PER ADCn X X(1) TCAn TCBn All other peripherals X Notes:  1. The RUNSTDBY bit of the corresponding peripheral must be set to enter an active state. 2. In Standby sleep mode, only the RTC functionality requires the RUNSTDBY to be set to enter an active state. In Power-Down sleep mode, only the PIT functionality is available. 3. Sampled mode only. 4. The clock domain depends on the clock source selected for CCL. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 101 ATtiny424/426/427 ATtiny824/826/827 SLPCTRL - Sleep Controller Table 12-2. Sleep Mode Activity Overview for Clock Sources Clock Source Active in Sleep Mode Idle Standby Main clock source X X(1) RTC clock source X X(1,2) X(2) WDT oscillator X X X BOD oscillator(3) X X X X X(1) CCL clock source Power-Down Notes:  1. The RUNSTDBY bit of the corresponding peripheral must be set to enter an active state. 2. In Standby sleep mode, only the RTC functionality requires the RUNSTDBY to be set to enter an active state. In Power-Down sleep mode, only the PIT functionality is available. 3. Sampled mode only. Table 12-3. Sleep Mode Wake-Up Sources Wake-Up Source Active in Sleep Mode Idle Standby Power-Down PORT Pin interrupt X X X(1) TWI Address Match interrupt X X X BOD VLM interrupt X X X CCL interrupts X X(2,3) X(3) RTC interrupts X X(2,4) X(4) USART interrupts X(5) X(6) - TCAn interrupts X X(2) X - TCBn interrupts ADCn interrupts ACn Compare interrupt All other interrupts - Notes:  1. The I/O pin has to be configured according to Asynchronous Sensing Pin Properties in the PORT section. 2. The RUNSTDBY bit of the corresponding peripheral must be set to enter an active state. 3. CCL can wake up the device if the path through LUTn is asynchronous (FILTSEL=0x0 and EDGEDET=0x0 in LUTnCTRLA register). 4. In Standby sleep mode, only the RTC functionality requires the RUNSTDBY to be set to enter an active state. In Power-Down sleep mode, only the PIT functionality is available. 5. Start-of-Frame interrupt is only available in Standby Sleep Mode. 6. In Standby Sleep Mode only the Start-of-Frame interrupt will trigger Wake-Up from USART. 12.3.2.2 Wake-up Time The normal wake-up time for the device is six main clock cycles (CLK_PER), plus the time it takes to start the main clock source: • In Idle sleep mode, the main clock source is kept running to eliminate additional wake-up time. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 102 ATtiny424/426/427 ATtiny824/826/827 SLPCTRL - Sleep Controller • • In Standby sleep mode, the main clock might be running depending on the peripheral configuration. In Power-Down sleep mode, only the ULP 32.768 kHz oscillator and the RTC clock may be running if it is used by the BOD or WDT. All other clock sources will be OFF. Table 12-4. Sleep Modes and Start-up Time Sleep Mode Start-up Time IDLE 6 CLK Standby 6 CLK + OSC start-up Power-Down 6 CLK + OSC start-up The start-up time for the different clock sources is described in the Clock Controller (CLKCTRL) section. In addition to the normal wake-up time, it is possible to make the device wait until the BOD is ready before executing code. This is done by writing 0x3 to the BOD Operation mode in Active and Idle bits (ACTIVE) in the BOD Configuration fuse (FUSE.BODCFG). If the BOD is ready before the normal wake-up time, the total wake-up time will be the same. If the BOD takes longer than the normal wake-up time, the wake-up time will be extended until the BOD is ready. This ensures correct supply voltage whenever code is executed. 12.3.3 Debug Operation During run-time debugging, this peripheral will continue normal operation. The SLPCTRL is only affected by a break in the debug operation: If the SLPCTRL is in a sleep mode when a break occurs, the device will wake up, and the SLPCTRL will go to Active mode, even if there are no pending interrupt requests. If the peripheral is configured to require periodic service by the CPU through interrupts or similar, improper operation or data loss may result during halted debugging. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 103 ATtiny424/426/427 ATtiny824/826/827 SLPCTRL - Sleep Controller 12.4 Register Summary Offset Name Bit Pos. 0x00 CTRLA 7:0 12.5 7 6 5 4 3 2 1 SMODE[1:0] 0 SEN Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 104 ATtiny424/426/427 ATtiny824/826/827 SLPCTRL - Sleep Controller 12.5.1 Control A Name:  Offset:  Reset:  Property:  CTRLA 0x00 0x00 - Bit 7 6 5 4 3 Access Reset R 0 R 0 R 0 R 0 R 0 2 1 SMODE[1:0] R/W R/W 0 0 0 SEN R/W 0 Bits 2:1 – SMODE[1:0] Sleep Mode Writing these bits selects which sleep mode to enter when the Sleep Enable (SEN) bit is written to ‘1’ and the SLEEP instruction is executed. Value Name Description 0x0 IDLE Idle sleep mode enabled 0x1 STANDBY Standby sleep mode enabled 0x2 PDOWN Power-Down sleep mode enabled other Reserved Bit 0 – SEN Sleep Enable This bit must be written to ‘1’ before the SLEEP instruction is executed to make the MCU enter the selected Sleep mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 105 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller 13. RSTCTRL - Reset Controller 13.1 Features • • • • 13.2 Returns the Device to an Initial State after a Reset Identifies the Previous Reset Source Power Supply Reset Sources: – Power-on Reset (POR) – Brown-out Detector (BOD) Reset User Reset Sources: – External Reset (RESET) – Watchdog Timer (WDT) Reset – Software Reset (SWRST) – Unified Program and Debug Interface (UPDI) Reset Overview The Reset Controller (RSTCTRL) manages the Reset of the device. It issues a device Reset, sets the device to its initial state, and allows the Reset source to be identified by software. 13.2.1 Block Diagram Figure 13-1. Reset System Overview RESET SOURCES VDD RESET CONTROLLER POR Pull-up resistor BOD UPDI External Reset RESET WDT All other peripherals UPDI CPU (SW) 13.2.2 Signal Description Signal Description Type RESET External Reset (active-low) Digital input © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 106 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller 13.3 Functional Description 13.3.1 Initialization The RSTCTRL is always enabled, but some of the Reset sources must be enabled individually (either by Fuses or by software) before they can request a Reset. After a Reset from any source, the registers in the device with automatic loading from the Fuses or from the Signature Row are updated. 13.3.2 Operation 13.3.2.1 Reset Sources After any Reset, the source that caused the Reset is found in the Reset Flag (RSTCTRL.RSTFR) register. The user can identify the previous Reset source by reading this register in the software application. There are two types of Resets based on the source: • Power Supply Reset Sources: – Power-on Reset (POR) – Brown-out Detector (BOD) Reset • User Reset Sources: – External Reset (RESET) – Watchdog Timer (WDT) Reset – Software Reset (SWRST) – Unified Program and Debug Interface (UPDI) Reset 13.3.2.1.1 Power-on Reset (POR) The purpose of the Power-on Reset (POR) is to ensure a safe start-up of logic and memories. It is generated by an on-chip detection circuit and is always enabled. The POR is activated when the VDD rises and gives active reset as long as VDD is below the POR threshold voltage (VPOR+). The reset will last until the Start-up and reset initialization sequence is finished. The Start-up Time (SUT) is determined by fuses. Reset is activated again, without any delay, when VDD falls below the detection level (VPOR-). Figure 13-2. MCU Start-Up, RESET Tied to VDD tSUT VDD DEVICE STATE tINIT VPOR- VPOR+ OFF Active Reset Start-up Initialization Running Active Reset INTERNAL RESET 13.3.2.1.2 Brown-out Detector (BOD) Reset The on-chip Brown-out Detector (BOD) circuit will monitor the VDD level during operation by comparing it to a fixed trigger level. The trigger level for the BOD can be selected by fuses. If BOD is unused in the application, it is forced to a minimum level in order to ensure a safe operation during internal Reset and chip erase. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 107 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller Figure 13-3. Brown-out Detector Reset tBOD tSUT tINIT VBOD+ VDD VBOD- DEVICE STATE Active Reset Running Initialization Start-up Running INTERNAL RESET 13.3.2.1.3 External Reset The external Reset is enabled by a fuse, see the RSTPINCFG field in FUSE.SYSCFG0. When enabled, the external Reset requests a Reset as long as the RESET pin is low. The device will stay in Reset until RESET is high again. Figure 13-4. External Reset Characteristics tRST tINIT VDD VRST+ RESET DEVICE STATE VRST- Running Active Reset Initialization Running INTERNAL RESET 13.3.2.1.4 Watchdog Reset The Watchdog Timer (WDT) is a system function for monitoring correct program operation. If the WDT is not reset from software according to the programmed time-out period, a Watchdog Reset will be issued. See the WDT Watchdog Timer section for further details. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 108 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller Figure 13-5. Watchdog Reset tWDTR tINIT VDD WDT TIME-OUT DEVICE STATE Running Active Reset Initialization Running INTERNAL RESET Note:  The time tWDTR is approximately 50 ns. 13.3.2.1.5 Software Reset The software Reset makes it possible to issue a system Reset from software. The Reset is generated by writing a ‘1’ to the Software Reset Enable (SWRE) bit in the Software Reset (RSTCTRL.SWRR) register. The Reset will take place immediately after the bit is written, and the device will be kept in Reset until the Reset sequence is completed. Figure 13-6. Software Reset tSWR tINIT VDD SWRST DEVICE STATE Running Active Reset Initialization Running INTERNAL RESET Note:  The time tSWR is approximately 50 ns. 13.3.2.1.6 Unified Program and Debug Interface (UPDI) Reset The Unified Program and Debug Interface (UPDI) contains a separate Reset source used to reset the device during external programming and debugging. The Reset source is accessible only from external debuggers and programmers. More details can be found in the UPDI - Unified Program and Debug Interface section. 13.3.2.1.7 Domains Affected By Reset The following logic domains are affected by the various Resets: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 109 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller Table 13-1. Logic Domains Affected by Various Resets Reset Type POR BOD Software Reset External Reset Watchdog Reset UPDI Reset Fuses are Reloaded X X X X X X Reset of UPDI X X Reset of Other Volatile Logic X X X X X X 13.3.2.2 Reset Time The Reset time can be split into two parts. The first part is when any of the Reset sources are active. This part depends on the input to the Reset sources. The external Reset is active as long as the RESET pin is low. The Power-on Reset (POR) and the Brown-out Detector (BOD) are active as long as the supply voltage is below the Reset source threshold. The second part is when all the Reset sources are released, and an internal Reset initialization of the device is done. This time will be increased with the start-up time given by the Start-Up Time Setting (SUT) bit field in the System Configuration 1 (FUSE.SYSCFG1) fuse when the reset is caused by a Power Supply Reset Source. The internal Reset initialization time will also increase if the Cyclic Redundancy Check Memory Scan (CRCSCAN) is configured to run at start-up. This configuration can be changed in the CRC Source (CRCSRC) bit field in the System Configuration 0 (FUSE.SYSCFG0) fuse. 13.3.3 Sleep Mode Operation The RSTCTRL operates in Active mode and in all sleep modes. 13.3.4 Configuration Change Protection This peripheral has registers that are under Configuration Change Protection (CCP). To write to these registers, a certain key must first be written to the CPU.CCP register, followed by a write access to the protected bits within four CPU instructions. Attempting to write to a protected register without following the appropriate CCP unlock sequence leaves the protected register unchanged. The following registers are under CCP: Table 13-2. RSTCTRL - Registers Under Configuration Change Protection Register Key RSTCTRL.SWRR © 2021 Microchip Technology Inc. IOREG Preliminary Datasheet DS40002311A-page 110 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller 13.4 Register Summary Offset Name Bit Pos. 0x00 0x01 RSTFR SWRR 7:0 7:0 13.5 7 6 5 4 3 2 1 0 UPDIRF SWRF WDRF EXTRF BORF PORF SWRE Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 111 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller 13.5.1 Reset Flag Register Name:  Offset:  Reset:  Property:  RSTFR 0x00 0xXX - All flags are cleared by writing a ‘1’ to them. They are also cleared by a Power-on Reset (POR), except for the Power-on Reset Flag (PORF). Bit 7 6 Access Reset 5 UPDIRF R/W x 4 SWRF R/W x 3 WDRF R/W x 2 EXTRF R/W x 1 BORF R/W x 0 PORF R/W x Bit 5 – UPDIRF UPDI Reset Flag This bit is set if a UPDI Reset occurs. Bit 4 – SWRF Software Reset Flag This bit is set if a Software Reset occurs. Bit 3 – WDRF Watchdog Reset Flag This bit is set if a Watchdog Reset occurs. Bit 2 – EXTRF External Reset Flag This bit is set if an External Reset occurs. Bit 1 – BORF Brown-out Reset Flag This bit is set if a Brown-out Reset occurs. Bit 0 – PORF Power-on Reset Flag This bit is set if a POR occurs. After a POR, only the POR flag is set and all the other flags are cleared. No other flags can be set before a full system boot is run after the POR. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 112 ATtiny424/426/427 ATtiny824/826/827 RSTCTRL - Reset Controller 13.5.2 Software Reset Register Name:  Offset:  Reset:  Property:  Bit 7 SWRR 0x01 0x00 Configuration Change Protection 6 5 4 3 Access Reset 2 1 0 SWRE R/W 0 Bit 0 – SWRE Software Reset Enable When this bit is written to ‘1’, a software Reset will occur. This bit will always read as ‘0’. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 113 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14. CPUINT - CPU Interrupt Controller 14.1 Features • • • • • • • 14.2 Short and Predictable Interrupt Response Time Separate Interrupt Configuration and Vector Address for Each Interrupt Interrupt Prioritizing by Level and Vector Address Non-Maskable Interrupts (NMI) for Critical Functions Two Interrupt Priority Levels: 0 (Normal) and 1 (High): – One of the interrupt requests can optionally be assigned as a priority level 1 interrupt – Optional round robin priority scheme for priority level 0 interrupts Interrupt Vectors Optionally Placed in the Application Section or the Boot Loader Section Selectable Compact Vector Table (CVT) Overview An interrupt request signals a change of state inside a peripheral and can be used to alter the program execution. The peripherals can have one or more interrupts. All interrupts are individually enabled and configured. When an interrupt is enabled and configured, it will generate an interrupt request when the interrupt condition occurs. The CPU Interrupt Controller (CPUINT) handles and prioritizes the interrupt requests. When an interrupt is enabled and the interrupt condition occurs, the CPUINT will receive the interrupt request. Based on the interrupt's priority level and the priority level of any ongoing interrupt, the interrupt request is either acknowledged or kept pending until it has priority. After returning from the interrupt handler, the program execution continues from where it was before the interrupt occurred, and any pending interrupts are served after one instruction is executed. The CPUINT offers NMI for critical functions, one selectable high-priority interrupt and an optional round robin scheduling scheme for normal-priority interrupts. The round robin scheduling ensures that all interrupts are serviced within a certain amount of time. 14.2.1 Block Diagram Figure 14-1. CPUINT Block Diagram Interrupt Controller Priority Decoder Peripheral 1 INT REQ CPU RETI CPU INT ACK CPU CPU INT REQ Peripheral n INT REQ STATUS LVL0PRI LVL1VEC © 2021 Microchip Technology Inc. Global Interrupt Enable CPU.SREG Preliminary Datasheet Wake-up SLPCTRL DS40002311A-page 114 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.3 Functional Description 14.3.1 Initialization An interrupt must be initialized in the following order: 1. 2. 3. 14.3.2 Configure the CPUINT if the default configuration is not adequate (optional): – Vector handling is configured by writing to the respective bits (IVSEL and CVT) in the Control A (CPUINT.CTRLA) register. – Vector prioritizing by round robin is enabled by writing a ‘1’ to the Round Robin Priority Enable (LVL0RR) bit in CPUINT.CTRLA. – Select the Priority Level 1 vector by writing the interrupt vector number to the Interrupt Vector with Priority Level 1 (CPUINT.LVL1VEC) register. Configure the interrupt conditions within the peripheral and enable the peripheral’s interrupt. Enable interrupts globally by writing a ‘1’ to the Global Interrupt Enable (I) bit in the CPU Status (CPU.SREG) register. Operation 14.3.2.1 Enabling, Disabling and Resetting The global enabling of interrupts is done by writing a ‘1’ to the Global Interrupt Enable (I) bit in the CPU Status (CPU.SREG) register. To disable interrupts globally, write a ‘0’ to the I bit in CPU.SREG. The desired interrupt lines must also be enabled in the respective peripheral by writing to the peripheral’s Interrupt Control (peripheral.INTCTRL) register. The interrupt flags are not automatically cleared after the interrupt is executed. The respective INTFLAGS register descriptions provide information on how to clear specific flags. 14.3.2.2 Interrupt Vector Locations The interrupt vector placement is dependent on the value of the Interrupt Vector Select (IVSEL) bit in the Control A (CPUINT.CTRLA) register. Refer to the IVSEL description in CPUINT.CTRLA for the possible locations. If the program never enables an interrupt source, the interrupt vectors are not used, and the regular program code can be placed at these locations. 14.3.2.3 Interrupt Response Time The minimum interrupt response time is represented in the following table. Table 14-1. Minimum Interrupt Response Time Flash Size > 8 KB Flash Size ≤ 8 KB Finish ongoing instruction One cycle One cycle Store PC to stack Two cycles Two cycles Jump to interrupt handler Three cycles (jmp) Two cycles (rjmp) After the Program Counter is pushed on the stack, the program vector for the interrupt is executed. See the following figure. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 115 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller Figure 14-2. Interrupt Execution of Single-Cycle Instruction Clock Program Counter "Instruction" (1) INT REQ INT ACK If an interrupt occurs during the execution of a multi-cycle instruction, the instruction is completed before the interrupt is served, as shown in the following figure. Figure 14-3. Interrupt Execution of Multi-Cycle Instruction Clock Program Counter "Instruction" (1) INT REQ INT ACK If an interrupt occurs when the device is in a sleep mode, the interrupt execution response time is increased by five clock cycles, as shown in the figure below. Also, the response time is increased by the start-up time from the selected sleep mode. Figure 14-4. Interrupt Execution From Sleep Clock Program Counter (1) "Instruction" INT REQ INT ACK A return from an interrupt handling routine takes four to five clock cycles, depending on the size of the Program Counter. During these clock cycles, the Program Counter is popped from the stack, and the Stack Pointer is incremented. Note:  1. Devices with 8 KB of Flash or less use RJMP instead of JMP, which takes only two clock cycles. 14.3.2.4 Interrupt Priority All interrupt vectors are assigned to one of three possible priority levels, as shown in the table below. An interrupt request from a high-priority source will interrupt any ongoing interrupt handler from a normal-priority source. When returning from the high-priority interrupt handler, the execution of the normal-priority interrupt handler will resume. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 116 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller Table 14-2. Interrupt Priority Levels Priority Level Source Highest Non-Maskable Interrupt Device-dependent and statically assigned ... Level 1 (high priority) One vector is optionally user selectable as level 1 Lowest Level 0 (normal priority) The remaining interrupt vectors 14.3.2.4.1 Non-Maskable Interrupts A Non-Maskable Interrupt (NMI) will be executed regardless of the I bit setting in CPU.SREG. An NMI will never change the I bit. No other interrupt can interrupt an NMI handler. If more than one NMI is requested at the same time, the priority is static according to the interrupt vector address, where the lowest address has the highest priority. Which interrupts are non-maskable is device-dependent and not subject to configuration. Non-maskable interrupts must be enabled before they can be used. Refer to the Interrupt Vector Mapping table of the device for available NMI sources. 14.3.2.4.2 High-Priority Interrupt It is possible to assign one interrupt request to level 1 (high priority) by writing its interrupt vector number to the CPUINT.LVL1VEC register. This interrupt request will have a higher priority than the other (normal priority) interrupt requests. The priority level 1 interrupts will interrupt the level 0 interrupt handlers. 14.3.2.4.3 Normal-Priority Interrupts All interrupt vectors other than NMI are assigned to priority level 0 (normal) by default. The user may override this by assigning one of these vectors as a high-priority vector. The device will have many normal-priority vectors, and some of these may be pending at the same time. Two different scheduling schemes are available to choose which of the pending normal-priority interrupts to service first: Static or round robin. IVEC is the interrupt vector mapping, as listed in the Peripherals and Architecture section. The following sections use IVEC to explain the scheduling schemes. IVEC0 is the Reset vector, IVEC1 is the NMI vector, and so on. In a vector table with n+1 elements, the vector with the highest vector number is denoted IVECn. Reset, non-maskable interrupts, and high-level interrupts are included in the IVEC map, but will always be prioritized over the normalpriority interrupts. Static Scheduling If several level 0 interrupt requests are pending at the same time, the one with the highest priority is scheduled for execution first. The following figure illustrates the default configuration, where the interrupt vector with the lowest address has the highest priority. Figure 14-5. Default Static Scheduling Lowest Address IVEC 0 Highest Priority IVEC 1 : : : Highest Address IVEC n Lowest Priority Modified Static Scheduling The default priority can be changed by writing a vector number to the CPUINT.LVL0PRI register. This vector number will be assigned the lowest priority. The next interrupt vector in the IVEC will have the highest priority among the LVL0 interrupts, as shown in the following figure. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 117 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller Figure 14-6. Static Scheduling when CPUINT.LVL0PRI is Different From Zero Lowest Address IVEC 0 RESET IVEC 1 NMI : : : IVEC Y Lowest Priority IVEC Y+1 Highest Priority : : : Highest Address IVEC n Here, value Y has been written to CPUINT.LVL0PRI, so that interrupt vector Y+1 has the highest priority. Note that, in this case, the priorities will wrap so that the lowest address no longer has the highest priority. This does not include RESET and NMI, which will always have the highest priority. Refer to the interrupt vector mapping of the device for available interrupt requests and their interrupt vector number. Round Robin Scheduling The static scheduling may prevent some interrupt requests from being serviced. To avoid this, the CPUINT offers round robin scheduling for normal-priority (LVL0) interrupts. In the round robin scheduling, the CPUINT.LVL0PRI register stores the last acknowledged interrupt vector number. This register ensures that the last acknowledged interrupt vector gets the lowest priority and is automatically updated by the hardware. The following figure illustrates the priority order after acknowledging IVEC Y and after acknowledging IVEC Y+1. Figure 14-7. Round Robin Scheduling IVEC Y was the last acknowledged interrupt IVEC Y+1 was the last acknowledged interrupt IVEC 0 RESET IVEC 0 RESET IVEC 1 NMI IVEC 1 NMI : : : : : : IVEC Y Lowest Priority IVEC Y IVEC Y+1 Highest Priority IVEC Y+1 Lowest Priority IVEC Y+2 Highest Priority : : : IVEC n : : : IVEC n The round robin scheduling for LVL0 interrupt requests is enabled by writing a ‘1’ to the Round Robin Priority Enable (LVL0RR) bit in the Control A (CPUINT.CTRLA) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 118 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.3.2.5 Compact Vector Table The Compact Vector Table (CVT) is a feature to allow writing of compact code by having all level 0 interrupts share the same interrupt vector number. Thus, the interrupts share the same Interrupt Service Routine (ISR). This reduces the number of interrupt handlers and thereby frees up memory that can be used for the application code. When CVT is enabled by writing a ‘1’ to the CVT bit in the Control A (CPUINT.CTRLA) register, the vector table contains these three interrupt vectors: 1. The non-maskable interrupts (NMI) at vector address 1. 2. The Priority Level 1 (LVL1) interrupt at vector address 2. 3. All priority level 0 (LVL0) interrupts at vector address 3. This feature is most suitable for devices with limited memory and applications using a small number of interrupt generators. 14.3.3 Debug Operation When using a level 1 priority interrupt, it is important to make sure the Interrupt Service Routine is configured correctly as it may cause the application to be stuck in an interrupt loop with level 1 priority. By reading the CPUINT STATUS (CPUINT.STATUS) register, it is possible to see if the application has executed the correct RETI (interrupt return) instruction. The CPUINT.STATUS register contains state information, which ensures that the CPUINT returns to the correct interrupt level when the RETI instruction is executed at the end of an interrupt handler. Returning from an interrupt will return the CPUINT to the state it had before entering the interrupt. 14.3.4 Configuration Change Protection This peripheral has registers that are under Configuration Change Protection (CCP). To write to these registers, a certain key must first be written to the CPU.CCP register, followed by a write access to the protected bits within four CPU instructions. Attempting to write to a protected register without following the appropriate CCP unlock sequence leaves the protected register unchanged. The following registers are under CCP: Table 14-3. CPUINT - Registers under Configuration Change Protection Register Key The IVSEL and CVT bitfields in CPUINT.CTRLA IOREG © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 119 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 CTRLA STATUS LVL0PRI LVL1VEC 7:0 7:0 7:0 7:0 14.5 7 6 5 IVSEL CVT 4 3 NMIEX 2 1 0 LVL1EX LVL0RR LVL0EX LVL0PRI[7:0] LVL1VEC[7:0] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 120 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.5.1 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CTRLA 0x00 0x00 Configuration Change Protection 6 IVSEL R/W 0 5 CVT R/W 0 4 3 2 1 0 LVL0RR R/W 0 Bit 6 – IVSEL Interrupt Vector Select Value Description 0 Interrupt vectors are placed after the BOOT section of the Flash(1) 1 Interrupt vectors are placed at the start of the BOOT section of the Flash Note:  1. When the entire Flash is configured as a BOOT section, this bit will be ignored. Bit 5 – CVT Compact Vector Table Value Description 0 Compact Vector Table function is disabled 1 Compact Vector Table function is enabled Bit 0 – LVL0RR Round Robin Priority Enable This bit is not protected by the Configuration Change Protection mechanism. Value Description 0 Priority is fixed for priority level 0 interrupt requests: The lowest interrupt vector address has the highest priority. 1 The round robin priority scheme is enabled for priority level 0 interrupt requests © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 121 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.5.2 Status Name:  Offset:  Reset:  Property:  Bit Access Reset 7 NMIEX R 0 STATUS 0x01 0x00 - 6 5 4 3 2 1 LVL1EX R 0 0 LVL0EX R 0 Bit 7 – NMIEX Non-Maskable Interrupt Executing This flag is set if a non-maskable interrupt is executing. The flag is cleared when returning (RETI) from the interrupt handler. Bit 1 – LVL1EX Level 1 Interrupt Executing This flag is set when a priority level 1 interrupt is executing, or when the interrupt handler has been interrupted by an NMI. The flag is cleared when returning (RETI) from the interrupt handler. Bit 0 – LVL0EX Level 0 Interrupt Executing This flag is set when a priority level 0 interrupt is executing, or when the interrupt handler has been interrupted by a priority level 1 interrupt or an NMI. The flag is cleared when returning (RETI) from the interrupt handler. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 122 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.5.3 Interrupt Priority Level 0 Name:  Offset:  Reset:  Property:  Bit Access Reset LVL0PRI 0x02 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 LVL0PRI[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – LVL0PRI[7:0] Interrupt Priority Level 0 This register is used to modify the priority of the LVL0 interrupts. See the section Normal-Priority Interrupts for more information. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 123 ATtiny424/426/427 ATtiny824/826/827 CPUINT - CPU Interrupt Controller 14.5.4 Interrupt Vector with Priority Level 1 Name:  Offset:  Reset:  Property:  Bit Access Reset LVL1VEC 0x03 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 LVL1VEC[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – LVL1VEC[7:0] Interrupt Vector with Priority Level 1 This bit field contains the number of the single vector with increased priority level 1 (LVL1). If this bit field has the value 0x00, no vector has LVL1. Consequently, the LVL1 interrupt is disabled. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 124 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System 15. EVSYS - Event System 15.1 Features • • • • • • • 15.2 System for Direct Peripheral-to-Peripheral Signaling Peripherals Can Directly Produce, Use, and React to Peripheral Events Short and Predictable Response Time Up to 6 Parallel Event Channels Available Each Channel is Driven by One Event Generator and Can Have Multiple Event Users Events Can be Sent and/or Received by Most Peripherals and by Software The Event System Works in Active, Idle, and Standby Sleep Modes Overview The Event System (EVSYS) enables direct peripheral-to-peripheral signaling. It allows a change in one peripheral (the event generator) to trigger actions in other peripherals (the event users) through event channels, without using the CPU. It is designed to provide a short and predictable response time between peripherals, allowing for autonomous peripheral control and interaction, and for synchronized timing of actions in several peripheral modules. Thus, it is a powerful tool for reducing the complexity, size, and execution time of the software. A change of the event generator’s state is referred to as an event and usually corresponds to one of the peripheral’s interrupt conditions. Events can be forwarded directly to other peripherals using the dedicated event routing network. The routing of each channel is configured in software, including event generation and use. Only one event signal can be routed on each channel. Multiple peripherals can use events from the same channel. The EVSYS can connect peripherals such as ADCs, analog comparators, I/O PORT pins, the real-time counter, timer/counters, and the configurable custom logic peripheral. Events can also be generated from software. 15.2.1 Block Diagram Figure 15-1. Block Diagram Event Channel n SWEVENTx[n] From Event Generators . . . 0 D QD Q CLK_PER CHANNELn 1 Is Async? To Channel MUX for Async Event User To Channel MUX for Sync Event User EVOUTx pin The block diagram shows the operation of an event channel. A multiplexer controlled by Channel n Generator Selection (EVSYS.CHANNELn) register at the input selects which of the event sources to route onto the event channel. Each event channel has two subchannels: one asynchronous and one synchronous. A synchronous user will listen to the synchronous subchannel, and an asynchronous user will listen to the asynchronous subchannel. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 125 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System An event signal from an asynchronous source will be synchronized by the Event System before being routed to the synchronous subchannel. An asynchronous event signal to be used by a synchronous consumer must last for at least one peripheral clock cycle to ensure that it will propagate through the synchronizer. The synchronizer will delay such an event between two and three clock cycles, depending on when the event occurs. Figure 15-2. Example of Event Source, Generator, User, and Action Event Generator Event User Timer/Counter ADC Compare Match Channel Sweep Event Routing Network Over/Underflow | Single Conversion Error Event Action Selection Event Source 15.2.2 Event Action Signal Description Signal EVOUTx Type Digital output 15.3 Functional Description 15.3.1 Initialization Description Event output, one output per I/O Port To utilize events, the Event System, the generating peripheral, and the peripheral(s) using the event must be set up accordingly: 1. 2. 3. 4. 15.3.2 Configure the generating peripheral appropriately. For example, if the generating peripheral is a timer, set the prescaling, the Compare register, etc., so that the desired event is generated. Configure the event user peripheral(s) appropriately. For example, if the ADC is the event user, set the ADC prescaler, resolution, conversion time, etc., as desired, and configure the ADC conversion to start at the reception of an event. Configure the Event System to route the desired source. In this case, the Timer/Compare match to the desired event channel. This may, for example, be Channel 0, which is accomplished by writing to the Channel 0 Generator Selection (EVSYS.CHANNEL0) register. Configure the ADC to listen to this channel by writing to the corresponding User x Channel MUX (EVSYS.USERx) register. Operation 15.3.2.1 Event User Multiplexer Setup Each event user has one dedicated event user multiplexer selecting which event channel to listen to. The application configures these multiplexers by writing to the corresponding EVSYS.USERx register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 126 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System 15.3.2.2 Event System Channel An event channel can be connected to one of the event generators. The source for each event channel is configured by writing to the respective Channel n Generator Selection (EVSYS.CHANNELn) register. 15.3.2.3 Event Generators Each event channel has several possible event generators, but only one can be selected at a time. The event generator for a channel is selected by writing to the respective Channel n Generator Selection (EVSYS.CHANNELn) register. By default, the channels are not connected to any event generator. For details on event generation, refer to the documentation of the corresponding peripheral. A generated event is either synchronous or asynchronous to the device peripheral clock (CLK_PER). Asynchronous events can be generated outside the normal edges of the peripheral clock, making the system respond faster than the selected clock frequency would suggest. Asynchronous events can also be generated while the device is in a sleep mode when the peripheral clock is not running. Any generated event is classified as either a pulse event or a level event. In both cases, the event can be either synchronous or asynchronous, with properties according to the table below. Table 15-1. Properties of Generated Events Event Type Pulse Level Sync/Async Description Sync An event generated from CLK_PER that lasts one clock cycle Async An event generated from a clock other than CLK_PER lasting one clock cycle Sync An event generated from CLK_PER that lasts multiple clock cycles Async An event generated without a clock (for example, a pin or a comparator), or an event generated from a clock other than CLK_PER that lasts multiple clock cycles The properties of both the generated event and the intended event user must be considered in order to ensure reliable and predictable operation. The table below shows the available event generators for this device family. Generator Name Description Event Type Generating Clock Domain Length of Event SYNCH character Level CLK_UPDI SYNCH character on UPDI RX input synchronized to CLK_UPDI Peripheral Event UPDI SYNCH © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 127 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System ...........continued Generator Name Description Event Type Generating Clock Domain Length of Event OVF Overflow Pulse CLK_RTC One CLK_RTC period CMP Compare Match PIT_DIV8192 Prescaled RTC clock divided by 8192 PIT_DIV4096 Prescaled RTC clock divided by 4096 Given by prescaled RTC clock divided by 4096 PIT_DIV2048 Prescaled RTC clock divided by 2048 Given by prescaled RTC clock divided by 2048 PIT_DIV1024 Prescaled RTC clock divided by 1024 Given by prescaled RTC clock divided by 1024 PIT_DIV512 Prescaled RTC clock divided by 512 Given by prescaled RTC clock divided by 512 PIT_DIV256 Prescaled RTC clock divided by 256 Given by prescaled RTC clock divided by 256 PIT_DIV128 Prescaled RTC clock divided by 128 Given by prescaled RTC clock divided by 128 PIT_DIV64 Prescaled RTC clock divided by 64 Given by prescaled RTC clock divided by 64 CCL LUTn LUT output level Level Asynchronous Depends on CCL configuration ACn OUT Comparator output level Level Asynchronous Given by AC output level ADCn RES Result ready Pulse CLK_PER One CLK_PER period SAMP Sample ready WCMP Window compare match PORTx PINn Pin level Level Asynchronous Given by pin level USARTn XCK USART Baud clock Level CLK_PER Minimum two CLK_PER periods SPIn SCK SPI Host clock Level CLK_PER Minimum two CLK_PER periods Peripheral Event RTC © 2021 Microchip Technology Inc. Level Given by prescaled RTC clock divided by 8192 Preliminary Datasheet DS40002311A-page 128 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System ...........continued Generator Name Description Event Type Generating Clock Domain Length of Event Normal mode: Overflow Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Peripheral Event TCAn OVF_LUNF Split mode: Low Byte Timer underflow HUNF Normal mode: Not available Split mode: High Byte Timer underflow CMP0_LCMP0 Normal mode: Compare Channel 0 match Split mode: Low Byte Timer Compare Channel 0 match CMP1_LCMP1 Normal mode: Compare Channel 1 match Split mode: Low Byte Timer Compare Channel 1 match CMP2_LCMP2 Normal mode: Compare Channel 2 match Split mode: Low byte timer Compare Channel 2 match TCBn CAPT CAPT flag set OVF OVF flag set 15.3.2.4 Event Users The event channel to listen to is selected by configuring the event user. An event user may require the event signal to be either synchronous or asynchronous to the peripheral clock. An asynchronous event user can respond to events in sleep modes when clocks are not running. Such events can be responded to outside the normal edges of the peripheral clock, making the event user respond faster than the clock frequency would suggest. For details on the requirements of each peripheral, refer to the documentation of the corresponding peripheral. Most event users implement edge or level detection to trigger actions in the corresponding peripheral based on the incoming event signal. In both cases, a user can either be synchronous, which requires that the incoming event is generated from the peripheral clock (CLK_PER), or asynchronous, if not. Some asynchronous event users do not apply event input detection but use the event signal directly. The different event user properties are described in general in the table below. Table 15-2. Properties of Event Users Input Detection Edge © 2021 Microchip Technology Inc. Async/Sync Description Sync An event user is triggered by an event edge and requires that the incoming event is generated from CLK_PER Async An event user is triggered by an event edge and has asynchronous detection or an internal synchronizer Preliminary Datasheet DS40002311A-page 129 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System ...........continued Input Detection Async/Sync Description Sync An event user is triggered by an event level and requires that the incoming event is generated from CLK_PER Async An event user is triggered by an event level and has asynchronous detection or an internal synchronizer Async An event user will use the event signal directly Level No detection The table below shows the available event users for this device family. USER Name Description Input Detection Async/Sync Peripheral Input CCL LUTnx LUTn input x or clock signal Level Async ADCn START ADC start on event Edge Async EVSYS EVOUTx Forward event signal to pin No detection Async USARTn IRDA IrDA mode input Level Sync TCAn CNTA Count on positive event edge Edge Sync Count on any event edge Edge Count while event signal is high Level Event level controls count direction, up when low and down when high Level Event level controls count direction, up when low and down when high Level Restart counter on positive event edge Edge Restart counter on any event edge Edge Restart counter while event signal is high Level Timeout check Edge Input capture on event Edge Input capture frequency measurement Edge Input capture pulse-width measurement Edge Input capture frequency and pulse-width measurement Edge Single-shot Edge Both Count on event Edge Sync CNTB TCBn CAPT COUNT Sync Sync 15.3.2.5 Synchronization Events can be either synchronous or asynchronous to the peripheral clock. Each Event System channel has two subchannels: one asynchronous and one synchronous. The asynchronous subchannel is identical to the event output from the generator. If the event generator generates a signal asynchronous to the peripheral clock, the signal on the asynchronous subchannel will be asynchronous. If the event generator generates a signal synchronous to the peripheral clock, the signal on the asynchronous subchannel will also be synchronous. The synchronous subchannel is identical to the event output from the generator, if the event generator generates a signal synchronous to the peripheral clock. If the event generator generates a signal asynchronous to the peripheral © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 130 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System clock, this signal is first synchronized before being routed onto the synchronous subchannel. Depending on when it occurs, synchronization will delay the event by two to three clock cycles. The Event System automatically performs this synchronization if an asynchronous generator is selected for an event channel. 15.3.2.6 Software Event The application can generate a software event. Software events on Channel n are issued by writing a ‘1’ to the Software Event Channel Select (CHANNEL[n]) bit in the Software Events (EVSYS.SWEVENTx) register. A software event appears as a pulse on the Event System channel, inverting the current event signal for one clock cycle. Event users see software events as no different from those produced by event generating peripherals. 15.3.3 Sleep Mode Operation When configured, the Event System will work in all sleep modes. Software events represent one exception since they require a peripheral clock. Asynchronous event users are able to respond to an event without their clock running in Standby sleep mode. Synchronous event users require their clock to be running to be able to respond to events. Such users will only work in Idle sleep mode or in Standby sleep mode, if configured to run in Standby mode by setting the RUNSTDBY bit in the appropriate register. Asynchronous event generators are able to generate an event without their clock running, that is, in Standby sleep mode. Synchronous event generators require their clock to be running to be able to generate events. Such generators will only work in Idle sleep mode or in Standby sleep mode, if configured to run in Standby mode by setting the RUNSTDBY bit in the appropriate register. 15.3.4 Debug Operation This peripheral is unaffected by entering Debug mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 131 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System 15.4 Register Summary Offset Name Bit Pos. 0x00 0x01 ... 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 ... 0x1F 0x20 ... 0x33 SWEVENTA 7:0 SWEVENTA[7:0] 7:0 7:0 7:0 7:0 7:0 7:0 CHANNEL0[7:0] CHANNEL1[7:0] CHANNEL2[7:0] CHANNEL3[7:0] CHANNEL4[7:0] CHANNEL5[7:0] USERCCLLUT0A 7:0 USER[7:0] USERTCB1COUNT 7:0 USER[7:0] 15.5 7 6 5 4 3 2 1 0 Reserved CHANNEL0 CHANNEL1 CHANNEL2 CHANNEL3 CHANNEL4 CHANNEL5 Reserved Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 132 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System 15.5.1 Software Events Name:  Offset:  Reset:  Property:  SWEVENTx 0x00 0x00 - Write bits in this register to create a software event on the corresponding event channels. Bits 0-7 in the EVSYS.SWEVENTA register correspond to event channels 0-7. If the number of available event channels is between eight and 15, these are available in the EVSYS.SWEVENTB register, where bit n corresponds to event channel 8+n. Refer to the Peripheral Overview section for the available number of Event System channels. Bit 7 6 5 Access Reset W 0 W 0 W 0 4 3 SWEVENTx[7:0] W W 0 0 2 1 0 W 0 W 0 W 0 Bits 7:0 – SWEVENTx[7:0] Software Event Channel Select Writing a bit in this bit group to ‘1’ will generate a single-pulse event on the corresponding event channel by inverting the signal on the event channel for one peripheral clock cycle. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 133 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System 15.5.2 Channel n Generator Selection Name:  Offset:  Reset:  Property:  CHANNELn 0x10 + n*0x01 [n=0..5] 0x00 - Each channel can be connected to one event generator. Not all generators can be connected to all channels. Refer to the table below to see which generator sources can be routed onto each channel and the generator value to be written to EVSYS.CHANNELn to achieve this routing. Writing the value 0x00 to EVSYS.CHANNELn turns the channel off. Bit Access Reset 7 6 5 R/W 0 R/W 0 R/W 0 4 3 CHANNELn[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – CHANNELn[7:0] Channel Generator Selection The specific generator name corresponding to each bit group configuration is given by combining Peripheral and Output from the table below in the following way: PERIPHERAL_OUTPUT. GENERATOR Async/ Sync Description Rising edge of SYNCH character detection Counter overflow Compare match Prescaled RTC clock divided by 8192 Prescaled RTC clock divided by 4096 Prescaled RTC clock divided by 2048 Prescaled RTC clock divided by 1024 Prescaled RTC clock divided by 512 Prescaled RTC clock divided by 256 Prescaled RTC clock divided by 128 Prescaled RTC clock divided by 64 LUT output level Value Name 0x01 UPDI SYNCH Sync 0x06 0x07 0x08 RTC OVF CMP PIT_DIV8192 Async Channel Availability Peripheral Output 0x09 PIT_DIV4096 0x0A PIT_DIV2048 0x0B PIT_DIV1024 0x08 PIT_DIV512 0x09 PIT_DIV256 0x0A PIT_DIV128 0x0B PIT_DIV64 0x10 0x11 0x12 0x13 0x20 0x24 0x25 0x26 0x40-0x47 CCL AC0 ADC0 PORTA LUT0 LUT1 LUT2 LUT3 OUT RES SAMP WCMP PIN0-PIN7 Async Async Sync Async Comparator output level Result ready Sample ready Window compare match PORTA PIN0-PIN7 level(2) 0x48-0x4F © 2021 Microchip Technology Inc. Preliminary Datasheet All channels All channels Even numbered channels only Odd numbered channels only All channels All channels All channels CHANNEL0 and CHANNEL1 only CHANNEL2 and CHANNEL3 only DS40002311A-page 134 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System ...........continued GENERATOR Async/ Sync Description PIN0-PIN7 Async PORTB PIN0-PIN7 level(2) 0x40-0x47 PORTC (1) PIN0-PIN7 Async PORTC PIN0-PIN7 level (2) Value Name Channel Availability Peripheral Output 0x40-0x47 PORTB 0x48-0x4F 0x48-0x4F 0x60 0x61 USART0 USART1 XCK XCK Sync 0x68 0x80 SPI0 TCA0 SCK OVF_LUNF Sync Sync Clock signal in SPI Host mode and synchronous USART Host mode SPI host clock signal Normal mode: Overflow Sync Split mode: Low byte timer underflow Normal mode: Not available 0x81 HUNF 0x84 CMP0_LCMP0 Sync 0x85 CMP1_LCMP1 Sync 0x86 0xA0 0xA1 0xA2 0xA3 CMP2_LCMP2 Sync TCB0 TCB1 CAPT OVF CAPT OVF Sync Sync CHANNEL4 and CHANNEL5 only CHANNEL0 and CHANNEL1 only CHANNEL2 and CHANNEL 3 only CHANNEL4 and CHANNEL5 only All channels All channels All channels Split mode: High byte timer underflow Normal mode: Compare Channel 0 match Split mode: Low byte timer Compare Channel 0 match Normal mode: Compare Channel 1 match Split mode: Low byte timer Compare Channel 1 match Normal mode: Compare Channel 2 match Split mode: Low byte timer Compare Channel 2 match CAPT flag set(3) OVF flag set CAPT flag set(3) OVF flag set All channels All channels Notes:  1. Not all peripheral instances are available for all pin counts. Refer to the Peripherals and Architecture section for details. 2. An event from the PORT pin will be zero if the input driver is disabled. 3. The operational mode of the timer decides when the CAPT flag is raised. Refer to the TCB section for details. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 135 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System 15.5.3 User Channel MUX Name:  Offset:  Reset:  Property:  USER 0x20 + n*0x01 [n=0..19] 0x00 - Each event user can be connected to one channel and several users can be connected to the same channel. The following table lists all Event System users with their corresponding user ID number and name. The user name is given by combining USER with Peripheral and Input from the table below in the following way: USERPERIPHERALINPUT. USER # 0x00 Async/Sync Description Name Peripheral Input CCL LUT0A Async CCL LUT0 event input A 0x01 LUT0B CCL LUT0 event input B 0x02 LUT1A CCL LUT1 event input A 0x03 LUT1B CCL LUT1 event input B 0x04 LUT2A CCL LUT2 event input A 0x05 LUT2B CCL LUT2 event input B 0x06 LUT3A CCL LUT3 event input A 0x07 LUT3B CCL LUT3 event input B 0x08 ADC0 START Async ADC start on event 0x09 EVSYS EVOUTA Async EVSYS pin output A 0x0A EVOUTB EVSYS pin output B 0x0B EVOUTC(1) EVSYS pin output C 0x0C USART0 IRDA 0x0D USART1 IRDA 0x0E TCA0 CNTA 0x0F 0x11 TCB0 TCB1 0x14 USART0 IrDA event input USART1 IrDA event input Sync CNTB 0x12 0x13 Sync Count on event or control count direction Restart on event or control count direction CAPT Both(2) Start, stop, capture, restart or clear counter COUNT Sync Count on event CAPT Both(2) Start, stop, capture, restart or clear counter COUNT Sync Count on event Notes:  1. Not all peripheral instances are available for all pin counts. Refer to the Peripherals and Architecture section for details. 2. Depends on the timer operational mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 136 ATtiny424/426/427 ATtiny824/826/827 EVSYS - Event System Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 USER[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – USER[7:0] User Channel Selection Configures which Event System channel the user is connected to. Value Description 0 OFF, no channel is connected to this Event System user n The event user is connected to CHANNEL(n-1) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 137 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16. PORTMUX - Port Multiplexer 16.1 Overview The Port Multiplexer (PORTMUX) can either enable or disable the functionality of the pins, or change between default and alternative pin positions. Available options are described in detail in the PORTMUX register map and depend on the actual pin and its properties. For available pins and functionalities, refer to the I/O Multiplexing and Considerations section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 138 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.2 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 0x04 0x05 EVSYSROUTEA CCLROUTEA USARTROUTEA SPIROUTEA TCAROUTEA TCBROUTEA 7:0 7:0 7:0 7:0 7:0 7:0 16.3 7 6 5 4 3 2 LUT3 LUT2 USART1[1:0] TCA05 TCA04 TCA03 TCA02 1 0 EVOUTB EVOUTA LUT1 LUT0 USART0[1:0] SPI0[1:0] TCA01 TCA00 TCB1 TCB0 Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 139 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.3.1 EVSYS Pin Position Name:  Offset:  Reset:  Property:  Bit 7 EVSYSROUTEA 0x00 0x00 - 6 5 4 3 Access Reset 2 1 EVOUTB R/W 0 0 EVOUTA R/W 0 Bit 1 – EVOUTB Event Output B This bit controls the pin position for event output B. Value Name 0x0 0x1 DEFAULT ALT1 Description EVOUT on PB2 EVOUT on PB7 Bit 0 – EVOUTA Event Output A This bit controls the pin position for event output A. Value Name 0x0 0x1 DEFAULT ALT1 © 2021 Microchip Technology Inc. Description EVOUT on PA2 EVOUT on PA7 Preliminary Datasheet DS40002311A-page 140 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.3.2 CCL Pin Position Name:  Offset:  Reset:  Property:  Bit 7 CCLROUTEA 0x01 0x00 - 6 5 4 3 LUT3 R/W 0 Access Reset 2 LUT2 R/W 0 1 LUT1 R/W 0 0 LUT0 R/W 0 Bit 3 – LUT3 CCL LUT 3 Signals This bit field controls the pin locations for CCL LUT 3 signals. Value Name 0x0 0x1 DEFAULT ALT1 Description OUT IN0 IN1 IN2 PC4 PA5 PC0 PC0 PC1 PC1 PC2 PC2 Bit 2 – LUT2 CCL LUT 2 Signals This bit field controls the pin locations for CCL LUT 2 signals. Value 0x0 0x1 Name DEFAULT ALT1 Description OUT IN0 IN1 IN2 PB3 PB6 PB0 PB0 PB1 PB1 PB2 PB2 Bit 1 – LUT1 CCL LUT 1 Signals This bit field controls the pin locations for CCL LUT 1 signals. Value 0x0 0x1 Name DEFAULT ALT1 Description OUT IN0 IN1 IN2 PA7 PC1 PC3 PC3 PC4 PC4 PC5 PC5 Bit 0 – LUT0 CCL LUT 0 Signals This bit field controls the pin locations for CCL LUT 0 signals. Value 0x0 0x1 Name DEFAULT ALT1 © 2021 Microchip Technology Inc. Description OUT IN0 IN1 IN2 PA4 PB4 PA0 PA0 PA1 PA1 PA2 PA2 Preliminary Datasheet DS40002311A-page 141 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.3.3 USART Pin Position Name:  Offset:  Reset:  Property:  Bit 7 USARTROUTEA 0x02 0x00 - 6 5 4 3 2 USART1[1:0] R/W R/W 0 0 Access Reset 1 0 USART0[1:0] R/W R/W 0 0 Bits 3:2 – USART1[1:0] USART 1 Signals This bit field controls the pin locations for USART 1 signals. Value Name 0x0 0x1 0x2 0x3 DEFAULT ALT1 NONE Description TxD RxD XCK XDIR PA1 PC2 PA2 PC1 PA3 PC0 PA4 PC3 Reserved Not connected to any pins Bits 1:0 – USART0[1:0] USART 0 Signals This bit field controls the pin locations for USART 0 signals. Value Name 0x0 0x1 0x2 0x3 DEFAULT ALT1 NONE © 2021 Microchip Technology Inc. Description TxD RxD XCK XDIR PB2 PA1 PB3 PA2 PB1 PA3 PB0 PA4 Reserved Not connected to any pins Preliminary Datasheet DS40002311A-page 142 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.3.4 SPI Pin Positions Name:  Offset:  Reset:  Property:  Bit 7 SPIROUTEA 0x03 0x00 - 6 5 4 3 2 1 0 SPI0[1:0] Access Reset R/W 0 R/W 0 Bits 1:0 – SPI0[1:0] SPI 0 Signals This bit field controls the pin positions for SPI 0 signals. Value Name 0x0 0x1 0x2 0x3 DEFAULT ALT1 NONE © 2021 Microchip Technology Inc. Description MOSI MISO SCK SS PA1 PC2 PA2 PC1 PA3 PC0 PA4 PC3 Reserved Not connected to any pins Preliminary Datasheet DS40002311A-page 143 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.3.5 TCA Pin Positions Name:  Offset:  Reset:  Property:  Bit TCAROUTEA 0x04 0x00 - 7 6 Access Reset 5 TCA05 R/W 0 4 TCA04 R/W 0 3 TCA03 R/W 0 2 TCA02 R/W 0 1 TCA01 R/W 0 0 TCA00 R/W 0 Bits 0, 1, 2, 3, 4, 5 – TCA0 TCA0 Signals This bit field controls the pin positions for TCA0 signals. Value Name 0x0 0x1 DEFAULT ALT1 © 2021 Microchip Technology Inc. Description WO0 on WO1 on WO2 on WO3 on WO4 on WO5 on PB0 PB3 PB1 PB4 PB2 PB5 PA3 PC3 PA4 PC4 PA5 PC5 Preliminary Datasheet DS40002311A-page 144 ATtiny424/426/427 ATtiny824/826/827 PORTMUX - Port Multiplexer 16.3.6 TCB Pin Position Name:  Offset:  Reset:  Property:  Bit 7 TCBROUTEA 0x05 0x00 - 6 5 4 3 2 Access Reset 1 TCB1 R/W 0 0 TCB0 R/W 0 Bit 1 – TCB1 TCB1 Output This bit controls the pin positions for TCB1 output. Value Name Description 0x0 0x1 DEFAULT ALT1 WO on PA3 WO on PC4 Bit 0 – TCB0 TCB0 Output This bit controls the pin positions for TCB0 output. Value Name Description 0x0 0x1 DEFAULT ALT1 WO on PA5 WO on PC0 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 145 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17. PORT - I/O Pin Configuration 17.1 Features • • • • • 17.2 General Purpose Input and Output Pins with Individual Configuration: – Pull-up – Inverted I/O Interrupts and Events: – Sense both edges – Sense rising edges – Sense falling edges – Sense low level Optional Slew Rate Control per I/O Port Asynchronous Pin Change Sensing that Can Wake the Device From all Sleep Modes Efficient and Safe Access to Port Pins – Hardware Read-Modify-Write (RMW) through dedicated toggle/clear/set registers – Mapping of often-used PORT registers into bit-accessible I/O memory space (virtual ports) Overview The I/O pins of the device are controlled by instances of the PORT peripheral registers. Each PORT instance has up to eight I/O pins. The PORTs are named PORTA, PORTB, PORTC, etc. Refer to the I/O Multiplexing and Considerations section to see which pins are controlled by what instance of PORT. The base addresses of the PORT instances and the corresponding Virtual PORT instances are listed in the Peripherals and Architecture section. Each PORT pin has a corresponding bit in the Data Direction (PORTx.DIR) and Data Output Value (PORTx.OUT) registers to enable that pin as an output and to define the output state. For example, pin PA3 is controlled by DIR[3] and OUT[3] of the PORTA instance. The input value of a PORT pin is synchronized to the Peripheral Clock (CLK_PER) and then made accessible as the data input value (PORTx.IN). The value of the pin can be read whether the pin is configured as input or output. The PORT also supports asynchronous input sensing with interrupts and events for selectable pin change conditions. Asynchronous pin change sensing means that a pin change can trigger an interrupt and wake the device from sleep, including sleep modes where CLK_PER is stopped. All pin functions are individually configurable per pin. The pins have hardware Read-Modify-Write functionality for a safe and correct change of the drive values and/or input and sense configuration. The PORT pin configuration controls input and output selection of other device functions. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 146 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.2.1 Block Diagram Figure 17-1. PORT Block Diagram Pull-up Enable DIRn Q D Peripheral Override R OUTn Q D Pxn Peripheral Override R Invert Enable Synchronizer INn Synchronous Input Q D Q R D R Sense Configuration Interrupt Generator Interrupt Asynchronous Input/Event Input Disable Peripheral Override Analog Input/Output 17.2.2 Signal Description Signal Type Description Pxn I/O pin I/O pin n on PORTx © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 147 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.3 Functional Description 17.3.1 Initialization After Reset, all outputs are tri-stated, and digital input buffers enabled even if there is no clock running. The following steps are all optional when initializing PORT operation: • • • • Enable or disable the output driver for pin Pxn by respectively writing ‘1’ to bit n in the PORTx.DIRSET or PORTx.DIRCLR register Set the output driver for pin Pxn to high or low level respectively by writing ‘1’ to bit n in the PORTx.OUTSET or PORTx.OUTCLR register Read the input of pin Pxn by reading bit n in the PORTx.IN register Configure the individual pin configurations and interrupt control for pin Pxn in PORTx.PINnCTRL Important:  For lowest power consumption, disable the digital input buffer of unused pins and pins that are used as analog inputs or outputs. Specific pins, such as those used to connect a debugger, may be configured differently, as required by their special function. 17.3.2 Operation 17.3.2.1 Basic Functions Each pin group x has its own set of PORT registers. I/O pin Pxn can be controlled by the registers in PORTx. To use pin number n as an output, write bit n of the PORTx.DIR register to ‘1’. This can be done by writing bit n in the PORTx.DIRSET register to ‘1’, which will avoid disturbing the configuration of other pins in that group. The nth bit in the PORTx.OUT register must be written to the desired output value. Similarly, writing a PORTx.OUTSET bit to ‘1’ will set the corresponding bit in the PORTx.OUT register to ‘1’. Writing a bit in PORTx.OUTCLR to ‘1’ will clear that bit in PORTx.OUT to ‘0’. Writing a bit in PORTx.OUTTGL or PORTx.IN to ‘1’ will toggle that bit in PORTx.OUT. To use pin n as an input, bit n in the PORTx.DIR register must be written to ‘0’ to disable the output driver. This can be done by writing bit n in the PORTx.DIRCLR register to ‘1’, which will avoid disturbing the configuration of other pins in that group. The input value can be read from bit n in the PORTx.IN register as long as the ISC bit is not set to INPUT_DISABLE. Writing a bit to ‘1’ in PORTx.DIRTGL will toggle that bit in PORTx.DIR and toggle the direction of the corresponding pin. 17.3.2.2 Port Configuration The Port Control (PORTx.PORTCTRL) register is used to configure the slew rate limitation for all the PORTx pins. The slew rate limitation is enabled by writing a ‘1’ to the Slew Rate Limit Enable (SLR) bit in PORTx.PORTCTRL. Refer to the Electrical Characteristics section for further details. 17.3.2.3 Pin Configuration The Pin n Control (PORTx.PINnCTRL) register is used to configure inverted I/O, pull-up, and input sensing of a pin. The control register for pin n is at the byte address PORTx + 0x10 + n. All input and output on the respective pin n can be inverted by writing a ‘1’ to the Inverted I/O Enable (INVEN) bit in PORTx.PINnCTRL. When INVEN is ‘1’, the PORTx.IN/OUT/OUTSET/OUTTGL registers will have an inverted operation for this pin. Toggling the INVEN bit causes an edge on the pin, which can be detected by all peripherals using this pin, and is seen by interrupts or events if enabled. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 148 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration The input pull-up of pin n is enabled by writing a ‘1’ to the Pull-up Enable (PULLUPEN) bit in PORTx.PINnCTRL. The pull-up is disconnected when the pin is configured as an output, even if PULLUPEN is ‘1’. Pin interrupts can be enabled for pin n by writing to the Input/Sense Configuration (ISC) bit field in PORTx.PINnCTRL. Refer to 17.3.3 Interrupts for further details. The digital input buffer for pin n can be disabled by writing the INPUT_DISABLE setting to ISC. This can reduce power consumption and may reduce noise if the pin is used as analog input. While configured to INPUT_DISABLE, bit n in PORTx.IN will not change since the input synchronizer is disabled. 17.3.2.4 Virtual Ports The Virtual PORT registers map the most frequently used regular PORT registers into the I/O Register space with single-cycle bit access. Access to the Virtual PORT registers has the same outcome as access to the regular registers but allows for memory specific instructions, such as bit manipulation instructions, which cannot be used in the extended I/O Register space where the regular PORT registers reside. The following table shows the mapping between the PORT and VPORT registers. Table 17-1. Virtual Port Mapping Regular PORT Register Mapped to Virtual PORT Register PORTx.DIR VPORTx.DIR PORTx.OUT VPORTx.OUT PORTx.IN VPORTx.IN PORTx.INTFLAGS VPORTx.INTFLAGS 17.3.2.5 Peripheral Override Peripherals such as USARTs, ADCs and timers may be connected to I/O pins. Such peripherals will usually have a primary and, optionally, one or more alternate I/O pin connections, selectable by PORTMUX or a multiplexer inside the peripheral. By configuring and enabling such peripherals, the general purpose I/O pin behavior normally controlled by PORT will be overridden in a peripheral dependent way. Some peripherals may not override all the PORT registers, leaving the PORT module to control some aspects of the I/O pin operation. Refer to the description of each peripheral for information on the peripheral override. Any pin in a PORT that is not overridden by a peripheral will continue to operate as a general purpose I/O pin. 17.3.3 Interrupts Table 17-2. Available Interrupt Vectors and Sources Name Vector Description Conditions PORTx PORT interrupt INTn in PORTx.INTFLAGS is raised as configured by the Input/Sense Configuration (ISC) bit in PORTx.PINnCTRL Each PORT pin n can be configured as an interrupt source. Each interrupt can be individually enabled or disabled by writing to ISC in PORTx.PINnCTRL. When an interrupt condition occurs, the corresponding interrupt flag is set in the Interrupt Flags register of the peripheral (peripheral.INTFLAGS). An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral's INTFLAGS register for details on how to clear interrupt flags. When setting or changing interrupt settings, take these points into account: • If an Inverted I/O Enable (INVEN) bit is toggled in the same cycle as ISC is changed, the edge caused by the inversion toggling may not cause an interrupt request • If an input is disabled by writing to ISC while synchronizing an interrupt, that interrupt may be requested on re-enabling the input, even if it is re-enabled with a different interrupt setting © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 149 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration • If the interrupt setting is changed by writing to ISC while synchronizing an interrupt, that interrupt may not be requested 17.3.3.1 Asynchronous Sensing Pin Properties All PORT pins support asynchronous input sensing with interrupts for selectable pin change conditions. Fully asynchronous pin change sensing can trigger an interrupt and wake the device from all sleep modes, including modes where the Peripheral Clock (CLK_PER) is stopped, while partially asynchronous pin change sensing is limited as per the table below. See the I/O Multiplexing and Considerations section for further details on which pins support fully asynchronous pin change sensing. Table 17-3. Behavior Comparison of Sense Pins Property Partially Asynchronous Pins Waking the device from sleep modes with CLK_PER running From all interrupt sense configurations Waking the device from sleep modes with CLK_PER stopped Only from BOTHEDGES or LEVEL interrupt sense configurations Minimum pulse-width to trigger an interrupt with CLK_PER running Minimum one CLK_PER cycle Minimum pulse-width to trigger an interrupt with CLK_PER stopped The pin value must be kept until CLK_PER has restarted(1) Interrupt “dead-time” No new interrupt for three CLK_PER cycles after the previous Fully Asynchronous Pins From all interrupt sense configurations Less than one CLK_PER cycle Note:  1. If a partially asynchronous input pin is used for wake-up from sleep with CLK_PER stopped, the required level must be held long enough for the MCU to complete the wake-up to trigger the interrupt. If the level disappears, the MCU can wake up without any interrupt generated. 17.3.4 Events PORT can generate the following events: Table 17-4. Event Generators in PORTx Generator Name Peripheral Event PORTx PINn Description Event Type Generating Clock Domain Length of Event Pin level Level Asynchronous Given by pin level All PORT pins are asynchronous event system generators. PORT has as many event generators as there are PORT pins in the device. Each event system output from PORT is the value present on the corresponding pin if the digital input buffer is enabled. If a pin input buffer is disabled, the corresponding event system output is zero. PORT has no event inputs. Refer to the Event System (EVSYS) section for more details regarding event types and Event System configuration. 17.3.5 Sleep Mode Operation Except for interrupts and input synchronization, all pin configurations are independent of sleep modes. All pins can wake the device from sleep, see the PORT Interrupt section for further details. Peripherals connected to the PORTs can be affected by sleep modes, described in the respective peripherals’ data sheet section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 150 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration Important:  The PORTs will always use the Peripheral Clock (CLK_PER). Input synchronization will halt when this clock stops. 17.3.6 Debug Operation When the CPU is halted in Debug mode, the PORT continues normal operation. If the PORT 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. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 151 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.4 Register Summary - PORTx Offset Name Bit Pos. 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B ... 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 0x17 DIR DIRSET DIRCLR DIRTGL OUT OUTSET OUTCLR OUTTGL IN INTFLAGS PORTCTRL 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 17.5 7 6 5 4 3 2 1 0 DIR[7:0] DIRSET[7:0] DIRCLR[7:0] DIRTGL[7:0] OUT[7:0] OUTSET[7:0] OUTCLR[7:0] OUTTGL[7:0] IN[7:0] INT[7:0] SRL Reserved PIN0CTRL PIN1CTRL PIN2CTRL PIN3CTRL PIN4CTRL PIN5CTRL PIN6CTRL PIN7CTRL 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 INVEN INVEN INVEN INVEN INVEN INVEN INVEN INVEN PULLUPEN PULLUPEN PULLUPEN PULLUPEN PULLUPEN PULLUPEN PULLUPEN PULLUPEN ISC[2:0] ISC[2:0] ISC[2:0] ISC[2:0] ISC[2:0] ISC[2:0] ISC[2:0] ISC[2:0] Register Description - PORTx © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 152 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.1 Data Direction Name:  Offset:  Reset:  Property:  Bit 7 DIR 0x00 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 DIR[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DIR[7:0] Data Direction This bit field controls the output driver for each PORTx pin. This bit field does not control the digital input buffer. The digital input buffer for pin n (Pxn) can be configured in the Input/Sense Configuration (ISC) bit field in the Pin n Control (PORTx.PINnCTRL) register. The available configuration for each bit n in this bit field is shown in the table below. Value Description 0 Pxn is configured as an input-only pin, and the output driver is disabled 1 Pxn is configured as an output pin, and the output driver is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 153 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.2 Data Direction Set Name:  Offset:  Reset:  Property:  Bit Access Reset DIRSET 0x01 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 DIRSET[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DIRSET[7:0] Data Direction Set This bit field controls the output driver for each PORTx pin, without using a read-modify-write operation. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will set the corresponding bit in PORTx.DIR, which will configure pin n (Pxn) as an output pin and enable the output driver. Reading this bit field will return the value of PORTx.DIR. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 154 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.3 Data Direction Clear Name:  Offset:  Reset:  Property:  Bit Access Reset DIRCLR 0x02 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 DIRCLR[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DIRCLR[7:0] Data Direction Clear This bit field controls the output driver for each PORTx pin, without using a read-modify-write operation. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will clear the corresponding bit in PORTx.DIR, which will configure pin n (Pxn) as an input-only pin and disable the output driver. Reading this bit field will return the value of PORTx.DIR. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 155 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.4 Data Direction Toggle Name:  Offset:  Reset:  Property:  Bit Access Reset DIRTGL 0x03 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 DIRTGL[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DIRTGL[7:0] Data Direction Toggle This bit field controls the output driver for each PORTx pin, without using a read-modify-write operation. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will toggle the corresponding bit in PORTx.DIR. Reading this bit field will return the value of PORTx.DIR. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 156 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.5 Output Value Name:  Offset:  Reset:  Property:  Bit 7 OUT 0x04 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 OUT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – OUT[7:0] Output Value This bit field controls the output driver level for each PORTx pin. This configuration only has an effect when the output driver (PORTx.DIR) is enabled for the corresponding pin. The available configuration for each bit n in this bit field is shown in the table below. Value Description 0 The pin n (Pxn) output is driven low 1 The Pxn output is driven high © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 157 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.6 Output Value Set Name:  Offset:  Reset:  Property:  Bit Access Reset OUTSET 0x05 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 OUTSET[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – OUTSET[7:0] Output Value Set This bit field controls the output driver level for each PORTx pin, without using a read-modify-write operation. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will set the corresponding bit in PORTx.OUT, which will configure the output for pin n (Pxn) to be driven high. Reading this bit field will return the value of PORTx.OUT. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 158 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.7 Output Value Clear Name:  Offset:  Reset:  Property:  Bit Access Reset OUTCLR 0x06 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 OUTCLR[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – OUTCLR[7:0] Output Value Clear This bit field controls the output driver level for each PORTx pin, without using a read-modify-write operation. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will clear the corresponding bit in PORTx.OUT, which will configure the output for pin n (Pxn) to be driven low. Reading this bit field will return the value of PORTx.OUT. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 159 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.8 Output Value Toggle Name:  Offset:  Reset:  Property:  Bit Access Reset OUTTGL 0x07 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 OUTTGL[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – OUTTGL[7:0] Output Value Toggle This bit field controls the output driver level for each PORTx pin, without using a read-modify-write operation. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will toggle the corresponding bit in PORTx.OUT. Reading this bit field will return the value of PORTx.OUT. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 160 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.9 Input Value Name:  Offset:  Reset:  Property:  Bit 7 IN 0x08 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 IN[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – IN[7:0] Input Value This bit field shows the state of the PORTx pins when the digital input buffer is enabled. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will toggle the corresponding bit in PORTx.OUT. If the digital input buffer is disabled, the input is not sampled, and the bit value will not change. The digital input buffer for pin n (Pxn) can be configured in the Input/Sense Configuration (ISC) bit field in the Pin n Control (PORTx.PINnCTRL) register. The available states of each bit n in this bit field is shown in the table below. Value Description 0 The voltage level on Pxn is low 1 The voltage level on Pxn is high © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 161 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.10 Interrupt Flags Name:  Offset:  Reset:  Property:  Bit 7 INTFLAGS 0x09 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 INT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – INT[7:0] Pin Interrupt Flag Pin interrupt flag n is cleared by writing a ‘1’ to it. Pin interrupt flag n is set when the change or state of pin n (Pxn) matches the pin's Input/Sense Configuration (ISC) in PORTx.PINnCTRL. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will clear Pin interrupt flag n. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 162 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.11 Port Control Name:  Offset:  Reset:  Property:  PORTCTRL 0x0A 0x00 - This register contains the slew rate limit enable bit for this port. Bit 7 6 5 4 3 Access Reset 2 1 0 SRL R/W 0 Bit 0 – SRL Slew Rate Limit Enable This bit controls slew rate limitation for all pins in PORTx. Value Description 0 Slew rate limitation is disabled for all pins in PORTx 1 Slew rate limitation is enabled for all pins in PORTx © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 163 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.5.12 Pin n Control Name:  Offset:  Reset:  Property:  Bit Access Reset 7 INVEN R/W 0 PINnCTRL 0x10 + n*0x01 [n=0..7] 0x00 - 6 5 4 3 PULLUPEN R/W 0 2 R/W 0 1 ISC[2:0] R/W 0 0 R/W 0 Bit 7 – INVEN Inverted I/O Enable This bit controls whether the input and output for pin n are inverted or not. Value Description 0 Input and output values are not inverted 1 Input and output values are inverted Bit 3 – PULLUPEN Pull-up Enable This bit controls whether the internal pull-up of pin n is enabled or not when the pin is configured as input-only. Value Description 0 Pull-up disabled 1 Pull-up enabled Bits 2:0 – ISC[2:0] Input/Sense Configuration This bit field controls the input and sense configuration of pin n. The sense configuration determines how a port interrupt can be triggered. Value Name Description 0x0 INTDISABLE Interrupt disabled but input buffer enabled 0x1 BOTHEDGES Interrupt enabled with sense on both edges 0x2 RISING Interrupt enabled with sense on rising edge 0x3 FALLING Interrupt enabled with sense on falling edge 0x4 INPUT_DISABLE Interrupt and digital input buffer disabled(1) 0x5 LEVEL Interrupt enabled with sense on low level other — Reserved Note:  1. If the digital input buffer for pin n is disabled, bit n in the Input Value (PORTx.IN) register will not be updated. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 164 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.6 Register Summary - VPORTx Offset Name Bit Pos. 0x00 0x01 0x02 0x03 DIR OUT IN INTFLAGS 7:0 7:0 7:0 7:0 17.7 7 6 5 4 3 2 1 0 DIR[7:0] OUT[7:0] IN[7:0] INT[7:0] Register Description - VPORTx © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 165 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.7.1 Data Direction Name:  Offset:  Reset:  Property:  DIR 0x00 0x00 - Access to the Virtual PORT registers has the same outcome as access to the regular registers but allows for memory specific instructions, such as bit manipulation instructions, which cannot be used in the extended I/O Register space where the regular PORT registers reside. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 DIR[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DIR[7:0] Data Direction This bit field controls the output driver for each PORTx pin. This bit field does not control the digital input buffer. The digital input buffer for pin n (Pxn) can be configured in the Input/Sense Configuration (ISC) bit field in the Pin n Control (PORTx.PINnCTRL) register. The available configuration for each bit n in this bit field is shown in the table below. Value Description 0 Pxn is configured as an input-only pin, and the output driver is disabled 1 Pxn is configured as an output pin, and the output driver is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 166 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.7.2 Output Value Name:  Offset:  Reset:  Property:  OUT 0x01 0x00 - Access to the Virtual PORT registers has the same outcome as access to the regular registers but allows for memory specific instructions, such as bit manipulation instructions, which cannot be used in the extended I/O Register space where the regular PORT registers reside. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 OUT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – OUT[7:0] Output Value This bit field controls the output driver level for each PORTx pin. This configuration only has an effect when the output driver (PORTx.DIR) is enabled for the corresponding pin. The available configuration for each bit n in this bit field is shown in the table below. Value Description 0 The pin n (Pxn) output is driven low 1 The Pxn output is driven high © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 167 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.7.3 Input Value Name:  Offset:  Reset:  Property:  IN 0x02 0x00 - Access to the Virtual PORT registers has the same outcome as access to the regular registers but allows for memory specific instructions, such as bit manipulation instructions, which cannot be used in the extended I/O Register space where the regular PORT registers reside. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 IN[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – IN[7:0] Input Value This bit field shows the state of the PORTx pins when the digital input buffer is enabled. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will toggle the corresponding bit in PORTx.OUT. If the digital input buffer is disabled, the input is not sampled, and the bit value will not change. The digital input buffer for pin n (Pxn) can be configured in the Input/Sense Configuration (ISC) bit field in the Pin n Control (PORTx.PINnCTRL) register. The available states of each bit n in this bit field is shown in the table below. Value Description 0 The voltage level on Pxn is low 1 The voltage level on Pxn is high © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 168 ATtiny424/426/427 ATtiny824/826/827 PORT - I/O Pin Configuration 17.7.4 Interrupt Flags Name:  Offset:  Reset:  Property:  INTFLAGS 0x03 0x00 - Access to the Virtual PORT registers has the same outcome as access to the regular registers but allows for memory specific instructions, such as bit manipulation instructions, which cannot be used in the extended I/O Register space where the regular PORT registers reside. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 INT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – INT[7:0] Pin Interrupt Flag Pin interrupt flag n is cleared by writing a ‘1’ to it. Pin interrupt flag n is set when the change or state of pin n (Pxn) matches the pin's Input/Sense Configuration (ISC) in PORTx.PINnCTRL. Writing a ‘0’ to bit n in this bit field has no effect. Writing a ‘1’ to bit n in this bit field will clear Pin interrupt flag n. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 169 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18. BOD - Brown-out Detector 18.1 Features • • • • • 18.2 Brown-out Detector Monitors the Power Supply to Avoid Operation Below a Programmable Level Three Available Modes: – Enabled mode (continuously active) – Sampled mode – Disabled Separate Selection of Mode for Active and Sleep Modes Voltage Level Monitor (VLM) with Interrupt Programmable VLM Level Relative to the BOD Level Overview The Brown-out Detector (BOD) monitors the power supply and compares the supply voltage with the programmable brown-out threshold level. The brown-out threshold level defines when to generate a System Reset. The Voltage Level Monitor (VLM) monitors the power supply and compares it to a threshold higher than the BOD threshold. The VLM can then generate an interrupt as an “early warning” when the supply voltage is approaching the BOD threshold. The VLM threshold level is expressed as a percentage above the BOD threshold level. The BOD is controlled mainly by fuses and has to be enabled by the user. The mode used in Standby sleep mode and Power-Down sleep mode can be altered in normal program execution. The VLM is controlled by I/O registers as well. When activated, the BOD can operate in Enabled mode, where the BOD is continuously active, or in Sampled mode, where the BOD is activated briefly at a given period to check the supply voltage level. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 170 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.2.1 Block Diagram Figure 18-1. BOD Block Diagram VDD BOD + BOD Reset - BOD Threshold VLM + VLM Interrupt - VLM Threshold 18.3 Functional Description 18.3.1 Initialization The BOD settings are loaded from fuses during Reset. The BOD level and operating mode in Active and Idle sleep mode are set by fuses and cannot be changed by software. The operating mode in Standby and Power-Down sleep mode is loaded from fuses and can be changed by software. The Voltage Level Monitor function can be enabled by writing a ‘1’ to the VLM Interrupt Enable (VLMIE) bit in the Interrupt Control (BOD.INTCTRL) register. The VLM interrupt is configured by writing the VLM Configuration (VLMCFG) bits in BOD.INTCTRL. An interrupt is requested when the supply voltage crosses the VLM threshold either from above, below, or any direction. The VLM functionality will follow the BOD mode. If the BOD is disabled, the VLM will not be enabled, even if the VLMIE is ‘1’. If the BOD is using Sampled mode, the VLM will also be sampled. When the VLM interrupt is enabled, the interrupt flag will be set according to VLMCFG when the voltage level is crossing the VLM level. The VLM threshold is defined by writing the VLM Level (VLMLVL) bits in the Control A (BOD.VLMCTRLA) register. 18.3.2 Interrupts Table 18-1. Available Interrupt Vectors and Sources Name Vector Description VLM Conditions Voltage Level Monitor Supply voltage crossing the VLM threshold as configured by the VLM Configuration (VLMCFG) bit field in the Interrupt Control (BOD.INTCTRL) register © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 171 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector The VLM interrupt will not be executed if the CPU is halted in Debug mode. When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. 18.3.3 Sleep Mode Operation The BOD configuration in the different sleep modes is defined by fuses. The mode used in Active mode and Idle sleep mode is defined by the ACTIVE fuses in FUSE.BODCFG, which is loaded into the ACTIVE bit field in the Control A (BOD.CTRLA) register. The mode used in Standby sleep mode and Power-Down sleep mode is defined by SLEEP in FUSE.BODCFG, which is loaded into the SLEEP bit field in the Control A (BOD.CTRLA) register. The operating mode in Active mode and Idle sleep mode (i.e., ACTIVE in BOD.CTRLA) cannot be altered by software. The operating mode in Standby sleep mode and Power-Down sleep mode can be altered by writing to the SLEEP bit field in the Control A (BOD.CTRLA) register. When the device is going into Standby or Power-Down sleep mode, the BOD will change the operation mode as defined by SLEEP in BOD.CTRLA. When the device is waking up from Standby or Power-Down sleep mode, the BOD will operate in the mode defined by the ACTIVE bit field in the Control A (BOD.CTRLA) register. 18.3.4 Configuration Change Protection This peripheral has registers that are under Configuration Change Protection (CCP). To write to these registers, a certain key must first be written to the CPU.CCP register, followed by a write access to the protected bits within four CPU instructions. Attempting to write to a protected register without following the appropriate CCP unlock sequence leaves the protected register unchanged. The following registers are under CCP: Table 18-2. Registers Under Configuration Change Protection Register Key SLEEP in BOD.CTRLA IOREG © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 172 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 ... 0x07 0x08 0x09 0x0A 0x0B CTRLA CTRLB 7:0 7:0 18.5 7 6 5 4 SAMPFREQ 3 2 ACTIVE[1:0] 1 0 SLEEP[1:0] LVL[2:0] Reserved VLMCTRLA INTCTRL INTFLAGS STATUS 7:0 7:0 7:0 7:0 VLMCFG[1:0] VLMLVL[1:0] VLMIE VLMIF VLMS Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 173 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.5.1 Control A Name:  Offset:  Reset:  Property:  Bit 7 CTRLA 0x00 Loaded from fuse Configuration Change Protection 6 Access Reset 5 4 SAMPFREQ R x 3 2 1 0 ACTIVE[1:0] R x SLEEP[1:0] R x R/W x R/W x Bit 4 – SAMPFREQ Sample Frequency This bit controls the BOD sample frequency. The Reset value is loaded from the SAMPFREQ bit in FUSE.BODCFG. This bit is not under Configuration Change Protection (CCP). Value Description 0x0 Sample frequency is 1 kHz 0x1 Sample frequency is 125 Hz Bits 3:2 – ACTIVE[1:0] Active These bits select the BOD operation mode when the device is in Active or Idle mode. The Reset value is loaded from the ACTIVE bit field in FUSE.BODCFG. This bit field is not under Configuration Change Protection (CCP). Value Name Description 0x0 DIS Disabled 0x1 ENABLED Enabled in continuous mode 0x2 SAMPLED Enabled in sampled mode 0x3 ENWAKE Enabled in continuous mode. Execution is halted at wake-up until BOD is running Bits 1:0 – SLEEP[1:0] Sleep These bits select the BOD operation mode when the device is in Standby or Power-Down sleep mode. The Reset value is loaded from the SLEEP bit field in FUSE.BODCFG. Value Name Description 0x0 DIS Disabled 0x1 ENABLED Enabled in continuous mode 0x2 SAMPLED Enabled in sampled mode 0x3 Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 174 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.5.2 Control B Name:  Offset:  Reset:  Property:  CTRLB 0x01 Loaded from fuse - Bit 7 6 5 4 3 2 Access Reset R 0 R 0 R 0 R 0 R 0 R x 1 LVL[2:0] R x 0 R x Bits 2:0 – LVL[2:0] BOD Level This bit field controls the BOD threshold level. The Reset value is loaded from the BOD Level (LVL) bits in the BOD Configuration Fuse (FUSE.BODCFG). Value Name Description 0x0 BODLEVEL0 1.8V 0x2 BODLEVEL2 2.6V 0x7 BODLEVEL7 4.2V Notes:  • Refer to the BOD and POR Characteristics in Electrical Characteristics for further details • Values in the description are typical values © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 175 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.5.3 VLM Control A Name:  Offset:  Reset:  Property:  Bit 7 VLMCTRLA 0x08 0x00 - 6 5 4 3 2 Access Reset 1 0 VLMLVL[1:0] R/W R/W 0 0 Bits 1:0 – VLMLVL[1:0] VLM Level These bits select the VLM threshold relative to the BOD threshold (LVL in BOD.CTRLB). Value Description 0x0 VLM threshold 5% above BOD threshold 0x1 VLM threshold 15% above BOD threshold 0x2 VLM threshold 25% above BOD threshold other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 176 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.5.4 Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 INTCTRL 0x09 0x00 - 6 5 4 3 Access Reset 2 1 VLMCFG[1:0] R/W R/W 0 0 0 VLMIE R/W 0 Bits 2:1 – VLMCFG[1:0] VLM Configuration These bits select which incidents will trigger a VLM interrupt. Value Name Description 0x0 BELOW VDD falls below VLM threshold 0x1 ABOVE VDD rises above VLM threshold 0x2 CROSS VDD crosses VLM threshold Other Reserved Bit 0 – VLMIE VLM Interrupt Enable Writing a ‘1’ to this bit enables the VLM interrupt. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 177 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.5.5 VLM Interrupt Flags Name:  Offset:  Reset:  Property:  Bit 7 INTFLAGS 0x0A 0x00 - 6 5 4 3 Access Reset 2 1 0 VLMIF R/W 0 Bit 0 – VLMIF VLM Interrupt Flag This flag is set when a trigger from the VLM is given, as configured by the VLMCFG bit in the BOD.INTCTRL register. The flag is only updated when the BOD is enabled. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 178 ATtiny424/426/427 ATtiny824/826/827 BOD - Brown-out Detector 18.5.6 VLM Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x0B 0x00 - 6 5 4 3 Access Reset 2 1 0 VLMS R 0 Bit 0 – VLMS VLM Status This bit is only valid when the BOD is enabled. Value Description 0 The voltage is above the VLM threshold level 1 The voltage is below the VLM threshold level © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 179 ATtiny424/426/427 ATtiny824/826/827 VREF - Voltage Reference 19. VREF - Voltage Reference 19.1 Features • • 19.2 Programmable Voltage Reference Source for: – AC – ADC Each Reference Source Supports the Following Voltages: – 1.024V – 2.048V – 2.500V – 4.096V – VDD Overview The Voltage Reference (VREF) peripheral provides voltage reference sources used by several peripherals. The user can select the reference voltages for the Analog Comparators by writing to the appropriate bit field in the Control A (VREF.CTRLA) register. A voltage reference source is enabled automatically when requested by a peripheral. The user can enable the reference voltage sources (and thus, override the automatic disabling of unused sources) by writing to the respective ALWAYSON bit in the Control B (VREF.CTRLB) register. This will decrease the start-up time at the cost of increased power consumption. 19.2.1 Block Diagram Figure 19-1. VREF Block Diagram Reference reque st Reference enable Reference se lect Bandgap Reference Gen erator Ban dgap ena ble 19.3 Functional Description 19.3.1 Initialization 1.024V 2.056V 2.500V 4.096V VDD BUF Inte rnal Reference The default configuration will enable the respective source when the ADC0 or the AC0 are requesting a reference voltage. The voltage references for the ADC0 and AC0 can be forced ON by writing a ‘1’ to the respective Reference Force Enable bits (ADC0REFEN and AC0REFEN) in the Control B (VREF.CTRLB) register. This serves to reduce the start-up time of the respective peripheral. The default reference voltage for the AC0 is 1.024V but can be configured by writing to the AC0 Reference Select (AC0REFSEL) bit field in the Control A (VREF.CTRLA) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 180 ATtiny424/426/427 ATtiny824/826/827 VREF - Voltage Reference The reference voltage for the ADC0 is configured by selecting the reference source within the ADC0 registers. Refer to the ADC documentation for details. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 181 ATtiny424/426/427 ATtiny824/826/827 VREF - Voltage Reference 19.4 Register Summary Offset Name Bit Pos. 0x00 0x01 CTRLA CTRLB 7:0 7:0 19.5 7 6 5 4 3 2 1 0 AC0REFSEL[2:0] NVMREFEN ADC0REFEN AC0REFEN Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 182 ATtiny424/426/427 ATtiny824/826/827 VREF - Voltage Reference 19.5.1 Control A Name:  Offset:  Reset:  Property:  Bit CTRLA 0x00 0x00 - 7 6 5 4 3 Access Reset 2 R/W 0 1 AC0REFSEL[2:0] R/W 0 0 R/W 0 Bits 2:0 – AC0REFSEL[2:0] Analog Comparator 0 Reference Select This bit field controls the reference voltage for the Analog Comparator 0. Note:  1. The values given for internal references are only typical. Refer to the Electrical Characteristics section for further details. Value 0x0 0x1 0x2 0x3 0x7 Other Name 1V024 2V048 2V500 4V096 VDD - © 2021 Microchip Technology Inc. Description 1.02V reference(1) 2.05V reference(1) 2.5V reference(1) 4.1V reference(1) Supply voltage as reference Reserved Preliminary Datasheet DS40002311A-page 183 ATtiny424/426/427 ATtiny824/826/827 VREF - Voltage Reference 19.5.2 Control B Name:  Offset:  Reset:  Property:  Bit 7 CTRLB 0x01 0x00 - 6 5 4 3 Access Reset 2 NVMREFEN R/W 0 1 ADC0REFEN R/W 0 0 AC0REFEN R/W 0 Bit 2 – NVMREFEN NVM Reference Force Enable This bit field controls whether the NVMREFEN reference is always on or not. Value Name Description 0 AUTO The reference is automatically enabled when needed 1 ALWAYSON The reference is always on Bit 1 – ADC0REFEN ADC0 Reference Force Enable This bit field controls whether the ADC0 reference is always on or not. Value Name Description 0 AUTO The reference is automatically enabled when needed 1 ALWAYSON The reference is always on Bit 0 – AC0REFEN AC0 DACREF Reference Force Enable This bit field controls whether the AC0 DACREF is always on or not. Value Name Description 0 AUTO The reference is automatically enabled when needed 1 ALWAYSON The reference is always on © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 184 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer 20. WDT - Watchdog Timer 20.1 Features • • • • • • 20.2 Issues a System Reset if the Watchdog Timer is not Cleared Before its Time-out Period Operates Asynchronously from the Peripheral Clock Using an Independent Oscillator Uses the 1.024 kHz Output of the 32.768 kHz Ultra Low-Power Oscillator (OSCULP32K) 11 Selectable Time-out Periods, from 8 ms to 8s Two Operation Modes: – Normal mode – Window mode Configuration Lock to Prevent Unwanted Changes Overview The Watchdog Timer (WDT) is a system function for monitoring the correct program operation. When enabled, the WDT is a constantly running timer with a configurable time-out period. If the WDT is not reset within the time-out period, it will issue a system Reset. This allows the system to recover from situations such as runaway or deadlocked code. The WDT is reset by executing the WDR (Watchdog Timer Reset) instruction from software. In addition to the Normal mode as described above, the WDT has a Window mode. The Window mode defines a time slot or “window” inside the time-out period during which the WDT must be reset. If the WDT is reset outside this window, either too early or too late, a system Reset will be issued. Compared to the Normal mode, the Window mode can catch situations where a code error causes constant WDR execution. When enabled, the WDT will run in Active mode and all sleep modes. Since it is asynchronous (that is running from a CPU independent clock source), it will continue to operate and be able to issue a system Reset, even if the main clock fails. The WDT has a Configuration Change Protection (CCP) mechanism and a lock functionality, ensuring the WDT settings cannot be changed by accident. 20.2.1 Block Diagram Figure 20-1. WDT Block Diagram WINDOW CTRLA PERIOD CLK_WDT WDR (Instruction) 20.2.2 COUNT + > Closed window = System Reset Time-out Signal Description Not applicable. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 185 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer 20.3 Functional Description 20.3.1 Initialization 1. 2. The WDT is enabled when a non-zero value is written to the Period (PERIOD) bit field in the Control A (WDT.CTRLA) register. Optional: Write a non-zero value to the Window (WINDOW) bit field in WDT.CTRLA to enable the Window mode operation. All bits in the Control A register and the Lock (LOCK) bit in the Status (WDT.STATUS) register are write-protected by the Configuration Change Protection (CCP) mechanism. A fuse (FUSE.WDTCFG) defines the Reset value of the WDT.CTRLA register. If the value of the PERIOD bit field in the FUSE.WDTCFG fuse is different than zero, the WDT is enabled and the LOCK bit in the WDT.STATUS register is set at boot time. 20.3.2 Clocks A 1.024 kHz oscillator clock (CLK_WDT_OSC) is sourced from the internal Ultra Low-Power Oscillator, OSCULP32K. Due to the ultra low-power design, the oscillator is less accurate than other oscillators featured in the device, and hence the exact time-out period may vary from device to device. This variation must be taken into consideration when designing software that uses the WDT to ensure that the time-out periods used are valid for all devices. Refer to the “Electrical Characteristics” section for more specific information. The counter clock (CLK_WDT_OSC) is asynchronous to the peripheral clock. Due to this asynchronicity, writing to the WDT Control register will require synchronization between the clock domains. Refer to 20.3.6 Synchronization for further details. 20.3.3 Operation 20.3.3.1 Normal Mode In Normal mode operation, a single time-out period is set for the WDT. If the WDT is not reset from software using the WDR instruction during the defined time-out period, the WDT will issue a system Reset. A new WDT time-out period will start each time the WDT resets the WDR. There are 11 possible WDT time-out periods (TOWDT), selectable from 8 ms to 8s by writing to the Period (PERIOD) bit field in the Control A (WDT.CTRLA) register. The figure below shows a typical timing scheme for the WDT operating in Normal mode. Figure 20-2. Normal Mode Operation WDT Count Timely WDT Reset (WDR) WDT Time-out System Reset Here: TO WDT ~ 16 ms 5 10 15 20 25 30 TOWDT 35 t [ms] Normal mode is enabled as long as the Window (WINDOW) bit field in the WDT.CTRLA register is 0x0. 20.3.3.2 Window Mode In the Window mode operation, the WDT uses two different time-out periods: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 186 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer • • The closed window time-out period (TOWDTW) defines a duration, from 8 ms to 8s, where the WDT cannot be reset. If the WDT is reset during this period, the WDT will issue a system Reset. The open window time-out period (TOWDT), which is also 8 ms to 8s, defines the duration of the open period during which the WDT can (and needs to) be reset. The open period will always follow the closed period, so the total duration of the time-out period is the sum of the closed window and the open window time-out periods. When enabling the Window mode or when going out of the Debug mode, the window is activated after the first WDR instruction. The figure below shows a typical timing scheme for the WDT operating in Window mode. Figure 20-3. Window Mode Operation WDT Count Open Timely WDT Reset (WDR) Closed WDR too early: System Reset Here: TOWDTW =TOWDT = 8 ms 5 10 15 20 TOWDTW 25 30 TOWDT 35 t [ms] The Window mode is enabled by writing a non-zero value to the Window (WINDOW) bit field in the Control A (WDT.CTRLA) register. The Window mode is disabled by writing the WINDOW bit field to ‘0x0’. 20.3.3.3 Preventing Unintentional Changes The WDT provides two security mechanisms to avoid unintentional changes to the WDT settings: • • The CCP mechanism, employing a timed write procedure for changing the WDT control registers. Refer to 20.3.7 Configuration Change Protection for further details. Locking the configuration by writing a ‘1’ to the Lock (LOCK) bit in the Status (WDT.STATUS) register. When this bit is ‘1’, the Control A (WDT.CTRLA) register cannot be changed. The LOCK bit can only be written to ‘1’ in software, while the device needs to be in Debug mode to be able to write it to ‘0’. Consequently, the WDT cannot be disabled from software. Note:  The WDT configuration is loaded from fuses after Reset. If the PERIOD bit field is set to a non-zero value, the LOCK bit is automatically set in WDT.STATUS. 20.3.4 Sleep Mode Operation The WDT will continue to operate in any sleep mode where the source clock is active. 20.3.5 Debug Operation When run-time debugging, this peripheral will continue normal operation. Halting the CPU in Debugging mode will halt the normal operation of the peripheral. When halting the CPU in Debug mode, the WDT counter is reset. When starting the CPU and when the WDT is operating in Window mode, the first closed window time-out period will be disabled, and a Normal mode time-out period is executed. 20.3.6 Synchronization The Control A (WDT.CTRLA) register is synchronized when written, due to the asynchronicity between the WDT clock domain and the peripheral clock domain. The Synchronization Busy (SYNCBUSY) flag in the STATUS (WDT.STATUS) register indicates if there is an ongoing synchronization. Writing to WDT.CTRLA while SYNCBUSY = 1 is not allowed. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 187 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer The following bit fields must be synchronized when written: • The Period (PERIOD) bit field in Control A (WDT.CTRLA) register • The Window (WINDOW) bit field in Control A (WDT.CTRLA) register The WDR instruction will need two to three cycles of the WDT clock to be synchronized. 20.3.7 Configuration Change Protection This peripheral has registers that are under Configuration Change Protection (CCP). To write to these registers, a certain key must first be written to the CPU.CCP register, followed by a write access to the protected bits within four CPU instructions. Attempting to write to a protected register without following the appropriate CCP unlock sequence leaves the protected register unchanged. The following registers are under CCP: Table 20-1. WDT - Registers Under Configuration Change Protection Register Key WDT.CTRLA IOREG LOCK bit in WDT.STATUS IOREG © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 188 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer 20.4 Register Summary Offset Name Bit Pos. 7 0x00 0x01 CTRLA STATUS 7:0 7:0 LOCK 20.5 6 5 4 WINDOW[3:0] 3 2 1 0 PERIOD[3:0] SYNCBUSY Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 189 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer 20.5.1 Control A Name:  Offset:  Reset:  Property:  Bit 7 Access Reset R/W x CTRLA 0x00 From FUSE.WDTCFG Configuration Change Protection 6 5 WINDOW[3:0] R/W R/W x x 4 3 R/W x R/W x 2 1 PERIOD[3:0] R/W R/W x x 0 R/W x Bits 7:4 – WINDOW[3:0] Window Writing a non-zero value to these bits enables the Window mode, and selects the duration of the closed period accordingly. The bits are optionally lock-protected: • If the LOCK bit in WDT.STATUS is ‘1’ all bits are change-protected (Access = R) • If the LOCK bit in WDT.STATUS is ‘0’ all bits can be changed (Access = R/W) Value 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 0x8 0x9 0xA 0xB Other Name OFF 8CLK 16CLK 32CLK 64CLK 128CLK 256CLK 512CLK 1KCLK 2KCLK 4KCLK 8KCLK - Description 0.008s 0.016s 0.031s 0.063s 0.125s 0.25s 0.5s 1s 2s 4s 8s Reserved Note:  Refer to the Electrical Characteristics section for specific information regarding the accuracy of the 32.768 kHz Ultra Low-Power Oscillator (OSCULP32K). Bits 3:0 – PERIOD[3:0] Period Writing a non-zero value to this bit enables the WDT and selects the time-out period in Normal mode accordingly. In Window mode, these bits select the duration of the open window. The bits are optionally lock-protected: • If the LOCK bit in WDT.STATUS is ‘1’ all bits are change-protected (Access = R) • If the LOCK bit in WDT.STATUS is ‘0’ all bits can be changed (Access = R/W) Value 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 0x8 0x9 0xA Name OFF 8CLK 16CLK 32CLK 64CLK 128CLK 256CLK 512CLK 1KCLK 2KCLK 4KCLK © 2021 Microchip Technology Inc. Description 0.008s 0.016s 0.031s 0.063s 0.125s 0.25s 0.5s 1s 2s 4s Preliminary Datasheet DS40002311A-page 190 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer Value 0xB Other Name 8KCLK - Description 8s Reserved Note:  Refer to the Electrical Characteristics section for specific information regarding the accuracy of the 32.768 kHz Ultra Low-Power Oscillator (OSCULP32K). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 191 ATtiny424/426/427 ATtiny824/826/827 WDT - Watchdog Timer 20.5.2 Status Name:  Offset:  Reset:  Property:  Bit Access Reset 7 LOCK R/W 0 STATUS 0x01 0x00 Configuration Change Protection 6 5 4 3 2 1 0 SYNCBUSY R 0 Bit 7 – LOCK Lock Writing this bit to ‘1’ write-protects the WDT.CTRLA register. It is only possible to write this bit to ‘1’. This bit can be cleared in Debug mode only. If the PERIOD bits in WDT.CTRLA are different from zero after boot code, the lock will automatically be set. This bit is under CCP. Bit 0 – SYNCBUSY Synchronization Busy This bit is set after writing to the WDT.CTRLA register, while the data is being synchronized from the peripheral clock domain to the WDT clock domain. This bit is cleared after the synchronization is finished. This bit is not under CCP. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 192 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21. TCA - 16-bit Timer/Counter Type A 21.1 Features • • • • • • • • • 21.2 16-Bit Timer/Counter Three Compare Channels Double-Buffered Timer Period Setting Double-Buffered Compare Channels Waveform Generation: – Frequency generation – Single-slope PWM (Pulse-Width Modulation) – Dual-slope PWM Count on Event Timer Overflow Interrupts/Events One Compare Match per Compare Channel Two 8-Bit Timer/Counters in Split Mode Overview The flexible 16-bit PWM Timer/Counter type A (TCA) provides accurate program execution timing, frequency and waveform generation, and command execution. A TCA consists of a base counter and a set of compare channels. The base counter can be used to count clock cycles or events or let events control how it counts clock cycles. It has direction control and period setting that can be used for timing. The compare channels can be used together with the base counter to perform a compare match control, frequency generation, and pulse-width waveform modulation. Depending on the mode of operation, the counter is cleared, reloaded, incremented, or decremented at each timer/ counter clock or event input. A timer/counter can be clocked and timed from the peripheral clock, with optional prescaling, or from the Event System. The Event System can also be used for direction control or to synchronize operations. By default, the TCA is a 16-bit timer/counter. The timer/counter has a Split mode feature that splits it into two 8-bit timer/counters with three compare channels each. A block diagram of the 16-bit timer/counter with closely related peripheral modules (in grey) is shown in the figure below. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 193 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A Figure 21-1. 16-bit Timer/Counter and Closely Related Peripherals Timer/Counter Base Counter Timer Period Counter Prescaler Control Logic Event System Waveform Generation Buffer Block Diagram The figure below shows a detailed block diagram of the timer/counter. Figure 21-2. Timer/Counter Block Diagram Base Counter CTRL A BV PERBUF CTRL B PER EVCTRL Clock Select Mode Event Action ‘‘count’’ ‘‘clear’’ ‘‘load’’ ‘‘direction’’ Counter CNT = =0 OVF (INT Req. and Event) Control Logic Event TOP BOTTOM UPDATE 21.2.1 PORTS Compare Channel 0 Compare Channel 1 Compare Channel 2 Comparator CLK_PER Compare Unit n BV Control Logic CMPnBUF CMPn = © 2021 Microchip Technology Inc. Waveform Generation ‘‘match’’ Preliminary Datasheet WOn Out CMPn (INT Req. and Event) DS40002311A-page 194 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A The Counter (TCAn.CNT) register, Period and Compare (TCAn.PER and TCAn.CMPn) registers, and their corresponding buffer registers (TCAn.PERBUF and TCAn.CMPnBUF) are 16-bit registers. All buffer registers have a Buffer Valid (BV) flag that indicates when the buffer contains a new value. During normal operation, the counter value is continuously compared to zero and the period (PER) value to determine whether the counter has reached TOP or BOTTOM. The counter value can also be compared to the TCAn.CMPn registers. The timer/counter can generate interrupt requests, events, or change the waveform output after being triggered by the Counter (TCAn.CNT) register reaching TOP, BOTTOM, or CMPn. The interrupt requests, events, or waveform output changes will occur on the next CLK_TCA cycle after the triggering. CLK_TCA is either the prescaled peripheral clock or events from the Event System, as shown in the figure below. Figure 21-3. Timer/Counter Clock Logic CLK_TCA CLK_PER CNT ‘‘Count Enable’’ Prescaler Event Logic CLKSEL Event ‘‘Count Direction’’ DIR EVACT CNTxEI 21.2.2 Signal Description Signal Description Type WOn Digital output Waveform output 21.3 Functional Description 21.3.1 Definitions The following definitions are used throughout the documentation: Table 21-1. Timer/Counter Definitions Name Description BOTTOM The counter reaches BOTTOM when it becomes 0x0000 MAX The counter reaches MAXimum when it becomes all ones TOP The counter reaches TOP when it becomes equal to the highest value in the count sequence The update condition is met when the timer/counter reaches BOTTOM or TOP, depending on the UPDATE Waveform Generator mode. Buffered registers with valid buffer values will be updated unless the Lock Update (LUPD) bit in the TCAn.CTRLE register has been set. CNT Counter register value CMP Compare register value PER Period register value © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 195 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A In general, the term timer is used when the timer/counter is counting periodic clock ticks. The term counter is used when the input signal has sporadic or irregular ticks. The latter can be the case when counting events. 21.3.2 Initialization To start using the timer/counter in a basic mode, follow these steps: 1. Write a TOP value to the Period (TCAn.PER) register. 2. Enable the peripheral by writing a ‘1’ to the Enable (ENABLE) bit in the Control A (TCAn.CTRLA) register. The counter will start counting clock ticks according to the prescaler setting in the Clock Select (CLKSEL) bit field in TCAn.CTRLA. 3. Optional: By writing a ‘1’ to the Enable Counter Event Input A (CNTAEI) bit in the Event Control (TCAn.EVCTRL) register, events are counted instead of clock ticks. 4. The counter value can be read from the Counter (CNT) bit field in the Counter (TCAn.CNT) register. 21.3.3 Operation 21.3.3.1 Normal Operation In normal operation the counter is counting clock ticks in the direction selected by the Direction (DIR) bit in the Control E (TCAn.CTRLE) register until it reaches TOP or BOTTOM. The clock ticks are given by the peripheral clock (CLK_PER), prescaled according to the Clock Select (CLKSEL) bit field in the Control A (TCAn.CTRLA) register. When TOP is reached while the counter is counting up, the counter will wrap to ‘0’ at the next clock tick. When counting down, the counter is reloaded with the Period (TCAn.PER) register value when the BOTTOM is reached. Figure 21-4. Normal Operation CNT written MAX ‘‘update’’ CNT TOP BOTTOM DIR It is possible to change the counter value in the Counter (TCAn.CNT) register when the counter is running. The write access to TCAn.CNT register has higher priority than count, clear or reload, and will be immediate. The direction of the counter can also be changed during normal operation by writing to the Direction (DIR) bit in the Control E (TCAn.CTRLE) register. 21.3.3.2 Double Buffering The Period (TCAn.PER) register value and the Compare n (TCAn.CMPn) register values are all double-buffered (TCAn.PERBUF and TCAn.CMPnBUF). Each buffer register has a Buffer Valid (BV) flag (PERBV, CMPnBV) in the Control F (TCAn.CTRLF) register, which indicates that the buffer register contains a valid (new) value that can be copied into the corresponding Period or Compare register. When the Period register and Compare n registers are used for a compare operation, the BV flag is set when data are written to the buffer register and cleared on an UPDATE condition. This is shown for a Compare (CMPn) register in the figure below. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 196 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A Figure 21-5. Period and Compare Double Buffering ‘‘write enable’’ BV EN EN UPDATE ‘‘data write’’ CMPnBUF CMPn CNT = ‘‘match’’ Both the TCAn.CMPn and TCAn.CMPnBUF registers are available as I/O registers. This allows the initialization and bypassing of the buffer register and the double-buffering function. 21.3.3.3 Changing the Period The Counter period is changed by writing a new TOP value to the Period (TCAn.PER) register. No Buffering: If double-buffering is not used, any period update is immediate. Figure 21-6. Changing the Period Without Buffering Counter wrap-around MAX ‘‘update’’ ‘‘write’’ CNT BOTTOM New TOP written to New TOP written to PER that is higher PER that is lower than current CNT. than current CNT. A counter wrap-around can occur in any mode of operation when counting up without buffering, as the TCAn.CNT and TCAn.PER registers are continuously compared. If a new TOP value is written to TCAn.PER that is lower than the current TCAn.CNT, the counter will wrap first, before a compare match occurs. Figure 21-7. Unbuffered Dual-Slope Operation Counter wrap-around MAX ‘‘update’’ ‘‘write’’ CNT BOTTOM New TOP written to PER that is higher than current CNT. New TOP written to PER that is lower than current CNT. With Buffering: When double-buffering is used, the buffer can be written at any time and still maintain the correct operation. The TCAn.PER is always updated on the UPDATE condition, as shown for dual-slope operation in the figure below. This prevents wrap-around and the generation of odd waveforms. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 197 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A Figure 21-8. Changing the Period Using Buffering MAX ‘‘update’’ ‘‘write’’ CNT BOTTOM New Period written to PERB that is higher than current CNT. New Period written to PERB that is lower than current CNT. New PER is updated with PERB value. Note:  Buffering is used in figures illustrating TCA operation if not otherwise specified. 21.3.3.4 Compare Channel Each Compare Channel n continuously compares the counter value (TCAn.CNT) with the Compare n (TCAn.CMPn) register. If TCAn.CNT equals TCAn.CMPn the Comparator n signals a match. The match will set the Compare Channel’s interrupt flag at the next timer clock cycle, and the optional interrupt is generated. The Compare n Buffer (TCAn.CMPnBUF) register provides double-buffer capability equivalent to that for the period buffer. The double-buffering synchronizes the update of the TCAn.CMPn register with the buffer value to either the TOP or BOTTOM of the counting sequence, according to the UPDATE condition. The synchronization prevents the occurrence of odd-length, non-symmetrical pulses for glitch-free output. The value in CMPnBUF is moved to CMPn at the UPDATE condition and is compared to the counter value (TCAn.CNT) from the next count. 21.3.3.4.1 Waveform Generation The compare channels can be used for waveform generation on the corresponding port pins. The following requirements must be met to make the waveform visible on the connected port pin: 1. 2. 3. 4. A Waveform Generation mode must be selected by writing the Waveform Generation Mode (WGMODE) bit field in the TCAn.CTRLB register. The compare channels used must be enabled (CMPnEN = 1 in TCAn.CTRLB). This will override the output value for the corresponding pin. An alternative pin can be selected by configuring the Port Multiplexer (PORTMUX). Refer to the PORTMUX section for details. The direction for the associated port pin n must be configured in the Port peripheral as an output. Optional: Enable the inverted waveform output for the associated port pin n. Refer to the PORT section for details. 21.3.3.4.2 Frequency (FRQ) Waveform Generation For frequency generation, the period time (T) is controlled by the TCAn.CMP0 register instead of the Period (TCAn.PER) register. The corresponding waveform generator output is toggled on each compare match between the TCAn.CNT and TCAn.CMPn registers. Figure 21-9. Frequency Waveform Generation Period (T) Direction change CNT written MAX ‘‘update’’ CNT TOP BOTTOM Waveform Output The following equation defines the waveform frequency (fFRQ): © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 198 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A fFRQ = f CLK_PER 2N CMP0+1 where N represents the prescaler divider used (see the CLKSEL bit field in the TCAn.CTRLA register), and fCLK_PER is the peripheral clock frequency. The maximum frequency of the waveform generated is half of the peripheral clock frequency (fCLK_PER/2) when TCAn.CMP0 is written to 0x0000 and no prescaling is used (N = 1, CLKSEL = 0x0 in TCAn.CTRLA). Use the TCAn.CMP1 and TCAn.CMP2 registers to get additional waveform outputs WOn. The waveforms WOn can either be identical or offset to WO0. The offset can be influenced by TCAn.CMPn, TCAn.CNT and the count direction. The offset in seconds tOffset can be calculated using the equations in the table below. The equations are only valid when CMPnCNT and CMPn>CNT WOn trailing WO0 UP CMPn TOP will produce a static high signal on WOn. Figure 21-12. Single-Slope Pulse-Width Modulation Period (T) CMPn=BOTTOM CMPn>TOP MAX TOP ‘‘update’’ ‘‘match’’ CNT CMPn BOTTOM Waveform Output Notes:  1. The representation in the figure above is valid when CMPn is updated using CMPnBUF. 2. For single-slope Pulse-Width Modulation (PWM) generation, the counter counting from TOP to BOTTOM is not supported. The TCAn.PER register defines the PWM resolution. The minimum resolution is 2 bits (TCAn.PER = 0x0003), and the maximum resolution is 16 bits (TCAn.PER = MAX). The following equation calculates the exact resolution in bits for single-slope PWM (RPWM_SS): RPWM_SS = log PER+1 log 2 fPWM_SS = fCLK_PER N PER+1 The single-slope PWM frequency (fPWM_SS) depends on the period setting (TCAn.PER), the peripheral clock frequency fCLK_PER and the TCA prescaler (the CLKSEL bit field in the TCAn.CTRLA register). It is calculated by the following equation where N represents the prescaler divider used: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 200 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.3.3.4.4 Dual-Slope PWM For the dual-slope PWM generation, the period (T) is controlled by TCAn.PER, while the values of TCAn.CMPn control the duty cycle of the WG output. The figure below shows how, for dual-slope PWM, the counter repeatedly counts from BOTTOM to TOP and then from TOP to BOTTOM. The waveform generator output is set at BOTTOM, cleared on compare match when up-counting, and set on compare match when down-counting. CMPn = BOTTOM produces a static low signal on WOn, while CMPn = TOP produces a static high signal on WOn. Figure 21-13. Dual-Slope Pulse-Width Modulation Period (T) CMPn=BOTTOM CMPn=TOP ‘‘update’’ ‘‘match’’ MAX CMPn CNT TOP BOTTOM Waveform Output Note:  The representation in the figure above is valid when CMPn is updated using CMPnBUF. The Period (TCAn.PER) register defines the PWM resolution. The minimum resolution is 2 bits (TCAn.PER = 0x0003), and the maximum resolution is 16 bits (TCAn.PER = MAX). The following equation calculates the exact resolution in bits for dual-slope PWM (RPWM_DS): RPWM_DS = log PER+1 log 2 fPWM_DS = fCLK_PER 2N ⋅ PER The PWM frequency depends on the period setting in the TCAn.PER register, the peripheral clock frequency (fCLK_PER), and the prescaler divider selected in the CLKSEL bit field in the TCAn.CTRLA register. It is calculated by the following equation: N represents the prescaler divider used. Using dual-slope PWM results in approximately half the maximum operation frequency compared to single-slope PWM operation, due to twice the number of timer increments per period. 21.3.3.4.5 Port Override for Waveform Generation To make the waveform generation available on the port pins, the corresponding port pin direction must be set as output (PORTx.DIR[n] = 1). The TCA will override the port pin values when the compare channel is enabled (CMPnEN = 1 in the TCAn.CTRLB register), and a Waveform Generation mode is selected. The figure below shows the port override for TCA. The timer/counter compare channel will override the port pin output value (PORTx.OUT) on the corresponding port pin. Enabling inverted I/O on the port pin (INVEN = 1 in the PORTx.PINnCTRL register) inverts the corresponding WG output. Figure 21-14. Port Override for Timer/Counter Type A OUT WOn Waveform CMPnEN © 2021 Microchip Technology Inc. INVEN Preliminary Datasheet DS40002311A-page 201 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.3.3.5 Timer/Counter Commands A set of commands can be issued by software to immediately change the state of the peripheral. These commands give direct control of the UPDATE, RESTART and RESET signals. A command is issued by writing the respective value to the Command (CMD) bit field in the Control E (TCAn.CTRLESET) register. An UPDATE command has the same effect as when an UPDATE condition occurs, except that the UPDATE command is not affected by the state of the Lock Update (LUPD) bit in the Control E (TCAn.CTRLE) register. The software can force a restart of the current waveform period by issuing a RESTART command. In this case, the counter, direction, and all compare outputs are set to ‘0’. A RESET command will set all timer/counter registers to their initial values. A RESET command can be issued only when the timer/counter is not running (ENABLE = 0 in the TCAn.CTRLA register). 21.3.3.6 Split Mode - Two 8-Bit Timer/Counters Split Mode Overview To double the number of timers and PWM channels in the TCA, a Split mode is provided. In this Split mode, the 16-bit timer/counter acts as two separate 8-bit timers, which each have three compare channels for PWM generation. The Split mode will only work with single-slope down-count. Event controlled operation is not supported in Split mode. The figure below shows single-slope PWM generation in Split mode. The waveform generator output is cleared at BOTTOM, and set on compare match between the counter value (TCAn.CNT) and the Compare n (TCAn.CMPn) register. Figure 21-15. Single-Slope Pulse-Width Modulation in Split mode Period (T) CMPn=BOTTOM CMPn>TOP ‘‘update’’ ‘‘match’’ MA X TOP CNT CMPn B OTTOM Waveform Output Note:  The maximum duty-cycle of the waveform output is TOP/(TOP+1) Activating Split mode results in changes to the functionality of some registers and register bits. The modifications are described in a separate register map (see 21.6 Register Summary - Split Mode). Split Mode Differences Compared to Normal Mode • Count: – Down-count only – Low Byte Timer Counter (TCAn.LCNT) register and High Byte Timer Counter (TCAn.HCNT) register are independent • Waveform generation: – Single-slope PWM only (WGMODE = SINGLESLOPE in the TCAn.CTRLB register) • Interrupt: – No change for Low Byte Timer Counter (TCAn.LCNT) register – Underflow interrupt for High Byte Timer Counter (TCAn.HCNT) register – No compare interrupt or flag for High Byte Compare n (TCAn.HCMPn) register • Event Actions: Not compatible • Buffer registers and buffer valid flags: Unused © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 202 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A • Register Access: Byte access to all registers Block Diagram Figure 21-16. Timer/Counter Block Diagram Split Mode Base Counter HPER LPER Clock Select CTRLA ‘‘count high’’ ‘‘load high’’ Counter HCNT ‘‘count low’’ ‘‘load low’’ LCNT HUNF Control Logic (INT Req. and Event) LUNF (INT Req. and Event) =0 BOTTOML BOTTOMH =0 Compare Unit n LCMPn = Waveform Generation WOn Out LCMPn ‘‘match’’ (INT Req. and Event) Compare Unit n HCMPn = Waveform Generation WO[n+3] Out ‘‘match’’ Split Mode Initialization When shifting between Normal mode and Split mode, the functionality of some registers and bits changes, but their values do not. For this reason, disabling the peripheral (ENABLE = 0 in the TCAn.CTRLA register) and doing a hard Reset (CMD = RESET in the TCAn.CTRLESET register) is recommended when changing the mode to avoid unexpected behavior. To start using the timer/counter in basic Split mode after a hard Reset, follow these steps: 1. Enable Split mode by writing a ‘1’ to the Split mode enable (SPLITM) bit in the Control D (TCAn.CTRLD) register. 2. Write a TOP value to the Period (TCAn.PER) registers. 3. Enable the peripheral by writing a ‘1’ to the Enable (ENABLE) bit in the Control A (TCAn.CTRLA) register. The counter will start counting clock ticks according to the prescaler setting in the Clock Select (CLKSEL) bit field in the TCAn.CTRLA register. 4. The counter values can be read from the Counter bit field in the Counter (TCAn.CNT) registers. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 203 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.3.4 Events The TCA can generate the events described in the table below. All event generators except TCAn_HUNF are shared between Normal mode and Split mode operation, and the generator name indicates what specific signal the generator represents in each mode in the following way: OVF_LUNF corresponds to overflow in Normal mode and Low byte timer underflow in Split mode. The same applies to CMPn_LCMPn. Table 21-3. Event Generators in TCA Generator Name Peripheral Event Description Event Type Generating Clock Domain Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Pulse CLK_PER One CLK_PER period Normal mode: Overflow OVF_LUNF Split mode: Low byte timer underflow Normal mode: Not available HUNF CMP0_LCMP0 TCAn CMP1_LCMP1 CMP2_LCMP2 Split mode: High byte timer underflow Normal mode: Compare Channel 0 match Split mode: Low byte timer Compare Channel 0 match Normal mode: Compare Channel 1 match Split mode: Low byte timer Compare Channel 1 match Normal mode: Compare Channel 2 match Split mode: Low byte timer Compare Channel 2 match Length of Event Note:  The conditions for generating an event are identical to those that will raise the corresponding interrupt flag in the TCAn.INTFLAGS register for both Normal mode and Split mode. The TCA has two event users for detecting and acting upon input events. The table below describes the event users and their associated functionality. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 204 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A Table 21-4. Event Users in TCA User Name Description Peripheral Input Input Detection Async/Sync Count on a positive event edge Edge Sync Count on any event edge Edge Sync Level Sync The event level controls the count direction, up when low and down when high Level Sync The event level controls count direction, up when low and down when high Level Sync Edge Sync Restart counter on any event edge Edge Sync Restart counter while the event signal is high Level Sync CNTA Count while the event signal is high TCAn CNTB Restart counter on a positive event edge The specific actions described in the table above are selected by writing to the Event Action (EVACTA, EVACTB) bits in the Event Control (TCAn.EVCTRL) register. Input events are enabled by writing a ‘1’ to the Enable Counter Event Input (CNTAEI and CNTBEI) bits in the TCAn.EVCTRL register. If both EVACTA and EVACTB are configured to control the count direction, the event signals will be OR’ed to determine the count direction. Both event inputs must then be low for the counter to count upwards. Notes:  1. Event inputs are not used in Split mode. 2. Event actions with level input detection only work reliably if the event frequency is less than the timer’s frequency. Refer to the Event System (EVSYS) section for more details regarding event types and Event System configuration. 21.3.5 Interrupts Table 21-5. Available Interrupt Vectors and Sources in Normal Mode Name OVF Vector Description Overflow or underflow interrupt Conditions The counter has reached TOP or BOTTOM CMP0 Compare Channel 0 interrupt Match between the counter value and the Compare 0 register CMP1 Compare Channel 1 interrupt Match between the counter value and the Compare 1 register CMP2 Compare Channel 2 interrupt Match between the counter value and the Compare 2 register Table 21-6. Available Interrupt Vectors and Sources in Split Mode Name Vector Description Conditions LUNF Low-byte Underflow interrupt Low byte timer reaches BOTTOM HUNF High-byte Underflow interrupt High byte timer reaches BOTTOM LCMP0 Compare Channel 0 interrupt Match between the counter value and the low byte of the Compare 0 register LCMP1 Compare Channel 1 interrupt Match between the counter value and the low byte of the Compare 1 register © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 205 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A ...........continued Name Vector Description LCMP2 Compare Channel 2 interrupt Conditions Match between the counter value and the low byte of the Compare 2 register When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. 21.3.6 Sleep Mode Operation TCA is by default disabled in Standby sleep mode. It will be halted as soon as the sleep mode is entered. The module can stay fully operational in Standby sleep mode if the Run Standby (RUNSTDBY) bit in the TCAn.CTRLA register is written to ‘1’. All operation is halted in Power-Down sleep mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 206 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.4 Register Summary - Normal Mode Offset Name Bit Pos. 7 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C ... 0x0D 0x0E 0x0F 0x10 ... 0x1F CTRLA CTRLB CTRLC CTRLD CTRLECLR CTRLESET CTRLFCLR CTRLFSET Reserved EVCTRL INTCTRL INTFLAGS 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 RUNSTDBY 0x20 CNT 0x22 ... 0x25 Reserved 0x26 PER 0x28 CMP0 0x2A CMP1 0x2C CMP2 0x2E ... 0x35 Reserved 0x36 PERBUF 0x38 CMP0BUF 0x3A CMP1BUF 0x3C CMP2BUF 21.5 7:0 7:0 7:0 6 5 4 3 CMP2EN CMP1EN CMP0EN ALUPD 2 1 CLKSEL[2:0] CMP2OV CMD[1:0] CMD[1:0] CMP2BV CMP1BV CMP2BV CMP1BV EVACTB[2:0] CMP2 CMP2 CMP1 CMP1 CNTBEI CMP0 CMP0 EVACTA[2:0] 0 ENABLE WGMODE[2:0] CMP1OV LUPD LUPD CMP0BV CMP0BV CMP0OV SPLITM DIR DIR PERBV PERBV CNTAEI OVF OVF Reserved DBGCTRL TEMP 7:0 7:0 TEMP[7:0] DBGRUN 7:0 15:8 CNT[7:0] CNT[15:8] 7:0 15:8 7:0 15:8 7:0 15:8 7:0 15:8 PER[7:0] PER[15:8] CMP[7:0] CMP[15:8] CMP[7:0] CMP[15:8] CMP[7:0] CMP[15:8] Reserved 7:0 PERBUF[7:0] 15:8 7:0 15:8 7:0 15:8 7:0 15:8 PERBUF[15:8] CMPBUF[7:0] CMPBUF[15:8] CMPBUF[7:0] CMPBUF[15:8] CMPBUF[7:0] CMPBUF[15:8] Register Description - Normal Mode © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 207 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.1 Control A - Normal Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RUNSTDBY R/W 0 CTRLA 0x00 0x00 - 6 5 4 3 R/W 0 2 CLKSEL[2:0] R/W 0 1 R/W 0 0 ENABLE R/W 0 Bit 7 – RUNSTDBY Run Standby Writing a ‘1’ to this bit will enable the peripheral to run in Standby sleep mode. Bits 3:1 – CLKSEL[2:0] Clock Select These bits select the clock frequency for the timer/counter. Value Name Description 0x0 DIV1 fTCA = fCLK_PER 0x1 DIV2 fTCA = fCLK_PER/2 0x2 DIV4 fTCA = fCLK_PER/4 0x3 DIV8 fTCA = fCLK_PER/8 0x4 DIV16 fTCA = fCLK_PER/16 0x5 DIV64 fTCA = fCLK_PER/64 0x6 DIV256 fTCA = fCLK_PER/256 0x7 DIV1024 fTCA = fCLK_PER/1024 Bit 0 – ENABLE Enable Value Description 0 The peripheral is disabled 1 The peripheral is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 208 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.2 Control B - Normal Mode Name:  Offset:  Reset:  Property:  Bit 7 Access Reset CTRLB 0x01 0x00 - 6 CMP2EN R/W 0 5 CMP1EN R/W 0 4 CMP0EN R/W 0 3 ALUPD R/W 0 2 R/W 0 1 WGMODE[2:0] R/W 0 0 R/W 0 Bits 4, 5, 6 – CMPEN Compare n Enable In the FRQ and PWM Waveform Generation modes, the Compare n Enable (CMPnEN) bits will make the waveform output available on the pin corresponding to WOn, overriding the value in the corresponding PORT output register. The corresponding pin direction must be configured as an output in the PORT peripheral. Value Description 0 Waveform output WOn will not be available on the corresponding pin 1 Waveform output WOn will override the output value of the corresponding pin Bit 3 – ALUPD Auto-Lock Update The Auto-Lock Update bit controls the Lock Update (LUPD) bit in the TCAn.CTRLE register. When ALUPD is written to ‘1’, the LUPD bit will be set to ‘1’ until the Buffer Valid (CMPnBV) bits of all enabled compare channels are ‘1’. This condition will clear the LUPD bit. It will remain cleared until the next UPDATE condition, where the buffer values will be transferred to the CMPn registers, and the LUPD bit will be set to ‘1’ again. This makes sure that the CMPnBUF register values are not transferred to the CMPn registers until all enabled compare buffers are written. Value Description 0 LUPD bit in the TCAn.CTRLE register is not altered by the system 1 LUPD bit in the TCAn.CTRLE register is set and cleared automatically Bits 2:0 – WGMODE[2:0] Waveform Generation Mode This bit field selects the Waveform Generation mode and controls the counting sequence of the counter, TOP value, UPDATE condition, Interrupt condition, and the type of waveform generated. No waveform generation is performed in the Normal mode of operation. For all other modes, the waveform generator output will only be directed to the port pins if the corresponding CMPnEN bit has been set. The port pin direction must be set as output. Table 21-7. Timer Waveform Generation Mode Value 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 Group Configuration NORMAL FRQ SINGLESLOPE DSTOP DSBOTH DSBOTTOM Mode of Operation Normal Frequency Reserved Single-slope PWM Reserved Dual-slope PWM Dual-slope PWM Dual-slope PWM TOP UPDATE OVF PER CMP0 PER PER PER PER TOP(1) TOP(1) TOP(1) BOTTOM TOP TOP and BOTTOM BOTTOM TOP(1) BOTTOM BOTTOM BOTTOM BOTTOM Note:  1. When counting up. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 209 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.3 Control C - Normal Mode Name:  Offset:  Reset:  Property:  Bit 7 CTRLC 0x02 0x00 - 6 5 4 3 Access Reset 2 CMP2OV R/W 0 1 CMP1OV R/W 0 0 CMP0OV R/W 0 Bit 2 – CMP2OV Compare Output Value 2 See CMP0OV. Bit 1 – CMP1OV Compare Output Value 1 See CMP0OV. Bit 0 – CMP0OV Compare Output Value 0 The CMPnOV bits allow direct access to the waveform generator’s output compare value when the timer/counter is not enabled. This is used to set or clear the WG output value when the timer/counter is not running. Note:  When the output is connected to the pad, overriding these bits will not work unless the CMPnEN bits in the TCAn.CTRLB register have been set. If the output is connected to CCL, the CMPnEN bits in the TCAn.CTRLB register are bypassed. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 210 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.4 Control D - Normal Mode Name:  Offset:  Reset:  Property:  Bit 7 CTRLD 0x03 0x00 - 6 5 4 3 Access Reset 2 1 0 SPLITM R/W 0 Bit 0 – SPLITM Enable Split Mode This bit sets the timer/counter in Split mode operation and will work as two 8-bit timer/counters. The register map will change compared to the normal 16-bit mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 211 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.5 Control Register E Clear - Normal Mode Name:  Offset:  Reset:  Property:  CTRLECLR 0x04 0x00 - Use this register instead of a Read-Modify-Write (RMW) to clear individual bits by writing a ‘1’ to its bit location. Bit 7 6 5 4 3 2 CMD[1:0] Access Reset R/W 0 R/W 0 1 LUPD R/W 0 0 DIR R/W 0 Bits 3:2 – CMD[1:0] Command This bit field is used for software control of update, restart, and Reset of the timer/counter. The command bit field is always read as ‘0’. Value Name Description 0x0 NONE No command 0x1 UPDATE Force update 0x2 RESTART Force restart 0x3 RESET Force hard Reset (ignored if the timer/counter is enabled) Bit 1 – LUPD Lock Update Lock update can be used to ensure that all buffers are valid before an update is performed. Value Description 0 The buffered registers are updated as soon as an UPDATE condition has occurred 1 No update of the buffered registers is performed, even though an UPDATE condition has occurred. This setting will not prevent an update issued by the Command bit field. Bit 0 – DIR Counter Direction Normally this bit is controlled in hardware by the Waveform Generation mode or by event actions, but can also be changed from the software. Value Description 0 The counter is counting up (incrementing) 1 The counter is counting down (decrementing) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 212 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.6 Control Register E Set - Normal Mode Name:  Offset:  Reset:  Property:  CTRLESET 0x05 0x00 - Use this register instead of a Read-Modify-Write (RMW) to set individual bits by writing a ‘1’ to its bit location. Bit 7 6 5 4 3 2 CMD[1:0] Access Reset R/W 0 R/W 0 1 LUPD R/W 0 0 DIR R/W 0 Bits 3:2 – CMD[1:0] Command This bit field is used for software control of update, restart, and Reset of the timer/counter. The command bit field is always read as ‘0’. Value Name Description 0x0 NONE No command 0x1 UPDATE Force update 0x2 RESTART Force restart 0x3 RESET Force hard Reset (ignored if the timer/counter is enabled) Bit 1 – LUPD Lock Update Locking the update ensures that all buffers are valid before an update is performed. Value Description 0 The buffered registers are updated as soon as an UPDATE condition has occurred 1 No update of the buffered registers is performed, even though an UPDATE condition has occurred. This setting will not prevent an update issued by the Command bit field. Bit 0 – DIR Counter Direction Normally this bit is controlled in hardware by the Waveform Generation mode or by event actions, but can also be changed from the software. Value Description 0 The counter is counting up (incrementing) 1 The counter is counting down (decrementing) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 213 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.7 Control Register F Clear Name:  Offset:  Reset:  Property:  CTRLFCLR 0x06 0x00 - Use this register instead of a Read-Modify-Write (RMW) to clear individual bits by writing a ‘1’ to its bit location. Bit 7 6 5 Access Reset 4 3 CMP2BV R/W 0 2 CMP1BV R/W 0 1 CMP0BV R/W 0 0 PERBV R/W 0 Bit 3 – CMP2BV Compare 2 Buffer Valid See CMP0BV. Bit 2 – CMP1BV Compare 1 Buffer Valid See CMP0BV. Bit 1 – CMP0BV Compare 0 Buffer Valid The CMPnBV bits are set when a new value is written to the corresponding TCAn.CMPnBUF register. These bits are automatically cleared on an UPDATE condition. Bit 0 – PERBV Period Buffer Valid This bit is set when a new value is written to the TCAn.PERBUF register. This bit is automatically cleared on an UPDATE condition. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 214 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.8 Control Register F Set Name:  Offset:  Reset:  Property:  CTRLFSET 0x07 0x00 - Use this register instead of a Read-Modify-Write (RMW) to set individual bits by writing a ‘1’ to its bit location. Bit 7 6 5 Access Reset 4 3 CMP2BV R/W 0 2 CMP1BV R/W 0 1 CMP0BV R/W 0 0 PERBV R/W 0 Bit 3 – CMP2BV Compare 2 Buffer Valid See CMP0BV. Bit 2 – CMP1BV Compare 1 Buffer Valid See CMP0BV. Bit 1 – CMP0BV Compare 0 Buffer Valid The CMPnBV bits are set when a new value is written to the corresponding TCAn.CMPnBUF register. These bits are automatically cleared on an UPDATE condition. Bit 0 – PERBV Period Buffer Valid This bit is set when a new value is written to the TCAn.PERBUF register. This bit is automatically cleared on an UPDATE condition. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 215 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.9 Event Control Name:  Offset:  Reset:  Property:  Bit Access Reset 7 R/W 0 EVCTRL 0x09 0x00 - 6 EVACTB[2:0] R/W 0 5 R/W 0 4 CNTBEI R/W 0 3 R/W 0 2 EVACTA[2:0] R/W 0 1 R/W 0 0 CNTAEI R/W 0 Bits 7:5 – EVACTB[2:0] Event Action B These bits define what action the counter will take upon certain event conditions. Value Name Description 0x0 NONE No action 0x1 Reserved 0x2 Reserved 0x3 UPDOWN Counts the prescaled clock cycles or counts the matching events according to the setting for event input A. The event signal controls the count direction, up when low and down when high. The direction is latched when the counter counts. 0x4 RESTART_POSEDGE Restart counter on positive event edge 0x5 RESTART_ANYEDGE Restart counter on any event edge 0x6 RESTART_HIGHLVL Restart counter while the event signal is high Other Reserved Bit 4 – CNTBEI Enable Counter Event Input B Value Description 0 Counter Event input B is disabled 1 Counter Event input B is enabled according to EVACTB bit field Bits 3:1 – EVACTA[2:0] Event Action A These bits define what action the counter will take upon certain event conditions. Value Name Description 0x0 CNT_POSEDGE Count on positive event edge 0x1 CNT_ANYEDGE Count on any event edge 0x2 CNT_HIGHLVL Count prescaled clock cycles while the event signal is high 0x3 UPDOWN Count prescaled clock cycles. The event signal controls the count direction, up when low and down when high. The direction is latched when the counter counts. Other Reserved Bit 0 – CNTAEI Enable Counter Event Input A Value Description 0 Counter Event input A is disabled 1 Counter Event input A is enabled according to EVACTA bit field © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 216 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.10 Interrupt Control Register - Normal Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 INTCTRL 0x0A 0x00 - 6 CMP2 R/W 0 5 CMP1 R/W 0 4 CMP0 R/W 0 3 2 1 0 OVF R/W 0 Bit 6 – CMP2 Compare Channel 2 Interrupt Enable See CMP0. Bit 5 – CMP1 Compare Channel 1 Interrupt Enable See CMP0. Bit 4 – CMP0 Compare Channel 0 Interrupt Enable Writing the CMPn bit to ‘1’ enables the interrupt from Compare Channel n. Bit 0 – OVF Timer Overflow/Underflow Interrupt Enable Writing the OVF bit to ‘1’ enables the overflow/underflow interrupt. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 217 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.11 Interrupt Flag Register - Normal Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 INTFLAGS 0x0B 0x00 - 6 CMP2 R/W 0 5 CMP1 R/W 0 4 CMP0 R/W 0 3 2 1 0 OVF R/W 0 Bit 6 – CMP2 Compare Channel 2 Interrupt Flag See the CMP0 flag description. Bit 5 – CMP1 Compare Channel 1 Interrupt Flag See the CMP0 flag description. Bit 4 – CMP0 Compare Channel 0 Interrupt Flag The Compare Interrupt (CMPn) flag is set on a compare match on the corresponding compare channel. For all modes of operation, the CMPn flag will be set when a compare match occurs between the Count (TCAn.CNT) register and the corresponding Compare n (TCAn.CMPn) register. The CMPn flag is not cleared automatically. It will be cleared only by writing a ‘1’ to its bit location. Bit 0 – OVF Overflow/Underflow Interrupt Flag This flag is set either on a TOP (overflow) or BOTTOM (underflow) condition, depending on the WGMODE setting. The OVF flag is not cleared automatically. It will be cleared only by writing a ‘1’ to its bit location. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 218 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.12 Debug Control Register - Normal Mode Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0E 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Run in Debug Value Description 0 The peripheral is halted in Break Debug mode and ignores events 1 The peripheral will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 219 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.13 Temporary Bits for 16-Bit Access Name:  Offset:  Reset:  Property:  TEMP 0x0F 0x00 - The Temporary register is used by the CPU for 16-bit single-cycle access to the 16-bit registers of this peripheral. The register is common for all the 16-bit registers of this peripheral and can be read and written by software. For more details on reading and writing 16-bit registers, refer to Accessing 16-Bit Registers in the AVR CPU section. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 TEMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – TEMP[7:0] Temporary Bits for 16-bit Access © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 220 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.14 Counter Register - Normal Mode Name:  Offset:  Reset:  Property:  CNT 0x20 0x00 - The TCAn.CNTL and TCAn.CNTH register pair represents the 16-bit value, TCAn.CNT. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit 15 14 13 12 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 CNT[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 CNT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – CNT[15:8] Counter High Byte This bit field holds the MSB of the 16-bit Counter register. Bits 7:0 – CNT[7:0] Counter Low Byte This bit field holds the LSB of the 16-bit Counter register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 221 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.15 Period Register - Normal Mode Name:  Offset:  Reset:  Property:  PER 0x26 0xFFFF - The TCAn.PER register contains the 16-bit TOP value in the timer/counter in all modes of operation, except Frequency Waveform Generation (FRQ). The TCAn.PERL and TCAn.PERH register pair represents the 16-bit value, TCAn.PER. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit 15 14 13 12 11 10 9 8 R/W 1 R/W 1 R/W 1 R/W 1 3 2 1 0 R/W 1 R/W 1 R/W 1 R/W 1 PER[15:8] Access Reset Bit R/W 1 R/W 1 R/W 1 R/W 1 7 6 5 4 PER[7:0] Access Reset R/W 1 R/W 1 R/W 1 R/W 1 Bits 15:8 – PER[15:8] Periodic High Byte This bit field holds the MSB of the 16-bit Period register. Bits 7:0 – PER[7:0] Periodic Low Byte This bit field holds the LSB of the 16-bit Period register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 222 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.16 Compare n Register - Normal Mode Name:  Offset:  Reset:  Property:  CMPn 0x28 + n*0x02 [n=0..2] 0x00 - This register is continuously compared to the counter value. Normally, the outputs from the comparators are used to generate waveforms. The TCAn.CMPn registers are updated with the buffer value from their corresponding TCAn.CMPnBUF register when an UPDATE condition occurs. The TCAn.CMPnL and TCAn.CMPnH register pair represents the 16-bit value, TCAn.CMPn. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit 15 14 13 12 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 CMP[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 CMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – CMP[15:8] Compare High Byte This bit field holds the MSB of the 16-bit Compare register. Bits 7:0 – CMP[7:0] Compare Low Byte This bit filed holds the LSB of the 16-bit Compare register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 223 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.17 Period Buffer Register Name:  Offset:  Reset:  Property:  PERBUF 0x36 0xFFFF - This register serves as the buffer for the Period (TCAn.PER) register. Writing to this register from the CPU or UPDI will set the Period Buffer Valid (PERBV) bit in the TCAn.CTRLF register. The TCAn.PERBUFL and TCAn.PERBUFH register pair represents the 16-bit value, TCAn.PERBUF. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit Access Reset Bit Access Reset 15 14 13 R/W 1 R/W 1 R/W 1 7 6 5 R/W 1 R/W 1 R/W 1 12 11 PERBUF[15:8] R/W R/W 1 1 4 3 PERBUF[7:0] R/W R/W 1 1 10 9 8 R/W 1 R/W 1 R/W 1 2 1 0 R/W 1 R/W 1 R/W 1 Bits 15:8 – PERBUF[15:8] Period Buffer High Byte This bit field holds the MSB of the 16-bit Period Buffer register. Bits 7:0 – PERBUF[7:0] Period Buffer Low Byte This bit field holds the LSB of the 16-bit Period Buffer register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 224 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.5.18 Compare n Buffer Register Name:  Offset:  Reset:  Property:  CMPnBUF 0x38 + n*0x02 [n=0..2] 0x00 - This register serves as the buffer for the associated Compare n (TCAn.CMPn) register. Writing to this register from the CPU or UPDI will set the Compare Buffer valid (CMPnBV) bit in the TCAn.CTRLF register. The TCAn.CMPnBUFL and TCAn.CMPnBUFH register pair represents the 16-bit value, TCAn.CMPnBUF. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit Access Reset Bit Access Reset 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 CMPBUF[15:8] R/W R/W 0 0 4 3 CMPBUF[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 15:8 – CMPBUF[15:8] Compare High Byte This bit field holds the MSB of the 16-bit Compare Buffer register. Bits 7:0 – CMPBUF[7:0] Compare Low Byte This bit field holds the LSB of the 16-bit Compare Buffer register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 225 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.6 Register Summary - Split Mode Offset Name Bit Pos. 7 0x00 0x01 0x02 0x03 0x04 0x05 0x06 ... 0x09 0x0A 0x0B 0x0C ... 0x0D 0x0E 0x0F ... 0x1F 0x20 0x21 0x22 ... 0x25 0x26 0x27 0x28 0x29 0x2A 0x2B 0x2C 0x2D CTRLA CTRLB CTRLC CTRLD CTRLECLR CTRLESET 7:0 7:0 7:0 7:0 7:0 7:0 RUNSTDBY 21.7 6 5 4 3 HCMP2EN HCMP2OV HCMP1EN HCMP1OV HCMP0EN HCMP0OV 2 1 CLKSEL[2:0] LCMP2EN LCMP2OV LCMP1EN LCMP1OV CMD[1:0] CMD[1:0] 0 ENABLE LCMP0EN LCMP0OV SPLITM CMDEN[1:0] CMDEN[1:0] Reserved INTCTRL INTFLAGS 7:0 7:0 LCMP2 LCMP2 LCMP1 LCMP1 LCMP0 LCMP0 HUNF HUNF LUNF LUNF Reserved DBGCTRL 7:0 DBGRUN Reserved LCNT HCNT 7:0 7:0 LCNT[7:0] HCNT[7:0] 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 LPER[7:0] HPER[7:0] LCMP[7:0] HCMP[7:0] LCMP[7:0] HCMP[7:0] LCMP[7:0] HCMP[7:0] Reserved LPER HPER LCMP0 HCMP0 LCMP1 HCMP1 LCMP2 HCMP2 Register Description - Split Mode © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 226 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.1 Control A - Split Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RUNSTDBY R/W 0 CTRLA 0x00 0x00 - 6 5 4 3 R/W 0 2 CLKSEL[2:0] R/W 0 1 R/W 0 0 ENABLE R/W 0 Bit 7 – RUNSTDBY Run Standby Writing a ‘1’ to this bit will enable the peripheral to run in Standby sleep mode. Bits 3:1 – CLKSEL[2:0] Clock Select These bits select the clock frequency for the timer/counter. Value Name Description 0x0 DIV1 fTCA = fCLK_PER 0x1 DIV2 fTCA = fCLK_PER/2 0x2 DIV4 fTCA = fCLK_PER/4 0x3 DIV8 fTCA = fCLK_PER/8 0x4 DIV16 fTCA = fCLK_PER/16 0x5 DIV64 fTCA = fCLK_PER/64 0x6 DIV256 fTCA = fCLK_PER/256 0x7 DIV1024 fTCA = fCLK_PER/1024 Bit 0 – ENABLE Enable Value Description 0 The peripheral is disabled 1 The peripheral is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 227 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.2 Control B - Split Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CTRLB 0x01 0x00 - 6 HCMP2EN R/W 0 5 HCMP1EN R/W 0 4 HCMP0EN R/W 0 3 2 LCMP2EN R/W 0 1 LCMP1EN R/W 0 0 LCMP0EN R/W 0 Bit 6 – HCMP2EN High byte Compare 2 Enable See HCMP0EN. Bit 5 – HCMP1EN High byte Compare 1 Enable See HCMP0EN. Bit 4 – HCMP0EN High byte Compare 0 Enable Setting the HCMPnEN bit in the FRQ or PWM Waveform Generation mode of operation will override the port output register for the corresponding WO[n+3] pin. Bit 2 – LCMP2EN Low byte Compare 2 Enable See LCMP0EN. Bit 1 – LCMP1EN Low byte Compare 1 Enable See LCMP0EN. Bit 0 – LCMP0EN Low byte Compare 0 Enable Setting the LCMPnEN bit in the FRQ or PWM Waveform Generation mode of operation will override the port output register for the corresponding WOn pin. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 228 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.3 Control C - Split Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CTRLC 0x02 0x00 - 6 HCMP2OV R/W 0 5 HCMP1OV R/W 0 4 HCMP0OV R/W 0 3 2 LCMP2OV R/W 0 1 LCMP1OV R/W 0 0 LCMP0OV R/W 0 Bit 6 – HCMP2OV High byte Compare 2 Output Value See HCMP0OV. Bit 5 – HCMP1OV High byte Compare 1 Output Value See HCMP0OV. Bit 4 – HCMP0OV High byte Compare 0 Output Value The HCMPnOV bit allows direct access to the output compare value of the waveform generator when the timer/ counter is not enabled. This is used to set or clear the WO[n+3] output value when the timer/counter is not running. Bit 2 – LCMP2OV Low byte Compare 2 Output Value See LCMP0OV. Bit 1 – LCMP1OV Low byte Compare 1 Output Value See LCMP0OV. Bit 0 – LCMP0OV Low byte Compare 0 Output Value The LCMPnOV bit allows direct access to the output compare value of the waveform generator when the timer/ counter is not enabled. This is used to set or clear the WOn output value when the timer/counter is not running. Note:  When the output is connected to the pad, overriding these bits will not work unless the xCMPnEN bits in the TCAn.CTRLB register have been set. If the output is connected to CCL, the xCMPnEN bits in the TCAn.CTRLB register are bypassed. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 229 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.4 Control D - Split Mode Name:  Offset:  Reset:  Property:  Bit 7 CTRLD 0x03 0x00 - 6 5 4 3 Access Reset 2 1 0 SPLITM R/W 0 Bit 0 – SPLITM Enable Split Mode This bit sets the timer/counter in Split mode operation and will work as two 8-bit timer/counters. The register map will change compared to the normal 16-bit mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 230 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.5 Control Register E Clear - Split Mode Name:  Offset:  Reset:  Property:  CTRLECLR 0x04 0x00 - Use this register instead of a Read-Modify-Write (RMW) to clear individual bits by writing a ‘1’ to its bit location. Bit 7 6 5 4 3 2 CMD[1:0] Access Reset R/W 0 R/W 0 1 0 CMDEN[1:0] R/W R/W 0 0 Bits 3:2 – CMD[1:0] Command This bit field is used for software control of restart and reset of the timer/counter. The command bit field is always read as ‘0’. Value Name Description 0x0 NONE No command 0x1 Reserved 0x2 RESTART Force restart 0x3 RESET Force hard Reset (ignored if the timer/counter is enabled) Bits 1:0 – CMDEN[1:0] Command Enable This bit field configures what timer/counters the command given by the CMD-bits will be applied to. Value Name Description 0x0 NONE None 0x1 Reserved 0x2 Reserved 0x3 BOTH Command (CMD) will be applied to both low byte and high byte timer/counter © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 231 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.6 Control Register E Set - Split Mode Name:  Offset:  Reset:  Property:  CTRLESET 0x05 0x00 - Use this register instead of a Read-Modify-Write (RMW) to set individual bits by writing a ‘1’ to its bit location. Bit 7 6 5 4 3 2 CMD[1:0] Access Reset R/W 0 R/W 0 1 0 CMDEN[1:0] R/W R/W 0 0 Bits 3:2 – CMD[1:0] Command This bit field is used for software control of restart and reset of the timer/counter. The command bit field is always read as ‘0’. The CMD bit field must be used together with the Command Enable (CMDEN) bits. Using the RESET command requires that both low byte and high byte timer/counter are selected with CMDEN. Value Name Description 0x0 NONE No command 0x1 Reserved 0x2 RESTART Force restart 0x3 RESET Force hard Reset (ignored if the timer/counter is enabled) Bits 1:0 – CMDEN[1:0] Command Enable This bit field configures what timer/counters the command given by the CMD-bits will be applied to. Value Name Description 0x0 NONE None 0x1 Reserved 0x2 Reserved 0x3 BOTH Command (CMD) will be applied to both low byte and high byte timer/counter © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 232 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.7 Interrupt Control Register - Split Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 INTCTRL 0x0A 0x00 - 6 LCMP2 R/W 0 5 LCMP1 R/W 0 4 LCMP0 R/W 0 3 2 1 HUNF R/W 0 0 LUNF R/W 0 Bit 6 – LCMP2 Low byte Compare Channel 2 Interrupt Enable See LCMP0. Bit 5 – LCMP1 Low byte Compare Channel 1 Interrupt Enable See LCMP0. Bit 4 – LCMP0 Low byte Compare Channel 0 Interrupt Enable Writing the LCMPn bit to ‘1’ enables the low byte Compare Channel n interrupt. Bit 1 – HUNF High byte Underflow Interrupt Enable Writing the HUNF bit to ‘1’ enables the high byte underflow interrupt. Bit 0 – LUNF Low byte Underflow Interrupt Enable Writing the LUNF bit to ‘1’ enables the low byte underflow interrupt. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 233 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.8 Interrupt Flag Register - Split Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 INTFLAGS 0x0B 0x00 - 6 LCMP2 R/W 0 5 LCMP1 R/W 0 4 LCMP0 R/W 0 3 2 1 HUNF R/W 0 0 LUNF R/W 0 Bit 6 – LCMP2 Low byte Compare Channel 2 Interrupt Flag See LCMP0 flag description. Bit 5 – LCMP1 Low byte Compare Channel 1 Interrupt Flag See LCMP0 flag description. Bit 4 – LCMP0 Low byte Compare Channel 0 Interrupt Flag The Low byte Compare Interrupt (LCMPn) flag is set on a compare match on the corresponding compare channel in the low byte timer. For all modes of operation, the LCMPn flag will be set when a compare match occurs between the Low Byte Timer Counter (TCAn.LCNT) register and the corresponding Compare n (TCAn.LCMPn) register. The LCMPn flag will not be cleared automatically and has to be cleared by software. This is done by writing a ‘1’ to its bit location. Bit 1 – HUNF High byte Underflow Interrupt Flag This flag is set on a high byte timer BOTTOM (underflow) condition. HUNF is not automatically cleared and needs to be cleared by software. This is done by writing a ‘1’ to its bit location. Bit 0 – LUNF Low byte Underflow Interrupt Flag This flag is set on a low byte timer BOTTOM (underflow) condition. LUNF is not automatically cleared and needs to be cleared by software. This is done by writing a ‘1’ to its bit location. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 234 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.9 Debug Control Register - Split Mode Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0E 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Run in Debug Value Description 0 The peripheral is halted in Break Debug mode and ignores events 1 The peripheral will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 235 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.10 Low Byte Timer Counter Register - Split Mode Name:  Offset:  Reset:  Property:  LCNT 0x20 0x00 - The TCAn.LCNT register contains the counter value for the low byte timer. CPU and UPDI write access has priority over count, clear or reload of the counter. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 LCNT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – LCNT[7:0] Counter Value for Low Byte Timer This bit field defines the counter value of the low byte timer. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 236 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.11 High Byte Timer Counter Register - Split Mode Name:  Offset:  Reset:  Property:  HCNT 0x21 0x00 - The TCAn.HCNT register contains the counter value for the high byte timer. CPU and UPDI write access has priority over count, clear or reload of the counter. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 HCNT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – HCNT[7:0] Counter Value for High Byte Timer This bit field defines the counter value in high byte timer. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 237 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.12 Low Byte Timer Period Register - Split Mode Name:  Offset:  Reset:  Property:  LPER 0x26 0xFF - The TCAn.LPER register contains the TOP value for the low byte timer. Bit 7 6 5 4 3 2 1 0 R/W 1 R/W 1 R/W 1 R/W 1 LPER[7:0] Access Reset R/W 1 R/W 1 R/W 1 R/W 1 Bits 7:0 – LPER[7:0] Period Value Low Byte Timer This bit field holds the TOP value for the low byte timer. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 238 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.13 High Byte Period Register - Split Mode Name:  Offset:  Reset:  Property:  HPER 0x27 0xFF - The TCAn.HPER register contains the TOP value for the high byte timer. Bit 7 6 5 4 3 2 1 0 R/W 1 R/W 1 R/W 1 R/W 1 HPER[7:0] Access Reset R/W 1 R/W 1 R/W 1 R/W 1 Bits 7:0 – HPER[7:0] Period Value High Byte Timer This bit field holds the TOP value for the high byte timer. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 239 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.14 Compare Register n For Low Byte Timer - Split Mode Name:  Offset:  Reset:  Property:  LCMPn 0x28 + n*0x02 [n=0..2] 0x00 - The TCAn.LCMPn register represents the compare value of Compare Channel n for the low byte timer. This register is continuously compared to the counter value of the low byte timer, TCAn.LCNT. Normally, the outputs from the comparators are then used to generate waveforms. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 LCMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – LCMP[7:0] Compare Value of Channel n This bit field holds the compare value of channel n that is compared to TCAn.LCNT. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 240 ATtiny424/426/427 ATtiny824/826/827 TCA - 16-bit Timer/Counter Type A 21.7.15 High Byte Compare Register n - Split Mode Name:  Offset:  Reset:  Property:  HCMPn 0x29 + n*0x02 [n=0..2] 0x00 - The TCAn.HCMPn register represents the compare value of Compare Channel n for the high byte timer. This register is continuously compared to the counter value of the high byte timer, TCAn.HCNT. Normally, the outputs from the comparators are then used to generate waveforms. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 HCMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – HCMP[7:0] Compare Value of Channel n This bit field holds the compare value of channel n that is compared to TCAn.HCNT. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 241 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22. TCB - 16-Bit Timer/Counter Type B 22.1 Features • • • 22.2 16-bit Counter Operation Modes: – Periodic interrupt – Time-out check – Input capture • On event • Frequency measurement • Pulse-width measurement • Frequency and pulse-width measurement • 32-bit capture – Single-shot – 8-bit Pulse-Width Modulation (PWM) Noise Canceler on Event Input Synchronize Operation with TCAn Overview The capabilities of the 16-bit Timer/Counter type B (TCB) include frequency and waveform generation and input capture on event with time and frequency measurement of digital signals. The TCB consists of a base counter and control logic that can be set in one of eight different modes, each mode providing unique functionality. The base counter is clocked by the peripheral clock with optional prescaling. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 242 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.2.1 Block Diagram Figure 22-1. Timer/Counter Type B Block Diagram Clock Select CTRLA Mode CTRLB EVCTRL Event Action Count Counter Clear CNT Restart Events Control Logic CAPT (Interrupt Request and Events) OVF = MAX (Interrupt Request and Events) BOTTOM =0 CCMP = Waveform Generation Match WO The timer/counter can be clocked from the Peripheral Clock (CLK_PER), from a 16-bit Timer/Counter type A (CLK_TCAn) or the Event System (EVSYS). Figure 22-2. Timer/Counter Clock Logic CTRLA CLK_PER DIV2 CLK_TCB CLK_TCAn CNT Events Control Logic © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 243 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B The Clock Select (CLKSEL) bit field in the Control A (TCBn.CTRLA) register selects one of the prescaler outputs directly, or an event channel as the clock (CLK_TCB) input. Setting the timer/counter to use the clock from a TCAn allows the timer/counter to run in sync with that TCAn. By using the EVSYS, any event source, such as an external clock signal on any I/O pin, may be used as the counter clock input or as a control logic input. When an event action controlled operation is used, the clock selection must be set to use an event channel as the counter input. 22.2.2 Signal Description Signal Description Type WO Digital Asynchronous Output Waveform Output 22.3 Functional Description 22.3.1 Definitions The following definitions are used throughout the documentation: Table 22-1. Timer/Counter Definitions Name Description BOTTOM The counter reaches BOTTOM when it becomes 0x0000 MAX The counter reaches the maximum when it becomes 0xFFFF TOP The counter reaches TOP when it becomes equal to the highest value in the count sequence CNT Count (TCBn.CNT) register value CCMP Capture/Compare (TCBn.CCMP) register value Note:  In general, the term ‘timer’ is used when the timer/counter is counting periodic clock ticks. The term ‘counter’ is used when the input signal has sporadic or irregular ticks. 22.3.2 Initialization By default, the TCB is in Periodic Interrupt mode. Follow these steps to start using it: 1. Write a TOP value to the Compare/Capture (TCBn.CCMP) register. 2. Optional: Write the Compare/Capture Output Enable (CCMPEN) bit in the Control B (TCBn.CTRLB) register to ‘1’. This will make the waveform output available on the corresponding pin, overriding the value in the corresponding PORT output register. 3. Enable the counter by writing a ‘1’ to the ENABLE bit in the Control A (TCBn.CTRLA) register. The counter will start counting clock ticks according to the prescaler setting in the Clock Select (CLKSEL) bit field in the Control A (TCBn.CTRLA) register. 4. The counter value can be read from the Count (TCBn.CNT) register. The peripheral will generate a CAPT interrupt and event when the CNT value reaches TOP. 4.1. If the Compare/Capture register is modified to a value lower than the current CNT, the peripheral will count to MAX and wrap around. 4.2. At MAX, an OVF interrupt and event will be generated. 22.3.3 Operation 22.3.3.1 Modes The timer can be configured to run in one of the eight different modes described in the sections below. The event pulse needs to be longer than one system clock cycle to ensure edge detection. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 244 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.3.3.1.1 Periodic Interrupt Mode In the Periodic Interrupt mode, the counter counts to the capture value and restarts from BOTTOM. A CAPT interrupt and event is generated when the CNT is equal to TOP. If TOP is updated to a value lower than CNT, upon reaching MAX, an OVF interrupt and event is generated, and the counter restarts from BOTTOM. Figure 22-3. Periodic Interrupt Mode CAPT (Interrupt Request MAX and Event) OVF (Interrupt Request and Event) TOP CNT BOTTOM TOP changed to a value lower than CNT OVF set, and CNT set to BOTTOM 22.3.3.1.2 Time-Out Check Mode In the Time-Out Check mode, the peripheral starts counting on the first signal edge and stops on the next signal edge detected on the event input channel. CNT remains stationary after the Stop edge (Freeze state). In Freeze state, the counter will restart on a new Start edge. This mode requires TCB to be configured as an event user and is explained in the Events section. Start or Stop edge is determined by the Event Edge (EDGE) bit in the Event Control (TCBn.EVCTRL) register. If CNT reaches TOP before the second edge, a CAPT interrupt and event will be generated. If TOP is updated to a value lower than the CNT upon reaching MAX, an OVF interrupt and the simultaneous event is generated, and the counter restarts from BOTTOM. In Freeze state, reading the Count (TCBn.CNT) register or Compare/Capture (TCBn.CCMP) register, or writing the Run (RUN) bit in the Status (TCBn.STATUS) register has no effect. Figure 22-4. Time-Out Check Mode CAPT Event Input (Interrupt Request and Event) OVF Event Detector (Interrupt Request and Event) MAX TOP CNT BOTTOM TOP changed to a value lower than CNT © 2021 Microchip Technology Inc. Preliminary Datasheet OVF set, and CNT set to BOTTOM DS40002311A-page 245 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.3.3.1.3 Input Capture on Event Mode In the Input Capture on Event mode, the counter will count from BOTTOM to MAX continuously. When an event is detected the Count (TCBn.CNT) register value is transferred to the Compare/Capture (TCBn.CCMP) register and a CAPT interrupt and event is generated. The Event edge detector that can be configured to trigger a capture on either rising or falling edges. This mode requires TCB to be configured as an event user and is explained in the Events section. The figure below shows the input capture unit configured to capture on the falling edge of the event input signal. The CAPT Interrupt flag is automatically cleared after the low byte of the Compare/Capture (TCBn.CCMP) register has been read. An OVF interrupt and event is generated when the CNT is MAX. Figure 22-5. Input Capture on Event CAPT (Interrupt Request Event Input and Event) OVF (Interrupt Request and Event) Event Detector MAX CNT BOTTOM Copy CNT to CCMP and CAPT OVF set, and CNT set to BOTTOM Copy CNT to CCMP and CAPT Important:  It is recommended to write 0x0000 to the Count (TCBn.CNT) register when entering this mode from any other mode. 22.3.3.1.4 Input Capture Frequency Measurement Mode In the Input Capture Frequency Measurement mode, the TCB captures the counter value and restarts on either a positive or negative edge of the event input signal. The CAPT Interrupt flag is automatically cleared after the low byte of the Compare/Capture (TCBn.CCMP) register has been read. An OVF interrupt and event is generated when the CNT value is MAX. This mode requires TCB to be configured as an event user and is explained in the Events section. The figure below illustrates this mode when configured to act on a rising edge. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 246 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B Figure 22-6. Input Capture Frequency Measurement CAPT (Interrupt Request and Event) Event Input OVF (Interrupt Request and Event) Event Detector MAX CNT BOTTOM OVF set, and CNT set to BOTTOM Copy CNT to CCMP, CAPT and restart Copy CNT to CCMP, CAPT and restart 22.3.3.1.5 Input Capture Pulse-Width Measurement Mode In the Input Capture Pulse-Width Measurement mode, the input capture pulse-width measurement will restart the counter on a positive edge, and capture on the next falling edge before an interrupt request is generated. The CAPT Interrupt flag is automatically cleared after the low byte of the Compare/Capture (TCBn.CCMP) register has been read. An OVF interrupt and event is generated when the CNT is MAX. The timer will automatically switch between rising and falling edge detection, but a minimum edge separation of two clock cycles is required for correct behavior. This mode requires TCB to be configured as an event user and is explained in the Events section. Figure 22-7. Input Capture Pulse-Width Measurement CAPT (Interrupt Request Event Input and Event) OVF (Interrupt Request and Event) Edge Detector MAX CNT BOTTOM Start counter Copy CNT to CCMP and CAPT Restart counter Copy CNT to CCMP and CAPT OVF set, and CNT set to BOTTOM 22.3.3.1.6 Input Capture Frequency and Pulse-Width Measurement Mode In the Input Capture Frequency and Pulse-Width Measurement mode, the timer will start counting when a positive edge is detected on the event input signal. The count value is captured on the following falling edge. The counter stops when the second rising edge of the event input signal is detected. This will set the CAPT interrupt flag. This mode requires TCB to be configured as an event user and is explained in the Events section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 247 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B The CAPT Interrupt flag is automatically cleared after the low byte of the Compare/Capture (TCBn.CCMP) register has been read, and the timer/counter is ready for a new capture sequence. Therefore, the Count (TCBn.CNT) register must be read before the Compare/Capture (TCBn.CCMP) register, since it is reset to BOTTOM at the next positive edge of the event input signal. An OVF interrupt and event is generated when the CNT value is MAX. Figure 22-8. Input Capture Frequency and Pulse-Width Measurement Ignored until CPU reads CCMP register Trigger next capture sequence CAPT (Interrupt Request Event Input and Event) Event Detector MAX CNT BOTTOM Start counter Copy CNT to CCMP Stop counter and CAPT CPU reads the CCMP register 22.3.3.1.7 Single-Shot Mode The Single-Shot mode can be used to generate a pulse with a duration defined by the Compare (TCBn.CCMP) register, every time a rising or falling edge is observed on a connected event channel. This mode requires TCB to be configured as an event user and is explained in the Events section. When the counter is stopped, the output pin is set low. If an event is detected on the connected event channel, the timer will reset and start counting from BOTTOM to TOP while driving its output high. The RUN bit in the Status (TCBn.STATUS) register can be read to see if the counter is counting or not. When CNT reaches the CCMP register value, the counter will stop, and the output pin will go low for at least one counter clock cycle (TCB_CLK), and a new event arriving during this time will be ignored. After this, there is a delay of two peripheral clock cycles (PER_CLK) from when a new event is received until the output is set high.When the EDGE bit of the TCB.EVCTRL register is written to ‘1’, any edge can trigger the start of counter. If the EDGE bit is ‘0’, only positive edges will trigger the start. The counter will start counting as soon as the peripheral is enabled, even without triggering by an event, or if the Event Edge (EDGE) bit in the Event Control (TCBn.EVCTRL) register is modified while the peripheral is enabled. This is prevented by writing TOP to the Counter register. Similar behavior is seen if the Event Edge (EDGE) bit in the Event Control (TCBn.EVCTRL) register is ‘1’ while the module is enabled. Writing TOP to the Counter register prevents this as well. If the Event Asynchronous (ASYNC) bit in the Control B (TCBn.CTRLB) register is written to ‘1’, the timer will react asynchronously to an incoming event. An edge on the event will immediately cause the output signal to be set. The counter will still start counting two clock cycles after the event is received. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 248 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B Figure 22-9. Single-Shot Mode Ignored Ignored CAPT (Interrupt Request and Event) Edge Detector TOP CNT BOTTOM Output Event starts counter Counter reaches TOP value Event starts counter Counter reaches TOP value 22.3.3.1.8 8-Bit PWM Mode The TCB can be configured to run in 8-bit PWM mode, where each of the register pairs in the 16-bit Compare/ Capture (TCBn.CCMPH and TCBn.CCMPL) register are used as individual Compare registers. The period (T) is controlled by CCMPL, while CCMPH controls the duty cycle of the waveform. The counter will continuously count from BOTTOM to CCMPL, and the output will be set at BOTTOM and cleared when the counter reaches CCMPH. CCMPH is the number of cycles for which the output will be driven high. CCMPL+1 is the period of the output pulse. Figure 22-10. 8-Bit PWM Mode Period (T) CCMPH=BOTTOM CCMPH=TOP CCMPH>TOP CAPT (Interrupt Request and Event) MAX OVF (Interrupt Request and Event) TOP CNT CCMPL CCMPH BOTTOM Output 22.3.3.2 Output Timer synchronization and output logic level are dependent on the selected Timer Mode (CNTMODE) bit field in Control B (TCBn.CTRLB) register. In Single-Shot mode, the timer/counter can be configured so that the signal generation happens asynchronously to an incoming event (ASYNC = 1 in TCBn.CTRLB). The output signal is then set immediately at the incoming event instead of being synchronized to the TCB clock. Even though the output is set immediately, it will take two to three CLK_TCB cycles before the counter starts counting. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 249 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B Writing the Compare/Capture Output Enable (CCMPEN) bit in TCBn.CTRLB to ‘1’ enables the waveform output. This will make the waveform output available on the corresponding pin, overriding the value in the corresponding PORT output register. The different configurations and their impact on the output are listed in the table below. Table 22-2. Output Configuration CCMPEN CNTMODE ASYNC 0 The output is high when the counter starts, and the output is low when the counter stops 1 The output is high when the event arrives, and the output is low when the counter stops Single-Shot mode 1 0 Output 8-bit PWM mode Not applicable 8-bit PWM mode Other modes Not applicable Not applicable Not applicable No output The Compare/Capture Pin Initial Value bit (CCMPINIT) in the Control B (TCBn.CTRLB) register selects the initial output level It is not recommended to change modes while the peripheral is enabled, as this can produce an unpredictable output. There is a possibility that an interrupt flag is set during the timer configuration. It is recommended to clear the Timer/Counter Interrupt Flags (TCBn.INTFLAGS) register after configuring the peripheral. 22.3.3.3 32-Bit Input Capture Two 16-bit Timer/Counter Type B (TCBn) can be combined to work as a true 32-bit input capture: One TCB is counting the two LSBs. Once this counter reaches MAX, an overflow (OVF) event is generated, and the counter wraps around. The second TCB is configured to count these OVF events and thus provides the two MSBs. The 32-bit counter value is concatenated from the two counter values. To function as a 32-bit counter, the two TCBs and the system have to be set up as described in the following paragraphs. System Configuration • Configure a source (TCA, events, CLK_PER) for the count input for the LSB TCB, according to the application requirements • Configure the event system to route the OVF events from the LSB TCB (event generator) to the MSB TCB (event user) • Configure the event system to route the same capture event (CAPT) generator to both TCBs Configuration of the LSB Counter • Select the configured count input by writing the Clock Select (CLKSEL) bit field in the Control A (CTRLA) register • Write the Timer Mode (CNTMODE) bit field in the Control B (CTRLB) register to select one of the Input Capture modes • The Cascade Two Timer/Counters (CASCADE) bit in CTRLA must be ‘0’ Configuration of the MSB Counter • Enable the 32-bit mode by writing the Cascade Two Timer/Counters bit (CASCADE) in CTRLA to ‘1’ • • Select events as clock input by writing to the Clock Select (CLKSEL) bit field in the Control A (CTRLA) register Write the Timer Mode (CNTMODE) bit field in the Control B (CTRLB) register to select the same Input Capture mode as the LSB TCB © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 250 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B Capturing a 32-Bit Counter Value To acquire a 32-bit counter value, send a CAPT event to both TCBs. Both TCBs are running in the same capture mode, so each will capture the current counter value (CNT) in the respective Capture/Compare (CCMP) register. The 32-bit capture value is formed by concatenating the two CCMP registers. Example 22-1. Using TCB0 as LSB Counter and TCB1 as MSB Counter TCB0 is counting the count input, and TCB1 is counting the OVF signals from TCB0. Both TCBs are in Input Capture on Event mode. A CAPT event is generated and causes both TCB0 and TCB1 to copy their current CNT values to their respective CCMP registers. The two different CASCADE bit values allow a correct timing of the CAPT event. The captured 32-bit value is concatenated from TCB1.CCMP (MSB) and TCB0.CCMP (LSB). Capture request TCB0 - LSB Counter Count input CAPT CTRLA.CASCADE=0 CTRLB.CNTMODE=CAPT CNT Event System CTRLA.CLKSEL=EVENT CTRLA.CASCADE=1 CTRLB.CNTMODE=CAPT OVF = MAX TCB1 - MSB Counter CNT TCB1.CCMP TCB0.CCMP 32-bit capture value: Byte 3 Byte 2 Byte 1 Byte 0 (MSB) (LSB) 22.3.3.4 Noise Canceler The Noise Canceler improves the noise immunity by using a simple digital filter scheme. When the Noise Filter (FILTER) bit in the Event Control (TCBn.EVCTRL) register is enabled, the peripheral monitors the event channel and keeps a record of the last four observed samples. If four consecutive samples are equal, the input is considered to be stable, and the signal is fed to the edge detector. When enabled, the Noise Canceler introduces an additional delay of four peripheral clock cycles between a change applied to the input and the update of the Input Compare register. The Noise Canceler uses the peripheral clock and is, therefore, not affected by the prescaler. 22.3.3.5 Synchronized with Timer/Counter Type A The TCB can be configured to use the clock (CLK_TCA) of a Timer/Counter type A (TCAn) by writing to the Clock Select bit field (CLKSEL) in the Control A register (TCBn.CTRLA). In this setting, the TCB will count on the same clock source as selected in TCAn. When the Synchronize Update (SYNCUPD) bit in the Control A (TCBn.CTRLA) register is written to ‘1’, the TCB counter will restart when the TCAn counter restarts. 22.3.4 Events The TCB can generate the events described in the following table: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 251 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B Table 22-3. Event Generators in TCB Generator Name Peripheral Description Event CAPT CAPT flag set TCBn OVF OVF flag set Event Type Generating Clock Domain Pulse CLK_PER Length of Event One CLK_PER period The conditions for generating the CAPT and OVF events are identical to those that will raise the corresponding interrupt flags in the Timer/Counter Interrupt Flags (TCBn.INTFLAGS) register. Refer to the Event System section for more details regarding event users and Event System configuration. The TCB can receive the events described in the following table: Table 22-4. Event Users and Available Event Actions in TCB User Name Peripheral Description Input Input Detection Async/Sync Time-Out Check Count mode Input Capture on Event Count mode Input Capture Frequency Measurement Count mode TCBn CAPT Input Capture Pulse-Width Measurement Count mode Sync Edge Input Capture Frequency and Pulse-Width Measurement Count mode Single-Shot Count mode Both COUNT Event as clock source in combination with a count mode Sync CAPT and COUNT are TCB event users that detect and act upon input events. The COUNT event user is enabled on the peripheral by modifying the Clock Select (CLKSEL) bit field in the Control A (TCBn.CTRLA) register to EVENT and setting up the Event System accordingly. If the Capture Event Input Enable (CAPTEI) bit in the Event Control (TCBn.EVCTRL) register is written to ‘1’, incoming events will result in an event action as defined by the Event Edge (EDGE) bit in Event Control (TCBn.EVCTRL) register and the Timer Mode (CNTMODE) bit field in Control B (TCBn.CTRLB) register. The event needs to last for at least one CLK_PER cycle to be recognized. If the Asynchronous mode is enabled for Single-Shot mode, the event is edge-triggered and will capture changes on the event input shorter than one peripheral clock cycle. 22.3.5 Interrupts Table 22-5. Available Interrupt Vectors and Sources Name Vector Description CAPT TCB interrupt OVF Conditions Depending on the operating mode. See the description of the CAPT bit in the TCBn.INTFLAG register. The timer/counter overflows from MAX to BOTTOM. When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 252 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. 22.3.6 Sleep Mode Operation TCBn is, by default, disabled in Standby sleep mode. It will be halted as soon as the sleep mode is entered. The module can stay fully operational in the Standby sleep mode if the Run Standby (RUNSTDBY) bit in the TCBn.CTRLA register is written to ‘1’. All operations are halted in Power-Down sleep mode. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 253 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 ... 0x03 0x04 0x05 0x06 0x07 0x08 0x09 CTRLA CTRLB EVCTRL INTCTRL INTFLAGS STATUS DBGCTRL TEMP 0x0A CNT 0x0C CCMP 22.5 7 6 5 4 3 7:0 7:0 RUNSTDBY ASYNC CASCADE CCMPINIT SYNCUPD CCMPEN 7:0 7:0 7:0 7:0 7:0 7:0 7:0 15:8 7:0 15:8 FILTER 2 1 CLKSEL[2:0] 0 ENABLE CNTMODE[2:0] Reserved EDGE OVF OVF CAPTEI CAPT CAPT RUN DBGRUN TEMP[7:0] CNT[7:0] CNT[15:8] CCMP[7:0] CCMP[15:8] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 254 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.1 Control A Name:  Offset:  Reset:  Property:  Bit 7 Access Reset CTRLA 0x00 0x00 - 6 RUNSTDBY R/W 0 5 CASCADE R/W 0 4 SYNCUPD R/W 0 3 R/W 0 2 CLKSEL[2:0] R/W 0 1 R/W 0 0 ENABLE R/W 0 Bit 6 – RUNSTDBY Run Standby Writing a ‘1’ to this bit will enable the peripheral to run in Standby sleep mode. Bit 5 – CASCADE Cascade Two Timer/Counters Writing this bit to ‘1’ enables cascading of two 16-bit Timer/Counters type B (TCBn) for 32-bit operation using the Event System. This bit must be ‘1’ for the timer/counter used for the two Most Significant Bytes (MSB). When this bit is ‘1’, the selected event source for capture (CAPT) is delayed by one peripheral clock cycle. This compensates the carry propagation delay when cascading two counters via the Event System. Bit 4 – SYNCUPD Synchronize Update When this bit is written to ‘1’, the TCB will restart whenever TCAn is restarted or overflows. This can be used to synchronize capture with the PWM period. If TCAn is selected as the clock source, the TCB will restart when that TCAn is restarted. For other clock selections, it will restart together with TCA0. Bits 3:1 – CLKSEL[2:0] Clock Select Writing these bits selects the clock source for this peripheral. Value Name Description 0x0 0x1 0x2 0x3-0x6 0x7 DIV1 DIV2 TCA0 EVENT CLK_PER CLK_PER / 2 Use CLK_TCA from TCA0 Reserved Positive edge on event input Bit 0 – ENABLE Enable Writing this bit to ‘1’ enables the Timer/Counter type B peripheral. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 255 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.2 Control B Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CTRLB 0x01 0x00 - 6 ASYNC R/W 0 5 CCMPINIT R/W 0 4 CCMPEN R/W 0 3 2 R/W 0 1 CNTMODE[2:0] R/W 0 0 R/W 0 Bit 6 – ASYNC Asynchronous Enable Writing this bit to ‘1’ will allow asynchronous updates of the TCB output signal in Single-Shot mode. Value Description 0 The output will go HIGH when the counter starts after synchronization 1 The output will go HIGH when an event arrives Bit 5 – CCMPINIT Compare/Capture Pin Initial Value This bit is used to set the initial output value of the pin when a pin output is used. This bit has no effect in 8-bit PWM mode and Single-Shot mode. Value Description 0 Initial pin state is LOW 1 Initial pin state is HIGH Bit 4 – CCMPEN Compare/Capture Output Enable Writing this bit to ‘1’ enables the waveform output. This will make the waveform output available on the corresponding pin, overriding the value in the corresponding PORT output register. The corresponding pin direction must be configured as an output in the PORT peripheral. Value Description 0 Waveform output is not enabled on the corresponding pin 1 Waveform output will override the output value of the corresponding pin Bits 2:0 – CNTMODE[2:0] Timer Mode Writing to this bit field selects the Timer mode. Value Name Description 0x0 INT Periodic Interrupt mode 0x1 TIMEOUT Time-out Check mode 0x2 CAPT Input Capture on Event mode 0x3 FRQ Input Capture Frequency Measurement mode 0x4 PW Input Capture Pulse-Width Measurement mode 0x5 FRQPW Input Capture Frequency and Pulse-Width Measurement mode 0x6 SINGLE Single-Shot mode 0x7 PWM8 8-Bit PWM mode © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 256 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.3 Event Control Name:  Offset:  Reset:  Property:  Bit EVCTRL 0x04 0x00 - 7 Access Reset 6 FILTER R/W 0 5 4 EDGE R/W 0 3 2 1 0 CAPTEI R/W 0 Bit 6 – FILTER Input Capture Noise Cancellation Filter Writing this bit to ‘1’ enables the Input Capture Noise Cancellation unit. Bit 4 – EDGE Event Edge This bit is used to select the event edge. The effect of this bit is dependent on the selected Count Mode (CNTMODE) bit field in TCBn.CTRLB. “—” means that an event or edge has no effect in this mode. Count Mode Periodic Interrupt mode Timeout Check mode Input Capture on Event mode Input Capture Frequency Measurement mode Input Capture Pulse-Width Measurement mode EDGE Positive Edge Negative Edge 0 1 0 1 0 1 — — Stop counter Start counter — Input Capture, interrupt 0 1 0 1 0 Input Capture Frequency and Pulse Width Measurement mode 1 Single-Shot mode 8-Bit PWM mode 0 1 0 1 — — Start counter Stop counter Input Capture, interrupt — Input Capture, clear and restart counter, interrupt — Input Capture, clear and restart counter, interrupt Clear and restart counter Input Capture, interrupt Input Capture, interrupt Clear and restart counter • On the 1st Positive: Clear and restart counter • On the following Negative: Input Capture • On the 2nd Positive: Stop counter, interrupt • On the 1st Negative: Clear and restart counter • On the following Positive: Input Capture • On the 2nd Negative: Stop counter, interrupt Start counter — Start counter Start counter — — — — — Bit 0 – CAPTEI Capture Event Input Enable Writing this bit to ‘1’ enables the input capture event. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 257 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.4 Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 INTCTRL 0x05 0x00 - 6 5 4 3 Access Reset 2 1 OVF R/W 0 0 CAPT R/W 0 Bit 1 – OVF Overflow Interrupt Enable Writing this bit to ‘1’ enables interrupt on overflow. Bit 0 – CAPT Capture Interrupt Enable Writing this bit to ‘1’ enables interrupt on capture. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 258 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.5 Interrupt Flags Name:  Offset:  Reset:  Property:  Bit INTFLAGS 0x06 0x00 - 7 6 5 4 3 2 Access Reset 1 OVF R/W 0 0 CAPT R/W 0 Bit 1 – OVF Overflow Interrupt Flag This bit is set when an overflow interrupt occurs. The flag is set whenever the timer/counter wraps from MAX to BOTTOM. The bit is cleared by writing a ‘1’ to the bit position. Bit 0 – CAPT Capture Interrupt Flag This bit is set when a capture interrupt occurs. The interrupt conditions are dependent on the Counter Mode (CNTMODE) bit field in the Control B (TCBn.CTRLB) register. This bit is cleared by writing a ‘1’ to it or when the Capture register is read in Capture mode. Table 22-6. Interrupt Sources Set Conditions by Counter Mode Counter Mode Interrupt Set Condition TOP Value CAPT Periodic Interrupt mode Timeout Check mode Single-Shot mode Set when the counter reaches TOP Set when the counter reaches TOP Set when the counter reaches TOP CCMP CNT == TOP Input Capture Frequency Measurement mode Set on edge when the Capture register is loaded and the counter restarts; the flag clears when the capture is read Set when an event occurs and the Capture register is loaded; the flag clears when the capture is read -Set on edge when the Capture register is Input Capture Pulse-Width loaded; the previous edge initialized the count; Measurement mode the flag clears when the capture is read Input Capture Frequency Set on the second edge (positive or negative) and Pulse-Width when the counter is stopped; the flag clears Measurement mode when the capture is read 8-Bit PWM mode Set when the counter reaches CCMH CCML On Event, copy CNT to CCMP, and restart counting (CNT == BOTTOM) Input Capture on Event mode © 2021 Microchip Technology Inc. Preliminary Datasheet On Event, copy CNT to CCMP, and continue counting CNT == CCMH DS40002311A-page 259 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.6 Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x07 0x00 - 6 5 4 3 2 1 0 RUN R 0 Access Reset Bit 0 – RUN Run When the counter is running, this bit is set to ‘1’. When the counter is stopped, this bit is cleared to ‘0’. The bit is read-only and cannot be set by UPDI. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 260 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.7 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x08 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run Value Description 0 The peripheral is halted in Break Debug mode and ignores events 1 The peripheral will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 261 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.8 Temporary Value Name:  Offset:  Reset:  Property:  TEMP 0x09 0x00 - The Temporary register is used by the CPU for 16-bit single-cycle access to the 16-bit registers of this peripheral. The register is common for all the 16-bit registers of this peripheral and can be read and written by software. For more details on reading and writing 16-bit registers, refer to Accessing 16-Bit Registers in the AVR CPU section. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 TEMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – TEMP[7:0] Temporary Value © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 262 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.9 Count Name:  Offset:  Reset:  Property:  CNT 0x0A 0x00 - The TCBn.CNTL and TCBn.CNTH register pair represents the 16-bit value TCBn.CNT. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. CPU and UPDI write access has priority over internal updates of the register. Bit 15 14 13 12 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 CNT[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 CNT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – CNT[15:8] Count Value High These bits hold the MSB of the 16-bit Counter register. Bits 7:0 – CNT[7:0] Count Value Low These bits hold the LSB of the 16-bit Counter register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 263 ATtiny424/426/427 ATtiny824/826/827 TCB - 16-Bit Timer/Counter Type B 22.5.10 Capture/Compare Name:  Offset:  Reset:  Property:  CCMP 0x0C 0x00 - The TCBn.CCMPL and TCBn.CCMPH register pair represents the 16-bit value TCBn.CCMP. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. This register has different functions depending on the mode of operation: • For Capture operation, these registers contain the captured value of the counter at the time the capture occurs • In Periodic Interrupt/Time-Out and Single-Shot mode, this register acts as the TOP value • In 8-bit PWM mode, TCBn.CCMPL and TCBn.CCMPH act as two independent registers: The period of the waveform is controlled by CCMPL, while CCMPH controls the duty cycle. Bit Access Reset Bit 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 12 11 CCMP[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 CCMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – CCMP[15:8] Capture/Compare Value High Byte These bits hold the MSB of the 16-bit compare, capture, and top value. Bits 7:0 – CCMP[7:0] Capture/Compare Value Low Byte These bits hold the LSB of the 16-bit compare, capture, and top value. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 264 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23. RTC - Real-Time Counter 23.1 Features • • • • • • • • • 23.2 16-bit Resolution Selectable Clock Sources Programmable 15-bit Clock Prescaling One Compare Register One Period Register Clear Timer on Period Overflow Optional Interrupt/Event on Overflow and Compare Match Periodic Interrupt and Event Crystal Error Correction Overview The RTC peripheral offers two timing functions: The Real-Time Counter (RTC) and a Periodic Interrupt Timer (PIT). The PIT functionality can be enabled independently of the RTC functionality. RTC - Real-Time Counter The RTC counts (prescaled) clock cycles in a Counter register and compares the content of the Counter register to a Period register and a Compare register. The RTC can generate both interrupts and events on compare match or overflow. It will generate a compare interrupt and/or event at the first count after the counter value equals the Compare register value, and an overflow interrupt and/or event at the first count after the counter value equals the Period register value. The overflow will reset the counter value to zero. The RTC peripheral typically runs continuously, including in Low-Power sleep modes, to keep track of time. It can wake up the device from sleep modes, and/or interrupt the device at regular intervals. The reference clock is typically the 32.768 kHz output from an external crystal. The RTC can also be clocked from an external clock signal, the 32.768 kHz internal ultra low-power oscillator (OSCULP32K), or the OSCULP32K divided by 32. The RTC peripheral includes a 15-bit programmable prescaler that can scale down the reference clock before it reaches the counter. A wide range of resolutions and time-out periods can be configured for the RTC. With a 32.768 kHz clock source, the maximum resolution is 30.5 μs, and time-out periods can be up to two seconds. With a resolution of 1s, the maximum time-out period is more than 18 hours (65536 seconds). The RTC also supports crystal error correction when operated using external crystal selection. An externally calibrated value will be used for correction. The RTC can be adjusted by software with an accuracy of ±1 PPM, and the maximum adjustment is ±127 PPM. The RTC correction operation will either speed up (by skipping count) or slow down (by adding extra count) the prescaler to account for the crystal error. PIT - Periodic Interrupt Timer The PIT uses the same clock source (CLK_RTC) as the RTC function and can generate an interrupt request or a level event on every nth clock period. The n can be selected from {4, 8, 16,... 32768} for interrupts, and from {64, 128, 256,... 8192} for events. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 265 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.2.1 Block Diagram Figure 23-1. Block Diagram EXTCLK TOSC1 TOSC2 External Clock 32.768 kHz Crystal Osc. 32.768 kHz Int. Osc. DIV32 PER CLK_RTC Correction counter RTC 15-bit prescaler PIT = Overflow = Compare CNT CMP Period 23.3 Clocks The peripheral clock (CLK_PER) is required to be at least four times faster than the RTC clock (CLK_RTC) for reading the counter value, regardless of the prescaler setting. A 32.768 kHz crystal can be connected to the TOSC1 or TOSC2 pins, along with any required load capacitors. Alternatively, an external digital clock can be connected to the TOSC1 pin. 23.4 RTC Functional Description The RTC peripheral offers two timing functions: The Real-Time Counter (RTC) and a Periodic Interrupt Timer (PIT). This subsection describes the RTC. 23.4.1 Initialization Before enabling the RTC peripheral and the desired actions (interrupt requests and output events), the source clock for the RTC counter must be configured to operate the RTC. 23.4.1.1 Configure the Clock CLK_RTC To configure the CLK_RTC, follow these steps: 1. 2. Configure the desired oscillator to operate as required, in the Clock Controller (CLKCTRL) peripheral. Write the Clock Select (CLKSEL) bit field in the Clock Selection (RTC.CLKSEL) register accordingly. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 266 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter The CLK_RTC clock configuration is used by both RTC and PIT functionalities. 23.4.1.2 Configure RTC To operate the RTC, follow these steps: 1. 2. 3. 4. 23.4.2 Set the compare value in the Compare (RTC.CMP) register, and/or the overflow value in the Period (RTC.PER) register. Enable the desired interrupts by writing to the respective interrupt enable bits (CMP, OVF) in the Interrupt Control (RTC.INTCTRL) register. Configure the RTC internal prescaler by writing the desired value to the Prescaler (PRESCALER) bit field in the Control A (RTC.CTRLA) register. Enable the RTC by writing a ‘1’ to the RTC Peripheral Enable (RTCEN) bit in the RTC.CTRLA register. Operation - RTC 23.4.2.1 Enabling and Disabling The RTC is enabled by writing the RTC Peripheral Enable (RTCEN) bit in the Control A (RTC.CTRLA) register to ‘1’. The RTC is disabled by writing the RTC Peripheral Enable (RTCEN) bit in RTC.CTRLA to ‘0’. 23.5 PIT Functional Description The RTC peripheral offers two timing functions: The Real-Time Counter (RTC) and a Periodic Interrupt Timer (PIT). This subsection describes the PIT. 23.5.1 Initialization To operate the PIT, follow these steps: 1. Configure the RTC clock CLK_RTC as described in section 23.4.1.1 Configure the Clock CLK_RTC. 2. Enable the interrupt by writing a ‘1’ to the Periodic Interrupt (PI) bit in the PIT Interrupt Control (RTC.PITINTCTRL) register. 3. Select the period for the interrupt by writing the desired value to the Period (PERIOD) bit field in the Periodic Interrupt Timer Control A (RTC.PITCTRLA) register. 4. Enable the PIT by writing a ‘1’ to the Periodic Interrupt Timer Enable (PITEN) bit in the RTC.PITCTRLA register. 23.5.2 Operation - PIT 23.5.2.1 Enabling and Disabling The PIT is enabled by writing the Periodic Interrupt Timer Enable (PITEN) bit in the Periodic Interrupt Timer Control A (RTC.PITCTRLA) register to ‘1’. The PIT is disabled by writing the Periodic Interrupt Timer Enable (PITEN) bit in RTC.PITCTRLA to ‘0’. 23.5.2.2 PIT Interrupt Timing Timing of the First Interrupt Both PIT and RTC functions are running from the same counter inside the prescaler and can be configured as described below: • The RTC interrupt period is configured by writing the Period (RTC.PER) register • The PIT interrupt period is configured by writing the Period (PERIOD) bit field in Periodic Interrupt Timer Control A (RTC.PITCTRLA) register The prescaler is OFF when both functions are OFF (RTC Peripheral Enable (RTCEN) bit in RTC.CTRLA and the Periodic Interrupt Timer Enable (PITEN) bit in RTC.PITCTRLA are ‘0’), but it is running (that is, its internal counter is counting) when either function is enabled. For this reason, the timing of the first PIT interrupt and the first RTC count tick will be unknown (anytime between enabling and a full period). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 267 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter Continuous Operation After the first interrupt, the PIT will continue toggling every ½ PIT period resulting in a full PIT period signal. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 268 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter Example 23-1. PIT Timing Diagram for PERIOD = CYC16 For PERIOD = CYC16 in RTC.PITCTRLA, the PIT output effectively follows the state of the prescaler counter bit 3, so the resulting interrupt output has a period of 16 CLK_RTC cycles. The time between writing PITEN to ‘1’ and the first PIT interrupt can vary between virtually zero and a full PIT period of 16 CLK_RTC cycles. The precise delay between enabling the PIT and its first output depends on the prescaler’s counting phase: The first interrupt shown below is produced by writing PITEN to ‘1’ at any time inside the leading time window. Figure 23-2. Timing Between PIT Enable and First Interrupt Prescaler counter value (LSB) ..000000 ..000001 ..000010 ..000011 ..000100 ..000101 ..000110 ..000111 ..001000 ..001001 ..001010 ..001011 ..001100 ..001101 ..001110 ..001111 ..010000 ..010001 ..010010 ..010011 ..010100 ..010101 ..010110 ..010111 ..011000 ..011001 ..011010 ..011011 ..011100 ..011101 ..011110 ..011111 ..100000 ..100001 ..100010 ..100011 ..100100 ..100101 ..100110 ..100111 ..101000 ..101001 ..101010 ..101011 ..101100 ..101101 ..101110 ..101111 CLK_RTC Prescaler bit 3 (CYC16) Continuous Operation PITENABLE = 0 PIT output Time window for writing PITENABLE = 1 First PIT output 23.6 Crystal Error Correction The prescaler for the RTC and PIT can do internal frequency correction of the crystal clock by using the PPM error value from the Crystal Frequency Calibration (CALIB) register when the Frequency Correction Enable (CORREN) bit in the RTC.CTRLA register is ‘1’. The CALIB register must be written by the user, based on the information about the frequency error. The correction operation is performed by adding or removing a number of cycles equal to the value given in the Error Correction Value (ERROR) bit field in the CALIB register spread throughout a million-cycle interval. The correction of the clock will be reflected in the RTC count value available through the Count (RTC.CNT) registers or in the PIT intervals. If disabling the correction feature, an ongoing correction cycle will be completed before the function is disabled. Note:  If using this feature with a negative correction, the minimum prescaler configuration is DIV2. 23.7 Events The RTC can generate the events described in the following table: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 269 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter Generator Name Description Event Type Generating Clock Domain Length of Event OVF Overflow Pulse CLK_RTC One CLK_RTC period CMP Compare Match Peripheral Event RTC PIT_DIV8192 Prescaled RTC clock divided by 8192 Level Given by prescaled RTC clock divided by 8192 PIT_DIV4096 Prescaled RTC clock divided by 4096 Given by prescaled RTC clock divided by 4096 PIT_DIV2048 Prescaled RTC clock divided by 2048 Given by prescaled RTC clock divided by 2048 PIT_DIV1024 Prescaled RTC clock divided by 1024 Given by prescaled RTC clock divided by 1024 PIT_DIV512 Prescaled RTC clock divided by 512 Given by prescaled RTC clock divided by 512 PIT_DIV256 Prescaled RTC clock divided by 256 Given by prescaled RTC clock divided by 256 PIT_DIV128 Prescaled RTC clock divided by 128 Given by prescaled RTC clock divided by 128 PIT_DIV64 Prescaled RTC clock divided by 64 Given by prescaled RTC clock divided by 64 The conditions for generating the OVF and CMP events are identical to those that will raise the corresponding interrupt flags in the RTC.INTFLAGS register. Refer to the Event System (EVSYS) section for more details regarding event users and Event System configuration. 23.8 Interrupts Table 23-1. Available Interrupt Vectors and Sources Name Vector Description RTC PIT Real-Time Counter overflow and compare match interrupt Periodic Interrupt Timer interrupt Conditions • • Overflow (OVF): The counter has reached the value from the RTC.PER register and wrapped to zero Compare (CMP): Match between the value from the Counter (RTC.CNT) register and the value from the Compare (RTC.CMP) register A time period has passed, as configured by the PERIOD bit field in RTC.PITCTRLA When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. Note that: • The RTC has two INTFLAGS registers: RTC.INTFLAGS and RTC.PITINTFLAGS. • The RTC has two INTCTRL registers: RTC.INTCTRL and RTC.PITINTCTRL. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 270 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.9 Sleep Mode Operation The RTC will continue to operate in Idle sleep mode. It will run in Standby sleep mode if the Run in Standby (RUNSTDBY) bit in RTC.CTRLA is set. The PIT will continue to operate in any sleep mode. 23.10 Synchronization Both the RTC and the PIT are asynchronous, operating from a different clock source (CLK_RTC) independently of the peripheral clock (CLK_PER). For Control and Count register updates, it will take some RTC and/or peripheral clock cycles before an updated register value is available in a register or until a configuration change affects the RTC or PIT, respectively. This synchronization time is described for each register in the Register Description section. For some RTC registers, a Synchronization Busy (CMPBUSY, PERBUSY, CNTBUSY, CTRLABUSY) flag is available in the Status (RTC.STATUS) register. For the RTC.PITCTRLA register, a Synchronization Busy (CTRLBUSY) flag is available in the Periodic Interrupt Timer Status (RTC.PITSTATUS) register. Check these flags before writing to the mentioned registers. 23.11 Debug Operation If the Debug Run (DBGRUN) bit in the Debug Control (RTC.DBGCTRL) register is ‘1’, the RTC will continue normal operation. If DBGRUN is ‘0’ and the CPU is halted, the RTC will halt the operation and ignore any incoming events. If the Debug Run (DBGRUN) bit in the Periodic Interrupt Timer Debug Control (RTC.PITDBGCTRL) register is ‘1’, the PIT will continue normal operation. If DBGRUN is ‘0’ in the Debug mode and the CPU is halted, the PIT output will be low. When the PIT output is high at the time, a new positive edge occurs to set the interrupt flag when restarting from a break. The result is an additional PIT interrupt that does not happen during normal operation. If the PIT output is low at the break, the PIT will resume low without additional interrupt. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 271 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.12 Register Summary Offset Name Bit Pos. 7 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 CTRLA STATUS INTCTRL INTFLAGS TEMP DBGCTRL CALIB CLKSEL 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 15:8 7:0 15:8 7:0 15:8 RUNSTDBY 0x08 CNT 0x0A PER 0x0C CMP 0x0E ... 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 23.13 6 5 4 3 2 CMPBUSY CORREN PERBUSY PRESCALER[3:0] 1 0 CNTBUSY CMP CMP RTCEN CTRLABUSY OVF OVF TEMP[7:0] DBGRUN SIGN ERROR[6:0] CLKSEL[1:0] CNT[7:0] CNT[15:8] PER[7:0] PER[15:8] CMP[7:0] CMP[15:8] Reserved PITCTRLA PITSTATUS PITINTCTRL PITINTFLAGS Reserved PITDBGCTRL 7:0 7:0 7:0 7:0 PERIOD[3:0] 7:0 PITEN CTRLBUSY PI PI DBGRUN Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 272 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.1 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RUNSTDBY R/W 0 CTRLA 0x00 0x00 - 6 R/W 0 5 4 PRESCALER[3:0] R/W R/W 0 0 3 R/W 0 2 CORREN R/W 0 1 0 RTCEN R/W 0 Bit 7 – RUNSTDBY Run in Standby Value Description 0 RTC disabled in Standby sleep mode 1 RTC enabled in Standby sleep mode Bits 6:3 – PRESCALER[3:0] Prescaler These bits define the prescaling of the CLK_RTC clock signal. Due to synchronization between the RTC clock and the peripheral clock, there is a latency of two RTC clock cycles from updating the register until this has an effect. Application software needs to check that the CTRLABUSY flag in the RTC.STATUS register is cleared before writing to this register. Value Name Description 0x0 DIV1 RTC clock/1 (no prescaling) 0x1 DIV2 RTC clock/2 0x2 DIV4 RTC clock/4 0x3 DIV8 RTC clock/8 0x4 DIV16 RTC clock/16 0x5 DIV32 RTC clock/32 0x6 DIV64 RTC clock/64 0x7 DIV128 RTC clock/128 0x8 DIV256 RTC clock/256 0x9 DIV512 RTC clock/512 0xA DIV1024 RTC clock/1024 0xB DIV2048 RTC clock/2048 0xC DIV4096 RTC clock/4096 0xD DIV8192 RTC clock/8192 0xE DIV16384 RTC clock/16384 0xF DIV32768 RTC clock/32768 Bit 2 – CORREN Frequency Correction Enable Value Description 0 Frequency correction is disabled 1 Frequency correction is enabled Bit 0 – RTCEN RTC Peripheral Enable Value Description 0 RTC peripheral is disabled 1 RTC peripheral is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 273 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.2 Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x01 0x00 - 6 Access Reset 5 4 3 CMPBUSY R 0 2 PERBUSY R 0 1 CNTBUSY R 0 0 CTRLABUSY R 0 Bit 3 – CMPBUSY Compare Synchronization Busy This bit is ‘1’ when the RTC is busy synchronizing the Compare (RTC.CMP) register in the RTC clock domain. Bit 2 – PERBUSY Period Synchronization Busy This bit is ‘1’ when the RTC is busy synchronizing the Period (RTC.PER) register in the RTC clock domain. Bit 1 – CNTBUSY Counter Synchronization Busy This bit is ‘1’ when the RTC is busy synchronizing the Count (RTC.CNT) register in the RTC clock domain. Bit 0 – CTRLABUSY Control A Synchronization Busy This bit is ‘1’ when the RTC is busy synchronizing the Control A (RTC.CTRLA) register in the RTC clock domain. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 274 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.3 Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 INTCTRL 0x02 0x00 - 6 5 4 3 Access Reset 2 1 CMP R/W 0 0 OVF R/W 0 Bit 1 – CMP Compare Match Interrupt Enable Enable interrupt-on-compare match (that is, when the value from the Count (RTC.CNT) register matches the value from the Compare (RTC.CMP) register). Value Description 0 The compare match interrupt is disabled 1 The compare match interrupt is enabled Bit 0 – OVF Overflow Interrupt Enable Enable interrupt-on-counter overflow (that is, when the value from the Count (RTC.CNT) register matched the value from the Period (RTC.PER) register and wraps around to zero). Value Description 0 The overflow interrupt is disabled 1 The overflow interrupt is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 275 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.4 Interrupt Flag Name:  Offset:  Reset:  Property:  Bit 7 INTFLAGS 0x03 0x00 - 6 5 4 3 Access Reset 2 1 CMP R/W 0 0 OVF R/W 0 Bit 1 – CMP Compare Match Interrupt Flag This flag is set when the value from the Count (RTC.CNT) register matches the value from the Compare (RTC.CMP) register. Writing a ‘1’ to this bit clears the flag. Bit 0 – OVF Overflow Interrupt Flag This flag is set when the value from the Count (RTC.CNT) register has reached the value from the Period (RTC.PER) register and wrapped to zero. Writing a ‘1’ to this bit clears the flag. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 276 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.5 Temporary Name:  Offset:  Reset:  Property:  TEMP 0x4 0x00 - The Temporary register is used by the CPU for 16-bit single-cycle access to the 16-bit registers of this peripheral. The register is common for all the 16-bit registers of this peripheral and can be read and written by software. For more details on reading and writing 16-bit registers, refer to Accessing 16-Bit Registers in the AVR CPU section. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 TEMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – TEMP[7:0] Temporary Temporary register for read/write operations in 16-bit registers. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 277 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.6 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x05 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run Value Description 0 The peripheral is halted in Break Debug mode and ignores events 1 The peripheral will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 278 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.7 Crystal Frequency Calibration Name:  Offset:  Reset:  Property:  CALIB 0x06 0x00 - This register stores the error value and the type of correction to be done. The register is written by software with an error value based on external calibration and/or temperature correction/s. Bit Access Reset 7 SIGN R/W 0 6 5 4 R/W 0 R/W 0 R/W 0 3 ERROR[6:0] R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bit 7 – SIGN Error Correction Sign Bit This bit shows the direction of the correction. Value Description 0x0 0x1 Positive correction causing the prescaler to count slower Negative correction causing the prescaler to count faster. This requires that the minimum prescaler configuration is DIV2 Bits 6:0 – ERROR[6:0] Error Correction Value The number of correction clocks for each million RTC clock cycles interval (PPM). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 279 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.8 Clock Selection Name:  Offset:  Reset:  Property:  Bit 7 CLKSEL 0x07 0x00 - 6 5 4 3 Access Reset 2 1 0 CLKSEL[1:0] R/W R/W 0 0 Bits 1:0 – CLKSEL[1:0] Clock Select Writing these bits select the source for the RTC clock (CLK_RTC). When configuring the RTC to use either XOSC32K or the external clock on TOSC1, XOSC32K needs to be enabled, and the Source Select (SEL) bit and Run Standby (RUNSTDBY) bit in the XOSC32K Control A of the Clock Controller (CLKCTRL.XOSC32KCTRLA) register must be configured accordingly. Value Name Description 0x00 0x01 0x02 0x03 INT32K INT1K TOSC32K EXTCLK Internal 32.768 kHz oscillator Internal 1.024 kHz oscillator 32.768 kHz crystal oscillator External clock from EXTCLK pin © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 280 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.9 Count Name:  Offset:  Reset:  Property:  CNT 0x08 0x0000 - The RTC.CNTL and RTC.CNTH register pair represents the 16-bit value, RTC.CNT. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Due to the synchronization between the RTC clock and main clock domains, there is a latency of two RTC clock cycles from updating the register until this has an effect. The application software needs to check that the CNTBUSY flag in RTC.STATUS is cleared before writing to this register. Bit 15 14 13 12 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 CNT[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 CNT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – CNT[15:8] Counter High Byte These bits hold the MSB of the 16-bit Counter register. Bits 7:0 – CNT[7:0] Counter Low Byte These bits hold the LSB of the 16-bit Counter register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 281 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.10 Period Name:  Offset:  Reset:  Property:  PER 0x0A 0xFFFF - The RTC.PERL and RTC.PERH register pair represents the 16-bit value, RTC.PER. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Due to the synchronization between the RTC clock and main clock domains, there is a latency of two RTC clock cycles from updating the register until this has an effect. The application software needs to check that the PERBUSY flag in RTC.STATUS is cleared before writing to this register. Bit 15 14 13 12 11 10 9 8 R/W 1 R/W 1 R/W 1 R/W 1 3 2 1 0 R/W 1 R/W 1 R/W 1 R/W 1 PER[15:8] Access Reset Bit R/W 1 R/W 1 R/W 1 R/W 1 7 6 5 4 PER[7:0] Access Reset R/W 1 R/W 1 R/W 1 R/W 1 Bits 15:8 – PER[15:8] Period High Byte These bits hold the MSB of the 16-bit Period register. Bits 7:0 – PER[7:0] Period Low Byte These bits hold the LSB of the 16-bit Period register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 282 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.11 Compare Name:  Offset:  Reset:  Property:  CMP 0x0C 0x0000 - The RTC.CMPL and RTC.CMPH register pair represents the 16-bit value, RTC.CMP. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Bit 15 14 13 12 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 CMP[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 CMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – CMP[15:8] Compare High Byte These bits hold the MSB of the 16-bit Compare register. Bits 7:0 – CMP[7:0] Compare Low Byte These bits hold the LSB of the 16-bit Compare register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 283 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.12 Periodic Interrupt Timer Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 PITCTRLA 0x10 0x00 - 6 R/W 0 5 4 PERIOD[3:0] R/W R/W 0 0 3 2 R/W 0 1 0 PITEN R/W 0 Bits 6:3 – PERIOD[3:0] Period Writing this bit field selects the number of RTC clock cycles between each interrupt. Value Name Description 0x0 OFF No interrupt 0x1 CYC4 4 cycles 0x2 CYC8 8 cycles 0x3 CYC16 16 cycles 0x4 CYC32 32 cycles 0x5 CYC64 64 cycles 0x6 CYC128 128 cycles 0x7 CYC256 256 cycles 0x8 CYC512 512 cycles 0x9 CYC1024 1024 cycles 0xA CYC2048 2048 cycles 0xB CYC4096 4096 cycles 0xC CYC8192 8192 cycles 0xD CYC16384 16384 cycles 0xE CYC32768 32768 cycles 0xF Reserved Bit 0 – PITEN Periodic Interrupt Timer Enable Value Description 0 Periodic Interrupt Timer disabled 1 Periodic Interrupt Timer enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 284 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.13 Periodic Interrupt Timer Status Name:  Offset:  Reset:  Property:  Bit 7 PITSTATUS 0x11 0x00 - 6 5 4 3 Access Reset 2 1 0 CTRLBUSY R 0 Bit 0 – CTRLBUSY PITCTRLA Synchronization Busy This bit is ‘1’ when the RTC is busy synchronizing the Periodic Interrupt Timer Control A (RTC.PITCTRLA) register in the RTC clock domain. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 285 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.14 PIT Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 PITINTCTRL 0x12 0x00 - 6 5 4 3 Access Reset 2 1 0 PI R/W 0 Bit 0 – PI Periodic Interrupt Value Description 0 The periodic interrupt is disabled 1 The periodic interrupt is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 286 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.15 PIT Interrupt Flag Name:  Offset:  Reset:  Property:  Bit 7 PITINTFLAGS 0x13 0x00 - 6 5 4 3 Access Reset 2 1 0 PI R/W 0 Bit 0 – PI Periodic Interrupt Flag This flag is set when a periodic interrupt is issued. Writing a ‘1’ clears the flag. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 287 ATtiny424/426/427 ATtiny824/826/827 RTC - Real-Time Counter 23.13.16 Periodic Interrupt Timer Debug Control Name:  Offset:  Reset:  Property:  Bit 7 PITDBGCTRL 0x15 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run Value Description 0 The peripheral is halted in Break Debug mode and ignores events 1 The peripheral will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 288 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24. USART - Universal Synchronous and Asynchronous Receiver and Transmitter 24.1 Features • • • • • • • • • • • • 24.2 Full-Duplex Operation Half-Duplex Operation: – One-Wire mode – RS-485 mode Asynchronous or Synchronous Operation Supports Serial Frames with Five, Six, Seven, Eight or Nine Data Bits and One or Two Stop Bits Fractional Baud Rate Generator: – Can generate the desired baud rate from any peripheral clock frequency – No need for an external oscillator Built-In Error Detection and Correction Schemes: – Odd or even parity generation and parity check – Buffer overflow and frame error detection – Noise filtering including false Start bit detection and digital low-pass filter Separate Interrupts for: – Transmit complete – Transmit Data register empty – Receive complete Host SPI Mode Multiprocessor Communication Mode Start-of-Frame Detection IRCOM Module for IrDA® Compliant Pulse Modulation/Demodulation LIN Client Support Overview The Universal Synchronous and Asynchronous serial Receiver and Transmitter (USART) is a fast and flexible serial communication peripheral. The USART supports several different modes of operation that can accommodate multiple types of applications and communication devices. For example, the One-Wire Half-Duplex mode is useful when low pin count applications are desired. The communication is frame-based, and the frame format can be customized to support a wide range of standards. The USART is buffered in both directions, enabling continued data transmission without any delay between frames. Separate interrupts for receive and transmit completion allow fully interrupt-driven communication. The transmitter consists of a two-level write buffer, a Shift register, and control logic for different frame formats. The receiver consists of a two-level receive buffer and a Shift register. The status information of the received data is available for error checking. Data and clock recovery units ensure robust synchronization and noise filtering during asynchronous data reception. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 289 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.2.1 Block Diagram Figure 24-1. USART Block Diagram CLOCK GENERATOR BAUD Baud Rate Generator XCK TRANSMITTER XDIR TX Shift Register TX Buffer TXD TXDATA RECEIVER RX Shift Register RX Buffer RXD RXDATA 24.2.2 Signal Description Signal Type Description XCK Output/input Clock for synchronous operation XDIR Output Transmit enable for RS-485 TxD Output/input Transmitting line (and receiving line in One-Wire mode) RxD Input Receiving line 24.3 Functional Description 24.3.1 Initialization Full-Duplex Mode: 1. 2. 3. 4. Set the baud rate (USARTn.BAUD). Set the frame format and mode of operation (USARTn.CTRLC). Configure the TXD pin as an output. Enable the transmitter and the receiver (USARTn.CTRLB). Notes:  • For interrupt-driven USART operation, global interrupts must be disabled during the initialization • Before doing a reinitialization with a changed baud rate or frame format, be sure that there are no ongoing transmissions while the registers are changed One-Wire Half-Duplex Mode: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 290 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 1. 2. 3. 4. 5. 6. Internally connect the TXD to the USART receiver (the LBME bit in the USARTn.CTRLA register). Enable internal pull-up for the RX/TX pin (the PULLUPEN bit in the PORTx.PINnCTRL register). Enable Open-Drain mode (the ODME bit in the USARTn.CTRLB register). Set the baud rate (USARTn.BAUD). Set the frame format and mode of operation (USARTn.CTRLC). Enable the transmitter and the receiver (USARTn.CTRLB). Notes:  • When Open-Drain mode is enabled, the TXD pin is automatically set to output by hardware • For interrupt-driven USART operation, global interrupts must be disabled during the initialization • Before doing a reinitialization with a changed baud rate or frame format, be sure that there are no ongoing transmissions while the registers are changed 24.3.2 Operation 24.3.2.1 Frame Formats The USART data transfer is frame-based. A frame starts with a Start bit followed by one character of data bits. If enabled, the Parity bit is inserted after the data bits and before the first Stop bit. After the Stop bit(s) of a frame, either the next frame can follow immediately, or the communication line can return to the Idle (high) state. The USART accepts all combinations of the following as valid frame formats: • • • • 1 Start bit 5, 6, 7, 8, or 9 data bits No, even, or odd Parity bit 1 or 2 Stop bits The figure below illustrates the possible combinations of frame formats. Bits inside brackets are optional. Figure 24-2. Frame Formats FRAME (IDLE) St 0 1 2 3 4 [5] [6] [7] [8] [P] Sp1 [Sp2] St Start bit, always low (n) Data bits (0 to 8) P Parity bit, may be odd or even Sp Stop bit, always high IDLE No transfer on the communication line (RxD or TxD). The Idle state is always high. (St/IDLE) 24.3.2.2 Clock Generation The clock used for shifting and sampling data bits is generated internally by the fractional baud rate generator or externally from the Transfer Clock (XCK) pin. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 291 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-3. Clock Generation Logic Block Diagram CLOCK GENERATOR Sync Register Edge Detector CLK_PER Fractional Baud Rate Generator BAUD XCK XCKO Transmitter TXCLK Receiver RXCLK 24.3.2.2.1 The Fractional Baud Rate Generator In modes where the USART is not using the XCK input as a clock source, the fractional Baud Rate Generator is used to generate the clock. Baud rate is given in terms of bits per second (bps) and is configured by writing the USARTn.BAUD register. The baud rate (fBAUD) is generated by dividing the peripheral clock (fCLK_PER) by a division factor decided by the BAUD register. The fractional Baud Rate Generator features hardware that accommodates cases where fCLK_PER is not divisible by fBAUD. Usually, this situation would lead to a rounding error. The fractional Baud Rate Generator expects the BAUD register to contain the desired division factor left shifted by six bits, as implemented by the equations in Table 24-1. The six Least Significant bits (LSbs) will then hold the fractional part of the desired divisor. Use the fractional part of the BAUD register to dynamically adjust fBAUD to achieve a closer approximation to the desired baud rate. Since the baud rate cannot be higher than fCLK_PER, the integer part of the BAUD register needs to be at least 1. Since the result is left shifted by six bits, the corresponding minimum value of the BAUD register is 64. The valid range is, therefore, 64 to 65535. In Synchronous mode, only the 10-bit integer part of the BAUD register (BAUD[15:6]) determines the baud rate, and the fractional part (BAUD[5:0]) must, therefore, be written to zero. The table below lists equations for translating baud rates into input values for the BAUD register. The equations consider fractional interpretation, so the BAUD values calculated with these equations can be written directly to USARTn.BAUD without any additional scaling. Table 24-1. Equations for Calculating Baud Rate Register Setting Operating Mode Asynchronous Synchronous Host Conditions Baud Rate (Bits Per Seconds) USART.BAUD Register Value Calculation fBAUD ≤ fCLK_PER 64 × fCLK_PER fBAUD = S S × BAUD BAUD = fBAUD ≤ fCLK_PER fCLK_PER fBAUD = S S × BAUD 15: 6 BAUD 15: 6 = USART.BAUD ≥ 64 USART.BAUD ≥ 64 © 2021 Microchip Technology Inc. Preliminary Datasheet 64 × fCLK_PER S × fBAUD fCLK_PER S × fBAUD DS40002311A-page 292 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... S is the number of samples per bit • Asynchronous Normal mode: S = 16 • Asynchronous Double-Speed mode: S = 8 • Synchronous mode: S = 2 24.3.2.3 Data Transmission The USART transmitter sends data by periodically driving the transmission line low. The data transmission is initiated by loading the Transmit Data (USARTn.TXDATAL and USARTn.TXDATAH) registers with the data to be sent. The data in the Transmit Data registers are moved to the TX Buffer once it is empty and onwards to the Shift register once it is empty and ready to send a new frame. After the Shift register is loaded with data, the data frame will be transmitted. When the entire frame in the Shift register has been shifted out, and there are no new data present in the Transmit Data registers or the TX Buffer, the Transmit Complete Interrupt Flag (the TXCIF bit in the USARTn.STATUS register) is set, and the interrupt is generated if it is enabled. The Transmit Data registers can only be written when the Data Register Empty Interrupt Flag (the DREIF bit in the USARTn.STATUS register) is set, indicating that they are empty and ready for new data. When using frames with fewer than eight bits, the Most Significant bits (MSb) written to the Transmit Data registers are ignored. When the Character Size (CHSIZE) bit field in the Control C (USARTn.CTRLC) register is configured to 9-bit (low byte first), the Transmit Data Register Low Byte (TXDATAL) must be written before the Transmit Data Register High Byte (TXDATAH). When CHSIZE is configured to 9-bit (high byte first), TXDATAH must be written before TXDATAL. 24.3.2.3.1 Disabling the Transmitter When disabling the transmitter, the operation will not become effective until ongoing and pending transmissions are completed. That is, when the Transmit Shift register, Transmit Data (USARTn.TXDATAL and USARTn.TXDATAH) registers, and TX Buffer register do not contain data to be transmitted. When the transmitter is disabled, it will no longer override the TXD pin, and the PORT module regains control of the pin. The pin is automatically configured as an input by hardware regardless of its previous setting. The pin can now be used as a normal I/O pin with no port override from the USART. 24.3.2.4 Data Reception The USART receiver samples the reception line to detect and interpret the received data. The direction of the pin must, therefore, be configured as an input by writing a ‘0’ to the corresponding bit in the Data Direction (PORTx.DIR) register. The receiver accepts data when a valid Start bit is detected. Each bit that follows the Start bit will be sampled at the baud rate or XCK clock and shifted into the Receive Shift register until the first Stop bit of a frame is received. A second Stop bit will be ignored by the receiver. When the first Stop bit is received, and a complete serial frame is present in the Receive Shift register, the contents of the Shift register will be moved into the receive buffer. The Receive Complete Interrupt Flag (the RXCIF bit in the USARTn.STATUS register) is set, and the interrupt is generated if enabled. The RXDATA registers are the part of the double-buffered RX buffer that can be read by the application software when RXCIF is set. If only one frame has been received, the data and status bits for that frame are pushed to the RXDATA registers directly. If two frames are present in the RX buffer, the RXDATA registers contain the data for the oldest frame. The buffer shifts out the data either when RXDATAL or RXDATAH is read, depending on the configuration. The register, which does not lead to data being shifted, must be read first to be able to read both bytes before shifting. When the Character Size (CHSIZE) bit field in the Control C (USARTn.CTRLC) register is configured to 9-bit (low byte first), a read of RXDATAH shifts the receive buffer. Otherwise, RXDATAL shifts the buffer. 24.3.2.4.1 Receiver Error Flags The USART receiver features error detection mechanisms that uncover any corruption of the transmission. These mechanisms include the following: • Frame Error detection - controls whether the received frame is valid • Buffer Overflow detection - indicates data loss due to the receiver buffer being full and overwritten by the new data © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 293 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... • Parity Error detection - checks the validity of the incoming frame by calculating its parity and comparing it to the Parity bit Each error detection mechanism controls one error flag that can be read in the RXDATAH register: • Frame Error (FERR) • Buffer Overflow (BUFOVF) • Parity Error (PERR) The error flags are located in the RX buffer together with their corresponding frame. The RXDATAH register that contains the error flags must be read before the RXDATAL register since reading the RXDATAL register will trigger the RX buffer to shift out the RXDATA bytes. Note:  If the Character Size (CHSIZE) bit field in the Control C (USARTn.CTRLC) register is set to nine bits, low byte first (9BITL), the RXDATAH register will, instead of the RXDATAL register, trigger the RX buffer to shift out the RXDATA bytes. The RXDATAL register must, in that case, be read before the RXDATAH register. 24.3.2.4.2 Disabling the Receiver When disabling the receiver, the operation is immediate. The receiver buffer will be flushed, and data from ongoing receptions will be lost. 24.3.2.4.3 Flushing the Receive Buffer If the RX buffer has to be flushed during normal operation, repeatedly read the DATA location (USARTn.RXDATAH and USARTn.RXDATAL registers) until the Receive Complete Interrupt Flag (the RXCIF bit in the USARTn.RXDATAH register) is cleared. 24.3.3 Communication Modes The USART is a flexible peripheral that supports multiple different communication protocols. The available modes of operation can be split into two groups: Synchronous and asynchronous communication. The synchronous communication relies on one device on the bus to be the host, providing the rest of the devices with a clock signal through the XCK pin. All the devices use this common clock signal for both transmission and reception, requiring no additional synchronization mechanism. The device can be configured to run either as a host or a client on the synchronous bus. The asynchronous communication does not use a common clock signal. Instead, it relies on the communicating devices to be configured with the same baud rate. When receiving a transmission, the hardware synchronization mechanisms are used to align the incoming transmission with the receiving device peripheral clock. Four different modes of reception are available when communicating asynchronously. One of these modes can receive transmissions at twice the normal speed, sampling only eight times per bit instead of the normal 16. The other three operating modes use variations of synchronization logic, all receiving at normal speed. 24.3.3.1 Synchronous Operation 24.3.3.1.1 Clock Operation The XCK pin direction controls whether the transmission clock is an input (Client mode) or an output (Host mode). The corresponding port pin direction must be set to output for Host mode or input for Client mode (PORTx.DIRn). The data input (on RXD) is sampled at the XCK clock edge, which is opposite the edge where data are transmitted (on TXD), as shown in the figure below. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 294 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-4. Synchronous Mode XCK Timing XCK INVEN = 0 Data transmit (TxD) Data sample (RxD) XCK INVEN = 1 Data transmit (TxD) Data sample (RxD) The I/O pin can be inverted by writing a ‘1’ to the Inverted I/O Enable (INVEN) bit in the Pin n Control register of the port peripheral (PORTx.PINnCTRL). When using the inverted I/O setting for the corresponding XCK port pin, the XCK clock edges used for sampling RxD and transmitting on TxD can be selected. If the inverted I/O is disabled (INVEN = 0), the rising XCK clock edge represents the start of a new data bit, and the received data will be sampled at the falling XCK clock edge. If inverted I/O is enabled (INVEN = 1), the falling XCK clock edge represents the start of a new data bit, and the received data will be sampled at the rising XCK clock edge. 24.3.3.1.2 External Clock Limitations When the USART is configured in Synchronous Client mode, the XCK signal must be provided externally by the host device. Since the clock is provided externally, configuring the BAUD register will have no impact on the transfer speed. Successful clock recovery requires the clock signal to be sampled at least twice for each rising and falling edge. The maximum XCK speed in Synchronous Operation mode, fClient_XCK, is therefore limited by: fClient_XCK< fCLK_PER 4 If the XCK clock has jitter, or if the high/low period duty cycle is not 50/50, the maximum XCK clock speed must be reduced accordingly to ensure that XCK is sampled a minimum of two times for each edge. 24.3.3.1.3 USART in Host SPI Mode The USART may be configured to function with multiple different communication interfaces, and one of these is the Serial Peripheral Interface (SPI), where it can work as the host device. The SPI is a four-wire interface that enables a host device to communicate with one or multiple clients. Frame Formats The serial frame for the USART in Host SPI mode always contains eight Data bits. The Data bits can be configured to be transmitted with either the LSb or MSb first by writing to the Data Order (UDORD) bit in the Control C (USARTn.CTRLC) register. SPI does not use Start, Stop, or Parity bits, so the transmission frame can only consist of the Data bits. Clock Generation Being a host device in a synchronous communication interface, the USART in Host SPI mode must generate the interface clock to be shared with the client devices. The interface clock is generated using the fractional Baud Rate Generator, which is described in 24.3.2.2.1 The Fractional Baud Rate Generator. Each Data bit is transmitted by pulling the data line high or low for one full clock period. The receiver will sample bits in the middle of the transmitter hold period, as shown in the figure below. It also shows how the timing scheme can be configured using the Inverted I/O Enable (INVEN) bit in the PORTx.PINnCTRL register and the USART Clock Phase (UCPHA) bit in the USARTn.CTRLC register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 295 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... UCPHA = 1 UCPHA = 0 Figure 24-5. Data Transfer Timing Diagrams INVEN = 0 INVEN = 1 XCK XCK Data transmit (TxD) Data transmit (TxD) Data sample (RxD) Data sample (RxD) XCK XCK Data transmit (TxD) Data transmit (TxD) Data sample (RxD) Data sample (RxD) The table below further explains the figure above. Table 24-2. Functionality of the INVEN and UCPHA Bits INVEN UCPHA Leading Edge (1) Trailing Edge (1) 0 0 Rising, sample Falling, transmit 0 1 Rising, transmit Falling, sample 1 0 Falling, sample Rising, transmit 1 1 Falling, transmit Rising, sample Note:  1. The leading edge is the first clock edge of a clock cycle. The trailing edge is the last clock edge of a clock cycle. Data Transmission Data transmission in Host SPI mode is functionally identical to the general USART operation, as described in the Operation section. The transmitter interrupt flags and corresponding USART interrupts are also identical. See 24.3.2.3 Data Transmission for further description. Data Reception Data reception in Host SPI mode is identical in function to general USART operation as described in the Operation section. The receiver interrupt flags and the corresponding USART interrupts are also identical, except for the receiver error flags that are not in use and always read as ‘0’. See 24.3.2.4 Data Reception for further description. USART in Host SPI Mode vs. SPI The USART in Host SPI mode is fully compatible with a stand-alone SPI peripheral. Their data frame and timing configurations are identical. Some SPI specific special features are, however, not supported with the USART in Host SPI mode: • Write Collision Flag Protection • Double-Speed mode • Multi-Host support A comparison of the pins used with USART in Host SPI mode and with SPI is shown in the table below. Table 24-3. Comparison of USART in Host SPI Mode and SPI Pins USART SPI Comment TXD MOSI Host out RXD MISO Host in © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 296 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... ...........continued USART SPI Comment XCK SCK Functionally identical - SS Not supported by USART in Host SPI mode(1) Note:  1. For the stand-alone SPI peripheral, this pin is used with the Multi-Host function or as a dedicated Client Select pin. The Multi-Host function is not available with the USART in Host SPI mode, and no dedicated Client Select pin is available. 24.3.3.2 Asynchronous Operation 24.3.3.2.1 Clock Recovery Since there is no common clock signal when using Asynchronous mode, each communicating device generates separate clock signals. These clock signals must be configured to run at the same baud rate for the communication to take place. The devices, therefore, run at the same speed, but their timing is skewed in relation to each other. To accommodate this, the USART features a hardware clock recovery unit which synchronizes the incoming asynchronous serial frames with the internally generated baud rate clock. The figure below illustrates the sampling process for the Start bit of an incoming frame. It shows the timing scheme for both Normal and Double-Speed mode (the RXMODE bit field in the USARTn.CTRLB register configured respectively to 0x00 and 0x01). The sample rate for Normal mode is 16 times the baud rate, while the sample rate for Double-Speed mode is eight times the baud rate (see 24.3.3.2.4 Double-Speed Operation for more details). The horizontal arrows show the maximum synchronization error. Note that the maximum synchronization error is larger in Double-Speed mode. Figure 24-6. Start Bit Sampling RxD IDLE START BIT 0 Sample (RXMODE = 0x0 ) 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 2 3 Sample (RXMODE = 0x1 ) 0 1 2 3 4 5 6 7 8 1 2 When the clock recovery logic detects a falling edge from the Idle (high) state to the Start bit (low), the Start bit detection sequence is initiated. In the figure above, sample 1 denotes the first sample reading ‘0’. The clock recovery logic then uses three subsequent samples (samples 8, 9, and 10 in Normal mode, and samples 4, 5, 6 in Double-Speed mode) to decide if a valid Start bit is received. If two or three samples read ‘0’, the Start bit is accepted. The clock recovery unit is synchronized, and the data recovery can begin. If less than two samples read ‘0’, the Start bit is rejected. This process is repeated for each Start bit. 24.3.3.2.2 Data Recovery As with clock recovery, the data recovery unit samples at a rate 8 or 16 times faster than the baud rate depending on whether it is running in Double-Speed or Normal mode, respectively. The figure below shows the sampling process for reading a bit in a received frame. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 297 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-7. Sampling of Data and Parity Bits RxD BIT n Sample 1 (CLK2X = 0) 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 Sample 1 (CLK2X = 1) 2 3 4 5 6 7 8 1 A majority voting technique is, like with clock recovery, used on the three center samples for deciding the logic level of the received bit. The process is repeated for each bit until a complete frame is received. The data recovery unit will only receive the first Stop bit while ignoring the rest if there are more. If the sampled Stop bit is read ‘0’, the Frame Error flag will be set. The figure below shows the sampling of a Stop bit. It also shows the earliest possible beginning of the next frame's Start bit. Figure 24-8. Stop Bit and Next Start Bit Sampling RxD STOP 1 (A) (B) (C) Sample 1 (CLK2X = 0) 2 3 4 5 6 7 8 9 10 0/1 0/1 0/1 Sample 1 (CLK2X = 1) 2 3 4 5 6 0/1 A new high-to-low transition indicating the Start bit of a new frame can come right after the last of the bits used for majority voting. For Normal-Speed mode, the first low-level sample can be at the point marked (A) in the figure above. For Double-Speed mode, the first low level must be delayed to point (B), being the first sample after the majority vote samples. Point (C) marks a Stop bit of full length at the nominal baud rate. 24.3.3.2.3 Error Tolerance The speed of the internally generated baud rate and the externally received data rate has to be identical, but, due to natural clock source error, this is usually not the case. The USART is tolerant of such error, and the limits of this tolerance make up what is sometimes known as the Operational Range. The following tables list the operational range of the USART, being the maximum receiver baud rate error that can be tolerated. Note that Normal-Speed mode has higher toleration of baud rate variations than Double-Speed mode. Table 24-4. Recommended Maximum Receiver Baud Rate Error for Normal-Speed Mode D Rslow [%] Rfast [%] Maximum Total Error [%] Recommended Max. Receiver Error [%] 5 93.20 106.67 -6.80/+6.67 ±3.0 6 94.12 105.79 -5.88/+5.79 ±2.5 7 94.81 105.11 -5.19/+5.11 ±2.0 8 95.36 104.58 -4.54/+4.58 ±2.0 9 95.81 104.14 -4.19/+4.14 ±1.5 10 96.17 103.78 -3.83/+3.78 ±1.5 Notes:  • D: The sum of character size and parity size (D = 5 to 10 bits) • RSLOW: The ratio of the slowest incoming data rate that can be accepted in relation to the receiver baud rate • RFAST: The ratio of the fastest incoming data rate that can be accepted in relation to the receiver baud rate © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 298 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Table 24-5. Recommended Maximum Receiver Baud Rate Error for Double-Speed Mode D Rslow [%] Rfast [%] Maximum Total Error [%] Recommended Max. Receiver Error [%] 5 94.12 105.66 -5.88/+5.66 ±2.5 6 94.92 104.92 -5.08/+4.92 ±2.0 7 95.52 104.35 -4.48/+4.35 ±1.5 8 96.00 103.90 -4.00/+3.90 ±1.5 9 96.39 103.53 -3.61/+3.53 ±1.5 10 96.70 103.23 -3.30/+3.23 ±1.0 Notes:  • D: The sum of character size and parity size (D = 5 to 10 bits) • RSLOW: The ratio of the slowest incoming data rate that can be accepted in relation to the receiver baud rate • RFAST: The ratio of the fastest incoming data rate that can be accepted in relation to the receiver baud rate The recommendations of the maximum receiver baud rate error were made under the assumption that the receiver and transmitter equally divide the maximum total error. The following equations are used to calculate the maximum ratio of the incoming data rate and the internal receiver baud rate. RSLOW = • • • • • • S D+1 S D + 1 + SF − 1 RFAST = S D+2 S D + 1 + SM D: The sum of character size and parity size (D = 5 to 10 bits) S: Samples per bit. S = 16 for Normal-Speed mode and S = 8 for Double-Speed mode. SF: First sample number used for majority voting. SF = 8 for Normal-Speed mode and SF = 4 for Double-Speed mode. SM: Middle sample number used for majority voting. SM = 9 for Normal-Speed mode and SM = 5 for DoubleSpeed mode. RSLOW: The ratio of the slowest incoming data rate that can be accepted in relation to the receiver baud rate RFAST: The ratio of the fastest incoming data rate that can be accepted in relation to the receiver baud rate 24.3.3.2.4 Double-Speed Operation The double-speed operation allows for higher baud rates under asynchronous operation with lower peripheral clock frequencies. This operation mode is enabled by writing the RXMODE bit field in the Control B (USARTn.CTRLB) register to 0x01. When enabled, the baud rate for a given asynchronous baud rate setting will be doubled, as shown in the equations in 24.3.2.2.1 The Fractional Baud Rate Generator. In this mode, the receiver will use half the number of samples (reduced from 16 to 8) for data sampling and clock recovery. This requires a more accurate baud rate setting and peripheral clock. See 24.3.3.2.3 Error Tolerance for more details. 24.3.3.2.5 Auto-Baud The auto-baud feature lets the USART configure its BAUD register based on input from a communication device, which allows the device to communicate autonomously with multiple devices communicating with different baud rates. The USART peripheral features two auto-baud modes: Generic Auto-Baud mode and LIN Constrained AutoBaud mode. Both auto-baud modes must receive an auto-baud frame, as seen in the figure below. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 299 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-9. Auto-Baud Timing Break Field Sync Field Tbit 8 Tbit The break field is detected when 12 or more consecutive low cycles are sampled and notifies the USART that it is about to receive the synchronization field. After the break field, when the Start bit of the synchronization field is detected, a counter running at the peripheral clock speed is started. The counter is then incremented for the next eight Tbit of the synchronization field. When all eight bits are sampled, the counter is stopped. The resulting counter value is in effect the new BAUD register value. When the USART Receive mode is set to GENAUTO (the RXMODE bit field in the USARTn.CTRLB register), the Generic Auto-Baud mode is enabled. In this mode, one can set the Wait For Break (WFB) bit in the USARTn.STATUS register to enable detection of a break field of any length (that is, also shorter than 12 cycles). This makes it possible to set an arbitrary new baud rate without knowing the current baud rate. If the measured sync field results in a valid BAUD value (0x0064 - 0xFFFF), the BAUD register is updated. When USART Receive mode is set to LINAUTO mode (the RXMODE bit field in the USARTn.CTRLB register), it follows the LIN format. The WFB functionality of the Generic Auto-Baud mode is not compatible with the LIN Constrained Auto-Baud mode, which means that the received signal must be low for 12 peripheral clock cycles or more for a break field to be valid. When a break field has been detected, the USART expects the following synchronization field character to be 0x55. If the received synchronization field character is not 0x55, the Inconsistent Sync Field Error Flag (the ISFIF bit in the USARTn.STATUS register) is set, and the baud rate is unchanged. 24.3.3.2.6 Half-Duplex Operation Half-duplex is a type of communication where two or more devices may communicate with each other, but only one at a time. The USART can be configured to operate in the following half-duplex modes: • One-Wire mode • RS-485 mode One-Wire Mode One-Wire mode is enabled by setting the Loop-Back Mode Enable (LBME) bit in the USARTn.CTRLA register. This will enable an internal connection between the TXD pin and the USART receiver, making the TXD pin a combined TxD/RxD line. The RXD pin will be disconnected from the USART receiver and may be controlled by a different peripheral. In One-Wire mode, multiple devices can manipulate the TxD/RxD line at the same time. In the case where one device drives the pin to a logical high level (VCC), and another device pulls the line low (GND), a short will occur. To accommodate this, the USART features an Open-Drain mode (the ODME bit in the USARTn.CTRLB register), which prevents the transmitter from driving a pin to a logical high level, thereby constraining it to only be able to pull it low. Combining this function with the internal pull-up feature (the PULLUPEN bit in the PORTx.PINnCTRL register) will let the line be held high through a pull-up resistor, allowing any device to pull it low. When the line is pulled low, the current from VCC to GND will be limited by the pull-up resistor. The TXD pin is automatically set to output by hardware when the Open-Drain mode is enabled. When the USART is transmitting to the TxD/RxD line, it will also receive its transmission. This can be used to detect overlapping transmissions by checking if the received data are the same as the transmitted data. RS-485 Mode RS-485 is a communication standard supported by the USART peripheral. It is a physical interface that defines the setup of a communication circuit. Data are transmitted using differential signaling, making communication robust against noise. RS-485 is enabled by writing the RS485 bit in the USARTn.CTRLA register to ‘1’. The RS-485 mode supports external line driver devices that convert a single USART transmission into corresponding differential pair signals. It implements automatic control of the XDIR pin that can be used to enable transmission or reception for the line driver device. The USART automatically drives the XDIR pin high while the USART is transmitting and pulls it low when the transmission is complete. An example of such a circuit is shown in the figure below. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 300 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-10. RS-485 Bus Connection Line Driver TXD TX Driver XDIR Differential Bus + - USART RX Driver RXD The XDIR pin goes high one baud clock cycle in advance of data being shifted out to allow some guard time to enable the external line driver. The XDIR pin will remain high for the complete frame, including Stop bit(s). Figure 24-11. XDIR Drive Timing TxD St 0 1 2 3 4 5 6 7 Sp1 XDIR Guard time Stop RS-485 mode is compatible with One-Wire mode. One-Wire mode enables an internal connection between the TXD pin and the USART receiver, making the TXD pin a combined TxD/RxD line. The RXD pin will be disconnected from the USART receiver and may be controlled by a different peripheral. An example of such a circuit is shown in the figure below. Figure 24-12. RS-485 with Loop-Back Mode Connection TXD Line Driver TX Driver XDIR Differential Bus + - USART RXD RX Driver 24.3.3.2.7 IRCOM Mode of Operation The USART peripheral can be configured in Infrared Communication mode (IRCOM), which is IrDA® 1.4 compatible with baud rates up to 115.2 kbps. When enabled, the IRCOM mode enables infrared pulse encoding/decoding for the USART. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 301 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-13. Block Diagram IRCOM Event System Events Encoded RxD Pulse Decoding Decoded RxD USART TXD Decoded RxD Pulse Encoding RXD Encoded RxD The USART is set in IRCOM mode by writing 0x02 to the CMODE bit field in the USARTn.CTRLC register. The data on the TXD/RXD pins are the inverted values of the transmitted/received infrared pulse. It is also possible to select an event channel from the Event System as an input for the IRCOM receiver. This enables the IRCOM to receive input from the I/O pins or sources other than the corresponding RXD pin, which will disable the RxD input from the USART pin. For transmission, three pulse modulation schemes are available: • • • 3/16 of the baud rate period Fixed programmable pulse time based on the peripheral clock frequency Pulse modulation disabled For the reception, a fixed programmable minimum high-level pulse-width for the pulse to be decoded as a logical ‘0’ is used. Shorter pulses will then be discarded, and the bit will be decoded to logical ‘1’ as if no pulse was received. Double-Speed mode cannot be used for the USART when IRCOM mode is enabled. 24.3.4 Additional Features 24.3.4.1 Parity Parity bits can be used by the USART to check the validity of a data frame. The Parity bit is set by the transmitter based on the number of bits with the value of ‘1’ in a transmission and controlled by the receiver upon reception. If the Parity bit is inconsistent with the transmission frame, the receiver may assume that the data frame has been corrupted. Even or odd parity can be selected for error checking by writing the Parity Mode (PMODE) bit field in the USARTn.CTRLC register. If even parity is selected, the Parity bit is set to ‘1’ if the number of Data bits with value ‘1’ is odd (making the total number of bits with value ‘1’ even). If odd parity is selected, the Parity bit is set to ‘1’ if the number of data bits with value ‘1’ is even (making the total number of bits with value ‘1’ odd). When enabled, the parity checker calculates the parity of the data bits in incoming frames and compares the result with the Parity bit of the corresponding frame. If a parity error is detected, the Parity Error flag (the PERR bit in the USARTn.RXDATAH register) is set. If LIN Constrained Auto-Baud mode is enabled (RXMODE = 0x03 in the USARTn.CTRLB register), a parity check is performed only on the protected identifier field. A parity error is detected if one of the equations below is not true, which sets the Parity Error flag. P0 = ID0 XOR ID1 XOR ID2 XOR ID4 P1 = NOT ID1 XOR ID3 XOR ID4 XOR ID5 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 302 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Figure 24-14. Protected Identifier Field and Mapping of Identifier and Parity Bits Protected identifier field St ID0 ID1 ID2 ID3 ID4 ID5 P0 P1 Sp 24.3.4.2 Start-of-Frame Detection The Start-of-Frame Detection feature enables the USART to wake up from Standby sleep mode upon data reception. When a high-to-low transition is detected on the RXD pin, the oscillator is powered up, and the USART peripheral clock is enabled. After start-up, the rest of the data frame can be received, provided that the baud rate is slow enough concerning the oscillator start-up time. The start-up time of the oscillators varies with supply voltage and temperature. For details on oscillator start-up time characteristics, refer to the Electrical Characteristics section. If a false Start bit is detected, the device will, if another wake-up source has not been triggered, go back into the Standby sleep mode. The Start-of-Frame detection works in Asynchronous mode only. It is enabled by writing the Start-of-Frame Detection Enable (SFDEN) bit in the USARTn.CTRLB register. If a Start bit is detected while the device is in Standby sleep mode, the USART Receive Start Interrupt Flag (RXSIF) bit is set. The USART Receive Complete Interrupt Flag (RXCIF) bit and the RXSIF bit share the same interrupt line, but each has its dedicated interrupt settings. The table below shows the USART Start Frame Detection modes, depending on the interrupt setting. Table 24-6. USART Start Frame Detection Modes SFDEN RXSIF Interrupt RXCIF Interrupt Comment 0 x x Standard mode 1 Disabled Disabled Only the oscillator is powered during the frame reception. If the interrupts are disabled and buffer overflow is ignored, all incoming frames will be lost 1 Disabled Enabled System/all clocks are awakened on Receive Complete interrupt 1 Enabled x System/all clocks are awakened when a Start bit is detected Note:  The SLEEP instruction will not shut down the oscillator if there is ongoing communication. 24.3.4.3 Multiprocessor Communication The Multiprocessor Communication mode (MPCM) effectively reduces the number of incoming frames that have to be handled by the receiver in a system with multiple microcontrollers communicating via the same serial bus. This mode is enabled by writing a ‘1’ to the MPCM bit in the Control B (USARTn.CTRLB) register. In this mode, a dedicated bit in the frames is used to indicate whether the frame is an address or data frame type. If the receiver is set up to receive frames that contain five to eight data bits, the first Stop bit is used to indicate the frame type. If the receiver is set up for frames with nine data bits, the ninth bit is used to indicate frame type. When the frame type bit is ‘1’, the frame contains an address. When the frame type bit is ‘0’, the frame is a data frame. If 5to 8-bit character frames are used, the transmitter must be set to use two Stop bits since the first Stop bit is used for indicating the frame type. If a particular client MCU has been addressed, it will receive the following data frames as usual, while the other client MCUs will ignore the frames until another address frame is received. 24.3.4.3.1 Using Multiprocessor Communication Use the following procedure to exchange data in Multiprocessor Communication mode (MPCM): 1. 2. 3. All client MCUs are in Multiprocessor Communication mode. The host MCU sends an address frame, and all clients receive and read this frame. Each client MCU determines if it has been selected. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 303 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 4. The addressed MCU will disable MPCM and receive all data frames. The other client MCUs will ignore the data frames. When the addressed MCU has received the last data frame, it must enable MPCM again and wait for a new address frame from the host. 5. The process then repeats from step 2. 24.3.5 Events The USART can generate the events described in the table below. Table 24-7. Event Generators in USART Generator Name Description Peripheral Event USARTn XCK The clock signal in SPI Host mode and Synchronous USART Host mode Event Type Generating Clock Domain Length of Event Pulse CLK_PER One XCK period The table below describes the event user and its associated functionality. Table 24-8. Event Users in USART User Name 24.3.6 Peripheral Input USARTn IREI Description USARTn IrDA event input Input Detection Async/Sync Pulse Sync Interrupts Table 24-9. Available Interrupt Vectors and Sources Name Vector Description Conditions RXC Receive Complete interrupt • • • There is unread data in the receive buffer (RXCIE) Receive of Start-of-Frame detected (RXSIE) Auto-Baud Error/ISFIF flag set (ABEIE) DRE Data Register Empty interrupt The transmit buffer is empty/ready to receive new data (DREIE) TXC Transmit Complete interrupt The entire frame in the Transmit Shift register has been shifted out and there are no new data in the transmit buffer (TXCIE) When an Interrupt condition occurs, the corresponding Interrupt flag is set in the STATUS (USARTn.STATUS) register. An interrupt source is enabled or disabled by writing to the corresponding bit in the Control A (USARTn.CTRLA) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the Interrupt flag is set. The interrupt request remains active until the Interrupt flag is cleared. See the USARTn.STATUS register for details on how to clear Interrupt flags. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 304 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x07 RXDATAL RXDATAH TXDATAL TXDATAH STATUS CTRLA CTRLB CTRLC CTRLC 0x08 BAUD 0x0A 0x0B 0x0C 0x0D 0x0E CTRLD DBGCTRL EVCTRL TXPLCTRL RXPLCTRL 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 15:8 7:0 7:0 7:0 7:0 7:0 24.5 7 6 RXCIF BUFOVF 5 4 3 2 1 0 FERR PERR DATA[8] DATA[7:0] DATA[7:0] RXCIF TXCIF RXCIE TXCIE RXEN TXEN CMODE[1:0] CMODE[1:0] DREIF DREIE RXSIF RXSIE SFDEN PMODE[1:0] ISFIF LBME ODME SBMODE BDF ABEIE RXMODE[1:0] CHSIZE[2:0] UDORD UCPHA DATA[8] WFB RS485 MPCM BAUD[7:0] BAUD[15:8] ABW[1:0] DBGRUN IREI TXPL[7:0] RXPL[6:0] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 305 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.1 Receiver Data Register Low Byte Name:  Offset:  Reset:  Property:  RXDATAL 0x00 0x00 - This register contains the eight LSbs of the data received by the USART receiver. The USART receiver is doublebuffered, and this register always represents the data for the oldest received frame. If the data for only one frame is present in the receive buffer, this register contains that data. The buffer shifts out the data either when RXDATAL or RXDATAH is read, depending on the configuration. The register, which does not lead to data being shifted, must be read first to be able to read both bytes before shifting. When the Character Size (CHSIZE) bit field in the Control C (USARTn.CTRLC) register is configured to 9-bit (low byte first), a read of RXDATAH shifts the receive buffer, or else, RXDATAL shifts the buffer. Bit 7 6 5 4 3 2 1 0 R 0 R 0 R 0 R 0 DATA[7:0] Access Reset R 0 R 0 R 0 R 0 Bits 7:0 – DATA[7:0] Receiver Data Register © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 306 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.2 Receiver Data Register High Byte Name:  Offset:  Reset:  Property:  RXDATAH 0x01 0x00 - This register contains the MSb of the data received by the USART receiver, as well as status bits reflecting the status of the received data frame. The USART receiver is double-buffered, and this register always represents the data and status bits for the oldest received frame. If the data and status bits for only one frame is present in the receive buffer, this register contains that data. The buffer shifts out the data either when RXDATAL or RXDATAH is read, depending on the configuration. The register, which does not lead to data being shifted, must be read first to be able to read both bytes before shifting. When the Character Size (CHSIZE) bits in the Control C (USARTn.CTRLC) register is configured to 9-bit (low byte first), a read of RXDATAH shifts the receive buffer, or else, RXDATAL shifts the buffer. Bit Access Reset 7 RXCIF R 0 6 BUFOVF R 0 5 4 3 2 FERR R 0 1 PERR R 0 0 DATA[8] R 0 Bit 7 – RXCIF USART Receive Complete Interrupt Flag This flag is set when there are unread data in the receive buffer and cleared when the receive buffer is empty. Bit 6 – BUFOVF Buffer Overflow This flag is set if a buffer overflow is detected. A buffer overflow occurs when the receive buffer is full, a new frame is waiting in the receive shift register, and a new Start bit is detected. This flag is cleared when the Receiver Data (USARTn.RXDATAL and USARTn.RXDATAH) registers are read. This flag is not used in the Host SPI mode of operation. Bit 2 – FERR Frame Error This flag is set if the first Stop bit is ‘0’ and cleared when it is correctly read as ‘1’. This flag is not used in the Host SPI mode of operation. Bit 1 – PERR Parity Error This flag is set if parity checking is enabled and the received data has a parity error, or else, this flag cleared. For details on parity calculation, refer to 24.3.4.1 Parity. This flag is not used in the Host SPI mode of operation. Bit 0 – DATA[8] Receiver Data Register When using a 9-bit frame size, this bit holds the ninth bit (MSb) of the received data. When the Receiver Mode (RXMODE) bit field in the Control B (USARTn.CTRLB) register is configured to LIN Constrained Auto-Baud (LINAUTO) mode, this bit indicates if the received data are within the response space of a LIN frame. This bit is cleared if the received data are in the protected identifier field and is otherwise set. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 307 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.3 Transmit Data Register Low Byte Name:  Offset:  Reset:  Property:  TXDATAL 0x02 0x00 - The data written to this register is automatically loaded into the TX Buffer and through to the dedicated Shift register. The shift register outputs each of the bits serially to the TXD pin. When using a 9-bit frame size, the ninth bit (MSb) must be written to the Transmit Data Register High Byte (USARTn.TXDATAH). In that case, the buffer shifts data either when the Transmit Data Register Low Byte (USARTn.TXDATAL) or the Transmit Data Register High Byte (USARTn.TXDATAH) is written, depending on the configuration. The register, which does not lead to data being shifted, must be written first to be able to write both registers before shifting. When the Character Size (CHSIZE) bit field in the Control C (USARTn.CTRLC) register is configured to 9-bit (low byte first), a write of the Transmit Data Register High Byte shifts the transmit buffer. Otherwise, the Transmit Data Register Low Byte shifts the buffer. This register may only be written when the Data Register Empty Interrupt Flag (DREIF) in the Status (USARTn.STATUS) register is set. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 DATA[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DATA[7:0] Transmit Data Register Low Byte © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 308 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.4 Transmit Data Register High Byte Name:  Offset:  Reset:  Property:  TXDATAH 0x03 0x00 - The data written to this register is automatically loaded into the TX Buffer and through to the dedicated Shift register. The shift register outputs each of the bits serially to the TXD pin. When using a 9-bit frame size, the ninth bit (MSb) must be written to the Transmit Data Register High Byte (USARTn.TXDATAH). In that case, the buffer shifts data either when the Transmit Data Register Low Byte (USARTn.TXDATAL) or the Transmit Data Register High Byte (USARTn.TXDATAH) is written, depending on the configuration. The register, which does not lead to data being shifted, must be written first to be able to write both registers before shifting. When the Character Size (CHSIZE) bit field in the Control C (USARTn.CTRLC) register is configured to 9-bit (low byte first), a write of the Transmit Data Register High Byte shifts the transmit buffer. Otherwise, the Transmit Data Register Low Byte shifts the buffer. This register may only be written when the Data Register Empty Interrupt Flag (DREIF) in the Status (USARTn.STATUS) register is set. Bit 7 6 5 4 3 Access Reset 2 1 0 DATA[8] R/W 0 Bit 0 – DATA[8] Transmit Data Register High Byte © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 309 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.5 USART Status Register Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RXCIF R 0 STATUS 0x04 0x00 - 6 TXCIF R/W 0 5 DREIF R 1 4 RXSIF R/W 0 3 ISFIF R/W 0 2 1 BDF R/W 0 0 WFB W 0 Bit 7 – RXCIF USART Receive Complete Interrupt Flag This flag is set when there are unread data in the receive buffer and cleared when the receive buffer is empty. Bit 6 – TXCIF USART Transmit Complete Interrupt Flag This flag is set when the entire frame in the Transmit Shift register has been shifted out, and there are no new data in the transmit buffer (TXDATAL and TXDATAH) registers. It is cleared by writing a ‘1’ to it. Bit 5 – DREIF USART Data Register Empty Interrupt Flag This flag is set when the Transmit Data (USARTn.TXDATAL and USARTn.TXDATAH) registers are empty and cleared when they contain data that has not yet been moved into the transmit shift register. Bit 4 – RXSIF USART Receive Start Interrupt Flag This flag is set when Start-of-Frame detection is enabled, the device is in Standby sleep mode, and a valid start bit is detected. It is cleared by writing a ‘1’ to it. This flag is not used in the Host SPI mode operation. Bit 3 – ISFIF Inconsistent Synchronization Field Interrupt Flag This flag is set if an auto-baud mode is enabled, and the synchronization field is too short or too long to give a valid baud setting. It will also be set when USART is set to LINAUTO mode, and the SYNC character differs from data value 0x55. This flag is cleared by writing a ‘1’ to it. See the Auto-Baud section for more information. Bit 1 – BDF Break Detected Flag This flag is set if an auto-baud mode is enabled and a valid break and synchronization character is detected, and is cleared when the next data are received. It can also be cleared by writing a ‘1’ to it. See the Auto-Baud section for more information. Bit 0 – WFB Wait For Break This bit controls whether the Wait For Break feature is enabled or not. Refer to the Auto-Baud section for more information. Value Description 0 Wait For Break is disabled 1 Wait For Break is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 310 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.6 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RXCIE R/W 0 CTRLA 0x05 0x00 - 6 TXCIE R/W 0 5 DREIE R/W 0 4 RXSIE R/W 0 3 LBME R/W 0 2 ABEIE R/W 0 1 0 RS485 R/W 0 Bit 7 – RXCIE Receive Complete Interrupt Enable This bit controls whether the Receive Complete Interrupt is enabled or not. When enabled, the interrupt will be triggered when the RXCIF bit in the USARTn.STATUS register is set. Value Description 0 The Receive Complete Interrupt is disabled 1 The Receive Complete Interrupt is enabled Bit 6 – TXCIE Transmit Complete Interrupt Enable This bit controls whether the Transmit Complete Interrupt is enabled or not. When enabled, the interrupt will be triggered when the TXCIF bit in the USARTn.STATUS register is set. Value Description 0 The Transmit Complete Interrupt is disabled 1 The Transmit Complete Interrupt is enabled Bit 5 – DREIE Data Register Empty Interrupt Enable This bit controls whether the Data Register Empty Interrupt is enabled or not. When enabled, the interrupt will be triggered when the DREIF bit in the USARTn.STATUS register is set. Value Description 0 The Data Register Empty Interrupt is disabled 1 The Data Register Empty Interrupt is enabled Bit 4 – RXSIE Receiver Start Frame Interrupt Enable This bit controls whether the Receiver Start Frame Interrupt is enabled or not. When enabled, the interrupt will be triggered when the RXSIF bit in the USARTn.STATUS register is set. Value Description 0 The Receiver Start Frame Interrupt is disabled 1 The Receiver Start Frame Interrupt is enabled Bit 3 – LBME Loop-Back Mode Enable This bit controls whether the Loop-back mode is enabled or not. When enabled, an internal connection between the TXD pin and the USART receiver is created, and the input from the RXD pin to the USART receiver is disconnected. Value Description 0 Loop-back mode is disabled 1 Loop-back mode is enabled Bit 2 – ABEIE Auto-Baud Error Interrupt Enable This bit controls whether the Auto-baud Error Interrupt is enabled or not. When enabled, the interrupt will be triggered when the ISFIF bit in the USARTn.STATUS register is set. Value Description 0 The Auto-Baud Error Interrupt is disabled 1 The Auto-Baud Error Interrupt is enabled Bit 0 – RS485 RS-485 Mode This bit controls whether the RS-485 mode is enabled or not. Refer to section RS-485 Mode for more information. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 311 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Value 0 1 Description RS-485 mode is disabled RS-485 mode is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 312 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.7 Control B Name:  Offset:  Reset:  Property:  Bit 7 RXEN R/W 0 Access Reset CTRLB 0x06 0x00 - 6 TXEN R/W 0 5 4 SFDEN R/W 0 3 ODME R/W 0 2 1 RXMODE[1:0] R/W R/W 0 0 0 MPCM R/W 0 Bit 7 – RXEN Receiver Enable This bit controls whether the USART receiver is enabled or not. Refer to 24.3.2.4.2 Disabling the Receiver for more information. Value Description 0 The USART receiver is disabled 1 The USART receiver is enabled Bit 6 – TXEN Transmitter Enable This bit controls whether the USART transmitter is enabled or not. Refer to 24.3.2.3.1 Disabling the Transmitter for more information. Value Description 0 The USART transmitter is disabled 1 The USART transmitter is enabled Bit 4 – SFDEN Start-of-Frame Detection Enable This bit controls whether the USART Start-of-Frame Detection mode is enabled or not. Refer to 24.3.4.2 Start-ofFrame Detection for more information. Value Description 0 The USART Start-of-Frame Detection mode is disabled 1 The USART Start-of-Frame Detection mode is enabled Bit 3 – ODME Open Drain Mode Enable This bit controls whether Open Drain mode is enabled or not. See the One-Wire Mode section for more information. Value Description 0 Open Drain mode is disabled 1 Open Drain mode is enabled Bits 2:1 – RXMODE[1:0] Receiver Mode Writing this bit field selects the receiver mode of the USART. • Writing the bits to 0x00 enables Normal-Speed (NORMAL) mode. When the USART Communication Mode (CMODE) bit field in the Control C (USARTn.CTRLC) register is configured to Asynchronous USART (ASYNCHRONOUS) or Infrared Communication (IRCOM), always write the RXMODE bit field to 0x00. • • • Writing the bits to 0x01 enables Double-Speed (CLK2X) mode. Refer to 24.3.3.2.4 Double-Speed Operation for more information. Writing the bits to 0x02 enables Generic Auto-Baud (GENAUTO) mode. Refer to the Auto-Baud section for more information. Writing the bits to 0x03 enables Lin Constrained Auto-Baud (LINAUTO) mode. Refer to the Auto-Baud section for more information. Value 0x00 0x01 0x02 0x03 Name NORMAL CLK2X GENAUTO LINAUTO © 2021 Microchip Technology Inc. Description Normal-Speed mode Double-Speed mode Generic Auto-Baud mode LIN Constrained Auto-Baud mode Preliminary Datasheet DS40002311A-page 313 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... Bit 0 – MPCM Multi-Processor Communication Mode This bit controls whether the Multi-Processor Communication mode is enabled or not. Refer to 24.3.4.3 Multiprocessor Communication for more information. Value Description 0 Multi-Processor Communication mode is disabled 1 Multi-Processor Communication mode is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 314 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.8 Control C - Normal Mode Name:  Offset:  Reset:  Property:  CTRLC 0x07 0x03 - This register description is valid for all modes except the Host SPI mode. When the USART Communication Mode (CMODE) bit field in this register is written to ‘MSPI’, see CTRLC - Host SPI mode for the correct description. Bit Access Reset 7 6 CMODE[1:0] R/W R/W 0 0 5 4 PMODE[1:0] R/W R/W 0 0 3 SBMODE R/W 0 2 R/W 0 1 CHSIZE[2:0] R/W 1 0 R/W 1 Bits 7:6 – CMODE[1:0] USART Communication Mode This bit field selects the communication mode of the USART. Writing a 0x03 to these bits alters the available bit fields in this register. See CTRLC - Host SPI mode. Value Name Description 0x00 ASYNCHRONOUS Asynchronous USART 0x01 SYNCHRONOUS Synchronous USART 0x02 IRCOM Infrared Communication 0x03 MSPI Host SPI Bits 5:4 – PMODE[1:0] Parity Mode This bit field enables and selects the type of parity generation. See 24.3.4.1 Parity for more information. Value Name Description 0x0 DISABLED Disabled 0x1 Reserved 0x2 EVEN Enabled, even parity 0x3 ODD Enabled, odd parity Bit 3 – SBMODE Stop Bit Mode This bit selects the number of Stop bits to be inserted by the transmitter. The receiver ignores this setting. Value Description 0 1 Stop bit 1 2 Stop bits Bits 2:0 – CHSIZE[2:0] Character Size This bit field selects the number of data bits in a frame. The receiver and transmitter use the same setting. For 9BIT character size, the order of which byte to read or write first, low or high byte of RXDATA or TXDATA, can be configured. Value Name Description 0x00 5BIT 5-bit 0x01 6BIT 6-bit 0x02 7BIT 7-bit 0x03 8BIT 8-bit 0x04 Reserved 0x05 Reserved 0x06 9BITL 9-bit (Low byte first) 0x07 9BITH 9-bit (High byte first) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 315 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.9 Control C - Host SPI Mode Name:  Offset:  Reset:  Property:  CTRLC 0x07 0x00 - This register description is valid only when the USART is in Host SPI mode (CMODE written to MSPI). For other CMODE values, see CTRLC - Normal Mode. See 24.3.3.1.3 USART in Host SPI Mode for a full description of the Host SPI mode operation. Bit Access Reset 7 6 CMODE[1:0] R/W R/W 0 0 5 4 3 2 UDORD R/W 0 1 UCPHA R/W 0 0 Bits 7:6 – CMODE[1:0] USART Communication Mode This bit field selects the communication mode of the USART. Writing a value different than 0x03 to these bits alters the available bit fields in this register. See CTRLC - Normal Mode. Value Name Description 0x00 ASYNCHRONOUS Asynchronous USART 0x01 SYNCHRONOUS Synchronous USART 0x02 IRCOM Infrared Communication 0x03 MSPI Host SPI Bit 2 – UDORD USART Data Order This bit controls the frame format. The receiver and transmitter use the same setting. Changing the setting of the UDORD bit will corrupt all ongoing communication for both the receiver and the transmitter. Value Description 0 MSb of the data word is transmitted first 1 LSb of the data word is transmitted first Bit 1 – UCPHA USART Clock Phase This bit controls the phase of the interface clock. Refer to the Clock Generation section for more information. Value Description 0 Data are sampled on the leading (first) edge 1 Data are sampled on the trailing (last) edge © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 316 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.10 Baud Register Name:  Offset:  Reset:  Property:  BAUD 0x08 0x00 - The USARTn.BAUDL and USARTn.BAUDH register pair represents the 16-bit value, USARTn.BAUD. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Ongoing transmissions of the transmitter and receiver will be corrupted if the baud rate is changed. Writing to this register will trigger an immediate update of the baud rate prescaler. For more information on how to set the baud rate, see Table 24-1. Bit 15 14 13 12 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 BAUD[15:8] Access Reset Bit R/W 0 R/W 0 R/W 0 R/W 0 7 6 5 4 BAUD[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – BAUD[15:8] USART Baud Rate High Byte This bit field holds the MSB of the 16-bit Baud register. Bits 7:0 – BAUD[7:0] USART Baud Rate Low Byte This bit field holds the LSB of the 16-bit Baud register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 317 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.11 Control D Name:  Offset:  Reset:  Property:  Bit CTRLD 0x0A 0x00 - 7 6 5 4 3 2 1 0 ABW[1:0] Access Reset R/W 0 R/W 0 Bits 7:6 – ABW[1:0] Auto-Baud Window Size These bits control the tolerance for the difference between the baud rates between the two synchronizing devices when using Lin Constrained Auto-baud mode. The tolerance is based on the number of baud samples between every two bits. When baud rates are identical, there must be 32 baud samples between each bit pair since each bit is sampled 16 times. Value Name Description 0x00 WDW0 32±6 (18% tolerance) 0x01 WDW1 32±5 (15% tolerance) 0x02 WDW2 32±7 (21% tolerance) 0x03 WDW3 32±8 (25% tolerance) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 318 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.12 Debug Control Register Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x0B 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run Value Description 0 The peripheral is halted in Break Debug mode and ignores events 1 The peripheral will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 319 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.13 IrDA Control Register Name:  Offset:  Reset:  Property:  Bit 7 EVCTRL 0x0C 0x00 - 6 5 4 3 Access Reset 2 1 0 IREI R/W 0 Bit 0 – IREI IrDA Event Input Enable This bit controls whether the IrDA event input is enabled or not. See 24.3.3.2.7 IRCOM Mode of Operation for more information. Value Description 0 IrDA Event input is enabled 1 IrDA Event input is disabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 320 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.14 IRCOM Transmitter Pulse Length Control Register Name:  Offset:  Reset:  Property:  Bit 7 TXPLCTRL 0x0D 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 TXPL[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – TXPL[7:0] Transmitter Pulse Length This 8-bit value sets the pulse modulation scheme for the transmitter. Setting this register will only have an effect if IRCOM mode is selected by the USART, and it must be configured before the USART transmitter is enabled (TXEN). Value Description 0x00 3/16 of the baud rate period pulse modulation is used 0x01Fixed pulse length coding is used. The 8-bit value sets the number of peripheral clock periods for the 0xFE pulse. The start of the pulse will be synchronized with the rising edge of the baud rate clock. 0xFF Pulse coding disabled. RX and TX signals pass through the IRCOM module unaltered. This enables other features through the IRCOM module, such as half-duplex USART, loop-back testing, and USART RX input from an event channel. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 321 ATtiny424/426/427 ATtiny824/826/827 USART - Universal Synchronous and Asynchrono... 24.5.15 IRCOM Receiver Pulse Length Control Register Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RXPLCTRL 0x0E 0x00 - 6 5 4 R/W 0 R/W 0 R/W 0 3 RXPL[6:0] R/W 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 6:0 – RXPL[6:0] Receiver Pulse Length This 7-bit value sets the filter coefficient for the IRCOM transceiver. Setting this register will only have an effect if IRCOM mode is selected by a USART, and it must be configured before the USART receiver is enabled (RXEN). Value Description 0x00 Filtering disabled 0x01Filtering enabled. The value of RXPL+1 represents the number of samples required for a received 0x7F pulse to be accepted. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 322 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25. SPI - Serial Peripheral Interface 25.1 Features • • • • • • • • 25.2 Full Duplex, Three-Wire Synchronous Data Transfer Host or Client Operation LSb First or MSb First Data Transfer Seven Programmable Bit Rates End of Transmission Interrupt Flag Write Collision Flag Protection Wake-up from Idle Mode Double-Speed (CK/2) Host SPI Mode Overview The Serial Peripheral Interface (SPI) is a high-speed synchronous data transfer interface using three or four pins. It allows full-duplex communication between an AVR® device and peripheral devices or between several microcontrollers. The SPI peripheral can be configured as either host or client. The host initiates and controls all data transactions. The interconnection between host and client devices with SPI is shown in the block diagram. The system consists of two shift registers and a server clock generator. The SPI host initiates the communication cycle by pulling the desired client’s Client Select (SS) signal low. The host and client prepare the data to be sent to their respective shift registers, and the host generates the required clock pulses on the SCK line to exchange data. Data are always shifted from host to client on the host output, client input (MOSI) line, and from client to host on the host input, client output (MISO) line. 25.2.1 Block Diagram Figure 25-1. SPI Block Diagram CLIENT HOST DATA DATA Transmit Data Buffer Transmit Data Buffer Buffer mode Buffer mode LSb MSb MISO MISO MOSI MOSI 8-bit Shift Register LSb MSb 8-bit Shift Register SPI CLOCK GENERATOR SCK SCK SS SS Receive Data Receive Data Receive Data Buffer Buffer mode Receive Data Buffer Buffer mode DATA DATA The SPI is built around an 8-bit shift register that will shift data out and in at the same time. The Transmit Data register and the Receive Data register are not physical registers but are mapped to other registers when written or © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 323 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface read: Writing the Transmit Data (SPIn.DATA) register will write the shift register in Normal mode and the Transmit Buffer register in Buffer mode. Reading the Receive Data (SPIn.DATA) register will read the Receive Data register in Normal mode and the Receive Data Buffer in Buffer mode. In Host mode, the SPI has a clock generator to generate the SCK clock. In Client mode, the received SCK clock is synchronized and sampled to trigger the shifting of data in the shift register. 25.2.2 Signal Description Table 25-1. Signals in Host and Client Mode Signal Pin Configuration Description Host Mode defined(1) Client Mode MOSI Host Out Client In User MISO Host In Client Out Input SCK Serial Clock User defined(1) Input Client Select defined(1) Input SS User Input User defined(1,2) Notes:  1. If the pin data direction is configured as output, the pin level is controlled by the SPI. 2. If the SPI is in Client mode and the MISO pin data direction is configured as output, the SS pin controls the MISO pin output in the following way: – If the SS pin is driven low, the MISO pin is controlled by the SPI – If the SS pin is driven high, the MISO pin is tri-stated When the SPI module is enabled, the pin data direction for the signals marked with “Input” in Table 25-1 is overridden. 25.3 Functional Description 25.3.1 Initialization Initialize the SPI to a basic functional state by following these steps: 1. Configure the SS pin in the port peripheral. 2. Select the SPI host/client operation by writing the Host/Client Select (MASTER) bit in the Control A (SPIn.CTRLA) register. 3. In Host mode, select the clock speed by writing the Prescaler (PRESC) bits and the Clock Double (CLK2X) bit in SPIn.CTRLA. 4. Optional: Select the Data Transfer mode by writing to the MODE bits in the Control B (SPIn.CTRLB) register. 5. Optional: Write the Data Order (DORD) bit in SPIn.CTRLA. 6. Optional: Set up the Buffer mode by writing the BUFEN and BUFWR bits in the Control B (SPIn.CTRLB) register. 7. Optional: To disable the multi-host support in Host mode, write ‘1’ to the Client Select Disable (SSD) bit in SPIn.CTRLB. 8. Enable the SPI by writing a ‘1’ to the ENABLE bit in SPIn.CTRLA. 25.3.2 Operation 25.3.2.1 Host Mode Operation When the SPI is configured in Host mode, a write to the SPIn.DATA register will start a new transfer. The SPI host can operate in two modes, Normal and Buffer, as explained below. 25.3.2.1.1 Normal Mode In Normal mode, the system is single-buffered in the transmit direction and double-buffered in the receive direction. This influences the data handling in the following ways: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 324 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 1. New bytes to be sent cannot be written to the DATA (SPIn.DATA) register before the entire transfer has been completed. A premature write will cause corruption of the transmitted data, and the Write Collision (WRCOL) flag in SPIn.INTFLAGS will be set. Received bytes are written to the Receive Data Buffer register immediately after the transmission is completed. The Receive Data Buffer register has to be read before the next transmission is completed, or the data will be lost. This register is read by reading SPIn.DATA. The Transmit Data Buffer and Receive Data Buffer registers are not used in Normal mode. 2. 3. 4. After a transfer has been completed, the Interrupt Flag (IF) will be set in the Interrupt Flags (SPIn.INTFLAGS) register. This will cause the corresponding interrupt to be executed if this interrupt and the global interrupts are enabled. Setting the Interrupt Enable (IE) bit in the Interrupt Control (SPIn.INTCTRL) register will enable the interrupt. 25.3.2.1.2 Buffer Mode The Buffer mode is enabled by writing the BUFEN bit in the SPIn.CTRLB register to ‘1’. The BUFWR bit in SPIn.CTRLB does not affect Host mode. In Buffer mode, the system is double-buffered in the transmit direction and triple-buffered in the receive direction. This influences the data handling in the following ways: 1. New bytes can be written to the DATA (SPIn.DATA) register as long as the Data Register Empty Interrupt Flag (DREIF) in the Interrupt Flag (SPIn.INTFLAGS) register is set. The first write will be transmitted right away, and the following write will go to the Transmit Data Buffer register. 2. A received byte is placed in a two-entry Receive First-In, First-Out (RX FIFO) queue comprised of the Receive Data register and Receive Data Buffer immediately after the transmission is completed. 3. The DATA register is used to read from the RX FIFO. The RX FIFO must be read at least every second transfer to avoid any loss of data. When both the shift register and the Transmit Data Buffer register become empty, the Transfer Complete Interrupt Flag (TXCIF) in the Interrupt Flags (SPIn.INTFLAGS) register will be set. This will cause the corresponding interrupt to be executed if this interrupt and the global interrupts are enabled. Setting the Transfer Complete Interrupt Enable (TXCIE) in the Interrupt Control (SPIn.INTCTRL) register enables the Transfer Complete Interrupt. 25.3.2.1.3 SS Pin Functionality in Host Mode - Multi-Host Support In Host mode, the Client Select Disable (SSD) bit in the Control B (SPIn.CTRLB) register controls how the SPI uses the SS pin. • • • If SSD in SPIn.CTRLB is ‘0’, the SPI can use the SS pin to transition from Host to Client mode. This allows multiple SPI hosts on the same SPI bus. If SSD in SPIn.CTRLB is ‘0’, and the SS pin is configured as an output pin, it can be used as a regular I/O pin or by other peripheral modules and will not affect the SPI system If SSD in SPIn.CTRLB is ‘1’, the SPI does not use the SS pin. It can be used as a regular I/O pin or by other peripheral modules. If the SSD bit in SPIn.CTRLB is ‘0’, and the SS is configured as an input pin, the SS pin must be held high to ensure Host SPI operation. A low level will be interpreted as another Host is trying to take control of the bus. This will switch the SPI into Client mode, and the hardware of the SPI will perform the following actions: 1. The Host (MASTER) bit in the SPI Control A (SPIn.CTRLA) register is cleared, and the SPI system becomes a client. The direction of the SPI pins will be switched when the conditions in Table 25-2 are met. 2. The Interrupt Flag (IF) bit in the Interrupt Flags (SPIn.INTFLAGS) register will be set. If the interrupt is enabled and the global interrupts are enabled, the interrupt routine will be executed. Table 25-2. Overview of the SS Pin Functionality when the SSD Bit in SPIn.CTRLB is ‘0’ SS Configuration Input Output © 2021 Microchip Technology Inc. SS Pin-Level Description High Host activated (selected) Low Host deactivated, switched to Client mode High Host activated (selected) Low Preliminary Datasheet DS40002311A-page 325 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface Note:  If the device is in Host mode and it cannot be ensured that the SS pin will stay high between two transmissions, the status of the Host (MASTER) bit in SPIn.CTRLA has to be checked before a new byte is written. After the Host bit has been cleared by a low level on the SS line, it must be set by the application to re-enable the SPI Host mode. 25.3.2.2 Client Mode In Client mode, the SPI peripheral receives SPI clock and Client Select from a Host. Client mode supports three operational modes: One Normal mode and two configurations for the Buffered mode. In Client mode, the control logic will sample the incoming signal on the SCK pin. To ensure correct sampling of this clock signal, the minimum low and high periods must each be longer than two peripheral clock cycles. 25.3.2.2.1 Normal Mode In Normal mode, the SPI peripheral will remain Idle as long as the SS pin is driven high. In this state, the software may update the contents of the DATA register, but the data will not be shifted out by incoming clock pulses on the SCK pin until the SS pin is driven low. If the SS pin is driven low, the client will start to shift out data on the first SCK clock pulse. When one byte has been completely shifted, the SPI Interrupt Flag (IF) in SPIn.INTFLAGS is set. The user application may continue placing new data to be sent into the DATA register before reading the incoming data. New bytes to be sent cannot be written to the DATA register before the entire transfer has been completed. A premature write will be ignored, and the hardware will set the Write Collision (WRCOL) flag in SPIn.INTFLAGS. When the SS pin is driven high, the SPI logic is halted, and the SPI client will not receive any new data. Any partially received packet in the shift register will be lost. Figure 25-2 shows a transmission sequence in Normal mode. Notice how the value 0x45 is written to the DATA register but never transmitted. Figure 25-2. SPI Timing Diagram in Normal Mode (Buffer Mode Not Enabled) SS SCK Write DATA Write value 0x43 0x44 0x45 0x46 WRCOL IF Shift Register Data sent 0x43 0x43 0x44 0x44 0x46 0x46 The figure above shows three transfers and one write to the DATA register while the SPI is busy with a transfer. This write will be ignored, and the Write Collision (WRCOL) flag in SPIn.INTFLAGS is set. 25.3.2.2.2 Buffer Mode To avoid data collisions, the SPI peripheral can be configured in Buffered mode by writing a ‘1’ to the Buffer Mode Enable (BUFEN) bit in the Control B (SPIn.CTRLB) register. In this mode, the SPI has additional interrupt flags and extra buffers. The extra buffers are shown in Figure 25-1. There are two different modes for the Buffer mode, selected with the Buffer mode Wait for Receive (BUFWR) bit. The two different modes are described below with timing diagrams. Client Buffer Mode with Wait for Receive Bit Written to ‘0’ In Client mode, if the Buffer mode Wait for Receive (BUFWR) bit in SPIn.CTRLB is written to ‘0’, a dummy byte will be sent before the transmission of user data starts. Figure 25-3 shows a transmission sequence with this configuration. Notice how the value 0x45 is written to the Data (SPIn.DATA) register but never transmitted. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 326 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface Figure 25-3. SPI Timing Diagram in Buffer Mode with BUFWR in SPIn.CTRLB Written to ‘0’ SS SCK Write DATA Write value 0x43 0x44 0x45 0x46 DREIF TXCIF RXCIF Transmit Buffer Shift Register Data sent 0x43 Dummy Dummy 0x46 0x44 0x44 0x43 0x43 0x44 0x46 0x46 When the Wait for Receive (BUFWR) bit in SPIn.CTRLB is written to ‘0’, all writes to the Data (SPIn.DATA) register go to the Transmit Data Buffer register. The figure above shows that the value 0x43 is written to the Data (SPIn.DATA) register but not immediately transferred to the shift register, so the first byte sent will be a dummy byte. The value of the dummy byte equals the values that were in the shift register at the same time. After the first dummy transfer is completed, the value 0x43 is transferred to the shift register. Then 0x44 is written to the Data (SPIn.DATA) register and goes to the Transmit Data Buffer register. A new transfer is started, and 0x43 will be sent. The value 0x45 is written to the Data (SPIn.DATA) register, but the Transmit Data Buffer register is not updated since it is already full containing 0x44 and the Data Register Empty Interrupt Flag (DREIF) in SPIn.INTFLAGS is low. The value 0x45 will be lost. After the transfer, the value 0x44 is moved to the shift register. During the next transfer, 0x46 is written to the Data (SPIn.DATA) register, and 0x44 is sent out. After the transfer is complete, 0x46 is copied into the shift register and sent out in the next transfer. The DREIF goes low every time the Transmit Data Buffer register is written and goes high after a transfer when the previous value in the Transmit Data Buffer register is copied into the shift register. The Receive Complete Interrupt Flag (RXCIF) in SPIn.INTFLAGS is set one cycle after the DREIF goes high. The Transfer Complete Interrupt Flag is set one cycle after the Receive Complete Interrupt Flag is set when both the value in the shift register and in the Transmit Data Buffer register has been sent. Client Buffer Mode with Wait for Receive Bit Written to ‘1’ In Client mode, if the Buffer mode Wait for Receive (BUFWR) bit in SPIn.CRTLB is written to ‘1’, the transmission of user data starts as soon as the SS pin is driven low. Figure 25-4 shows a transmission sequence with this configuration. Notice how the value 0x45 is written to the Data (SPIn.DATA) register but never transmitted. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 327 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface Figure 25-4. SPI Timing Diagram in Buffer Mode with CTRLB.BUFWR Written to ‘1’ SS SCK Write DATA Write value 0x43 0x44 0x45 0x46 DREIF TXCIF RXCIF Transmit Buffer Shift Register 0x46 0x44 0x43 0x43 Data sent 0x46 0x44 0x43 0x44 0x46 All writes to the Data (SPIn.DATA) register go to the Transmit Data Buffer register. The figure above shows that the value 0x43 is written to the Data (SPIn.DATA) register, and since the SS pin is high, it is copied to the shift register in the next cycle. The next write (0x44) will go to the Transmit Data Buffer register. During the first transfer, the value 0x43 will be shifted out. In the figure above, the value 0x45 is written to the Data (SPIn.DATA) register, but the Transmit Data Buffer register is not updated since the DREIF is low. After the transfer is completed, the value 0x44 from the Transmit Data Buffer register is copied to the shift register. The value 0x46 is written to the Transmit Data Buffer register. During the next two transfers, 0x44 and 0x46 are shifted out. The flags behave identically to the Buffer Mode Wait for Receive (BUFWR) bit in SPIn.CTRLB set to ‘0’. 25.3.2.2.3 SS Pin Functionality in Client Mode The Client Select (SS) pin plays a central role in the operation of the SPI. Depending on the SPI mode and the configuration of this pin, it can be used to activate or deactivate devices. The SS pin is used as a Chip Select pin. In Client mode, the SS, MOSI, and SCK are always inputs. The behavior of the MISO pin depends on the configured data direction of the pin in the port peripheral and the value of SS. When the SS pin is driven low, the SPI is activated and will respond to received SCK pulses by clocking data out on MISO if the user has configured the data direction of the MISO pin as an output. When the SS pin is driven high, the SPI is deactivated, meaning that it will not receive incoming data. If the MISO pin data direction is configured as an output, the MISO pin will be tri-stated. Table 25-3 shows an overview of the SS pin functionality. Table 25-3. Overview of the SS Pin Functionality MISO Pin Mode SS Configuration SS Pin-Level Description Port Direction = Output Port Direction = Input High Client deactivated (deselected) Tri-stated Input Low Client activated (selected) Output Input Always Input Note:  In Client mode, the SPI state machine will be reset when the SS pin is driven high. If the SS pin is driven high during a transmission, the SPI will stop sending and receiving data immediately and both data received and data sent must be considered lost. As the SS pin is used to signal the start and end of a transfer, it is useful for achieving packet/byte synchronization and keeping the Client bit counter synchronized with the host clock generator. 25.3.2.3 Data Modes There are four combinations of SCK phase and polarity concerning the serial data. The desired combination is selected by writing to the MODE bits in the Control B (SPIn.CTRLB) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 328 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface The SPI data transfer formats are shown below. Data bits are shifted out and latched in on opposite edges of the SCK signal, ensuring sufficient time for data signals to stabilize. The leading edge is the first clock edge of a clock cycle. The trailing edge is the last clock edge of a clock cycle. Figure 25-5. SPI Data Transfer Modes 1 2 3 4 5 6 7 8 MISO 1 2 3 4 5 6 7 8 MOSI 1 2 3 4 5 6 7 8 SPI Mode 0 Cycle # SS SCK Sampling SPI Mode 1 Cycle # 1 2 3 4 5 6 7 8 MISO 1 2 3 4 5 6 7 8 MOSI 1 2 3 4 5 6 7 8 SS SCK Sampling SPI Mode 2 Cycle # 1 2 3 4 5 6 7 8 MISO 1 2 3 4 5 6 7 8 MOSI 1 2 3 4 5 6 7 8 SS SCK Sampling SPI Mode 3 Cycle # 1 2 3 4 5 6 7 8 MISO 1 2 3 4 5 6 7 8 MOSI 1 2 3 4 5 6 7 8 SS SCK Sampling 25.3.2.4 Events The SPI can generate the following events: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 329 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface Table 25-4. Event Generators in SPI Generator Name Module Event SPIn SCK Description Event Type SPI Host clock Level Generating Clock Domain CLK_PER Length of Event Minimum two CLK_PER periods The SPI has no event users. Refer to the Event System section for more details regarding event types and Event System configuration. 25.3.2.5 Interrupts Table 25-5. Available Interrupt Vectors and Sources Name SPIn Conditions Vector Description SPI interrupt Normal Mode • • IF: Interrupt Flag interrupt WRCOL: Write Collision interrupt Buffer Mode • • • • SSI: Client Select Trigger Interrupt DRE: Data Register Empty interrupt TXC: Transfer Complete interrupt RXC: Receive Complete interrupt When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 330 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.4 Register Summary Offset Name Bit Pos. 7 6 5 4 0x00 0x01 0x02 0x03 0x03 0x04 CTRLA CTRLB INTCTRL INTFLAGS INTFLAGS DATA 7:0 7:0 7:0 7:0 7:0 7:0 DORD BUFWR TXCIE WRCOL TXCIF MASTER CLK2X BUFEN RXCIE IF RXCIF DREIE SSIE DREIF SSIF DATA[7:0] 25.5 3 2 1 PRESC[1:0] SSD 0 ENABLE MODE[1:0] IE BUFOVF Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 331 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.5.1 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CTRLA 0x00 0x00 - 6 DORD R/W 0 5 MASTER R/W 0 4 CLK2X R/W 0 3 2 1 PRESC[1:0] R/W R/W 0 0 0 ENABLE R/W 0 Bit 6 – DORD Data Order Value Description 0 The MSb of the data word is transmitted first 1 The LSb of the data word is transmitted first Bit 5 – MASTER Host/Client Select This bit selects the desired SPI mode. If SS is configured as input and driven low while this bit is ‘1’, then this bit is cleared, and the IF in SPIn.INTFLAGS is set. The user has to write MASTER = 1 again to re-enable SPI Host mode. This behavior is controlled by the Client Select Disable (SSD) bit in SPIn.CTRLB. Value Description 0 SPI Client mode selected 1 SPI Host mode selected Bit 4 – CLK2X Clock Double When this bit is written to ‘1’, the SPI speed (SCK frequency, after internal prescaler) is doubled in Host mode. Value Description 0 SPI speed (SCK frequency) is not doubled 1 SPI speed (SCK frequency) is doubled in Host mode Bits 2:1 – PRESC[1:0] Prescaler This bit field controls the SPI clock rate configured in Host mode. These bits have no effect in Client mode. The relationship between SCK and the peripheral clock frequency (fCLK_PER) is shown below. The output of the SPI prescaler can be doubled by writing the CLK2X bit to ‘1’. Value Name Description 0x0 DIV4 CLK_PER/4 0x1 DIV16 CLK_PER/16 0x2 DIV64 CLK_PER/64 0x3 DIV128 CLK_PER/128 Bit 0 – ENABLE SPI Enable Value Description 0 SPI is disabled 1 SPI is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 332 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.5.2 Control B Name:  Offset:  Reset:  Property:  Bit Access Reset 7 BUFEN R/W 0 CTRLB 0x01 0x00 - 6 BUFWR R/W 0 5 4 3 2 SSD R/W 0 1 0 MODE[1:0] R/W 0 R/W 0 Bit 7 – BUFEN Buffer Mode Enable Writing this bit to ‘1’ enables Buffer mode. This will enable two receive buffers and one transmit buffer. Both will have separate interrupt flags, transmit complete and receive complete. Bit 6 – BUFWR Buffer Mode Wait for Receive When writing this bit to ‘0’, the first data transferred will be a dummy sample. Value Description 0 One SPI transfer must be completed before the data are copied into the shift register 1 If writing to the Data register when the SPI is enabled and SS is high, the first write will go directly to the shift register Bit 2 – SSD Client Select Disable If this bit is set when operating as SPI Host (MASTER = 1 in SPIn.CTRLA), SS does not disable Host mode. Value Description 0 Enable the Client Select line when operating as SPI host 1 Disable the Client Select line when operating as SPI host Bits 1:0 – MODE[1:0] Mode These bits select the Transfer mode. The four combinations of SCK phase and polarity concerning the serial data are shown below. These bits decide whether the first edge of a clock cycle (leading edge) is rising or falling and whether data setup and sample occur on the leading or trailing edge. When the leading edge is rising, the SCK signal is low when idle, and when the leading edge is falling, the SCK signal is high when idle. Value Name Description 0x0 0 Leading edge: Rising, sample Trailing edge: Falling, setup 0x1 1 Leading edge: Rising, setup Trailing edge: Falling, sample 0x2 2 Leading edge: Falling, sample Trailing edge: Rising, setup 0x3 3 Leading edge: Falling, setup Trailing edge: Rising, sample © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 333 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.5.3 Interrupt Control Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RXCIE R/W 0 INTCTRL 0x02 0x00 - 6 TXCIE R/W 0 5 DREIE R/W 0 4 SSIE R/W 0 3 2 1 0 IE R/W 0 Bit 7 – RXCIE Receive Complete Interrupt Enable In Buffer mode, this bit enables the Receive Complete interrupt. The enabled interrupt will be triggered when the RXCIF in the SPIn.INTFLAGS register is set. In the Non-Buffer mode, this bit is ‘0’. Bit 6 – TXCIE Transfer Complete Interrupt Enable In Buffer mode, this bit enables the Transfer Complete interrupt. The enabled interrupt will be triggered when the TXCIF in the SPIn.INTFLAGS register is set. In the Non-Buffer mode, this bit is ‘0’. Bit 5 – DREIE Data Register Empty Interrupt Enable In Buffer mode, this bit enables the Data Register Empty interrupt. The enabled interrupt will be triggered when the DREIF in the SPIn.INTFLAGS register is set. In the Non-Buffer mode, this bit is ‘0’. Bit 4 – SSIE Client Select Trigger Interrupt Enable In Buffer mode, this bit enables the Client Select interrupt. The enabled interrupt will be triggered when the SSIF in the SPIn.INTFLAGS register is set. In the Non-Buffer mode, this bit is ‘0’. Bit 0 – IE Interrupt Enable This bit enables the SPI interrupt when the SPI is not in Buffer mode. The enabled interrupt will be triggered when RXCIF/IF is set in the SPIn.INTFLAGS register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 334 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.5.4 Interrupt Flags - Normal Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 IF R/W 0 INTFLAGS 0x03 0x00 - 6 WRCOL R/W 0 5 4 3 2 1 0 Bit 7 – IF Interrupt Flag This flag is set when a serial transfer is complete, and one byte is completely shifted in/out of the SPIn.DATA register. If SS is configured as input and is driven low when the SPI is in Host mode, this will also set this flag. The IF is cleared by hardware when executing the corresponding interrupt vector. Alternatively, the IF can be cleared by first reading the SPIn.INTFLAGS register when IF is set and then accessing the SPIn.DATA register. Bit 6 – WRCOL Write Collision The WRCOL flag is set if the SPIn.DATA register is written before a complete byte has been shifted out. This flag is cleared by first reading the SPIn.INTFLAGS register when WRCOL is set and then accessing the SPIn.DATA register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 335 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.5.5 Interrupt Flags - Buffer Mode Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RXCIF R/W 0 INTFLAGS 0x03 0x00 - 6 TXCIF R/W 0 5 DREIF R/W 0 4 SSIF R/W 0 3 2 1 0 BUFOVF R/W 0 Bit 7 – RXCIF Receive Complete Interrupt Flag This flag is set when there are unread data in the Receive Data Buffer register and cleared when the Receive Data Buffer register is empty (that is, it does not contain any unread data). When interrupt-driven data reception is used, the Receive Complete Interrupt routine must read the received data from the DATA register to clear RXCIF. If not, a new interrupt will occur directly after the return from the current interrupt. This flag can also be cleared by writing a ‘1’ to its bit location. Bit 6 – TXCIF Transfer Complete Interrupt Flag This flag is set when all the data in the Transmit shift register has been shifted out, and there is no new data in the transmit buffer (SPIn.DATA). The flag is cleared by writing a ‘1’ to its bit location. Bit 5 – DREIF Data Register Empty Interrupt Flag This flag indicates whether the Transmit Data Buffer register is ready to receive new data. The flag is ‘1’ when the transmit buffer is empty and ‘0’ when the transmit buffer contains data to be transmitted that has not yet been moved into the shift register. The DREIF is cleared after a Reset to indicate that the transmitter is ready. The DREIF is cleared by writing to DATA. When interrupt-driven data transmission is used, the Data Register Empty Interrupt routine must either write new data to DATA to clear DREIF or disable the Data Register Empty interrupt. If not, a new interrupt will occur directly after the return from the current interrupt. Bit 4 – SSIF Client Select Trigger Interrupt Flag This flag indicates that the SPI has been in Host mode, and the SS pin has been pulled low externally, so the SPI is now working in Client mode. The flag will only be set if the Client Select Disable (SSD) bit is not ‘1’. The flag is cleared by writing a ‘1’ to its bit location. Bit 0 – BUFOVF Buffer Overflow This flag indicates data loss due to a Receive Data Buffer full condition. This flag is set if a Buffer Overflow condition is detected. A Buffer Overflow occurs when the receive buffer is full (two bytes), and a third byte has been received in the shift register. If there is no transmit data, the Buffer Overflow will not be set before the start of a new serial transfer. This flag is cleared when the DATA register is read or by writing a ‘1’ to its bit location. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 336 ATtiny424/426/427 ATtiny824/826/827 SPI - Serial Peripheral Interface 25.5.6 Data Name:  Offset:  Reset:  Property:  Bit 7 DATA 0x04 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 DATA[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DATA[7:0] SPI Data The DATA register is used for sending and receiving data. Writing to the register initiates the data transmission when in Host mode while preparing data for sending in Client mode. The byte written to the register shifts out on the SPI output line when a transaction is initiated. The SPIn.DATA register is not a physical register. Depending on what mode is configured, it is mapped to other registers, as described below. • Normal mode: – Writing the DATA register will write the shift register – Reading from DATA will read from the Receive Data register • Buffer mode: – Writing the DATA register will write to the Transmit Data Buffer register – Reading from DATA will read from the Receive Data Buffer register. The contents of the Receive Data register will then be moved to the Receive Data Buffer register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 337 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26. TWI - Two-Wire Interface 26.1 Features • • Bidirectional, Two-Wire Communication Interface Philips I2C Compatible1 – Standard mode – Fast mode – Fast mode plus System Management Bus (SMBus) 2.0 Compatible – Support arbitration between Start/repeated Start and data bit – Client arbitration allows support for the Address Resolution Protocol (ARP) – Configurable SMBus Layer 1 time-outs in hardware Independent Host and Client Operation – Single or multi-host bus operation with full arbitration support Flexible Client Address Match Hardware Operating in All Sleep Modes, Including Power-Down – 7-bit and general call address recognition – 10-bit addressing support in collaboration with software – Support for address range masking or secondary address match – Optional software address recognition (permissive mode) for an unlimited number of addresses Input Filter for Bus Noise Suppression Smart Mode Support • • • • • 26.2 Overview The Two-Wire Interface (TWI) is a bidirectional, two-wire communication interface (bus) with a Serial Data Line (SDA) and a Serial Clock Line (SCL). The TWI bus connects one or several client devices to one or several host devices. Any device connected to the bus can act as a host, a client, or both. The host generates the SCL by using a Baud Rate Generator (BRG) and initiates data transactions by addressing one client and telling whether it wants to transmit or receive data. The BRG is capable of generating the Standard mode (Sm) and Fast mode (Fm, Fm+) bus frequencies from 100 kHz up to 1 MHz. The TWI will detect Start and Stop conditions, bus collisions, and bus errors. Arbitration lost, errors, collision, and clock hold are also detected and indicated in separate status flags available in both Host and Client modes. The TWI supports multi-host bus operation and arbitration. An arbitration scheme handles the case where more than one host tries to transmit data at the same time. The TWI also supports Smart mode, which can auto-trigger operations and thus reduce software complexity. The TWI supports Quick Command mode, where the host can address a client without exchanging data. 1 The I2C standard uses the terminology "host" and "client". The equivalent Microchip terminology used in this document is "host" and "client" respectively. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 338 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.2.1 Block Diagram Figure 26-1. TWI Block Diagram Host BAUD Client TxDATA TxDATA SCL 0 Baud Rate Generator SCL Hold Low 0 SCL Hold Low shift register shift register SDA 0 0 RxDATA 26.2.2 ADDR/ADDRMASK RxDATA == Signal Description Signal Description Type SCL Serial Clock Line Digital I/O SDA Serial Data Line Digital I/O 26.3 Functional Description 26.3.1 General TWI Bus Concepts The TWI provides a simple, bidirectional, two-wire communication bus consisting of: • Serial Data Line (SDA) for packet transfer • Serial Clock Line (SCL) for the bus clock The two lines are open-collector lines (wired-AND). The TWI bus topology is a simple and efficient method of interconnecting multiple devices on a serial bus. A device connected to the bus can be a host or a client. Only host devices can control the bus and the bus communication. A unique address is assigned to each client device connected to the bus, and the host will use it to control the client and initiate a transaction. Several hosts can be connected to the same bus. This is called a multi-host environment. An arbitration mechanism is provided for resolving bus ownership among hosts since only one host device may own the bus at any given time. A host indicates the start of a transaction by issuing a Start condition (S) on the bus. The host provides the clock signal for the transaction. An address packet with a 7-bit client address (ADDRESS) and a direction bit, representing whether the host wishes to read or write data (R/W), are then sent. The addressed I2C client will then acknowledge (ACK) the address, and data packet transactions can begin. Every 9-bit data packet consists of eight data bits followed by a 1-bit reply indicating whether the data was acknowledged or not by the receiver. After all the data packets (DATA) are transferred, the host issues a Stop condition (P) on the bus to end the transaction. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 339 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface Figure 26-2. Basic TWI Transaction Diagram Topology for a 7-bit Address Bus SDA SCL 6 ... 0 S 7 ... 0 ADDRESS S ADDRESS R/W R/W ACK 7 ... 0 DATA ACK DATA A A DATA P ACK/NACK DATA A/A P Direction Address Packet Data Packet #0 Data Packet #1 Transaction Bus Driver Host driving bus S START condition Client driving bus Sr repeated START condition Either Host or Client driving bus P STOP condition Data Package Direction R Host Read W Acknowledge A Acknowledge (ACK) '0' '1' Host Write '0' 26.3.2 Special Bus Conditions A Not Acknowledge (NACK) '1' TWI Basic Operation 26.3.2.1 Initialization If used, the following bits must be configured before enabling the TWI device: • The SDA Hold Time (SDAHOLD) bit field from the Control A (TWIn.CTRLA) register • The FM Plus Enable (FMPEN) bit from the Control A (TWIn.CTRLA) register 26.3.2.1.1 Host Initialization Write the Host Baud Rate (TWIn.MBAUD) register to a value that will result in a valid TWI bus clock frequency. Writing a ‘1’ to the Enable TWI Host (ENABLE) bit in the Host Control A (TWIn.MCTRLA) register will enable the TWI host. The Bus State (BUSSTATE) bit field from the Host Status (TWIn.MSTATUS) register must be set to 0x1 to force the bus state to Idle. 26.3.2.1.2 Client Initialization Follow these steps to initialize the client: 1. 2. 3. Before enabling the TWI device, configure the SDA Setup Time (SDASETUP) bit from the Control A (TWIn.CTRLA) register. Write the address of the client to the Client Address (TWIn.SADDR) register. Write a ‘1’ to the Enable TWI Client (ENABLE) bit in the Client Control A (TWIn.SCTRLA) register to enable the TWI client. The client device will now wait for a host device to issue a Start condition and the matching client address. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 340 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.3.2.2 TWI Host Operation The TWI host is byte-oriented, with an optional interrupt after each byte. There are separate interrupt flags for the host write and read operation. Interrupt flags can also be used for polled operation. There are dedicated status flags for indicating ACK/NACK received, bus error, arbitration lost, clock hold, and bus state. When an interrupt flag is set to ‘1’, the SCL is forced low. This will give the host time to respond or handle any data and will, in most cases, require software interaction. Clearing the interrupt flags releases the SCL. The number of interrupts generated is kept to a minimum by automatic handling of most conditions. 26.3.2.2.1 Clock Generation The TWI supports several transmission modes with different frequency limitations: • Standard mode (Sm) up to 100 kHz • Fast mode (Fm) up to 400 kHz • Fast mode Plus (Fm+) up to 1 MHz Write the Host Baud Rate (TWIn.MBAUD) register to a value that will result in a TWI bus clock frequency equal to, or less than, those frequency limits, depending on the transmission mode. The low (tLOW) and high (tHIGH) times are determined by the Host Baud Rate (TWIn.MBAUD) register, while the rise (tR) and fall (tOF) times are determined by the bus topology. Figure 26-3. SCL Timing SCL tHD;STA tSU;STA tLOW tHIGH tOF tSP tHD;DAT tSU;DAT tR tBUF tSU;STO SDA S • • • • P S tLOW is the low period of SCL clock tHIGH is the high period of SCL clock tR is determined by the bus impedance; for internal pull-ups. Refer to the Electrical Characteristics section for details. tOF is the output fall time and is determined by the open-drain current limit and bus impedance. Refer to the Electrical Characteristics section for details. Properties of the SCL Clock The SCL frequency is given by: Equation 26-1. SCL Frequency 1 fSCL = t [Hz] LOW + tHIGH + tOF + tR The SCL clock is designed to have a 50/50 duty cycle, where the low period of the duty cycle comprises of tOF and tLOW. tHIGH will not start until a high state of SCL has been detected. The BAUD bit field in the TWIn.MBAUD register and the SCL frequency are related by the following formula: Equation 26-2. SCL Frequency fSCL = fCLK_PER 10 + 2 × BAUD + fCLK_PER × tR Equation 26-2 can be transformed to express BAUD: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 341 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface Equation 26-3. BAUD BAUD = fCLK_PER fCLK_PER × tR − 5+ 2 2 × fSCL Calculation of the BAUD Value To ensure operation within the specifications of the desired speed mode (Sm, Fm, Fm+), follow these steps: 1. Calculate a value for the BAUD bit field using Equation 26-3. 2. Calculate tLOW using the BAUD value from step 1: 3. Equation 26-4. tLOW tLOW = BAUD + 5 − tOF fCLK_PER Check if tLOW from Equation 26-4 is above the specified minimum of the desired mode (tLOW_Sm = 4700 ns, tLOW_Fm = 1300 ns, tLOW_Fm+ = 500 ns). – If the calculated tLOW is above the limit, use the BAUD value from Equation 26-3 – If the limit is not met, calculate a new BAUD value using Equation 26-5 below, where tLOW_mode is either tLOW_Sm, tLOW_Fm, or tLOW_Fm+ from the mode specifications: Equation 26-5. BAUD BAUD = fCLK_PER × (tLOW_mode + tOF) − 5 26.3.2.2.2 TWI Bus State Logic The bus state logic continuously monitors the activity on the TWI bus when the host is enabled. It continues to operate in all sleep modes, including Power-Down. The bus state logic includes Start and Stop condition detectors, collision detection, inactive bus time-out detection, and a bit counter. These are used to determine the bus state. The software can get the current bus state by reading the Bus State (BUSSTATE) bit field in the Host Status (TWIn.MSTATUS) register. The bus state can be Unknown, Idle, Busy or Owner, and it is determined according to the state diagram shown below. Figure 26-4. Bus State Diagram RESET UNKNOWN (0b00) Time-out or Stop Condition External Start Condition IDLE (0b01) Time-out or Stop Condition BUSY (0b11) Write ADDR to generate Start Condition OWNER (0b10) Lost Arbitration External Repeated Start Condition Stop Condition Write ADDR to generate Repeated Start Condition © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 342 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 1. 2. 3. 4. Unknown: The bus state machine is active when the TWI host is enabled. After the TWI host has been enabled, the bus state is Unknown. The bus state will also be set to Unknown after a system Reset is performed or after the TWI host is disabled. Idle: The bus state machine can be forced to enter the Idle state by writing 0x1 to the Bus State (BUSSTATE) bit field. The bus state logic cannot be forced into any other state. If no state is set by the application software, the bus state will become Idle when the first Stop condition is detected. If the Inactive Bus Time-Out (TIMEOUT) bit field from the Host Control A (TWIn.MCTRLA) register is configured to a nonzero value, the bus state will change to Idle on the occurrence of a time-out. When the bus is Idle, it is ready for a new transaction. Busy: If a Start condition, generated externally, is detected when the bus is Idle, the bus state becomes Busy. The bus state changes back to Idle when a Stop condition is detected or when a time-out, if configured, is set. Owner: If a Start condition is generated internally when the bus is Idle, the bus state becomes Owner. If the complete transaction is performed without interference, the host issues a Stop condition, and the bus state changes back to Idle. If a collision is detected, the arbitration is lost, and the bus state becomes Busy until a Stop condition is detected. 26.3.2.2.3 Transmitting Address Packets The host starts performing a bus transaction when the Host Address (TWIn.MADDR) register is written with the client address and the R/W direction bit. The value of the MADDR register is then copied into the Host Data (TWIn.MDATA) register. If the bus state is Busy, the TWI host will wait until the bus state becomes Idle before issuing the Start condition. The TWI will issue a Start condition, and the shift register performs a byte transmit operation on the bus. Depending on the arbitration and the R/W direction bit, one of four cases (M1 to M4) arises after the transmission of the address packet. Figure 26-5. TWI Host Operation M4 HOST DATA INTERRUPT P P A Sr BUSY P IDLE S ADDRESS W OWNER M3 A Sr A IF M1 DATA Sr A M4 M4 IF A The host provides data on the bus Mn P P R BUSY BUSY Interrupt flag raised Addressed client provides data on the bus BUSY OWNER A M3 A Sr DATA IF M2 Sr A Diagram cases Case M1: Address Packet Transmit Complete - Direction Bit Set to ‘0’ If a client device responds to the address packet with an ACK, the Write Interrupt Flag (WIF) is set to ‘1’, the Received Acknowledge (RXACK) flag is set to ‘0’, and the Clock Hold (CLKHOLD) flag is set to ‘1’. The WIF, RXACK and CLKHOLD flags are located in the Host Status (TWIn.MSTATUS) register. The clock hold is active at this point, forcing the SCL low. This will stretch the low period of the clock to slow down the overall clock frequency, forcing delays required to process the data and preventing further activity on the bus. The software can prepare to: • Transmit data packets to the client Case M2: Address Packet Transmit Complete - Direction Bit Set to ‘1’ If a client device responds to the address packet with an ACK, the RXACK flag is set to ‘0’, and the client can start sending data to the host without any delays because the client owns the bus at this moment. The clock hold is active at this point, forcing the SCL low. The software can prepare to: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 343 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface • Read the received data packet from the client Case M3: Address Packet Transmit Complete - Address not Acknowledged by Client If no client device responds to the address packet, the WIF and the RXACK flags will be set to ‘1’. The clock hold is active at this point, forcing the SCL low. The missing ACK response can indicate that the I2C client is busy with other tasks, or it is in a sleep mode, and it is not able to respond. The software can prepare to take one of the following actions: • Retransmit the address packet • Complete the transaction by issuing a Stop condition in the Command (MCMD) bit field from the Host Control B (TWIn.MCTRLB) register, which is the recommended action Case M4: Arbitration Lost or Bus Error If the arbitration is lost, both the WIF and the Arbitration Lost (ARBLOST) flags in the Host Status (TWIn.MSTATUS) register are set to ‘1’. The SDA is disabled, and the SCL is released. The bus state changes to Busy, and the host is no longer allowed to perform any operation on the bus until the bus state is changed back to Idle. A bus error will behave similarly to the arbitration lost condition. In this case, the Bus Error (BUSERR) flag in the Host Status (TWIn.MSTATUS) register is set to ‘1’, in addition to the WIF and ARBLOST flags. The software can prepare to: • Abort the operation and wait until the bus state changes to Idle by reading the Bus State (BUSSTATE) bit field in the Host Status (TWIn.MSTATUS) register 26.3.2.2.4 Transmitting Data Packets Assuming the above M1 case, the TWI host can start transmitting data by writing to the Host Data (TWIn.MDATA) register, which will also clear the Write Interrupt Flag (WIF). During the data transfer, the host is continuously monitoring the bus for collisions and errors. The WIF flag will be set to ‘1’ after the data packet transfer has been completed. If the transmission is successful and the host receives an ACK bit from the client, the Received Acknowledge (RXACK) flag will be set to ‘0’, meaning that the client is ready to receive new data packets. The software can prepare to take one of the following actions: • Transmit a new data packet • Transmit a new address packet • Complete the transaction by issuing a Stop condition in the Command (MCMD) bit field from the Host Control B (TWIn.MCTRLB) register If the transmission is successful and the host receives a NACK bit from the client, the RXACK flag will be set to ‘1’, meaning that the client is not able to or does not need to receive more data. The software can prepare to take one of the following actions: • Transmit a new address packet • Complete the transaction by issuing a Stop condition in the Command (MCMD) bit field from the Host Control B (TWIn.MCTRLB) register The RXACK status is valid only if the WIF flag is set to ‘1’ and the Arbitration Lost (ARBLOST) and Bus Error (BUSERR) flags are set to ‘0’. The transmission can be unsuccessful if a collision is detected. Then, the host will lose the arbitration, the Arbitration Lost (ARBLOST) flag will be set to ‘1’, and the bus state changes to Busy. An arbitration lost during the sending of the data packet is treated the same way as the above M4 case. The WIF, ARBLOST, BUSERR and RXACK flags are all located in the Host Status (TWIn.MSTATUS) register. 26.3.2.2.5 Receiving Data Packets Assuming the M2 case above, the clock is released for one byte, allowing the client to put one byte of data on the bus. The host will receive one byte of data from the client, and the Read Interrupt Flag (RIF) will be set to ‘1’ together with the Clock Hold (CLKHOLD) flag. The action selected by the Acknowledge Action (ACKACT) bit in the Host Control B (TWIn.MCTRLB) register is automatically sent on the bus when a command is written to the Command (MCMD) bit field in the TWIn.MCTRLB register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 344 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface The software can prepare to take one of the following actions: • Respond with an ACK by writing ‘0’ to the ACKACT bit in the TWIn.MCTRLB register and prepare to receive a new data packet • Respond with a NACK by writing ‘1’ to the ACKACT bit and then transmit a new address packet • Respond with a NACK by writing ‘1’ to the ACKACT bit and then complete the transaction by issuing a Stop condition in the MCMD bit field from the TWIn.MCTRLB register A NACK response might not be successfully executed, as the arbitration can be lost during the transmission. If a collision is detected, the host loses the arbitration, the Arbitration Lost (ARBLOST) flag is set to ‘1’, and the bus state changes to Busy. The Host Write Interrupt Flag (WIF) is set if the arbitration was lost when sending a NACK or a bus error occurred during the procedure. An arbitration lost during the sending of the data packet is treated in the same way as the above M4 case. The RIF, CLKHOLD, ARBLOST and WIF flags are all located in the Host Status (TWIn.MSTATUS) register. Note:  The RIF and WIF flags are mutually exclusive and cannot be set simultaneously. 26.3.2.3 TWI Client Operation The TWI client is byte-oriented with optional interrupts after each byte. There are separate interrupt flags for the client data and address/Stop recognition. Interrupt flags can also be used for polled operation. There are dedicated status flags for indicating ACK/NACK received, clock hold, collision, bus error, and R/W direction bit. When an interrupt flag is set to ‘1’, the SCL is forced low. This will give the client time to respond or handle any data and will, in most cases, require software interaction. The number of interrupts generated is kept to a minimum by automatic handling of most conditions. The Permissive Mode Enable (PMEN) bit in the Client Control A (TWIn.SCTRLA) register can be configured to allow the client to respond to all received addresses. 26.3.2.3.1 Receiving Address Packets When the TWI is configured as a client, it will wait for a Start condition to be detected. When this happens, the successive address packet will be received and checked by the address match logic. The client will ACK a correct address and store the address in the Client Data (TWIn.SDATA) register. If the received address is not a match, the client will not acknowledge or store the address but wait for a new Start condition. The Address or Stop Interrupt Flag (APIF) in the Client Status (TWIn.SSTATUS) register is set to ‘1’ when a Start condition is succeeded by one of the following: • • A valid address match with the address stored in the Address (ADDR[7:1]) bit field in the Client Address (TWIn.SADDR) register The General Call Address 0x00 and the Address (ADDR[0]) bit in the Client Address (TWIn.SADDR) register are set to ‘1’ • A valid address match with the secondary address stored in the Address Mask (ADDRMASK) bit field and the Address Mask Enable (ADDREN) bit is set to ‘1’ in the Client Address Mask (TWIn.SADDRMASK) register • Any address if the Permissive Mode Enable (PMEN) bit in the Client Control A (TWIn.SCTRLA) register is set to ‘1’ Depending on the Read/Write Direction (DIR) bit in the Client Status (TWIn.SSTATUS) register and the bus condition, one of four distinct cases (S1 to S4) arises after the reception of the address packet. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 345 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface Figure 26-6. TWI Client Operation CLIENT ADDRESS INTERRUPT S4 S3 IF S A ADDRESS R Interrupt flag raised Addressed client provides data on the bus W IF Interrupton STOP Condition Enabled IF P S3 Sr S4 S3 Sr S4 A S3 Sr S4 P S3 A Sr S4 A Sr S4 A IF P P S3 P A A The host provides data on the bus Sn IF CLIENT DATA INTERRUPT S2 DATA A S3 P DATA IF S1 Diagram cases Case S1: Address Packet Accepted - Direction Bit Set to ‘0’ If an ACK is sent by the client after the address packet is received, and the Read/Write Direction (DIR) bit in the Client Status (TWIn.SSTATUS) register is set to ‘0’, the host indicates a write operation. The clock hold is active at this point, forcing the SCL low. This will stretch the low period of the clock to slow down the overall clock frequency, forcing delays required to process the data and preventing further activity on the bus. The software can prepare to: • Read the received data packet from the host Case S2: Address Packet Accepted - Direction Bit Set to ‘1’ If an ACK is sent by the client after the address packet is received, and the DIR bit is set to ‘1’, the host indicates a read operation, and the Data Interrupt Flag (DIF) in the Client Status (TWIn.SSTATUS) register will be set to ‘1’. The clock hold is active at this point, forcing the SCL low. The software can prepare to: • Transmit data packets to the host Case S3: Stop Condition Received When the Stop condition is received, the Address or Stop (AP) flag will be set to ‘0’, indicating that a Stop condition, and not an address match, activated the Address or Stop Interrupt Flag (APIF). The AP and APIF flags are located in the Client Status (TWIn.SSTATUS) register. The software can prepare to: • Wait until a new address packet has been addressed to it Case S4: Collision If the client is not able to send a high-level data bit or a NACK, the Collision (COLL) bit in the Client Status (TWIn.SSTATUS) register is set to ‘1’. The client will commence its operation as normal, except no low values will be shifted out on the SDA. The data and acknowledge output from the client logic will be disabled. The clock hold is released. A Start or repeated Start condition will be accepted. The COLL bit is intended for systems where the Address Resolution Protocol (ARP) is employed. A detected collision in non-ARP situations indicates that there has been a protocol violation and must be treated as a bus error. 26.3.2.3.2 Receiving Data Packets Assuming the above S1 case, the client must be ready to receive data. When a data packet is received, the Data Interrupt Flag (DIF) in the Client Status (TWIn.SSTATUS) register is set to ‘1’. The action selected by the Acknowledge Action (ACKACT) bit in the Client Control B (TWIn.SCTRLB) register is automatically sent on the bus when a command is written to the Command (SCMD) bit field in the TWIn.SCTRLB register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 346 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface The software can prepare to take one of the following actions: • Respond with an ACK by writing ‘0’ to the ACKACT bit in the TWIn.SCTRLB register, indicating that the client is ready to receive more data • Respond with a NACK by writing ‘1’ to the ACKACT bit, indicating that the client cannot receive any more data and the host must issue a Stop or repeated Start condition 26.3.2.3.3 Transmitting Data Packets Assuming the above S2 case, the client can start transmitting data by writing to the Client Data (TWIn.SDATA) register. When a data packet transmission is completed, the Data Interrupt Flag (DIF) in the Client Status (TWIn.SSTATUS) register is set to ‘1’. The software can prepare to take one of the following actions: • Check if the host responded with an ACK by reading the Received Acknowledge (RXACK) bit from the Client Status (TWIn.SSTATUS) register, and start transmitting new data packets • Check if the host responded with a NACK by reading the RXACK bit, and stop transmitting data packets. The host must send a Stop or repeated Start condition after the NACK. 26.3.3 Additional Features 26.3.3.1 SMBus If the TWI is used in an SMBus environment, the Inactive Bus Time-Out (TIMEOUT) bit field from the Host Control A (TWIn.MCTRLA) register must be configured. It is recommended to write to the Host Baud Rate (TWIn.MBAUD) register before setting the time-out because it is dependent on the baud rate setting. A frequency of 100 kHz can be used for the SMBus environment. For the Standard mode (Sm) and Fast mode (Fm), the operating frequency has slew rate limited output, while for the Fast mode Plus (Fm+), it has x10 output drive strength. The TWI also allows for an SMBus compatible SDA hold time configured in the SDA Hold Time (SDAHOLD) bit field from the Control A (TWIn.CTRLA) register. 26.3.3.2 Multi-Host A host can start a bus transaction only if it has detected that the bus is in the Idle state. As the TWI bus is a multi-host bus, more devices may try to initiate a transaction at the same time. This results in multiple hosts owning the bus simultaneously. The TWI solves this problem by using an arbitration scheme where the host loses control of the bus if it is not able to transmit a high-level data bit on the SDA and the Bus State (BUSSTATE) bit field from the Host Status (TWIn.MSTATUS) register will be changed to Busy. The hosts that lose the arbitration must wait until the bus becomes Idle before attempting to reacquire the bus ownership. Both devices can issue a Start condition, but DEVICE1 loses arbitration when attempting to transmit a high-level (bit 5) while DEVICE2 is transmitting a low-level. Figure 26-7. TWI Arbitration DEVICE1 Loses arbitration DEVICE1_SDA DEVICE2_SDA SDA (wired-AND) bit 7 bit 6 bit 5 bit 4 SCL S © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 347 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.3.3.3 Smart Mode The TWI interface has a Smart mode that simplifies the application code and minimizes the user interaction needed to adhere to the I2C protocol. For the TWI host, the Smart mode will automatically send the ACK action as soon as the Host Data (TWIn.MDATA) register is read. This feature is only active when the Acknowledge Action (ACKACT) bit in the Host Control B (TWIn.MCTRLB) register is set to ACK. If the ACKACT bit is set to NACK, the TWI host will not generate a NACK after the MDATA register is read. This feature is enabled when the Smart Mode Enable (SMEN) bit in the Host Control A (TWIn.MCTRLA) register is set to ‘1’. For the TWI client, the Smart mode will automatically send the ACK action as soon as the Client Data (TWIn.SDATA) register is read. The Smart mode will automatically set the Data Interrupt Flag (DIF) to ‘0’ in the Client Status (TWIn.SSTATUS) register if the TWIn.SDATA register is read or written. This feature is enabled when the Smart Mode Enable (SMEN) bit in the Client Control A (TWIn.SCTRLA) register is set to ‘1’. 26.3.3.4 Quick Command Mode With Quick Command mode, the R/W bit from the address packet denotes the command. This mode is enabled by writing ‘1’ to the Quick Command Enable (QCEN) bit in the Host Control A (TWIn.MCTRLA) register. There are no data sent or received. The Quick Command mode is SMBus specific, where the R/W bit can be used to turn a device function on/off or to enable/disable a low-power Standby mode. This mode can be enabled to auto-trigger operations and reduce software complexity. After the host receives an ACK from the client, either the Read Interrupt Flag (RIF) or Write Interrupt Flag (WIF) will be set, depending on the value of the R/W bit. When either the RIF or WIF flag is set after issuing a Quick Command, the TWI will accept a Stop command by writing the Command (MCMD) bit field in the Host Control B (TWIn.MCTRLB) register. The RIF and WIF flags, together with the value of the last Received Acknowledge (RXACK) flag, are all located in the Host Status (TWIn.MSTATUS) register. Figure 26-8. Quick Command Frame Format BUSY P BUSY IDLE S ADDRESS R/W OWNER A P The host provides data on the bus Addressed client provides data on the bus 26.3.3.5 10-bit Address Regardless of whether the transaction is a read or write, the host must start by sending the 10-bit address with the R/W direction bit set to ‘0’. The client address match logic supports recognition of 7-bit addresses and General Call Address. The Client Address (TWIn.SADDR) register is used by the client address match logic to determine if a host device has addressed the TWI client. The TWI client address match logic only supports recognition of the first byte of a 10-bit address, and the second byte must be handled in software. The first byte of the 10-bit address will be recognized if the upper five bits of the Client Address (TWIn.SADDR) register are 0b11110. Thus, the first byte will consist of five indication bits, the two Most Significant bits (MSb) of the 10-bits address, and the R/W direction bit. The Least Significant Byte (LSB) of the address that follows from the host will come in the form of a data packet. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 348 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface Figure 26-9. 10-bit Address Transmission S SW 1 1 1 0 1 A9 A8 W A A7 A6 A5 A4 A3 A2 A1 A0 A S W Software interaction The host provides data on the bus Addressed client provides data on the bus 26.3.4 Interrupts Table 26-1. Available Interrupt Vectors and Sources Name Vector Description Client TWI Client interrupt Host TWI Host interrupt Conditions • DIF: Data Interrupt Flag in TWIn.SSTATUS is set to ‘1’ • APIF: Address or Stop Interrupt Flag in TWIn.SSTATUS is set to ‘1’ • RIF: Read Interrupt Flag in TWIn.MSTATUS is set to ‘1’ • WIF: Write Interrupt Flag in TWIn.MSTATUS is set to ‘1’ When an interrupt condition occurs, the corresponding interrupt flag is set in the Host Status (TWIn.MSTATUS) register or the Client Status (TWIn.SSTATUS) register. When several interrupt request conditions are supported by an interrupt vector, the interrupt requests are ORed together into one combined interrupt request to the interrupt controller. The user must read the interrupt flags from the TWIn.MSTATUS register or the TWIn.SSTATUS register to determine which of the interrupt conditions are present. 26.3.5 Sleep Mode Operation The bus state logic and the address recognition hardware continue to operate in all sleep modes. If a client device is in a sleep mode and a Start condition followed by the address of the client is detected, clock stretching is active during the wake-up period until the main clock is available. The host will stop operation in all sleep modes. 26.3.6 Debug Operation During run-time debugging, the TWI will continue normal operation. Halting the CPU in Debugging mode will halt the normal operation of the TWI. The TWI can be forced to operate with a halted CPU by writing a ‘1’ to the Debug Run (DBGRUN) bit in the Debug Control (TWIn.DBGCTRL) register. When the CPU is halted in Debug mode, and the DBGRUN bit is ‘1’, reading or writing the Host Data (TWIn.MDATA) register or the Client Data (TWIn.SDATA) register will neither trigger a bus operation nor cause transmit and clear flags. If the TWI is configured to require periodical service by the CPU through interrupts or similar, improper operation or data loss may result during halted debugging. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 349 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D 0x0E CTRLA Reserved DBGCTRL MCTRLA MCTRLB MSTATUS MBAUD MADDR MDATA SCTRLA SCTRLB SSTATUS SADDR SDATA SADDRMASK 7:0 26.5 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7 6 5 4 SDASETUP RIEN WIEN RIF WIF DIEN APIEN DIF APIF QCEN 3 2 SDAHOLD[1:0] TIMEOUT[1:0] FLUSH ACKACT CLKHOLD RXACK ARBLOST BUSERR BAUD[7:0] ADDR[7:0] DATA[7:0] PIEN PMEN ACKACT CLKHOLD RXACK COLL BUSERR ADDR[7:0] DATA[7:0] ADDRMASK[6:0] 1 0 FMPEN DBGRUN SMEN ENABLE MCMD[1:0] BUSSTATE[1:0] SMEN ENABLE SCMD[1:0] DIR AP ADDREN Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 350 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.1 Control A Name:  Offset:  Reset:  Property:  Bit 7 CTRLA 0x00 0x00 - 6 Access Reset 5 4 SDASETUP R/W 0 3 2 SDAHOLD[1:0] R/W R/W 0 0 1 FMPEN R/W 0 0 Bit 4 – SDASETUP  SDA Setup Time This bit is used in TWI Client mode to select the clock hold time to ensure minimum setup time on the SDA out signal. By default, there are four clock cycles of setup time on the SDA out signal while reading from the client part of the TWI module. Writing this bit to ‘1’ will change the setup time to eight clock cycles. Value Name Description 0 4CYC SDA setup time is four clock cycles 1 8CYC SDA setup time is eight clock cycles Bits 3:2 – SDAHOLD[1:0]  SDA Hold Time Writing this bit field selects the SDA hold time for the TWI. See the Electrical Characteristics section for details. Value Name Description 0x0 OFF Hold time OFF 0x1 50NS Short hold time 0x2 300NS Meets the SMBus 2.0 specifications under typical conditions 0x3 500NS Meets the SMBus 2.0 specifications across all corners Bit 1 – FMPEN  FM Plus Enable Writing a ‘1’ to this bit selects the 1 MHz bus speed (Fast mode plus, Fm+) for the TWI in default configuration. Value Description 0 Operating in Standard mode or Fast mode 1 Operating in Fast mode plus © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 351 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.2 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x02 0x00 - 6 5 4 3 2 Access Reset 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Debug Run Refer to the Debug Operation section for details. Value Description 0 The TWI is halted in Break Debug mode and ignores events 1 The TWI will continue to run in Break Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 352 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.3 Host Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RIEN R/W 0 MCTRLA 0x03 0x00 - 6 WIEN R/W 0 5 4 QCEN R/W 0 3 2 TIMEOUT[1:0] R/W R/W 0 0 1 SMEN R/W 0 0 ENABLE R/W 0 Bit 7 – RIEN Read Interrupt Enable A TWI host read interrupt will be generated only if this bit and the Global Interrupt Enable (I) bit in the Status (CPU.SREG) register are set to ‘1’. Writing a ‘1’ to this bit enables the interrupt on the Read Interrupt Flag (RIF) in the Host Status (TWIn.MSTATUS) register. When the host read interrupt occurs, the RIF flag is set to ‘1’. Bit 6 – WIEN Write Interrupt Enable A TWI host write interrupt will be generated only if this bit and the Global Interrupt Enable (I) bit in the Status (CPU.SREG) register are set to ‘1’. Writing a ‘1’ to this bit enables the interrupt on the Write Interrupt Flag (WIF) in the Host Status (TWIn.MSTATUS) register. When the host write interrupt occurs, the WIF flag is set to ‘1’. Bit 4 – QCEN Quick Command Enable Writing a ‘1’ to this bit enables the Quick Command mode. If the Quick Command mode is enabled and a client acknowledges the address, the corresponding Read Interrupt Flag (RIF) or Write Interrupt Flag (WIF) will be set depending on the value of the R/W bit. The software must issue a Stop command by writing to the Command (MCMD) bit field in the Host Control B (TWIn.MCTRLB) register. Bits 3:2 – TIMEOUT[1:0] Inactive Bus Time-Out Setting this bit field to a nonzero value will enable the inactive bus time-out supervisor. If the bus is inactive for longer than the TIMEOUT setting, the bus state logic will enter the Idle state. Value Name Description 0x0 DISABLED Bus time-out disabled - I2C 0x1 50US 50 µs - SMBus (assume the baud rate is set to 100 kHz) 0x2 100US 100 µs (assume the baud rate is set to 100 kHz) 0x3 200US 200 µs (assume the baud rate is set to 100 kHz) Bit 1 – SMEN Smart Mode Enable Writing a ‘1’ to this bit enables the Host Smart mode. When the Smart mode is enabled, the existing value in the Acknowledge Action (ACKACT) bit from the Host Control B (TWIn.MCTRLB) register is sent immediately after reading the Host Data (TWIn.MDATA) register. Bit 0 – ENABLE Enable TWI Host Writing a ‘1’ to this bit enables the TWI as host. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 353 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.4 Host Control B Name:  Offset:  Reset:  Property:  Bit MCTRLB 0x04 0x00 - 7 6 5 4 Access Reset 3 FLUSH R/W 0 2 ACKACT R/W 0 1 0 MCMD[1:0] R/W 0 R/W 0 Bit 3 – FLUSH Flush This bit clears the internal state of the host and the bus states changes to Idle. The TWI will transmit invalid data if the Host Data (TWIn.MDATA) register is written before the Host Address (TWIn.MADDR) register. Writing a ‘1’ to this bit generates a strobe for one clock cycle, disabling the host and then re-enabling the host. Writing a ‘0’ to this bit has no effect. Bit 2 – ACKACT Acknowledge Action The ACKACT(1) bit represents the behavior in the Host mode under certain conditions defined by the bus state and the software interaction. If the Smart Mode Enable (SMEN) bit in the Host Control A (TWIn.MCTRLA) register is set to ‘1’, the acknowledge action is performed when the Host Data (TWIn.MDATA) register is read, else a command must be written to the Command (MCDM) bit field in the Host Control B (TWIn.MCTRLB) register. The acknowledge action is not performed when the Host Data (TWIn.MDATA) register is written since the host is sending data. Value Name Description 0 ACK Send ACK 1 NACK Send NACK Bits 1:0 – MCMD[1:0] Command The MCMD(1) bit field is a strobe. This bit field is always read as ‘0’. Writing to this bit field triggers a host operation, as defined by the table below. Table 26-2. Command Settings MCMD[1:0] Group Configuration DIR Description 0x0 NOACT X Reserved 0x1 REPSTART 0x2 RECVTRANS 0x3 STOP X Execute Acknowledge Action followed by repeated Start condition W Execute Acknowledge Action (no action) followed by a byte write operation(2) R Execute Acknowledge Action followed by a byte read operation X Execute Acknowledge Action followed by issuing a Stop condition Notes:  1. The ACKACT bit and the MCMD bit field can be written at the same time. 2. For a host write operation, the TWI will wait for new data to be written to the Host Data (TWIn.MDATA) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 354 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.5 Host Status Name:  Offset:  Reset:  Property:  Bit 7 RIF R/W 0 Access Reset MSTATUS 0x05 0x00 - 6 WIF R/W 0 5 CLKHOLD R/W 0 4 RXACK R 0 3 ARBLOST R/W 0 2 BUSERR R/W 0 1 0 BUSSTATE[1:0] R/W R/W 0 0 Bit 7 – RIF Read Interrupt Flag This flag is set to ‘1’ when the host byte read operation is completed. The RIF flag can be used for a host read interrupt. More information can be found in the Read Interrupt Enable (RIEN) bit from the Host Control A (TWIn.MCTRLA) register. This flag is automatically cleared when accessing several other TWI registers. The RIF flag can be cleared by choosing one of the following methods: 1. Writing a ‘1’ to it. 2. 3. 4. Writing to the Host Address (TWIn.MADDR) register. Writing/Reading the Host Data (TWIn.MDATA) register. Writing to the Command (MCMD) bit field from the Host Control B (TWIn.MCTRLB) register. Bit 6 – WIF Write Interrupt Flag This flag is set to ‘1’ when a host transmit address or byte write operation is completed, regardless of the occurrence of a bus error or arbitration lost condition. The WIF flag can be used for a host write interrupt. More information can be found from the Write Interrupt Enable (WIEN) bit in the Host Control A (TWIn.MCTRLA) register. This flag can be cleared by choosing one of the methods described for the RIF flag. Bit 5 – CLKHOLD Clock Hold When this bit is read as ‘1’, it indicates that the host is currently holding the SCL low, stretching the TWI clock period. This bit can be cleared by choosing one of the methods described for the RIF flag. Bit 4 – RXACK Received Acknowledge When this flag is read as ‘0’, it indicates that the most recent Acknowledge bit from the client was ACK, and the client is ready for more data. When this flag is read as ‘1’, it indicates that the most recent Acknowledge bit from the client was NACK, and the client is not able to or does not need to receive more data. Bit 3 – ARBLOST Arbitration Lost When this bit is read as ‘1’, it indicates that the host has lost arbitration. This can happen in one of the following cases: 1. While transmitting a high data bit. 2. While transmitting a NACK bit. 3. While issuing a Start condition (S). 4. While issuing a repeated Start (Sr). This flag can be cleared by choosing one of the methods described for the RIF flag. Bit 2 – BUSERR Bus Error The BUSERR flag indicates that an illegal bus operation has occurred. An illegal bus operation is detected if a protocol violating the Start (S), repeated Start (Sr), or Stop (P) conditions is detected on the TWI bus lines. A Start condition directly followed by a Stop condition is one example of a protocol violation. The BUSERR flag can be cleared by choosing one of the following methods: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 355 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 1. Writing a ‘1’ to it. 2. Writing to the Host Address (TWIn.MADDR) register. The TWI bus error detector is part of the TWI host circuitry. For the bus errors to be detected, the TWI host must be enabled (ENABLE bit in TWIn.MCTRLA is ‘1’), and the main clock frequency must be at least four times the SCL frequency. Bits 1:0 – BUSSTATE[1:0] Bus State This bit field indicates the current TWI bus state. Value Name Description 0x0 UNKNOWN Unknown bus state 0x1 IDLE Idle bus state 0x2 OWNER This TWI controls the bus 0x3 BUSY Busy bus state © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 356 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.6 Host Baud Rate Name:  Offset:  Reset:  Property:  Bit 7 MBAUD 0x06 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 BAUD[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – BAUD[7:0] Baud Rate This bit field is used to derive the SCL high and low time. It must be written while the host is disabled. The host can be disabled by writing ‘0’ to the Enable TWI Host (ENABLE) bit from the Host Control A (TWIn.MCTRLA) register. Refer to the Clock Generation section for more information on how to calculate the frequency of the SCL. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 357 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.7 Host Address Name:  Offset:  Reset:  Property:  Bit 7 MADDR 0x07 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 ADDR[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – ADDR[7:0] Address This register contains the address of the external client device. When this bit field is written, the TWI will issue a Start condition, and the shift register performs a byte transmit operation on the bus depending on the bus state. This register can be read at any time without interfering with the ongoing bus activity since a read access does not trigger the host logic to perform any bus protocol related operations. The host control logic uses the bit 0 of this register as the R/W direction bit. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 358 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.8 Host Data Name:  Offset:  Reset:  Property:  Bit 7 MDATA 0x08 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 DATA[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DATA[7:0] Data This bit field provides direct access to the host’s physical shift register, which is used to shift out data on the bus (transmit) and to shift in data received from the bus (receive). The direct access implies that the MDATA register cannot be accessed during byte transmissions. Reading valid data or writing data to be transmitted can only be successful when the CLKHOLD bit is read as ‘1’ or when an interrupt occurs. A write access to the MDATA register will command the host to perform a byte transmit operation on the bus, directly followed by receiving the Acknowledge bit from the client. This is independent of the Acknowledge Action (ACKACT) bit from the Host Control B (TWIn.MCTRLB) register. The write operation is performed regardless of winning or losing arbitration before the Write Interrupt Flag (WIF) is set to ‘1’. If the Smart Mode Enable (SMEN) bit in the Host Control A (TWIn.MCTRLA) register is set to ‘1’, a read access to the MDATA register will command the host to perform an acknowledge action. This is dependent on the setting of the Acknowledge Action (ACKACT) bit from the Host Control B (TWIn.MCTRLB) register. Notes:  1. The WIF and RIF flags are cleared automatically if the MDATA register is read while ACKACT is set to ‘1’. 2. 3. The ARBLOST and BUSEER flags are left unchanged. The WIF, RIF, ARBLOST, and BUSERR flags together with the Clock Hold (CLKHOLD) bit are all located in the Host Status (TWIn.MSTATUS) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 359 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.9 Client Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 DIEN R/W 0 SCTRLA 0x09 0x00 - 6 APIEN R/W 0 5 PIEN R/W 0 4 3 2 PMEN R/W 0 1 SMEN R/W 0 0 ENABLE R/W 0 Bit 7 – DIEN Data Interrupt Enable Writing this bit to ‘1’ enables an interrupt on the Data Interrupt Flag (DIF) from the Client Status (TWIn.SSTATUS) register. A TWI client data interrupt will be generated only if this bit, the DIF flag, and the Global Interrupt Enable (I) bit in the Status (CPU.SREG) register are all ‘1’. Bit 6 – APIEN Address or Stop Interrupt Enable Writing this bit to ‘1’ enables an interrupt on the Address or Stop Interrupt Flag (APIF) from the Client Status (TWIn.SSTATUS) register. A TWI client address or stop interrupt will be generated only if this bit, the APIF flag, and the Global Interrupt Enable (I) bit in the Status (CPU.SREG) register are all ‘1’. Notes:  1. The client stop interrupt shares the interrupt flag and vector with the client address interrupt. 2. The Stop Interrupt Enable (PIEN) bit in the Client Control A (TWIn.SCTRLA) register must be written to ‘1’ for the APIF to be set on a Stop condition. 3. When the interrupt occurs, the Address or Stop (AP) bit in the Client Status (TWIn.SSTATUS) register will determine whether an address match or a Stop condition caused the interrupt. Bit 5 – PIEN Stop Interrupt Enable Writing this bit to ‘1’ allows the Address or Stop Interrupt Flag (APIF) in the Client Status (TWIn.SSTATUS) register to be set when a Stop condition occurs. The main clock frequency must be at least four times the SCL frequency to use this feature. Bit 2 – PMEN Permissive Mode Enable If this bit is written to ‘1’, the client address match logic responds to all received addresses. If this bit is written to ‘0’, the address match logic uses the Client Address (TWIn.SADDR) register to determine which address to recognize as the client’s address. Bit 1 – SMEN Smart Mode Enable Writing this bit to ‘1’ enables the client Smart mode. When the Smart mode is enabled, issuing a command by writing to the Command (SCMD) bit field in the Client Control B (TWIn.SCTRLB) register or accessing the Client Data (TWIn.SDATA) register resets the interrupt, and the operation continues. If the Smart mode is disabled, the client always waits for a new client command before continuing. Bit 0 – ENABLE Enable TWI Client Writing this bit to ‘1’ enables the TWI client. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 360 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.10 Client Control B Name:  Offset:  Reset:  Property:  Bit SCTRLB 0x0A 0x00 - 7 6 5 4 3 Access Reset 2 ACKACT R/W 0 1 0 SCMD[1:0] R/W 0 R/W 0 Bit 2 – ACKACT Acknowledge Action The ACKACT(1) bit represents the behavior of the client device under certain conditions defined by the bus protocol state and the software interaction. If the Smart Mode Enable (SMEN) bit in the Client Control A (TWIn.SCTRLA) register is set to ‘1’, the acknowledge action is performed when the Client Data (TWIn.SDATA) register is read, else a command must be written to the Command (SCMD) bit field in the Client Control B (TWIn.SCTRLB) register. The acknowledge action is not performed when the Client Data (TWIn.SDATA) register is written since the client is sending data. Value Name Description 0 ACK Send ACK 1 NACK Send NACK Bits 1:0 – SCMD[1:0] Command The SCMD(1) bit field is a strobe. This bit field is always read as ‘0’. Writing to this bit field triggers a client operation as defined by the table below. Table 26-3. Command Settings Value Name 0x0 0x1 NOACT — 0x2 COMPTRANS DIR Description X X W R W 0x3 RESPONSE R No action Reserved Execute Acknowledge Action succeeded by waiting for any Start (S/Sr) condition Used to complete a transaction Wait for any Start (S/Sr) condition Execute Acknowledge Action succeeded by reception of next byte Used in response to an address interrupt (APIF): Execute Acknowledge Action succeeded by client data interrupt. Used in response to a data interrupt (DIF): Execute a byte read operation followed by Acknowledge Action. Note:  1. The ACKACT bit and the SCMD bit field can be written at the same time. The ACKACT will be updated before the command is triggered. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 361 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.11 Client Status Name:  Offset:  Reset:  Property:  Bit 7 DIF R/W 0 Access Reset SSTATUS 0x0B 0x00 - 6 APIF R/W 0 5 CLKHOLD R 0 4 RXACK R 0 3 COLL R/W 0 2 BUSERR R/W 0 1 DIR R 0 0 AP R 0 Bit 7 – DIF Data Interrupt Flag This flag is set to ‘1’ when the client byte transmit or receive operation is completed without any bus errors. This flag can be set to ‘1’ with an unsuccessful transaction in case of collision detection. More information can be found in the Collision (COLL) bit description. The DIF flag can generate a client data interrupt. More information can be found in Data Interrupt Enable (DIEN) bit from the Client Control A (TWIn.SCTRLA) register. This flag is automatically cleared when accessing several other TWI registers. The DIF flag can be cleared by choosing one of the following methods: 1. Writing/Reading the Client Data (TWIn.SDATA) register. 2. Writing to the Command (SCMD) bit field from the Client Control B (TWIn.SCTRLB) register. Bit 6 – APIF Address or Stop Interrupt Flag This flag is set to ‘1’ when the client address has been received or by a Stop condition. The APIF flag can generate a client address or stop interrupt. More information can be found in the Address or Stop Interrupt Enable (APIEN) bit from the Client Control A (TWIn.SCTRLA) register. This flag can be cleared by choosing one of the methods described for the DIF flag. Bit 5 – CLKHOLD Clock Hold When this bit is read as ‘1’, it indicates that the client is currently holding the SCL low, stretching the TWI clock period. This bit is set to ‘1’ when an address or data interrupt occurs. Resetting the corresponding interrupt will indirectly set this bit to ‘0’. Bit 4 – RXACK Received Acknowledge When this flag is read as ‘0’, it indicates that the most recent Acknowledge bit from the host was ACK. When this flag is read as ‘1’, it indicates that the most recent Acknowledge bit from the host was NACK. Bit 3 – COLL Collision When this bit is read as ‘1’, it indicates that the client has not been able to do one of the following: 1. 2. Transmit high bits on the SDA. The Data Interrupt Flag (DIF) will be set to ‘1’ at the end as a result of the internal completion of an unsuccessful transaction. Transmit the NACK bit. The collision occurs because the client address match already took place, and the APIF flag is set to ‘1’ as a result. Writing a ‘1’ to this bit will clear the COLL flag. The flag is automatically cleared if any Start condition (S/Sr) is detected. Note:  The APIF and DIF flags can only generate interrupts whose handlers can be used to check for the collision. Bit 2 – BUSERR Bus Error The BUSERR flag indicates that an illegal bus operation has occurred. An illegal bus operation is detected if a protocol violating the Start (S), repeated Start (Sr), or Stop (P) conditions is detected on the TWI bus lines. A Start condition directly followed by a Stop condition is one example of a protocol violation. Writing a ‘1’ to this bit will clear the BUSERR flag. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 362 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface The TWI bus error detector is part of the TWI Host circuitry. For the bus errors to be detected by the client, the TWI Host must be enabled, and the main clock frequency must be at least four times the SCL frequency. The TWI Host can be enabled by writing ‘1’ to the ENABLE bit in the TWIn.MCTRLA register. Bit 1 – DIR Read/Write Direction This bit indicates the current TWI bus direction. The DIR bit reflects the direction bit value from the last address packet received from a host TWI device. When this bit is read as ‘1’, it indicates that a host read operation is in progress. When this bit is read as ‘0’, it indicates that a host write operation is in progress. Bit 0 – AP Address or Stop When the TWI client Address or Stop Interrupt Flag (APIF) is set ‘1’, this bit determines whether the interrupt is due to an address detection or a Stop condition. Value Name Description 0 STOP A Stop condition generated the interrupt on the APIF flag 1 ADR Address detection generated the interrupt on the APIF flag © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 363 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.12 Client Address Name:  Offset:  Reset:  Property:  Bit 7 SADDR 0x0C 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 ADDR[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – ADDR[7:0] Address The Client Address (TWIn.SADDR) register is used by the client address match logic to determine if a host device has addressed the TWI client. The Address or Stop Interrupt Flag (APIF) and the Address or Stop (AP) bit in the Client Status (TWIn.SSTATUS) register are set to ‘1’ if an address packet is received. The upper seven bits (ADDR[7:1]) of the TWIn.SADDR register represent the main client address. The Least Significant bit (ADDR[0]) of the TWIn.SADDR register is used for the recognition of the General Call Address (0x00) of the I2C protocol. This feature is enabled when this bit is set to ‘1’. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 364 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.13 Client Data Name:  Offset:  Reset:  Property:  Bit 7 SDATA 0x0D 0x00 - 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 DATA[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – DATA[7:0] Data This bit field provides access to the client data register. Reading valid data or writing data to be transmitted can only be achieved when the SCL is held low by the client (i.e., when the client CLKHOLD bit is set to ‘1’). It is not necessary to check the Clock Hold (CLKHOLD) bit from the Client Status (TWIn.SSTATUS) register in software before accessing the SDATA register if the software keeps track of the present protocol state by using interrupts or observing the interrupt flags. If the Smart Mode Enable (SMEN) bit in the Client Control A (TWIn.SCTRLA) register is set to ‘1’, a read access to the SDATA register, when the clock hold is active, auto-triggers bus operations and will command the client to perform an acknowledge action. This is dependent on the setting of the Acknowledge Action (ACKACT) bit from the Client Control B (TWIn.SCTRLB) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 365 ATtiny424/426/427 ATtiny824/826/827 TWI - Two-Wire Interface 26.5.14 Client Address Mask Name:  Offset:  Reset:  Property:  Bit Access Reset SADDRMASK 0x0E 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 ADDRMASK[6:0] R/W 0 3 2 1 R/W 0 R/W 0 R/W 0 0 ADDREN R/W 0 Bits 7:1 – ADDRMASK[6:0] Address Mask The ADDRMASK bit field acts as a second address match or an address mask register depending on the ADDREN bit. If the ADDREN bit is written to ‘0’, the ADDRMASK bit field can be loaded with a 7-bit Client Address mask. Each of the bits in the Client Address Mask (TWIn.SADDRMASK) register can mask (disable) the corresponding address bits in the TWI Client Address (TWIn.SADDR) register. When a bit from the mask is written to ‘1’, the address match logic ignores the comparison between the incoming address bit and the corresponding bit in the Client Address (TWIn.SADDR) register. In other words, masked bits will always match, making it possible to recognize the ranges of addresses. If the ADDREN bit is written to ‘1’, the Client Address Mask (TWIn.SADDRMASK) register can be loaded with a second client address in addition to the Client Address (TWIn.SADDR) register. In this mode, the client will have two unique addresses, one in the Client Address (TWIn.SADDR) register and the other one in the Client Address Mask (TWIn.SADDRMASK) register. Bit 0 – ADDREN Address Mask Enable If this bit is written to ‘0’, the TWIn.SADDRMASK register acts as a mask to the TWIn.SADDR register. If this bit is written to ‘1’, the client address match logic responds to the two unique addresses in the client TWIn.SADDR and TWIn.SADDRMASK registers. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 366 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... 27. CRCSCAN - Cyclic Redundancy Check Memory Scan 27.1 Features • • • • 27.2 CRC-16-CCITT Check of the Entire Flash Section, Application Code, and/or Boot Section Selectable NMI Trigger on Failure User-Configurable Check During Internal Reset Initialization Overview A Cyclic Redundancy Check (CRC) takes a data stream of bytes from the NVM (either the entire Flash, only the Boot section, or both the Boot section and the application code section) and generates a checksum. The CRC peripheral (CRCSCAN) can be used to detect errors in the program memory. The last location in the section to check has to contain the correct pre-calculated 16-bit checksum for comparison. If the checksum calculated by the CRCSCAN and the pre-calculated checksums match, a status bit is set. If they do not match, the Status register (CRCSCAN.STATUS) will indicate that it failed. The user can choose to let the CRCSCAN generate a Non-Maskable Interrupt (NMI) if the checksums do not match. An n-bit CRC applied to a data block of arbitrary length will detect any single alteration (error burst) up to n bits in length. For longer error bursts a fraction 1-2-n will be detected. The CRC generator supports CRC-16-CCITT. Polynomial: • CRC-16-CCITT: x16 + x12 + x5 + 1 The CRC reads byte-by-byte the content of the section(s) it is set up to check, starting with byte 0, and generates a new checksum per byte. The byte is sent through a shift register as depicted below, starting with the Most Significant bit. If the last bytes in the section contain the correct checksum, the CRC will pass. See 27.3.2.1 Checksum for how to place the checksum. The initial value of the Checksum register is 0xFFFF. Figure 27-1. CRC Implementation Description data 15 x14 x13 x12 x11 x10 x9 x8 x7 x6 x5 x4 x3 x2 x1 x0 Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D Q D x © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 367 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... 27.2.1 Block Diagram Figure 27-2. Cyclic Redundancy Check Block Diagram Memory (Boot, App, Flash) CTRLB CTRLA Source Enable, Reset CRC calculation BUSY STATUS CRC OK CHECKSUM 27.3 Functional Description 27.3.1 Initialization NMI Req To enable a CRC in software (or via the debugger): 1. Write the Source (SRC) bit field of the Control B register (CRCSCAN.CTRLB) to select the desired mode and source settings. 2. Enable the CRCSCAN by writing a ‘1’ to the ENABLE bit in the Control A register (CRCSCAN.CTRLA). 3. The CRC will start after three cycles. The CPU will continue executing during these three cycles. The CRCSCAN can be configured to perform a code memory scan before the device leaves Reset. If this check fails, the CPU is not allowed to start normal code execution. This feature is enabled and controlled by the CRCSRC field in FUSE.SYSCFG0, see the Fuses chapter for more information. If this feature is enabled, a successful CRC check will have the following outcome: • Normal code execution starts • The ENABLE bit in CRCSCAN.CTRLA will be ‘1’ • • The SRC bit field in CRCSCAN.CTRLB will reflect the checked section(s) The OK flag in CRCSCAN.STATUS will be ‘1’ If this feature is enabled, a non-successful CRC check will have the following outcome: • Normal code execution does not start, the CPU will hang executing no code • The ENABLE bit in CRCSCAN.CTRLA will be ‘1’ 27.3.2 • • The SRC bit field in CRCSCAN.CTRLB will reflect the checked section(s) The OK flag in CRCSCAN.STATUS will be ‘0’ • This condition may be observed using the debug interface Operation When the CRC is operating in Priority mode, the CRC peripheral has priority access to the Flash and will stall the CPU until completed. In Priority mode the CRC fetches a new word (16-bit) on every third main clock cycle, or when the CRC peripheral is configured to do a scan from start-up. 27.3.2.1 Checksum The pre-calculated checksum must be present in the last location of the section to be checked. If the BOOT section is to be checked, the checksum must be saved in the last bytes of the BOOT section, and similarly for APPLICATION and the entire Flash. Table 27-1 shows explicitly how the checksum must be stored for the different sections. Also, © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 368 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... see the CRCSCAN.CTRLB register description for how to configure which section to check and the device fuse description for how to configure the BOOTEND and APPEND fuses. Table 27-1. Placement of the Pre-Calculated Checksum in Flash 27.3.3 Section to Check CHECKSUM[15:8] CHECKSUM[7:0] BOOT FUSE_BOOTEND*256-2 FUSE_BOOTEND*256-1 BOOT and APPLICATION FUSE_APPEND*256-2 FUSE_APPEND*256-1 Full Flash FLASHEND-1 FLASHEND Interrupts Table 27-2. Available Interrupt Vectors and Sources Name Vector Description Conditions NMI Non-Maskable Interrupt CRC failure When the interrupt condition occurs the OK flag in the Status (CRCSCAN.STATUS) register is cleared to ‘0’. A Non-Maskable Interrupt (NMI) is enabled by writing a ‘1’ to the respective Enable (NMIEN) bit in the Control A (CRCSCAN.CTRLA) register, but can only be disabled with a System Reset. An NMI is generated when the OK flag in the CRCSCAN.STATUS register is cleared, and the NMIEN bit is ‘1’. The NMI request remains active until a System Reset and cannot be disabled. An NMI can be triggered even if interrupts are not globally enabled. 27.3.4 Sleep Mode Operation CRCSCAN is halted in all Sleep modes. In all CPU Sleep modes, the CRCSCAN peripheral is halted and will resume operation when the CPU wakes up. The CRCSCAN starts operation three cycles after writing the EN bit in CRCSCAN.CTRLA. During these three cycles, it is possible to enter Sleep mode. In this case: 1. The CRCSCAN will not start until the CPU is woken up. 2. Any interrupt handler will execute after CRCSCAN has finished. 27.3.5 Debug Operation Whenever the debugger reads or writes a peripheral or memory location, the CRCSCAN will be disabled. If the CRCSCAN is busy when the debugger accesses the device, the CRCSCAN will restart the ongoing operation when the debugger accesses an internal register or when the debugger disconnects. The BUSY bit in the Status (CRCSCAN.STATUS) register will read ‘1’ if the CRCSCAN was busy when the debugger caused it to disable, but it will not actively check any section as long as the debugger keeps it disabled. There are synchronized CRC status bits in the debugger's internal register space, which can be read by the debugger without disabling the CRCSCAN. Reading the debugger's internal CRC status bits will make sure that the CRCSCAN is enabled. It is possible to write the CRCSCAN.STATUS register directly from the debugger: • BUSY bit in CRCSCAN.STATUS: – Writing the BUSY bit to ‘0’ will stop the ongoing CRC operation (so that the CRCSCAN does not restart its operation when the debugger allows it). – Writing the BUSY bit to ‘1’ will make the CRC start a single check with the settings in the Control B (CRCSCAN.CTRLB) register, but not until the debugger allows it. • As long as the BUSY bit in CRCSCAN.STATUS is ‘1’, CRCSCAN.CTRLB and the Non-Maskable Interrupt Enable (NMIEN) bit in the Control A (CRCSCAN.CTRLA) register cannot be altered. OK bit in CRCSCAN.STATUS: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 369 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... – Writing the OK bit to ‘0’ can trigger a Non-Maskable Interrupt (NMI) if the NMIEN bit in CRCSCAN.CTRLA is ‘1’. If an NMI has been triggered, no writes to the CRCSCAN are allowed. – Writing the OK bit to ‘1’ will make the OK bit read as ‘1’ when the BUSY bit in CRCSCAN.STATUS is ‘0’. Writes to CRCSCAN.CTRLA and CRCSCAN.CTRLB from the debugger are treated in the same way as writes from the CPU. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 370 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... 27.4 Register Summary Offset Name Bit Pos. 7 0x00 0x01 0x02 CTRLA CTRLB STATUS 7:0 7:0 7:0 RESET 27.5 6 5 4 MODE[1:0] 3 2 1 0 NMIEN ENABLE SRC[1:0] OK BUSY Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 371 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... 27.5.1 Control A Name:  Offset:  Reset:  Property:  CTRLA 0x00 0x00 - If an NMI has been triggered this register is not writable. Bit Access Reset 7 RESET R/W 0 6 5 4 3 2 1 NMIEN R/W 0 0 ENABLE R/W 0 Bit 7 – RESET Reset CRCSCAN Writing this bit to ‘1’ resets the CRCSCAN peripheral. The CRCSCAN Control registers and Status register (CRCSCAN.CTRLA, CRCSCAN.CTRLB, CRCSCAN.STATUS) will be cleared one clock cycle after the RESET bit is written to ‘1’. If NMIEN is ‘0’, this bit is writable both when the CRCSCAN is busy (the BUSY bit in CRCSCAN.STATUS is ‘1’) and not busy (the BUSY bit is ‘0’), and will take effect immediately. If NMIEN is ‘1’, this bit is only writable when the CRCSCAN is not busy (the BUSY bit in CRCSCAN.STATUS is ‘0’). The RESET bit is a strobe bit. Bit 1 – NMIEN Enable NMI Trigger When this bit is written to ‘1’, any CRC failure will trigger an NMI. This bit can only be cleared by a system Reset - it is not cleared by a write to the RESET bit. This bit can only be written to ‘1’ when the CRCSCAN is not busy (the BUSY bit in CRCSCAN.STATUS is ‘0’). Bit 0 – ENABLE Enable CRCSCAN Writing this bit to ‘1’ enables the CRCSCAN peripheral with the current settings. It will stay ‘1’ even after a CRC check has completed, but writing it to ‘1’ again will start a new check. Writing the bit to ‘0’ has no effect The CRCSCAN can be configured to run a scan during the MCU start-up sequence to verify the Flash sections before letting the CPU start normal code execution (see the 27.3.1 Initialization section). If this feature is enabled, the ENABLE bit will read as ‘1’ when normal code execution starts. To see whether the CRCSCAN peripheral is busy with an ongoing check, poll the BUSY bit in the Status register (CRCSCAN.STATUS). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 372 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... 27.5.2 Control B Name:  Offset:  Reset:  Property:  CTRLB 0x01 0x00 - The CRCSCAN.CTRLB register contains the mode and source settings for the CRC. It is not writable when the CRC is busy, or when an NMI has been triggered. Bit 7 6 5 4 3 2 1 0 MODE[1:0] Access Reset R/W 0 SRC[1:0] R/W 0 R/W 0 R/W 0 Bits 5:4 – MODE[1:0] CRC Flash Access Mode The CRC can be enabled during internal Reset initialization to verify Flash sections before letting the CPU start (see the device data sheet fuse description). If the CRC is enabled during internal Reset initialization, the MODE bit field will read out non-zero when normal code execution starts. To ensure proper operation of the CRC under code execution, write the MODE bit to 0x0 again. Value Name Description 0x0 PRIORITY The CRC module runs a single check with priority to Flash. The CPU is halted until the CRC completes. other Reserved Bits 1:0 – SRC[1:0] CRC Source The SRC bit field selects which section of the Flash the CRC module will check. To set up section sizes, refer to the fuse description. The CRC can be enabled during internal Reset initialization to verify Flash sections before letting the CPU start (see the Fuses chapter). If the CRC is enabled during internal Reset initialization, the SRC bit field will read out as FLASH, BOOTAPP, or BOOT when normal code execution starts (depending on the configuration). Value Name Description 0x0 FLASH The CRC is performed on the entire Flash (boot, application code, and application data sections). 0x1 BOOTAPP The CRC is performed on the boot and application code sections of Flash. 0x2 BOOT The CRC is performed on the boot section of Flash. 0x3 Reserved. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 373 ATtiny424/426/427 ATtiny824/826/827 CRCSCAN - Cyclic Redundancy Check Memory Sca... 27.5.3 Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x02 0x02 - 6 5 4 3 Access Reset 2 1 OK R 1 0 BUSY R 0 Bit 1 – OK CRC OK When this bit is read as ‘1’, the previous CRC completed successfully. The bit is set to ‘1’ by default before a CRC scan is run. The bit is not valid unless BUSY is ‘0’. Bit 0 – BUSY CRC Busy When this bit is read as ‘1’, the CRCSCAN is busy. As long as the module is busy, the access to the control registers is limited. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 374 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28. CCL - Configurable Custom Logic 28.1 Features • • • • • • • • • 28.2 Glue Logic for General Purpose PCB Design 4 Programmable Look-Up Tables (LUTs) Combinatorial Logic Functions: Any Logic Expression which is a Function of up to Three Inputs. Sequencer Logic Functions: – Gated D flip-flop – JK flip-flop – Gated D latch – RS latch Flexible LUT Input Selection: – I/Os – Events – Subsequent LUT output – Internal peripherals such as: • Analog comparator • Timers/Counters • USART • SPI Clocked by a System Clock or other Peripherals Output can be Connected to I/O Pins or an Event System Optional Synchronizer, Filter, or Edge Detector Available on Each LUT Output Optional Interrupt Generation from Each LUT Output: – Rising edge – Falling edge – Both edges Overview The Configurable Custom Logic (CCL) is a programmable logic peripheral which can be connected to the device pins, to events, or to other internal peripherals. The CCL can serve as ‘glue logic’ between the device peripherals and external devices. The CCL can eliminate the need for external logic components, and can also help the designer to overcome real-time constraints by combining Core Independent Peripherals (CIPs) to handle the most time-critical parts of the application independent of the CPU. The CCL peripheral provides a number of Look-up Tables (LUTs). Each LUT consists of three inputs, a truth table, a synchronizer/filter, and an edge detector. Each LUT can generate an output as a user programmable logic expression with three inputs. The output is generated from the inputs using the combinatorial logic and can be filtered to remove spikes. The CCL can be configured to generate an interrupt request on changes in the LUT outputs. Neighboring LUTs can be combined to perform specific operations. A sequencer can be used for generating complex waveforms. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 375 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.2.1 Block Diagram Figure 28-1. Configurable Custom Logic Even LUT n INSEL Internal Events I/O Peripherals FILTSEL LUTn-TRUTHSEL[2:0] Filter/ Synch TRUTH CLKSRC Edge Detector LUTn-OUT CLK_LUTn Clock Sources LUTn-TRUTHSEL[2] Sequencer Odd LUT n+1 INSEL Internal Events I/O Peripherals FILTSEL LUTn+1-TRUTHSEL[2:0] Filter/ Synch TRUTH CLKSRC SEQSEL EDGEDET EDGEDET LUTn+1-OUT Edge Detector CLK_LUTn+1 Clock Sources LUTn+1-TRUTHSEL[2] Table 28-2. Sequencer and LUT Connection 28.2.2 Sequencer Even and Odd LUT SEQ0 LUT0 and LUT1 SEQ1 LUT2 and LUT3 Signal Description Name Type Description LUTn-OUT Digital output Output from the look-up table LUTn-IN[2:0] Digital input Input to the look-up table. LUTn-IN[2] can serve as CLK_LUTn. Refer to I/O Multiplexing and Considerations for details on the pin mapping for this peripheral. One signal can be mapped to several pins. 28.2.2.1 CCL Input Selection MUX The following peripherals outputs are available as inputs into the CCL LUT. Value Input source 0x00 MASK None 0x01 FEEDBACK LUTn 0x02 LINK LUT(n+1) 0x03 EVENTA EVENTA 0x04 EVENTB EVENTB 0x05 IO 0x06 AC0 0x07 - © 2021 Microchip Technology Inc. INSEL0[3:0] IN0 INSEL1[3:0] IN1 INSEL2[3:0] IN2 AC0 OUT - Preliminary Datasheet DS40002311A-page 376 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic ...........continued Value Input source INSEL0[3:0] INSEL1[3:0] INSEL2[3:0] 0x08(1) USARTn USART0 TXD USART1 TXD - 0x09(2) SPI SPI0 MOSI SPI0 MOSI SPI0 SCK WO0 WO1 WO2 0x0A TCA0 0x0B - 0x0C TCB TCB0 WO TCB1 WO - Notes:  1. USART connections to the CCL work only in asynchronous/synchronous USART host mode. 2. SPI connections to the CCL work only in host SPI mode. 28.3 Functional Description 28.3.1 Operation 28.3.1.1 Enable-Protected Configuration The configuration of the LUTs and sequencers is enable-protected, meaning that they can only be configured when the corresponding even LUT is disabled (ENABLE=‘0’ in the LUT n Control A (CCL.LUTnCTRLA) register). This is a mechanism to suppress the undesired output from the CCL under (re-)configuration. The following bits and registers are enable-protected: • • Sequencer Selection (SEQSEL) in the Sequencer Control n (CCL.SEQCTRLn) register LUT n Control x (CCL.LUTnCTRLx) registers, except the ENABLE bit in CCL.LUTnCTRLA The enable-protected bits in the CCL.LUTnCTRLx registers can be written at the same time as ENABLE in CCL.LUTnCTRLA is written to ‘1’, but not at the same time as ENABLE is written to ‘0’. The enable protection is denoted by the enable-protected property in the register description. 28.3.1.2 Enabling, Disabling, and Resetting The CCL is enabled by writing a ‘1’ to the ENABLE bit in the Control A (CCL.CTRLA) register. The CCL is disabled by writing a ‘0’ to that ENABLE bit. Each LUT is enabled by writing a ‘1’ to the LUT Enable (ENABLE) bit in the LUT n Control A (CCL.LUTnCTRLA) register. Each LUT is disabled by writing a ‘0’ to the ENABLE bit in CCL.LUTnCTRLA. 28.3.1.3 Truth Table Logic The truth table in each LUT unit can generate a combinational logic output as a function of up to three inputs (LUTn-TRUTHSEL[2:0]). It is possible to realize any 3-input boolean logic function using one LUT. Figure 28-2. Truth Table Output Value Selection of a LUT TRUTHn[0] TRUTHn[1] TRUTHn[2] TRUTHn[3] TRUTHn[4] TRUTHn[5] TRUTHn[6] TRUTHn[7] OUT LUTn-TRUTHSEL[2:0] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 377 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic The truth table inputs (LUTn-TRUTHSEL[2:0]) are configured by writing the Input Source Selection bit fields in the LUT Control registers: • INSEL0 in CCL.LUTnCTRLB • INSEL1 in CCL.LUTnCTRLB • INSEL2 in CCL.LUTnCTRLC Each combination of the input bits (LUTn-TRUTHSEL[2:0]) corresponds to one bit in the CCL.TRUTHn register, as shown in the table below: Table 28-3. Truth Table of a LUT LUTn-TRUTHSEL[2] LUTn-TRUTHSEL[1] LUTn-TRUTHSEL[0] OUT 0 0 0 TRUTHn[0] 0 0 1 TRUTHn[1] 0 1 0 TRUTHn[2] 0 1 1 TRUTHn[3] 1 0 0 TRUTHn[4] 1 0 1 TRUTHn[5] 1 1 0 TRUTHn[6] 1 1 1 TRUTHn[7] Important:  Consider the unused inputs turned off (tied low) when logic functions are created. Example 28-1. LUT Output for CCL.TRUTHn = 0x42 If CCL.TRUTHn is configured to 0x42, the LUT output will be 1 when the inputs are 'b001 or 'b110 and 0 for any other combination of inputs. 28.3.1.4 Truth Table Inputs Selection Input Overview The inputs can be individually: • • • • • OFF Driven by peripherals Driven by internal events from the Event System Driven by I/O pin inputs Driven by other LUTs Internal Feedback Inputs (FEEDBACK) The output from a sequencer can be used as an input source for the two LUTs it is connected to. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 378 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic Figure 28-3. Feedback Input Selection Even LUT Sequencer Odd LUT When selected (INSELy=FEEDBACK in LUTnCTRLx), the sequencer (SEQ) output is used as input for the corresponding LUTs. Linked LUT (LINK) When selecting the LINK input option, the next LUT’s direct output is used as LUT input. In general, LUT[n+1] is linked to the input of LUT[n]. LUT0 is linked to the input of the last LUT. Example 28-2. Linking all LUTs on a Device with Four LUTs • • • • LUT1 is the input for LUT0 LUT2 is the input for LUT1 LUT3 is the input for LUT2 LUT0 is the input for LUT3 (wrap-around) Figure 28-4. Linked LUT Input Selection LUT0 SEQ0 LUT1 LUT2 SEQ1 LUT3 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 379 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic Event Input Selection (EVENTx) Events from the Event System can be used as inputs to the LUTs by writing to the INSELn bit groups in the LUT n Control B and C registers. I/O Pin Inputs (IO) When selecting the IO option, the LUT input will be connected to its corresponding I/O pin. Refer to the I/O Multiplexing section in the data sheet for more details about where the LUTn-INy pins are located. Peripherals The different peripherals on the three input lines of each LUT are selected by writing to the Input Select (INSEL) bits in the LUT Control (LUTnCTRLB and LUTnCTRLC) registers. 28.3.1.5 Filter By default, the LUT output is a combinational function of the LUT inputs. This may cause some short glitches when the inputs change the value. These glitches can be removed by clocking through filters if demanded by application needs. The Filter Selection (FILTSEL) bits in the LUT n Control A (CCL.LUTnCTRLA) registers define the digital filter options. When FILTSEL=SYNCH, the output is synchronized with CLK_LUTn. The output will be delayed by two positive CLK_LUTn edges. When FILTSEL=FILTER, only the input that is persistent for more than two positive CLK_LUTn edges will pass through the gated flip-flop to the output. The output will be delayed by four positive CLK_LUTn edges. One clock cycle later, after the corresponding LUT is disabled, all internal filter logic is cleared. Figure 28-5. Filter FILTSEL DISABLE Input SYNCH OUT Q D R Q D R Q D R D EN Q FILTER R CLK_LUTn CLR 28.3.1.6 Edge Detector The edge detector can be used to generate a pulse when detecting a rising edge on its input. To detect a falling edge, the TRUTH table can be programmed to provide an inverted output. The edge detector is enabled by writing ‘1’ to the Edge Detection (EDGEDET) bit in the LUTn Control A (CCL.LUTnCTRLA) register. To avoid unpredictable behavior, a valid filter option must be enabled. The edge detection is disabled by writing a ‘0’ to EDGEDET in CCL.LUTnCTRLA. After disabling a LUT, the corresponding internal edge detector logic is cleared one clock cycle later. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 380 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic Figure 28-6. Edge Detector EDGEDET CLK_LUTn 28.3.1.7 Sequencer Logic Each LUT pair can be connected to a sequencer. The sequencer can function as either D flip-flop, JK flip-flop, gated D latch, or RS latch. The function is selected by writing the Sequencer Selection (SEQSEL) bit group in the Sequencer Control (CCL.SEQCTRLn) register. The sequencer receives its input from either the LUT, filter or edge detector, depending on the configuration. A sequencer is clocked by the same clock as the corresponding even LUT. The clock source is selected by the Clock Source (CLKSRC) bit group in the LUT n Control A (CCL.LUTnCTRLA) register. The flip-flop output (OUT) is refreshed on the rising edge of the clock. When the even LUT is disabled, the latch is cleared asynchronously. The flip-flop Reset signal (R) is kept enabled for one clock cycle. Gated D Flip-Flop (DFF) The D input is driven by the even LUT output, and the G input is driven by the odd LUT output. Figure 28-7. D Flip-Flop Even LUT CLK_LUTn Odd LUT Table 28-4. DFF Characteristics R G D OUT 1 X X Clear 0 1 1 Set 0 1 0 Clear 0 0 X Hold state (no change) JK Flip-Flop (JK) The J input is driven by the even LUT output, and the K input is driven by the odd LUT output. Figure 28-8. JK Flip-Flop Even LUT CLK_LUTn Odd LUT © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 381 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic Table 28-5. JK Characteristics R J K OUT 1 X X Clear 0 0 0 Hold state (no change) 0 0 1 Clear 0 1 0 Set 0 1 1 Toggle Gated D Latch (DLATCH) The D input is driven by the even LUT output, and the G input is driven by the odd LUT output. Figure 28-9. D Latch Even LUT D Odd LUT G Q OUT Table 28-6. D Latch Characteristics G D OUT 0 X Hold state (no change) 1 0 Clear 1 1 Set RS Latch (RS) The S input is driven by the even LUT output, and the R input is driven by the odd LUT output. Figure 28-10. RS Latch Even LUT S Odd LUT R Q OUT Table 28-7. RS Latch Characteristics S R OUT 0 0 Hold state (no change) 0 1 Clear 1 0 Set 1 1 Forbidden state 28.3.1.8 Clock Source Settings The filter, edge detector, and sequencer are, by default, clocked by the peripheral clock (CLK_PER). It is also possible to use other clock inputs (CLK_LUTn) to clock these blocks. This is configured by writing the Clock Source (CLKSRC) bits in the LUT Control A register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 382 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic Figure 28-11. CCL Clock Sources Edge Detector IN[2] OSCULP1K OSCULP32K OSC20M CLK_PER Filter CLK_MUX_OUT CLKSRC even LUT Edge Detector IN[2] OSCULP1K OSCULP32K OSC20M CLK_PER Sequencer Filter CLK_MUX_OUT CLKSRC odd LUT When the Clock Source (CLKSRC) bit is written to 0x1, LUTn-TRUTHSEL[2] is used to clock the corresponding filter and edge detector (CLK_LUTn). The sequencer is clocked by the CLK_LUTn of the even LUT in the pair. When CLKSRC is written to 0x1, LUTn-TRUTHSEL[2] is treated as OFF (low) in the TRUTH table. The CCL peripheral must be disabled while changing the clock source to avoid undefined outputs from the peripheral. 28.3.2 Interrupts Table 28-8. Available Interrupt Vectors and Sources Name Vector Description Conditions CCL CCL interrupt INTn in INTFLAG is raised as configured by the INTMODEn bits in the CCL.INTCTRLn register When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 383 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. When several interrupt request conditions are supported by an interrupt vector, the interrupt requests are ORed together into one combined interrupt request to the interrupt controller. The user must read the peripheral’s INTFLAGS register to determine which of the interrupt conditions are present. 28.3.3 Events The CCL can generate the events shown in the table below. Table 28-9. Event Generators in the CCL Generator Name Description Event Type Generating Clock Domain Length of Event Peripheral Event CCL LUTn LUT output level Level Asynchronous Depends on the CCL configuration The CCL has the event users below for detecting and acting upon input events. Table 28-10. Event Users in the CCL User Name Peripheral Input CCL LUTnx Description Input Detection Async/Sync LUTn input x or clock signal No detection Async The event signals are passed directly to the LUTs without synchronization or input detection logic. Two event users are available for each LUT. They can be selected as LUTn inputs by writing to the INSELn bit groups in the LUT n Control B and Control C (CCL.LUTnCTRLB or LUTnCTRLC) registers. Refer to the Event System (EVSYS) section for more details regarding the event types and the EVSYS configuration. 28.3.4 Sleep Mode Operation Writing the Run In Standby (RUNSTDBY) bit in the Control A (CCL.CTRLA) register to ‘1’ will allow the selected clock source to be enabled in Standby sleep mode. If RUNSTDBY is ‘0’, the peripheral clock will be disabled in Standby sleep mode. If the filter, edge detector, and/or sequencer are enabled, the LUT output will be forced to ‘0’ in Standby sleep mode. In Idle sleep mode, the TRUTH table decoder will continue the operation, and the LUT output will be refreshed accordingly, regardless of the RUNSTDBY bit. If the Clock Source (CLKSRC) bit in the LUT n Control A (CCL.LUTnCTRLA) register is written to ‘1’, the LUTnTRUTHSEL[2] will always clock the filter, edge detector, and sequencer. The availability of the LUTn-TRUTHSEL[2] clock in sleep modes will depend on the sleep settings of the peripheral used. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 384 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 ... 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D 0x0E 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 0x17 CTRLA SEQCTRL0 SEQCTRL1 7:0 7:0 7:0 28.5 7 6 5 4 3 2 1 RUNSTDBY 0 ENABLE SEQSEL0[3:0] SEQSEL1[3:0] Reserved INTCTRL0 Reserved INTFLAGS LUT0CTRLA LUT0CTRLB LUT0CTRLC TRUTH0 LUT1CTRLA LUT1CTRLB LUT1CTRLC TRUTH1 LUT2CTRLA LUT2CTRLB LUT2CTRLC TRUTH2 LUT3CTRLA LUT3CTRLB LUT3CTRLC TRUTH3 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 INTMODE3[1:0] INTMODE2[1:0] INTMODE1[1:0] INT3 EDGEDET OUTEN INSEL1[3:0] FILTSEL[1:0] EDGEDET OUTEN INSEL1[3:0] FILTSEL[1:0] EDGEDET OUTEN INSEL1[3:0] FILTSEL[1:0] EDGEDET OUTEN INSEL1[3:0] FILTSEL[1:0] INTMODE0[1:0] INT2 INT1 CLKSRC[2:0] INSEL0[3:0] INSEL2[3:0] INT0 ENABLE CLKSRC[2:0] INSEL0[3:0] INSEL2[3:0] ENABLE CLKSRC[2:0] INSEL0[3:0] INSEL2[3:0] ENABLE CLKSRC[2:0] INSEL0[3:0] INSEL2[3:0] ENABLE TRUTH0[7:0] TRUTH1[7:0] TRUTH2[7:0] TRUTH3[7:0] Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 385 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.1 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 CTRLA 0x00 0x00 - 6 RUNSTDBY R/W 0 5 4 3 2 1 0 ENABLE R/W 0 Bit 6 – RUNSTDBY Run in Standby Writing this bit to ‘1’ will enable the peripheral to run in Standby sleep mode. Value Description 0 The CCL will not run in Standby sleep mode 1 The CCL will run in Standby sleep mode Bit 0 – ENABLE Enable Value Description 0 The peripheral is disabled 1 The peripheral is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 386 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.2 Sequencer Control 0 Name:  Offset:  Reset:  Property:  Bit 7 SEQCTRL0 0x01 0x00 Enable-Protected 6 Access Reset 5 4 3 R/W 0 2 1 SEQSEL0[3:0] R/W R/W 0 0 0 R/W 0 Bits 3:0 – SEQSEL0[3:0] Sequencer Selection This bit group selects the sequencer configuration for LUT0 and LUT1. Value Name Description 0x0 DISABLE The sequencer is disabled 0x1 DFF D flip-flop 0x2 JK JK flip-flop 0x3 LATCH D latch 0x4 RS RS latch Other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 387 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.3 Sequencer Control 1 Name:  Offset:  Reset:  Property:  Bit 7 SEQCTRL1 0x02 0x00 Enable-Protected 6 Access Reset 5 4 3 R/W 0 2 1 SEQSEL1[3:0] R/W R/W 0 0 0 R/W 0 Bits 3:0 – SEQSEL1[3:0] Sequencer Selection This bit group selects the sequencer configuration for LUT2 and LUT3. Value Name Description 0x0 DISABLE The sequencer is disabled 0x1 DFF D flip-flop 0x2 JK JK flip-flop 0x3 LATCH D latch 0x4 RS RS latch Other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 388 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.4 Interrupt Control 0 Name:  Offset:  Reset:  Property:  Bit Access Reset INTCTRL0 0x05 0x00 - 7 6 INTMODE3[1:0] R/W R/W 0 0 5 4 INTMODE2[1:0] R/W R/W 0 0 3 2 INTMODE1[1:0] R/W R/W 0 0 1 0 INTMODE0[1:0] R/W R/W 0 0 Bits 0:1, 2:3, 4:5, 6:7 – INTMODE The bits in INTMODEn select the interrupt sense configuration for LUTn-OUT. Value Name Description 0x0 INTDISABLE Interrupt disabled 0x1 RISING Sense rising edge 0x2 FALLING Sense falling edge 0x3 BOTH Sense both edges © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 389 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.5 Interrupt Flag Name:  Offset:  Reset:  Property:  Bit 7 INTFLAGS 0x07 0x00 - 6 Access Reset 5 4 3 INT3 R/W 0 2 INT2 R/W 0 1 INT1 R/W 0 0 INT0 R/W 0 Bits 0, 1, 2, 3 – INT Interrupt Flag The INTn flag is set when the LUTn output change matches the Interrupt Sense mode as defined in CCL.INTCTRLn. Writing a ‘1’ to this flag’s bit location will clear the flag. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 390 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.6 LUT n Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 EDGEDET R/W 0 LUTnCTRLA 0x08 + n*0x04 [n=0..3] 0x00 Enable-Protected 6 OUTEN R/W 0 5 4 FILTSEL[1:0] R/W R/W 0 0 3 R/W 0 2 CLKSRC[2:0] R/W 0 1 R/W 0 0 ENABLE R/W 0 Bit 7 – EDGEDET Edge Detection Value Description 0 Edge detector is disabled 1 Edge detector is enabled Bit 6 – OUTEN Output Enable This bit enables the LUT output to the LUTn OUT pin. When written to ‘1’, the pin configuration of the PORT I/O-Controller is overridden. Value Description 0 Output to pin disabled 1 Output to pin enabled Bits 5:4 – FILTSEL[1:0] Filter Selection These bits select the LUT output filter options. Value Name 0x0 DISABLE 0x1 SYNCH 0x2 FILTER 0x3 - Description Filter disabled Synchronizer enabled Filter enabled Reserved Bits 3:1 – CLKSRC[2:0] Clock Source Selection This bit selects between various clock sources to be used as the clock (CLK_LUTn) for a LUT. The CLK_LUTn of the even LUT is used for clocking the sequencer of a LUT pair. Value Name Description 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 CLKPER IN2 OSC20M OSCULP32K OSCULP1K - CLK_PER is clocking the LUT LUT input 2 is clocking the LUT Reserved Reserved 20 MHz oscillator before prescaler is clocking the LUT 32.768 kHz internal oscillator is clocking the LUT 1.024 kHz (OSCKULP32K after DIV32) is clocking the LUT Reserved Bit 0 – ENABLE LUT Enable Value Description 0 The LUT is disabled 1 The LUT is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 391 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.7 LUT n Control B Name:  Offset:  Reset:  Property:  LUTnCTRLB 0x09 + n*0x04 [n=0..3] 0x00 Enable-Protected Notes:  1. SPI connections to the CCL work in Host SPI mode only. 2. USART connections to the CCL work only when the USART is in one of the following modes: – Asynchronous USART – Synchronous USART host Bit Access Reset 7 6 5 INSEL1[3:0] R/W R/W 0 0 R/W 0 4 3 R/W 0 R/W 0 2 1 INSEL0[3:0] R/W R/W 0 0 0 R/W 0 Bits 7:4 – INSEL1[3:0] LUT n Input 1 Source Selection These bits select the source for input 1 of LUT n. Value Name Description 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 0x8 0x9 0xA 0xB 0xC Other MASK FEEDBACK LINK EVENTA EVENTB IO AC0 USART1 SPI0 TCA0 TCB1 - Masked input Feedback input Output from LUT(n+1) as input source Event A as input source Event B as input source IN1 input source AC0 OUT input source Reserved USART1 TXD input source SPI0 MOSI input source TCA0 WO1 input source Reserved TCB1 WO input source Reserved Bits 3:0 – INSEL0[3:0] LUT n Input 0 Source Selection These bits select the source for input 0 of LUT n. Value Name Description 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 0x8 0x9 0xA 0xB 0xC Other MASK FEEDBACK LINK EVENTA EVENTB IO AC0 USART0 SPI0 TCA0 TCB0 - Masked input Feedback input Output from LUT(n+1) as input source Event A as input source Event B as input source IN0 input source AC0 OUT input source Reserved USART0 TXD input source SPI0 MOSI input source TCA0 WO0 input source Reserved TCB0 WO input source Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 392 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.8 LUT n Control C Name:  Offset:  Reset:  Property:  Bit LUTnCTRLC 0x0A + n*0x04 [n=0..3] 0x00 Enable-Protected 7 6 5 4 Access Reset 3 R/W 0 2 1 INSEL2[3:0] R/W R/W 0 0 0 R/W 0 Bits 3:0 – INSEL2[3:0] LUT n Input 2 Source Selection These bits select the source for input 2 of LUT n. Value Name Description 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 0x8 0x9 0xA Other MASK FEEDBACK LINK EVENTA EVENTB IO AC0 SPI0 TCA0 - Masked input Feedback input Output from LUT(n+1) as input source Event A as input source Event B as input source IN2 input source AC0 OUT input source Reserved Reserved SPI0 SCK input source TCA0 WO2 input source Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 393 ATtiny424/426/427 ATtiny824/826/827 CCL - Configurable Custom Logic 28.5.9 TRUTHn Name:  Offset:  Reset:  Property:  Bit Access Reset TRUTHn 0x0B + n*0x04 [n=0..3] 0x00 Enable-Protected 7 6 5 R/W 0 R/W 0 R/W 0 4 3 TRUTHn[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – TRUTHn[7:0] Truth Table These bits determine the output of LUTn according to the LUTn-TRUTHSEL[2:0] inputs. Bit Name TRUTHn[0] TRUTHn[1] TRUTHn[2] TRUTHn[3] TRUTHn[4] TRUTHn[5] TRUTHn[6] TRUTHn[7] Value Description 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 The output of LUTn is 0 when the inputs are 'b000 The output of LUTn is 1 when the inputs are 'b000 The output of LUTn is 0 when the inputs are 'b001 The output of LUTn is 1 when the inputs are 'b001 The output of LUTn is 0 when the inputs are 'b010 The output of LUTn is 1 when the inputs are 'b010 The output of LUTn is 0 when the inputs are 'b011 The output of LUTn is 1 when the inputs are 'b011 The output of LUTn is 0 when the inputs are 'b100 The output of LUTn is 1 when the inputs are 'b100 The output of LUTn is 0 when the inputs are 'b101 The output of LUTn is 1 when the inputs are 'b101 The output of LUTn is 0 when the inputs are 'b110 The output of LUTn is 1 when the inputs are 'b110 The output of LUTn is 0 when the inputs are 'b111 The output of LUTn is 1 when the inputs are 'b111 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 394 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29. AC - Analog Comparator 29.1 Features • • • • • • • 29.2 Selectable Response Time Selectable Hysteresis Analog Comparator Output Available on Pin Comparator Output Inversion Available Flexible Input Selection: – Up to four Positive pins – Up to three Negative pins – Internal reference voltage generator (DACREF) Interrupt Generation on: – Rising edge – Falling edge – Both edges Event Generation: – Comparator output Overview The analog comparator (AC) compares the voltage levels on two inputs and gives a digital output based on this comparison. The AC can be configured to generate interrupt requests and/or events upon several different combinations of input change. The dynamic behavior of the AC can be adjusted by a hysteresis feature. The hysteresis can be customized to optimize the operation for each application. The input selection includes analog port pins and internally generated inputs. The analog comparator output state can also be the output on a pin for use by external devices. An AC has one positive input and one negative input. The digital output from the comparator is '1' when the difference between the positive and the negative input voltage is positive, and '0' otherwise. Block Diagram Figure 29-1. Analog Comparator AINP0 . . . + AINPn VREF . .. Voltage divider - Controller logic Invert AINNn AC Hysteresis AINN0 Enable 29.2.1 CMP (Int. Req) OUT Event out CTRLA DACREF © 2021 Microchip Technology Inc. MUXCTRLA Preliminary Datasheet DS40002311A-page 395 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.2.2 Signal Description Signal Description Type AINNn Negative Input n Analog AINPn Positive Input n Analog OUT Comparator Output for AC Digital 29.3 Functional Description 29.3.1 Initialization For a basic operation, follow these steps: • Configure the desired input pins in the port peripheral. • Select the positive and negative input sources by writing the Positive and Negative Input MUX Selection bit fields (MUXPOS and MUXNEG) in the MUX Control A register (ACn.MUXCTRLA). • Optional: Enable the output to pin by writing a '1' to the Output Pad Enable bit (OUTEN) in the Control A register (ACn.CTRLA). • Enable the AC by writing a '1' to the ENABLE bit in ACn.CTRLA. During the start-up time after enabling the AC, the output of the AC may be invalid. The start-up time of the AC by itself is at most 2.5 µs. If an internal reference is used, the reference start-up time is normally longer than the AC start-up time. To avoid the pin being tri-stated when the AC is disabled, the OUT pin must be configured as output in PORTx.DIR. 29.3.2 Operation 29.3.2.1 Input Hysteresis Applying an input hysteresis helps to prevent constant toggling of the output when the noise-afflicted input signals are close to each other. The input hysteresis can either be disabled or have one of three levels. The hysteresis is configured by writing to the Hysteresis Mode Select bit field (HYSMODE) in the Control A register (ACn.CTRLA). 29.3.2.2 Input Sources An AC has one positive and one negative input. The inputs can be pins and internal sources, such as a voltage reference. Each input is selected by writing to the Positive and Negative Input MUX Selection bit field (MUXPOS and MUXNEG) in the MUX Control A register (ACn.MUXCTRLA). 29.3.2.2.1 Pin Inputs The following analog input pins on the port can be selected as input to the analog comparator: • • • • • • • AINN0 AINN1 AINN2 AINP0 AINP1 AINP2 AINP3 29.3.2.2.2 Internal Inputs The AC has the following internal inputs: • Internal reference voltage generator (DACREF) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 396 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.3.2.3 Power Modes For power sensitive applications, the AC provides a low-power mode with lower power consumption and increased propagation delay. The low-power mode is selected by writing the Low Power Mode (LPMODE) bit in the Control A (ACn.CTRLA) register to ‘1’. 29.3.2.4 Signal Compare and Interrupt After the successful initialization of the AC and after configuring the desired properties, the result of the comparison is continuously updated and is available for the application software, for the Event System, or on a pin. The AC can generate a comparator interrupt, COMP, and can request this interrupt on either rising, falling, or both edges of the toggling comparator output. This is configured by writing to the Interrupt Modes bit field in the Control A register (INTMODE bits in ACn.CTRLA). The interrupt is enabled by writing a ‘1’ to the Analog Comparator Interrupt Enable bit in the Interrupt Control register (COMP bit in ACn.INTCTRL). 29.3.3 Events The AC can generate the events described in the table below. Table 29-1. Event Generators in AC Generator Name Description Peripheral Event ACn OUT Event Type Generating Clock Domain Comparator output level. Level Asynchronous Length of Event Given by AC output level The AC has no event inputs. 29.3.4 Interrupts Table 29-2. Available Interrupt Vectors and Sources Name Vector Description Conditions COMP Analog comparator interrupt AC output is toggling as configured by INTMODE in ACn.CTRLA When an interrupt condition occurs, the corresponding Interrupt flag is set in the Status register (ACn.STATUS). An interrupt source is enabled or disabled by writing to the corresponding bit in the peripheral's Interrupt Control register (ACn.INTCTRL). An interrupt request is generated when the corresponding interrupt source is enabled and the Interrupt flag is set. The interrupt request remains active until the Interrupt flag is cleared. See the ACn.STATUS register description for details on how to clear the Interrupt flags. 29.3.5 Sleep Mode Operation In Idle Sleep mode the AC will continue to operate as normal. In Standby Sleep mode the AC is disabled by default. If the Run in Standby Sleep Mode bit (RUNSTDBY) in the Control A register (ACn.CTRLA) is written to '1', the AC will continue to operate as normal with event, interrupt and AC output on pad even if the CLK_PER is not running in Standby Sleep mode. In Power-Down Sleep mode the AC and the output to the pad are disabled. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 397 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.4 Register Summary Offset Name Bit Pos. 7 6 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 CTRLA Reserved MUXCTRLA Reserved DACREF Reserved INTCTRL STATUS 7:0 RUNSTDBY OUTEN 7:0 INVERT 29.5 7:0 7:0 7:0 5 4 3 INTMODE[1:0] LPMODE MUXPOS[1:0] 2 1 HYSMODE[1:0] 0 ENABLE MUXNEG[1:0] DACREF[7:0] STATE CMP CMP Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 398 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.5.1 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RUNSTDBY R/W 0 CTRLA 0x00 0x00 - 6 OUTEN R/W 0 5 4 INTMODE[1:0] R/W R/W 0 0 3 LPMODE R/W 0 2 1 HYSMODE[1:0] R/W R/W 0 0 0 ENABLE R/W 0 Bit 7 – RUNSTDBY Run in Standby Mode Writing a '1' to this bit allows the AC to continue operation in Standby Sleep mode. Since the clock is stopped, interrupts and Status flags are not updated. Value Description 0 In Standby Sleep mode, the peripheral is halted 1 In Standby Sleep mode, the peripheral continues operation Bit 6 – OUTEN Analog Comparator Output Pad Enable Writing this bit to '1' makes the OUT signal available on the pin. Bits 5:4 – INTMODE[1:0] Interrupt Modes Writing to these bits selects which edges of the AC output triggers an interrupt request. Table 29-3. Interrupts in Regular Mode Value Name Description 0x0 0x1 0x2 0x3 BOTHEDGE NEGEDGE POSEDGE Both negative and positive edge Reserved Negative edge Positive edge Bit 3 – LPMODE Low-Power Mode Writing a '1' to this bit reduces the current through the comparator. This reduces the power consumption, but increases the reaction time of the AC. Value Description 0 Low-Power mode disabled 1 Low-Power mode enabled Bits 2:1 – HYSMODE[1:0] Hysteresis Mode Select Writing these bits selects the Hysteresis mode for the AC input. Value Name Description 0x0 NONE No hysteresis 0x1 SMALL Small hysteresis 0x2 MEDIUM Medium hysteresis 0x3 LARGE Large hysteresis Bit 0 – ENABLE Enable AC Writing this bit to '1' enables the AC. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 399 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.5.2 MUX Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 INVERT R/W 0 MUXCTRLA 0x02 0x00 - 6 5 4 3 MUXPOS[1:0] R/W R/W 0 0 2 1 0 MUXNEG[1:0] R/W R/W 0 0 Bit 7 – INVERT Invert AC Output Writing this bit to ‘1’ enables inversion of the output of the AC. This inversion has to be taken into account when using the AC output signal as an input signal to other peripherals or parts of the system. Bits 4:3 – MUXPOS[1:0] Positive Input MUX Selection Writing to this bit field selects the input signal to the positive input of the AC. Value Name Description 0x0 0x1 0x2 0x3 AINP0 AINP1 AINP2 AINP3 Positive pin 0 Positive pin 1 Positive pin 2 Positive pin 3 Bits 1:0 – MUXNEG[1:0] Negative Input MUX Selection Writing to this bit field selects the input signal to the negative input of the AC. Value Name Description 0x0 0x1 0x2 0x3 AINN0 AINN1 AINN2 DACREF Negative pin 0 Negative pin 1 Negative pin 2 Voltage reference © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 400 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.5.3 DAC Voltage Reference Name:  Offset:  Reset:  Property:  Bit Access Reset DACREF 0x04 0xFF R/W 7 6 5 R/W 1 R/W 1 R/W 1 4 3 DACREF[7:0] R/W R/W 1 1 2 1 0 R/W 1 R/W 1 R/W 1 Bits 7:0 – DACREF[7:0] DACREF Data Value These bits define the output voltage from the internal voltage divider. The DAC voltage reference depends on the DACREF value and the reference voltage selected in the VREF module, and is calculated as: VDACREF = DACREF × VREF 256 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 401 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.5.4 Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 INTCTRL 0x06 0x00 - 6 5 4 3 Access Reset 2 1 0 CMP R/W 0 Bit 0 – CMP  Analog Comparator Interrupt Enable Writing this bit to '1' enables the Analog Comparator Interrupt. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 402 ATtiny424/426/427 ATtiny824/826/827 AC - Analog Comparator 29.5.5 Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x07 0x00 - 6 Access Reset 5 4 STATE R 0 3 2 1 0 CMP R/W 0 Bit 4 – STATE Analog Comparator State This bit shows the current status of the OUT signal from the AC. It will have a synchronizer delay to get updated in the I/O register (three cycles). Bit 0 – CMP Analog Comparator Interrupt Flag This is the interrupt flag for the AC. Writing a ‘1’ to this bit will clear the interrupt flag. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 403 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30. ADC - Analog-to-Digital Converter 30.1 Features • • • • • • • • • • • • • • • 30.2 12-Bit Resolution – Up to 17 bits with oversampling Conversion Rate Up to 375 ksps at 12-bit Resolution Up to 15 Inputs Differential and Single-Ended Conversion Programmable Gain Amplifier (PGA) from 1x to 16x Input Voltage Range from -100 mV to VDD+100 mV Multiple Internal ADC Reference Voltages – VDD – 1.024V – 2.048V – 2.500V – 4.096V External Reference Input Single and Free-Running Conversions Series and Burst Accumulation Modes Accumulation of Up to 1024 Conversions Left or Right Adjusted Result Interrupts on Conversion Complete Optional Event Triggered Conversion Configurable Window Comparator Overview The Analog-to-Digital Converter (ADC) peripheral is a 12-bit differential and single-ended ADC, with a Programmable Gain Amplifier (PGA), and a conversion rate up to 375 ksps at 12-bit resolution. The ADC is connected to an analog input multiplexer for selection between multiple single-ended or differential inputs. In single-ended conversions, the ADC measures the voltage between the selected input and 0V (GND). In differential conversions, the ADC measures the voltage between two selected inputs. The ADC inputs can be either internal (for example, a voltage reference) or external analog input pins. An ADC conversion can be started by software, or by using the Event System (EVSYS) to route an event from other peripherals. This makes it possible to sample input signals periodically, trigger an ADC conversion on a special condition, and also trigger ADC conversions in Standby sleep mode. A digital window compare feature is available for monitoring the input signal and can be configured to trigger an interrupt if the sample is under or over a user-defined threshold, or inside or outside a user-defined window, with minimum software intervention required. The ADC input signal is fed through a sample-and-hold circuit that ensures the input voltage to the ADC is held at a constant level during the conversion. The ADC supports sampling in bursts where a configurable number of samples are accumulated into a single ADC result (Sample Accumulation). The ADC reference voltage can be either internal or supplied from the external analog reference pin (VREFA). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 404 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.2.1 Block Diagram Figure 30-1. Block Diagram SAMPRDY (Int. Req.) SAMPLE VDD VREFA Internal References MUXPOS .. . VINP > < AINn ADC PGA .. . VINN Gain Internal Sources RESRDY (Int. Req.) RESULT ACC Convert Internal Sources AIN0 AIN1 WCMP (Int. Req.) WINHT Diff AINn WINLT Enable AIN0 AIN1 > < VREF Accumulate RESOVR (Int. Req.) Enable SAMPOVR (Int. Req.) Control Logic MUXNEG TRIGOVR (Int. Req.) 30.2.2 Signal Description Pin Name Type AIN[n:0] Analog input Analog input pin VREFA Analog input External voltage reference pin 30.3 Functional Description 30.3.1 Definitions • • • 30.3.2 Description Conversion: The operation where analog values on the selected ADC inputs are transformed into a digital representation. Sample: The value placed in the Sample (ADCn.SAMPLE) register, that is, the outcome of a conversion operation. Result: The value placed in the Result (ADCn.RESULT) register. Depending on the ADC configuration, this value is a single sample or the sum of multiple accumulated samples. Basic Operation The following steps are recommended to initialize and run the ADC in basic operation: 1. Enable the ADC by writing a ‘1’ to the ENABLE bit in the Control A (ADCn.CTRLA) register. 2. 3. 4. Configure the Prescaler (PRESC) bit field in the Control B (ADCn.CTRLB) register. Configure the Timebase (TIMEBASE) and Reference Select (REFSEL) bit fields in the Control C (ADCn.CTRLC) register. Configure the Sample Duration (SAMPDUR) bit field in the Control E (ADCn.CTRLE) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 405 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 5. Optional: Configure the number of samples to be accumulated by writing the Sample Accumulation Number Select (SAMPNUM) bit field in the Control F (ADCn.CTRLF) register. 6. Optional: Enable the Free-Running mode by writing a ‘1’ to the Free-Running (FREERUN) bit in the Control F register. 7. Configure a positive input by writing to the MUXPOS bit field in the Positive Input Multiplexer (ADCn.MUXPOS) register. 8. Optional: Configure a negative input by writing to the MUXNEG bit field in the Negative Input Multiplexer (ADCn.MUXNEG) register. 9. Optional: Select Differential ADC conversion by writing a ‘1’ to the Differential (DIFF) bit in the Command (ADCn.COMMAND) register. 10. Configure the mode of operation for the ADC by writing to the MODE bit field in the Command register. 11. Configure how an ADC conversion will start by writing to the START bit field in the Command register. If the IMMEDIATE command is written, a conversion will start immediately. 12. Wait until the Result Ready (RESRDY) bit in the Interrupt Flags (ADCn.INTFLAGS) register is ‘1’ before reading the updated Result (ADCn.RESULT) register. 30.3.3 Operation 30.3.3.1 Operation Modes The ADC supports six different operation modes, with differential and single-ended conversions possible for each mode. This is configured in the Command (ADCn.COMMAND) register. The operation modes can be split into three groups: • Single mode - Single conversion per trigger, with 8- or 12-bit conversion output • Series Accumulation mode - One conversion per trigger, with an accumulation of n samples • Burst Accumulation mode - A burst with n samples accumulated as fast as possible after a single trigger Series and Burst modes utilize 12-bit conversions and can be configured with or without scaling of the accumulated result. The number of samples to accumulate is controlled by the SAMPNUM bit in the Control F (ADCn.CTRLF) register. The accumulator is always reset to zero when a new Series or Burst accumulation is started. The table below shows an overview of the available operation modes. Table 30-1. Operation Modes Operation Mode COMMAND Mode Single 8-bit 0 Single 12-bit 1 Series Accumulation 2 Series Accumulation with Scaling 3 Burst Accumulation 4 Burst Accumulation with Scaling 5 Conversions per Trigger Accumulation Type 1 N/A Every conversion Full After SAMPNUM conversions 1 SAMPNUM Scaled Full Scaled RESULT Update After SAMPNUM conversions 30.3.3.2 Conversion Triggers A conversion is started by one of the following triggers, depending on the configuration of the START bit field in the Command (ADCn.COMMAND) register: • • • Writing the IMMEDIATE value to the START bit field in the Command register Receiving an event input Writing to one of the input multiplexer (ADCn.MUXPOS or ADCn.MUXNEG) registers Continuously repeating Single conversions or Burst accumulations can be enabled by writing a ‘1’ to the FREERUN bit in the Control F (ADCn.CTRLF) register before starting the first conversion. This bit has no effect for Series accumulations. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 406 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter An ongoing conversion can be aborted by writing the STOP value to the START bit field in the Command register, and a new conversion can be started immediately. Triggering a new conversion before the ongoing conversion has finished will set the Trigger Overrun Interrupt (TRIGOVR) flag in the Interrupt Flags (ADCn.INTFLAGS) register, and the trigger will be ignored. The Result Ready and Sample Ready (RESRDY and SAMPRDY) interrupt flags in the Interrupt Flags register show if a conversion or accumulation has finished. These flags also trigger the corresponding interrupts if enabled in the Interrupt Control (ADCn.INTCTRL) register. 30.3.3.3 Output Formats The output from an ADC conversion is given by the following equations: Single‐Ended 12‐bit conversion = Single‐Ended 8‐bit conversion = Differential 12‐bit conversion = Differential 8‐bit conversion = VINP × Gain × 4096 ∈ 0, 4095 VREF VINP × Gain × 256 ∈ 0, 255 VREF VINP − VINN × Gain × 2048 ∈ −2048, 2047 VREF VINP − VINN × Gain × 128 ∈ −128, 127 VREF Where VINP and VINN are the positive and negative inputs to the ADC, and VREF is the selected voltage reference. The gain is between 1x and 16x as configured in the PGA, and 1x if the PGA is not in use. The ADC has two output registers, the Sample (ADCn.SAMPLE) and Result (ADCn.RESULT) registers. The 16-bit Sample register will always be updated with the latest ADC conversion output (one sample). All accumulation modes will accumulate samples in an internal sample accumulator, configured by the Sample Accumulation Number Select (SAMPNUM) bit field in the Control F (ADCn.CTRLF) register. The sample accumulator is sufficiently wide to avoid overflow for all supported accumulation configurations, and the accumulated result is automatically transferred to the 32-bit Result register at the end of a Burst or Series mode accumulation. In single conversion modes, the Result register will be updated with the latest sample, identical to the Sample register. Operating modes with scaling can be selected to limit the accumulated result to 16 bits of resolution if more than 16 samples are accumulated. Scaling is always applied after accumulating the last sample in Burst or Series modes and is carried out by right shifting the accumulated result by SAMPNUM-4 bits. The Left Adjust (LEFTADJ) bit in the Control F register enables left shift of the output data in the modes where this is supported. If enabled, this will left shift the output from both the Result and the Sample registers. The data format for a sample in Single-Ended mode is an unsigned number, where 0x0000 represents zero, and 0x0FFF represents the largest number (full scale). If the analog input is higher than the reference level of the ADC, the 12-bit ADC output will be equal the maximum value of 0x0FFF. Likewise, if the input is below 0V, the ADC output will be 0x0000. For Differential mode, the data format is two's complement, with sign extension. The following tables show the Result register output formats for single-ended and differential conversions, by mode of operation and left adjustment. Table 30-2. RESULT Register - Single-Ended Mode MODE LEFTADJ 0 X(1) 0x00 0 0x00 1 0x00 X(1) 0x00 0 0x00 Scaled accumulation[15:0] 1 0x00 Scaled accumulation[15:0](2) 1 2, 4 3, 5 RES[31:24] © 2021 Microchip Technology Inc. RES[23:16] RES[15:12] RES[11:8] RES[7:0] Conversion[7:0] Conversion[11:0] Conversion[11:0] = 8; © 2021 Microchip Technology Inc. // Read signed offset from signature row // Read unsigned gain/slope from // 10-bit MSb of ADC result with 1.024V - sigrow_offset; // Result might overflow 16-bit variable (10-bit + 8// Add 256/2 to get correct integer rounding on // Divide result by 256 to get processed temperature in Preliminary Datasheet DS40002311A-page 415 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter Kelvin uint16_t temperature_in_K = temp; 30.3.3.8 Window Comparator The ADC can raise the Window Comparator Interrupt (WCMP) flag in the Interrupt Flags (ADCn.INTFLAGS) register and request an interrupt (WCMP) when the output of a conversion or accumulation is above and/or below certain thresholds. The available modes are: • The value is above a threshold • The value is below a threshold • The value is inside a window (above the lower threshold and below the upper threshold) • The value is outside a window (either below the lower threshold or above the upper threshold) The thresholds are set by writing to the Window Comparator Low and High Threshold (ADCn.WINLT and ADCn.WINHT) registers. The Window mode to use is selected by the Window Comparator mode (WINCM) bit field in the Control D (ADCn.CTRLD) register. The Window Mode Source (WINSRC) bit in the Control D (ADCn.CTRLD) register selects if the comparison is done on the 16 LSb of the Result (ADCn.RESULT) register or the Sample (ADCn.SAMPLE) register. If an interrupt request is enabled for the WCMP flag, WINSRC selects which interrupt vector to request, RESRDY or SAMPRDY. When accumulating multiple samples, if the Window Comparator source is the Result register, the comparison between the result and the threshold(s) will happen after the last conversion is complete. If the source is the Sample register, the comparison will happen after every conversion. Assuming the ADC is already configured to run, follow these steps to use the Window Comparator mode: 1. Set the required threshold(s) by writing to the Window Comparator Low and High Threshold (ADCn.WINLT and ADCn.WINHT) registers. 2. Optional: Enable the interrupt request by writing a ‘1’ to the Window Comparator Interrupt Enable (WCMP) bit in the Interrupt Control (ADCn.INTCTRL) register. 3. Enable the Window Comparator by writing the WINSRC bit field and a non-zero value to the WINCM bit field in the Control D (ADCn.CTRLD) register. 30.3.4 Events The ADC can generate the following events: Table 30-8. ADC Event Generators Generator Name Module ADCn Description Event Type Generating Clock Domain Pulse CLK_PER Event RES Result ready SAMP Sample ready WCMP Window compare match Length of Event One CLK_PER period The conditions for generating an event are identical to those that will raise the corresponding flag in the Interrupt Flags (ADCn.INTFLAGS) register. The ADC has one event user for detecting and acting upon input events. The table below describes the event user and the associated functionality. Table 30-9. ADC Event Users and Available Event Actions User Name Peripheral Event ADCn START © 2021 Microchip Technology Inc. Description Input Detection Async/Sync Edge Async ADC start on event Preliminary Datasheet DS40002311A-page 416 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter The START event action can be triggered if the EVENT_TRIGGER setting is written to the START bit field in the Command (ADCn.COMMAND) register. 30.3.5 Interrupts Table 30-10. Available Interrupt Vectors and Sources Name ERROR Vector Description Error interrupt Interrupt Flag TRIGOVR A new conversion is triggered while one is ongoing SAMPOVR A new conversion overwrites an unread sample in ADCn.SAMPLE RESOVR SAMPRDY Sample Ready interrupt RESRDY Result Ready interrupt Conditions SAMPRDY WCMP The sample is available in ADCn.SAMPLE As defined by WINSRC and WINCM in ADCn.CTRLD RESRDY WCMP A new conversion or accumulation overwrites an unread result in ADCn.RESULT The result is available in ADCn.RESULT As defined by WINSRC and WINCM in ADCn.CTRLD When an interrupt condition occurs, the corresponding interrupt flag is set in the peripheral’s Interrupt Flags (peripheral.INTFLAGS) register. An interrupt source is enabled or disabled by writing to the corresponding enable bit in the peripheral’s Interrupt Control (peripheral.INTCTRL) register. An interrupt request is generated when the corresponding interrupt source is enabled, and the interrupt flag is set. The interrupt request remains active until the interrupt flag is cleared. See the peripheral’s INTFLAGS register for details on how to clear interrupt flags. 30.3.6 Sleep Mode Operation The ADC will finish a conversion before going to Idle/Standby sleep mode. The ADC can start conversions in Idle sleep mode if the START bit field in the Command (ADCn.COMMAND) register is configured to start a conversion on an event trigger. This is also possible in Standby sleep mode if the RUNSTDBY bit is set in the Control A (ADCn.CTRLA) register. If both the LOWLAT and RUNSTDBY bits in the Control A register are set, the ADC will keep all required modules ON during Standby sleep mode to start a conversion faster, at the expense of increased power consumption during sleep. When the system enters POWERDOWN, the ADC will abort an ongoing conversion and enter sleep mode immediately. It is recommended to make sure conversions have completed before entering Power-Down mode. 30.3.7 Debug Operation If the Run in Debug mode (DBGRUN) bit in the Debug Control (ADCn.DBGCTRL) register is written to ‘1’, the ADC will continue operating when the CPU is halted in Debug mode. If DBGRUN is ‘0’ when the CPU is halted, an ongoing conversion will finish before the ADC halts. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 417 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.4 Register Summary Offset Name Bit Pos. 7 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D 0x0E ... 0x0F CTRLA CTRLB CTRLC CTRLD INTCTRL INTFLAGS STATUS DBGCTRL CTRLE CTRLF COMMAND PGACTRL MUXPOS MUXNEG 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 7:0 RUNSTDBY RESULT 0x14 SAMPLE 4 3 TRIGOVR TRIGOVR FREERUN MODE[2:0] GAIN[2:0] VIA[1:0] VIA[1:0] 1 LOWLAT 0 ENABLE TIMEBASE[4:0] DIFF 2 SAMPOVR SAMPOVR WINSRC RESOVR RESOVR PRESC[3:0] REFSEL[2:0] WINCM[2:0] WCMP SAMPRDY WCMP SAMPRDY RESRDY RESRDY ADCBUSY DBGRUN SAMPDUR[7:0] LEFTADJ SAMPNUM[3:0] START[2:0] PGABIASSEL[1:0] ADCPGASAMPDUR[1:0] MUXPOS[5:0] MUXNEG[5:0] PGAEN 7:0 15:8 23:16 31:24 7:0 15:8 RESULT[7:0] RESULT[15:8] RESULT[23:16] RESULT[31:24] SAMPLE[7:0] SAMPLE[15:8] 7:0 7:0 7:0 TEMP[7:0] TEMP[7:0] TEMP[7:0] 7:0 15:8 7:0 15:8 WINLT[7:0] WINLT[15:8] WINHT[7:0] WINHT[15:8] Reserved TEMP0 TEMP1 TEMP2 Reserved 0x1C WINLT 0x1E WINHT 30.5 5 Reserved 0x10 0x16 ... 0x17 0x18 0x19 0x1A 0x1B 6 Register Description © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 418 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.1 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 RUNSTDBY R/W 0 CTRLA 0x00 0x00 - 6 5 LOWLAT R/W 0 4 3 2 1 0 ENABLE R/W 0 Bit 7 – RUNSTDBY Run in Standby This bit controls whether the ADC will run in Standby sleep mode or not. Value Description 0 The ADC will not run in Standby sleep mode. An ongoing conversion will finish before the ADC enters sleep mode. 1 The ADC will run in Standby sleep mode Bit 5 – LOWLAT Low Latency This bit controls whether the analog modules required by the ADC are enabled continuously or only when needed. Value Description 0 The ADC enables the required analog modules only when starting a conversion. This reduces the overall power consumption of the ADC and increases the initialization time when starting an ADC conversion. 1 The analog modules stay enabled as long as they are selected as input to the ADC. Using this setting will minimize the initialization time of the ADC. Bit 0 – ENABLE ADC Enable This bit controls whether the ADC is enabled or not. Value Description 0 The ADC is disabled 1 The ADC is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 419 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.2 Control B Name:  Offset:  Reset:  Property:  Bit 7 CTRLB 0x01 0x00 - 6 Access Reset 5 4 3 R/W 0 2 1 PRESC[3:0] R/W R/W 0 0 0 R/W 0 Bits 3:0 – PRESC[3:0] Prescaler This bit field controls the division factor from the peripheral clock (CLK_PER) to the ADC clock (CLK_ADC). Value Name Description 0x0 DIV2 CLK_PER divided by 2 0x1 DIV4 CLK_PER divided by 4 0x2 DIV6 CLK_PER divided by 6 0x3 DIV8 CLK_PER divided by 8 0x4 DIV10 CLK_PER divided by 10 0x5 DIV12 CLK_PER divided by 12 0x6 DIV14 CLK_PER divided by 14 0x7 DIV16 CLK_PER divided by 16 0x8 DIV20 CLK_PER divided by 20 0x9 DIV24 CLK_PER divided by 24 0xA DIV28 CLK_PER divided by 28 0xB DIV32 CLK_PER divided by 32 0xC DIV40 CLK_PER divided by 40 0xD DIV48 CLK_PER divided by 48 0xE DIV56 CLK_PER divided by 56 0xF DIV64 CLK_PER divided by 64 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 420 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.3 Control C Name:  Offset:  Reset:  Property:  Bit Access Reset CTRLC 0x02 0x00 - 7 6 R/W 0 R/W 0 5 TIMEBASE[4:0] R/W 0 4 3 2 R/W 0 R/W 0 R/W 0 1 REFSEL[2:0] R/W 0 0 R/W 0 Bits 7:3 – TIMEBASE[4:0] Timebase This bit field controls the number of CLK_PER cycles to get a period equal to or larger than 1 µs. This is used for timing internal delays in the ADC before starting a conversion, such as the guard time between changing input reference or PGA gain settings. Bits 2:0 – REFSEL[2:0] Reference Selection This bit field controls the voltage reference for the ADC. Changing to one of the internal references will require a 60 µs initialization time. Value Name Description 0x0 VDD VDD 0x1 Reserved 0x2 VREFA External reference VREFA 0x3 Reserved 0x4 1024MV Internal reference 1.024V 0x5 2048MV Internal reference 2.048V 0x6 2500MV Internal reference 2.500V 0x7 4096MV Internal reference 4.096V Note:  The internal references can only be used if lower than VDD - 0.5V. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 421 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.4 Control D Name:  Offset:  Reset:  Property:  Bit 7 CTRLD 0x03 0x00 - 6 Access Reset 5 4 3 WINSRC R/W 0 2 R/W 0 1 WINCM[2:0] R/W 0 0 R/W 0 Bit 3 – WINSRC Window Mode Source This bit controls which source is used by the Window Comparator. Value Name Description 0 RESULT ADCn.RESULT[15:0] is used as the Window Comparator source 1 SAMPLE ADCn.SAMPLE[15:0] is used as the Window Comparator source Bits 2:0 – WINCM[2:0] Window Comparator Mode This bit field controls whether the Window Comparator is enabled or not, and which thresholds will set the Window Comparator (WCMP) interrupt flag. In the table below, OUTPUT is the 16-bit result or sample selected by WINSRC. WINLT and WINHT are the 16-bit low threshold value and the 16-bit high threshold value, respectively. Value Name Description 0x0 NONE Window Comparator disabled 0x1 BELOW OUTPUT < WINLT 0x2 ABOVE OUTPUT > WINHT 0x3 INSIDE WINLT < OUTPUT < WINHT 0x4 OUTSIDE OUTPUT < WINLT or OUTPUT >WINHT Other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 422 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.5 Interrupt Control Name:  Offset:  Reset:  Property:  Bit 7 INTCTRL 0x04 0x00 - 6 Access Reset 5 TRIGOVR R/W 0 4 SAMPOVR R/W 0 3 RESOVR R/W 0 2 WCMP R/W 0 1 SAMPRDY R/W 0 0 RESRDY R/W 0 Bit 5 – TRIGOVR Trigger Overrun Interrupt Enable This bit controls whether the interrupt for a trigger overrun is enabled or not. Value Description 0 The Trigger Overrun interrupt is disabled 1 The Trigger Overrun interrupt is enabled Bit 4 – SAMPOVR Sample Overwrite Interrupt Enable This bit controls whether the interrupt for a sample overwrite is enabled or not. Value Description 0 The Sample Overwrite interrupt is disabled 1 The Sample Overwrite interrupt is enabled Bit 3 – RESOVR Result Overwrite Interrupt Enable This bit controls whether the interrupt for a result overwrite is enabled or not. Value Description 0 The Result Overwrite interrupt is disabled 1 The Result Overwrite interrupt is enabled Bit 2 – WCMP Window Comparator Interrupt Enable This bit controls whether the interrupt for the Window Comparator is enabled or not. Value Description 0 The Window Comparator interrupt is disabled 1 The Window Comparator interrupt is enabled Bit 1 – SAMPRDY Sample Ready Interrupt Enable This bit controls whether the Sample Ready interrupt is enabled or not. Value Description 0 The Sample Ready interrupt is disabled 1 The Sample Ready interrupt is enabled Bit 0 – RESRDY Result Ready Interrupt Enable This bit controls whether the Result Ready interrupt is enabled or not. Value Description 0 The Result Ready interrupt is disabled 1 The Result Ready interrupt is enabled © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 423 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.6 Interrupt Flags Name:  Offset:  Reset:  Property:  Bit 7 INTFLAGS 0x05 0x00 - 6 Access Reset 5 TRIGOVR R/W 0 4 SAMPOVR R/W 0 3 RESOVR R/W 0 2 WCMP R/W 0 1 SAMPRDY R/W 0 0 RESRDY R/W 0 Bit 5 – TRIGOVR Trigger Overrun Interrupt Flag This flag is cleared by writing a ‘1’ to it. This flag is set when a start trigger is received while a conversion is ongoing. Writing a ‘0’ to this bit has no effect. Writing a ‘1’ to this bit will clear the Trigger Overrun interrupt flag. Bit 4 – SAMPOVR Sample Overwrite Interrupt Flag This flag is cleared by writing a ‘1’ to it. This flag is set when an unread sample is overwritten in the Sample (ADCn.SAMPLE) register. Writing a ‘0’ to this bit has no effect. Writing a ‘1’ to this bit will clear the Sample Overwrite interrupt flag. Bit 3 – RESOVR Result Overwrite Interrupt Flag This flag is cleared by writing a ‘1’ to it. This flag is set when an unread result is overwritten in the Result (ADCn.RESULT) register. Writing a ‘0’ to this bit has no effect. Writing a ‘1’ to this bit will clear the Result Overwrite interrupt flag. Bit 2 – WCMP Window Comparator Interrupt Flag This flag is cleared by writing a ‘1’ to it. This flag is set when the conversion or accumulation is complete, and the thresholds match the selected window comparator source and mode, as set by WINSRC and WINCM in the Control D (ADCn.CTRLD) register. Writing a ‘0’ to this bit has no effect. Writing a ‘1’ to this bit will clear the Window Comparator interrupt flag. Bit 1 – SAMPRDY Sample Ready Interrupt Flag This flag is cleared by writing a ‘1’ to it or by reading the Sample (ADCn.SAMPLE) register. This flag is set when a conversion is complete, and a new sample is ready. Writing a ‘0’ to this bit has no effect. Writing a ‘1’ to this bit will clear the Sample Ready interrupt flag. Bit 0 – RESRDY Result Ready Interrupt Flag This flag is cleared by writing a ‘1’ to it or by reading the Result (ADCn.RESULT) register. This flag is set when a conversion or accumulation is complete, and a new result is ready. Writing a ‘0’ to this bit has no effect. Writing a ‘1’ to this bit will clear the Result Ready interrupt flag. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 424 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.7 Status Name:  Offset:  Reset:  Property:  Bit 7 STATUS 0x06 0x00 - 6 5 4 3 Access Reset 2 1 0 ADCBUSY R 0 Bit 0 – ADCBUSY ADC Busy This bit is cleared when an ADC conversion is complete, and settling times related to configuration changes are finished. This bit is set when the ADC is doing a conversion or waiting for settling times related to configuration changes. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 425 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.8 Debug Control Name:  Offset:  Reset:  Property:  Bit 7 DBGCTRL 0x07 0x00 - 6 5 4 3 Access Reset 2 1 0 DBGRUN R/W 0 Bit 0 – DBGRUN Run in Debug Mode This bit controls whether the ADC will continue operation or not when in Debug mode and the CPU is halted. Value Description 0 The ADC will not continue operating in Debug mode when the CPU is halted. An ongoing conversion or burst accumulation will finish before the ADC stops. 1 The ADC will continue operating in Debug mode when the CPU is halted © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 426 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.9 Control E Name:  Offset:  Reset:  Property:  Bit Access Reset CTRLE 0x08 0x00 - 7 6 5 R/W 0 R/W 0 R/W 0 4 3 SAMPDUR[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – SAMPDUR[7:0] Sample Duration This bit field controls the input sample duration in ADC clock (CLK_ADC) cycles. The sample duration without the PGA is (SAMPDUR + ½) CLK_ADC cycles. If the PGA is used, the input sample duration is (SAMPDUR + 1) CLK_ADC cycles, while the ADC PGA Sample Duration (ADCPGASAMPDUR) bit field in the PGA Control (ADCn.PGACTRL) register controls how long the ADC will sample the PGA. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 427 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.10 Control F Name:  Offset:  Reset:  Property:  Bit 7 CTRLF 0x09 0x00 - 6 Access Reset 5 FREERUN R/W 0 4 LEFTADJ R/W 0 3 R/W 0 2 1 SAMPNUM[3:0] R/W R/W 0 0 0 R/W 0 Bit 5 – FREERUN Free-Running This bit controls whether the ADC Free-Running mode is enabled or not. Value Description 0 The ADC Free-Running mode is disabled 1 The ADC Free-Running mode is enabled. A new conversion is started as soon as the previous conversion or accumulation has completed. Note:  Free-Running mode is not supported in Series mode. Bit 4 – LEFTADJ Left Adjust This bit controls whether the ADC output is left adjusted or not. Value Description 0 The ADC output left adjustment is disabled 1 The ADC output left adjustment is enabled Bits 3:0 – SAMPNUM[3:0] Sample Accumulation Number Select This bit field controls the number of consecutive ADC samples that are accumulated automatically into the ADC Result (ADCn.RESULT) register. The most recent sample will be available in the ADC Sample (ADCn.SAMPLE) register. Value Name Description 0x0 NONE No accumulation, single sample per conversion result 0x1 ACC2 2 samples accumulated 0x2 ACC4 4 samples accumulated 0x3 ACC8 8 samples accumulated 0x4 ACC16 16 samples accumulated 0x5 ACC32 32 samples accumulated 0x6 ACC64 64 samples accumulated 0x7 ACC128 128 samples accumulated 0x8 ACC256 256 samples accumulated 0x9 ACC512 512 samples accumulated 0xA ACC1024 1024 samples accumulated Other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 428 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.11 Command Name:  Offset:  Reset:  Property:  Bit Access Reset 7 DIFF R/W 0 COMMAND 0x0A 0x00 - 6 R/W 0 5 MODE[2:0] R/W 0 4 3 R/W 0 2 R/W 0 1 START[2:0] R/W 0 0 R/W 0 Bit 7 – DIFF Differential This bit controls whether the ADC conversion is Single-Ended or Differential. Value Description 0x0 Unsigned Single-Ended conversion. Only the ADCn.MUXPOS register is used. 0x1 Signed Differential conversion. Both the ADCn.MUXPOS and ADCn.MUXNEG registers are used. Bits 6:4 – MODE[2:0] Mode This bit field controls the conversion mode for the ADC. Switching from one of the accumulation modes to a Single mode will reset the accumulator. Value Name Description 0x0 SINGLE_8BIT Single conversion with 8-bit resolution 0x1 SINGLE_12BIT Single conversion with 12-bit resolution 0x2 SERIES Series with accumulation, separate trigger for every 12-bit conversion 0x3 SERIES_SCALING Series with accumulation and scaling, separate trigger for every 12-bit conversion 0x4 BURST Burst with accumulation, one trigger will run SAMPNUM 12-bit conversions in one sequence 0x5 BURST_SCALING Burst with accumulation and scaling, one trigger will run SAMPNUM 12-bit conversions in one sequence Other Reserved Bits 2:0 – START[2:0] Start Conversion This bit field starts or stops an ADC conversion, or controls how an ADC conversion will start. Value Name Description 0x0 STOP Stop an ongoing conversion 0x1 IMMEDIATE Start a conversion immediately. This will be set back to STOP when the conversion is done, unless Free-Running mode is enabled. 0x2 MUXPOS_WRITE Start when a write to the MUXPOS register is done 0x3 MUXNEG_WRITE Start when a write to the MUXNEG register is done 0x4 EVENT_TRIGGER Start when an event is received by the ADC Other Reserved Note:  If the ENABLE bit in ADCn.CTRLA is ‘0’ when writing the START bit field to IMMEDIATE, it will be automatically set to STOP. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 429 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.12 PGA Control Name:  Offset:  Reset:  Property:  Bit 7 Access Reset R/W 0 PGACTRL 0x0B 0x04 - 6 GAIN[2:0] R/W 0 5 R/W 0 4 3 PGABIASSEL[1:0] R/W R/W 0 0 Bits 7:5 – GAIN[2:0] GAIN This bit field controls the gain setting for the PGA. Value Name 0x0 1X 0x1 2X 0x2 4X 0x3 8X 0x4 16X Other - 2 1 ADCPGASAMPDUR[1:0] R/W R/W 1 0 0 PGAEN R/W 0 Description 1x gain 2x gain 4x gain 8x gain 16x gain Reserved Bits 4:3 – PGABIASSEL[1:0] PGA Bias Select This bit field controls the bias current supplied to the PGA. Value Name Description 0x0 0x1 0x2 0x3 1X 3_4X 1_2X 1_4X 100% BIAS current. Usable for fCLK_ADC ≤ 6 MHz. 75% BIAS current. Usable for fCLK_ADC ≤ 4 MHz. 50% BIAS current. Usable for fCLK_ADC ≤ 2.5 MHz. 25% BIAS current. Usable for fCLK_ADC ≤ 1.25 MHz. Bits 2:1 – ADCPGASAMPDUR[1:0] ADC PGA Sample Duration This bit field controls the sampling duration for the ADC to sample the PGA output. Value Name Description 0x0 0x1 0x2 0x3 6CYC 15CYC 20CYC - 6 CLK_ADC cycles. Usable for fCLK_ADC ≤ 1.25 MHz. 15 CLK_ADC cycles. Usable for fCLK_ADC ≤ 5 MHz. 20 CLK_ADC cycles. Usable for fCLK_ADC ≤ 6 MHz. Reserved Bit 0 – PGAEN PGA Enable This bit controls whether the PGA is enabled or not when selected by the VIA bit field in the Input Multiplexer (ADCn.MUXPOS or ADCn.MUXNEG) registers. Value Description 0 The PGA is disabled 1 The PGA is enabled Note:  If both PGAEN and the Low Latency (LOWLAT) bit in the Control A (ADCn.CTRLA) register are ‘1’, the PGA will be ON continuously, even when not selected by the VIA bit field. This eliminates the initialization time if reconfiguring the ADC to use the PGA. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 430 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.13 Positive Input Multiplexer Name:  Offset:  Reset:  Property:  Bit MUXPOS 0x0C 0x00 - 7 6 5 4 R/W 0 R/W 0 R/W 0 VIA[1:0] Access Reset R/W 0 3 2 MUXPOS[5:0] R/W R/W 0 0 1 0 R/W 0 R/W 0 Bits 7:6 – VIA[1:0] This bit field controls how the analog input is connected to the ADC input. Value Name Description 0x0 DIRECT Input connected directly to the ADC 0x1 PGA Input connected to the ADC via the PGA Other Reserved Note:  The VIA bits in MUXPOS and MUXNEG are shared, so a value written to the VIA bit field in one of the two registers is updated in both. It is, therefore, not possible to have one input using the PGA and the other not using the PGA. Bits 5:0 – MUXPOS[5:0] Positive Input Multiplexer This bit field controls which analog input is connected to the positive input of the ADC/PGA. Changing this setting may require some settling time. Refer to the Electrical Characteristics section for further details. Value Name Description 0x00 0x01-0x0F 0x30 0x31 0x32 0x33 Other DEFAULT AIN1-AIN15 GND VDDDIV10 TEMPSENSE DACREF0 - Internal ground ADC input pin 1-15 Internal ground VDD divided by 10 Temperature sensor DACREF from AC0 Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 431 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.14 Negative Input Multiplexer Name:  Offset:  Reset:  Property:  Bit MUXNEG 0x0D 0x00 - 7 6 5 4 R/W 0 R/W 0 R/W 0 VIA[1:0] Access Reset R/W 0 3 2 MUXNEG[5:0] R/W R/W 0 0 1 0 R/W 0 R/W 0 Bits 7:6 – VIA[1:0] This bit field controls how the analog input is connected to the ADC input. Value Name Description 0x0 DIRECT Input connected directly to the ADC 0x1 PGA Input connected to the ADC via the PGA Other Reserved Note:  The VIA bits in MUXPOS and MUXNEG are shared, so a value written to the VIA bit field in one of the two registers is updated in both. It is, therefore, not possible to have one input using the PGA and the other not using the PGA. Bits 5:0 – MUXNEG[5:0] Negative Input Multiplexer This bit field controls which analog input is connected to the negative input of the ADC/PGA. Changing this setting may require some settling time. Refer to the Electrical Characteristics section for further details. Value Name Description 0x00 0x01-0x07 0x30 0x31 0x33 Other DEFAULT AIN1-AIN7 GND VDD/10 DACREF0 - Internal ground ADC input pin 1-7 Internal ground Divided VDD DACREF from AC0 Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 432 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.15 Result Name:  Offset:  Reset:  Property:  RESULT 0x10 0x00 - The ADCn.RESULT0 to ADCn.RESULT3 registers represent the 32-bit value, ADCn.RESULT. The low byte [7:0] (suffix 0) is accessible at the original offset. The n higher bytes [31:8] can be accessed at offset + n. Refer to the Output Formats section for details on the output from this register. Bit 31 30 29 28 27 RESULT[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 RESULT[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 RESULT[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 RESULT[7:0] Access Reset R 0 R 0 R 0 R 0 Bits 31:24 – RESULT[31:24] Result byte 3 This bit field constitutes the MSB of the ADCn.RESULT register. Bits 23:16 – RESULT[23:16] Result byte 2 This bit field constitutes the third byte of the ADCn.RESULT register. Bits 15:8 – RESULT[15:8] Result byte 1 This bit field constitutes the second byte of the ADCn.RESULT register. Bits 7:0 – RESULT[7:0] Result byte 0 This bit field constitutes the LSB of the ADCn.RESULT register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 433 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.16 Sample Name:  Offset:  Reset:  Property:  SAMPLE 0x14 0x00 - The ADCn.SAMPLEL and ADCn.SAMPLEH register pair represents the 16-bit value, ADCn.SAMPLE. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. Refer to the Output Formats section for details on the output from this register. Bit 15 14 13 10 9 8 R 0 12 11 SAMPLE[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 SAMPLE[7:0] Access Reset R 0 R 0 R 0 R 0 Bits 15:8 – SAMPLE[15:8] Sample high byte This bit field constitutes the MSB of the 16-bit register. Bits 7:0 – SAMPLE[7:0] Sample low byte This bit field constitutes the LSB of the 16-bit register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 434 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.17 Temporary n Name:  Offset:  Reset:  Property:  TEMPn 0x18 + n*0x01 [n=0..2] 0x00 - The Temporary registers are used by the CPU for single-cycle access to the 16- and 32-bit registers of this peripheral. The registers are common for all the 16- and 32-bit registers of this peripheral and can be read and written by software. For more details on reading and writing 16- and 32-bit registers, refer to Accessing 16-Bit Registers and Accessing 32-Bit Registers in the AVR CPU section. Bit 7 6 5 4 3 2 1 0 R/W 0 R/W 0 R/W 0 R/W 0 TEMP[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – TEMP[7:0] Temporary Temporary bit field for read/write operations in 16- and 32-bit registers. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 435 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.18 Window Comparator Low Threshold Name:  Offset:  Reset:  Property:  WINLT 0x1C 0x00 - This register is the 16-bit Low Threshold for the digital comparator monitoring the ADC Result or Sample (ADCn.RESULT or ADCn.SAMPLE) registers. The data format must be according to Conversion mode and left adjustment setting. The ADCn.WINLTH and ADCn.WINLTL register pair represents the 16-bit value, ADCn.WINLT. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. When monitoring the ADC Result register, in an accumulation mode, the window comparator thresholds are applied to the result after all accumulation and, optionally, scaling has been done. Bit Access Reset Bit 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 12 11 WINLT[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 WINLT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – WINLT[15:8] Window Comparator Low Threshold high byte This bit field holds the MSB of the 16-bit register. Bits 7:0 – WINLT[7:0] Window Comparator Low Threshold low byte This bit field holds the LSB of the 16-bit register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 436 ATtiny424/426/427 ATtiny824/826/827 ADC - Analog-to-Digital Converter 30.5.19 Window Comparator High Threshold Name:  Offset:  Reset:  Property:  WINHT 0x1E 0x00 - This register is the 16-bit High Threshold for the digital comparator monitoring the ADC Result or Sample (ADCn.RESULT or ADCn.SAMPLE) registers. The data format must be according to Conversion mode and left adjustment setting. The ADCn.WINHTH and ADCn.WINHTL register pair represents the 16-bit value, ADCn.WINHT. The low byte [7:0] (suffix L) is accessible at the original offset. The high byte [15:8] (suffix H) can be accessed at offset + 0x01. When monitoring the ADC Result register, in an accumulation mode, the window comparator thresholds are applied to the result after all accumulation and, optionally, scaling has been done. Bit Access Reset Bit 15 14 13 R/W 0 R/W 0 R/W 0 7 6 5 12 11 WINHT[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 WINHT[7:0] Access Reset R/W 0 R/W 0 R/W 0 R/W 0 Bits 15:8 – WINHT[15:8] Window Comparator High Threshold high byte This bit field holds the MSB of the 16-bit register. Bits 7:0 – WINHT[7:0] Window Comparator High Threshold low byte This bit field holds the LSB of the 16-bit register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 437 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31. UPDI - Unified Program and Debug Interface 31.1 Features • • • 31.2 UPDI One-Wire Interface for External Programming and On-Chip-Debugging (OCD) – Enable programming by high-voltage or fuse – Uses the RESET pin of the device for programming – No GPIO pins occupied during the operation – Asynchronous half-duplex UART protocol towards the programmer Programming: – Built-in error detection and error signature generation – Override of response generation for faster programming Debugging: – Memory-mapped access to device address space (NVM, RAM, I/O) – No limitation on the device clock frequency – Unlimited number of user program breakpoints – Two hardware breakpoints – Support for advanced OCD features • Run-time readout of the CPU Program Counter (PC), Stack Pointer (SP) and Status Register (SREG) for code profiling • Detection and signalization of the Break/Stop condition in the CPU • Program flow control for Run, Stop and Reset debug instructions – Nonintrusive run-time chip monitoring without accessing the system registers – Interface for reading the result of the CRC check of the Flash on a locked device Overview The Unified Program and Debug Interface (UPDI) is a proprietary interface for external programming and OCD of a device. The UPDI supports programming of Nonvolatile Memory (NVM) space, Flash, EEPROM, fuses, lock bits, and the user row. Some memory-mapped registers are accessible only with the correct access privilege enabled (key, lock bits) and only in the OCD Stopped mode or certain Programming modes. These modes are unlocked by sending the correct key to the UPDI. See the NVMCTRL - Nonvolatile Memory Controller section for programming via the NVM controller and executing NVM controller commands. The UPDI is partitioned into three separate protocol layers: the UPDI Physical (PHY) Layer, the UPDI Data Link (DL) Layer and the UPDI Access (ACC) Layer. The default PHY layer handles bidirectional UART communication over the UPDI pin line towards a connected programmer/debugger and provides data recovery and clock recovery on an incoming data frame in the One-Wire Communication mode. Received instructions and corresponding data are handled by the DL layer, which sets up the communication with the ACC layer based on the decoded instruction. Access to the system bus and memory-mapped registers is granted through the ACC layer. Programming and debugging are done through the PHY layer, which is a one-wire UART based on a half-duplex interface using the RESET pin for data reception and transmission. The clocking of the PHY layer is done by a dedicated internal oscillator. The ACC layer is the interface between the UPDI and the connected bus matrix. This layer grants access via the UPDI interface to the bus matrix with memory-mapped access to system blocks such as memories, NVM, and peripherals. The Asynchronous System Interface (ASI) provides direct interface access to select features in the OCD, NVM, and System Management systems. This gives the debugger direct access to system information without requesting bus access. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 438 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.2.1 Block Diagram Figure 31-1. UPDI Block Diagram ASI Memories UPDI Pin (RX/TX Data) UPDI Physical layer UPDI Access layer Bus Matrix UPDI Controller NVM Peripherals ASI Access 31.2.2 OCD NVM Controller System Management ASI Internal Interfaces Clocks The PHY layer and the ACC layer can operate on different clock domains. The PHY layer clock is derived from the dedicated internal oscillator, and the ACC layer clock is the same as the peripheral clock. There is a synchronization boundary between the PHY and the ACC layer, which ensures correct operation between the clock domains. The UPDI clock output frequency is selected through the ASI, and the default UPDI clock start-up frequency is 4 MHz after enabling or resetting the UPDI. The UPDI clock frequency can be changed by writing to the UPDI Clock Divider Select (UPDICLKSEL) bit field in the ASI Control A (UPDI.ASI_CTRLA) register. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 439 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-2. UPDI Clock Domains ASI SYNCH UPDI Controller UPDI Physical layer Clock Controller 31.2.3 Clock Controller CLK_UPDI CLK_UPDI source ~ UPDI Access layer CLK_PER CLK_PER UPDICLKSEL ~ Physical Layer The PHY layer is the communication interface between a connected programmer/debugger and the device. The main features of the PHY layer can be summarized as follows: • Support for UPDI One-Wire mode, using asynchronuous, half-duplex UART communication on the UPDI pin • Internal baud detection, clock and data recovery on the UART frame • Error detection (parity, clock recovery, frame, system errors) • Transmission response generation (ACK) • Generation of error signatures during operation • Guard time control 31.2.4 I/O Lines and Connections To operate the UPDI, the RESET pin must be set to UPDI mode. This is not done through the port I/O pin configuration as regular I/O pins but through setting the RESET Pin Configuration (RSTPINCFG) bits in FUSE.SYSCFG0, as described in UPDI Enable with Fuse Override of RESET Pin, or by following the UPDI highvoltage enable sequence from UPDI Enable with High-Voltage Override of RESET Pin. Pull enable, input enable, and output enable settings are automatically controlled by the UPDI when active. 31.3 Functional Description 31.3.1 Principle of Operation The communication through the UPDI is based on standard UART communication, using a fixed frame format, and automatic baud rate detection for clock and data recovery. In addition to the data frame, several control frames are important to the communication: DATA, IDLE, BREAK, SYNCH, ACK. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 440 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-3. Supported UPDI Frame Formats DATA St 0 1 2 3 4 5 6 7 P S1 S2 P S1 S2 P S1 S2 IDLE BREAK SYNCH (0x55) St Synch Part End_synch ACK (0x40) St Frame Description DATA A DATA frame consists of one Start (St) bit, which is always low, eight Data bits, one Parity (P) bit for even parity, and two Stop (S1 and S2) bits, which are always high. If the Parity bit or Stop bits have an incorrect value, an error will be detected and signalized by the UPDI. The parity bit-check in the UPDI can be disabled by writing to the Parity Disable (PARD) bit in the Control A (UPDI.CTRLA) register, in which case the parity generation from the debugger is ignored. IDLE This is a special frame that consists of at least 12 high bits. This is the same as keeping the transmission line in an Idle state. BREAK This is a special frame that consists of at least 12 low bits. It is used to reset the UPDI back to its default state and is typically used for error recovery. SYNCH The SYNCH frame is used by the Baud Rate Generator to set the baud rate for the coming transmission. A SYNCH character is always expected by the UPDI in front of every new instruction, and after a successful BREAK has been transmitted. ACK The ACK frame is transmitted from the UPDI whenever an ST or an STS instruction has successfully crossed the synchronization boundary and gained bus access. When an ACK is received by the debugger, the next transmission can start. 31.3.1.1 UPDI UART The communication is initiated from the debugger/programmer side. Every transmission must start with a SYNCH character, which the UPDI can use to recover the transmission baud rate and store this setting for the incoming data. The baud rate set by the SYNCH character will be used for both reception and transmission of the subsequent instruction and data bytes. See the UPDI Instruction Set section for details on when the next SYNCH character is expected in the instruction stream. There is no writable Baud Rate register in the UPDI, so the baud rate sampled from the SYNCH character is used for data recovery when sampling the data byte. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 441 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface The transmission baud rate of the PHY layer is related to the selected UPDI clock, which can be adjusted by writing to the UPDI Clock Divider Select (UPDICLKSEL) bit field in the ASI Control A (UPDI.ASI_CTRLA) register. The receive and transmit baud rates are always the same within the accuracy of the auto-baud. Table 31-1. Recommended UART Baud Rate Based on UPDICLKSEL Setting UPDICLKSEL[1:0] Max. Recommended Baud Rate Min. Recommended Baud Rate 0x1 (16 MHz) 0.9 Mbps 0.300 kbps 0x2 (8 MHz) 450 kbps 0.150 kbps 0x3 (4 MHz) - Default 225 kbps 0.075 kbps The UPDI Baud Rate Generator utilizes fractional baud counting to minimize the transmission error. With the fixed frame format used by the UPDI, the maximum and recommended receiver transmission error limits can be seen in Table 31-2. Table 31-2. Receiver Baud Rate Error Data + Parity Bits Rslow Rfast Max. Total Error [%] Recommended Max. RX Error [%] 9 96.39 104.76 +4.76/-3.61 +1.5/-1.5 31.3.1.2 BREAK Character The BREAK character is used to reset the internal state of the UPDI to the default setting. This is useful if the UPDI enters an Error state due to a communication error or when the synchronization between the debugger and the UPDI is lost. To ensure that a BREAK is successfully received by the UPDI in all cases, the debugger must send two consecutive BREAK characters. The first BREAK will be detected if the UPDI is in Idle state and will not be detected if it is sent while the UPDI is receiving or transmitting (at a very low baud rate). However, this will cause a frame error for the reception (RX) or a contention error for the transmission (TX), and abort the ongoing operation. The UPDI will then detect the next BREAK successfully. Upon receiving a BREAK, the UPDI oscillator setting in the ASI Control A (UPDI.ASI_CTRLA) register is reset to the 4 MHz default UPDI clock selection. This changes the baud rate range of the UPDI, according to Table 31-1. 31.3.1.2.1 BREAK in One-Wire Mode In One-Wire mode, the programmer/debugger and UPDI can be totally out of synch, requiring a worst-case length for the BREAK character to be sure that the UPDI can detect it. Assuming the slowest UPDI clock speed of 4 MHz (250 ns), the maximum length of the 8-bit SYNCH pattern value that can be contained in 16 bits is 65535 × 250 ns = 16.4 ms/byte = 16.4 ms/8 bits = 2.05 ms/bit. This gives a worst-case BREAK frame duration of 2.05 ms × 12bits ≈ 24.6 ms for the slowest prescaler setting. When the prescaler setting is known, the time of the BREAK frame can be relaxed according to the values from Table 31-3. Table 31-3. Recommended BREAK Character Duration UPDICLKSEL[1:0] Recommended BREAK Character Duration 0x1 (16 MHz) 6.15 ms 0x2 (8 MHz) 12.30 ms 0x3 (4 MHz) 24.60 ms 31.3.1.3 SYNCH Character The SYNCH character has eight bits and follows the regular UPDI frame format. It has a fixed value of 0x55. The SYNCH character has two main purposes: 1. It acts as the enabling character for the UPDI after a disable. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 442 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 2. It is used by the Baud Rate Generator to set the baud rate for the subsequent transmission. If an invalid SYNCH character is sent, the next transmission will not be sampled correctly. 31.3.1.3.1 SYNCH in One-Wire Mode The SYNCH character is used before each new instruction. When using the REPEAT instruction, the SYNCH character is expected only before the first instruction after REPEAT. The SYNCH is a known character which, through its property of toggling for each bit, allows the UPDI to measure how many UPDI clock cycles are needed to sample the 8-bit SYNCH pattern. The information obtained through the sampling is used to provide Asynchronous Clock Recovery and Asynchronous Data Recovery on reception, and to keep the baud rate of the connected programmer when doing transmit operations. 31.3.2 Operation The UPDI must be enabled before the UART communication can start. 31.3.2.1 UPDI Enabling The enable sequence for the UPDI is device independent and is described in the following paragraphs. 31.3.2.1.1 One-Wire Enable The UPDI pin has an internal pull-up resistor, and by driving the UPDI pin low for more than 200 ns, a connected programmer will initiate the start-up sequence. The negative edge transition will cause an edge detector (located in the high-voltage domain if it is in a MultiVoltage System) to start driving the UPDI pin low, so when the programmer releases the line, it will stay low until the requested UPDI oscillator is ready. The expected arrival time for the clock will depend on the oscillator implementation regarding the accuracy, overshoot, and readout of the oscillator calibration. For a Multi-Voltage System, the line will be driven low until the regulator is at the correct level, and the system is powered up with the selected oscillator ready and stable. The programmer must poll the UPDI pin after releasing it the first time to detect when the pin transitions to high again. This transition means that the edge detector has released the pin (pull-up), and the UPDI can receive a SYNCH character. Upon successful detection of the SYNCH character, the UPDI is enabled and will prepare for the reception of the first instruction. The enable transmission sequence is shown in the next figure, where the active driving periods for the programmer and edge detector are included. The “UPDI pin” waveform shows the pin value at any given time. The delay given for the edge detector active drive period is a typical start-up time waiting for 256 cycles on a 32 MHz oscillator + the calibration readout. Refer to the Electrical Characteristics section for details on the expected start-up times. Note:  The first instruction issued after the initial enable SYNCH does not need an extra SYNCH to be sent because the enable sequence SYNCH sets up the Baud Rate Generator for the first instruction. To avoid the UPDI from staying enabled if an accidental trigger of the edge detector happens, the UPDI will automatically disable itself and lower its clock request. See 31.3.2.2.1 Disable During Start-up for more details. UPDI Enable with Fuse Override of RESET Pin When the RESET Pin Configuration (RSTPINCFG) bit in FUSE.SYSCFG0 is 0x1, the RESET pin will be overridden, and the UPDI will take control of the pin and configure it as an input with pull-up. When the pull-up is detected, the debugger initiates the enable sequence by driving the line low for a duration of tDeb0, as depicted in Figure 31-4: © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 443 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-4. UPDI Enable Sequence with UPDI PAD Enabled By Fuse 1 Fuse read in. Pull-up enabled. Ready to receive init. 2 Drive low from the debugger to request the UPDI clock. 3 UPDI clock ready; Communication channel ready. RESET 1 2 Hi-Z St D0 D1 D2 Handshake / BREAK UPDI.txd D4 D5 D6 D7 Sp SYNC (0x55) (Auto-baud) t RES UPDI.rxd D3 (Ignore) 3 Hi-Z Hi-Z UPDI.txd = 0 t UPDI debugger. UPDI.txd Hi-Z Hi-Z Debugger.txd = 0 Debugger.txd = z t Deb0 t DebZ When the negative edge is detected, the UPDI clock starts. The UPDI will continue to drive the line low until the clock is stable and ready for the UPDI to use. The duration of tUPDI will vary, depending on the status of the oscillator when the UPDI is enabled. After this duration, the data line will be released by the UPDI and pulled high. When the debugger detects that the line is high, the initial SYNCH character 0x55 must be transmitted to synchronize the UPDI communication data rate. If the Start bit of the SYNCH character is not sent within maximum tDebZ, the UPDI will disable itself, and the UPDI enabling sequence must be reinitiated. If the timing is violated, the UPDI is disabled to avoid unintentional enabling of the UPDI. After a successful SYNCH character transmission, the first instruction frame can be transmitted. UPDI Enable with High-Voltage Override of RESET Pin GPIO or Reset functionality on the RESET pin can be overridden by the UPDI by using high-voltage (HV) programming. Applying an HV pulse to the RESET pin will switch the pin functionality to UPDI. This is independent of the RESET Pin Configuration (RSTPINCFG) in FUSE.SYSCFG0. Follow these steps to override the pin functionality: 1. Recommended: Reset the device before starting the HV enable sequence. 2. Apply the HV signal, as described in Figure 31-5. 3. Send the NVMPROG key using the key instruction after the first SYNC character to start programming. Locked devices will only accept the CHIPERASE key. See also section Chip Erase. 4. After the programming is finished, reset the UPDI by writing the UPDI Disable (UPDIDIS) bit in the Control B (UPDI.CTRLB) register to ‘1’ using the STCS instruction. During power-up, the RESET signal must be released before the HV pulse can be applied. The duration of the pulse is recommended in the range from 100 μs to 1 ms before tri-stating. When applying the rising edge of the HV pulse, the UPDI will be reset. After tri-stating, the UPDI will remain in Reset until the RESET pin is driven low by the debugger. This will release the UPDI Reset and initiate the same enable sequence, as explained in UPDI Enable with Fuse Override of RESET Pin. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 444 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-5. UPDI Enable Sequence by High-Voltage (HV) Programming 1 Fused pin function disabled; UPDI pin function enabled. 2 UPDI interface enabled with pull-up. 1 (Ignore) St Hi-Z D0 D1 D2 D3 D4 D5 D6 D7 Sp UPDIPAD HV ramp t HV_ramp Min. is 10 ns Max. is 4 ms Debugger.txd = z t DebZ Min. is 1 μs Max. is 10 μs Handshake/BREAK SYNC (0x55) (Auto-baud) t RES Min. is 10 μs Max. is 200 μs (Ignore) UPDI.rxd Hi-Z UPDI.txd Hi-Z 2 UPDI.txd = 0 t UPDI Min. is 10 μs Max. is 200 μs debugger UPDI.txd debugger UPDI HV Hi-Z HV Vdd Hi-Z Debugger.txd = 0 Debugger.txd = z t Deb0 Min. is 200 ns Max. is 1 μs t DebZ Min. is 200 μs Max. is 14 ms When enabled by an HV pulse, only a POR will disable the UPDI configuration on the RESET pin and restore the default setting. If issuing a UPDI Disable command through the UPDIDIS bit in UPDI.CTRLB, the UPDI will be reset, and the clock request will be canceled, but the RESET pin will remain in UPDI configuration. Notes:  1. If insufficient external protection is added to the UPDI pin, an ESD pulse can be interpreted by the device as a high-voltage override and enable the UPDI. 2. The actual threshold voltage for the UPDI HV activation depends on VDD. See the Electrical Characteristics section for more details. Output Enable Timer Protection for GPIO Configuration When the RESET Pin Configuration (RSTPINCFG) bit in FUSE.SYSCFG0 is ‘0x0’, the RESET pin is configured as GPIO. To avoid a potential conflict between the GPIO actively driving the output and a UPDI high-voltage (HV) enable sequence initiation, the GPIO output driver is disabled for a minimum of 8.8 ms after a System Reset. It is always recommended to issue a Power-On Reset (POR) before entering the HV programming sequence. 31.3.2.2 UPDI Disabling 31.3.2.2.1 Disable During Start-up During the enable sequence, the UPDI can disable itself in case of an invalid enable sequence. There are two mechanisms implemented to reset any requests the UPDI has given to the Power Management and set the UPDI to the disabled state. A new enable sequence must then be initiated to enable the UPDI. Time-Out Disable When the start-up negative edge detector releases the pin after the UPDI has received its clock, or when the regulator is stable and the system has power in a Multi-Voltage system, the default pull-up drives the UPDI pin high. If the programmer does not detect that the pin is high, and does not initiate a transmission of the SYNCH character within 16.4 ms at 4 MHz UPDI clock after the UPDI has released the pin, the UPDI will disable itself. Note:  Start-up oscillator frequency is device-dependent. The UPDI will count for 65536 cycles on the UPDI clock before issuing the time-out. Incorrect SYNCH pattern An incorrect SYNCH pattern is detected if the length of the SYNCH character is longer than the number of samples that can be contained in the UPDI Baud Rate register (overflow), or shorter than the minimum fractional count that can be handled for the sampling length of each bit. If any of these errors are detected, the UPDI will disable itself. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 445 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.3.2.2.2 UPDI Regular Disable Any programming or debugging session that does not require any specific operation from the UPDI after disconnecting the programmer has to be terminated by writing the UPDI Disable (UPDIDIS) bit in the Control B (UPDI.CTRLB) register, upon which the UPDI will issue a System Reset and disable itself. The Reset will restore the CPU to the Run state, independent of the previous state. It will also lower the UPDI clock request to the system and reset any UPDI KEYs and settings. If the disable operation is not performed, the UPDI and the oscillator’s request will remain enabled. This causes increased power consumption for the application. 31.3.2.3 UPDI Communication Error Handling The UPDI contains a comprehensive error detection system that provides information to the debugger when recovering from an error scenario. The error detection consists of detecting physical transmission errors like parity error, contention error, and frame error, to more high-level errors like access time-out error. See the UPDI Error Signature (PESIG) bit field in the Status B (UPDI.STATUSB) register for an overview of the available error signatures. Whenever the UPDI detects an error, it will immediately enter an internal Error state to avoid unwanted system communication. In the Error state, the UPDI will ignore all incoming data requests, except when a BREAK character is received. The following procedure must always be applied when recovering from an Error condition. 1. Send a BREAK character. See section BREAK Character for recommended BREAK character handling. 2. Send a SYNCH character at the desired baud rate for the next data transfer. 3. Execute a Load Control Status (LDCS) instruction to read the UPDI Error Signature (PESIG) bit field in the Status B (UPDI.STATUSB) register and get the information about the occurred error. 4. The UPDI has now recovered from the Error state and is ready to receive the next SYNCH character and instruction. 31.3.2.4 Direction Change To ensure correct timing for a half-duplex UART operation, the UPDI has a built-in guard time mechanism to relax the timing when changing direction from RX to TX mode. The guard time is represented by Idle bits inserted before the next Start bit of the first response byte is transmitted. The number of Idle bits can be configured through the Guard Time Value (GTVAL) bit field in the Control A (UPDI.CTRLA) register. The duration of each Idle bit is given by the baud rate used by the current transmission. Figure 31-6. UPDI Direction Change by Inserting Idle Bits RX Data Frame St RX Data Frame Dir Change P Data from debugger to UPDI S1 S2 IDLE bits TX Data Frame St G uard Tim e # IDLE bits inserted TX Data Frame P S1 S2 Data from UPDI to debugger The UPDI guard time is the minimum Idle time that the connected debugger will experience when waiting for data from the UPDI. The maximum Idle time is the same as time-out. The Idle time before a transmission will be more than the expected guard time when the synchronization time plus the data bus accessing time is longer than the guard time. It is recommended to always use the insertion of minimum two Guard Time bits on the UPDI side, and one guard time cycle insertion from the debugger side. 31.3.3 UPDI Instruction Set The communication through the UPDI is based on a small instruction set. These instructions are part of the UPDI Data Link (DL) layer. The instructions are used to access the UPDI registers, since they are mapped into an internal memory space called “ASI Control and Status (CS) space”, as well as the memory-mapped system space. All instructions are byte instructions and must be preceded by a SYNCH character to determine the baud rate for the communication. See section UPDI UART for information about setting the baud rate for the transmission. The following figure gives an overview of the UPDI instruction set. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 446 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-7. UPDI Instruction Set Overview Opcode LDS STS 0 0 0 1 Size A 0 0 0 0 Opcode LD ST 0 0 0 1 Ptr 1 1 Size B Size A/B 0 STCS 1 1 0 1 0 0 0 0 0 LDS 0 0 1 LD 0 1 0 STS 0 1 1 ST 1 0 0 LDCS (LDS Control/Status) 1 0 1 REPEAT 1 1 0 STCS (STS Control/Status) 1 1 1 KEY Size A - Address Size 0 CS Address LDCS OPCODE 0 0 0 0 Byte - can address 0-255 B 0 1 Word (2 Bytes) - for memories up to 64 KB in size 1 0 3 Bytes - for memories above 64 KB in size 1 1 Reserved Ptr - Pointer Access 0 0 * (ptr) 0 1 * (ptr++) 1 0 ptr 1 1 Reserved Size B - Data Size Size B REPEAT 1 0 1 0 0 0 SIB KEY 1 1 1 0 Size C 0 0 0 Byte 0 1 Word (2 Bytes) 1 0 Reserved 1 1 Reserved CS Address (CS - Control/Status reg.) Size C - Key Size 0 0 64 bits (8 Bytes) 0 1 128 bits (16 Bytes) 1 0 Reserved 1 1 Reserved SIB - System Information Block Sel. 0 Receive KEY 1 Send SIB 31.3.3.1 LDS - Load Data from Data Space Using Direct Addressing The LDS instruction is used to load data from the system bus into the PHY layer shift register for serial readout. The LDS instruction is based on direct addressing, and the address must be given as an operand to the instruction for the © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 447 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface data transfer to start. The maximum supported size for the address and data is 32 bits. The LDS instruction supports repeated memory access when combined with the REPEAT instruction. After issuing the LDS instruction, the number of desired address bytes, as indicated by the Size A field followed by the output data size, which is selected by the Size B field, must be transmitted. The output data is issued after the specified Guard Time (GT). When combined with the REPEAT instruction, the address must be sent in for each iteration of the repeat, meaning after each time the output data sampling is done. There is no automatic address increment when using REPEAT with LDS, as it uses a direct addressing protocol. Figure 31-8. LDS Instruction Operation OPCODE Size A Size B Size A - Address Size 0 LDS 0 0 0 0 0 0 1 Word (2 Bytes) - for memories up to 64 KB in size 1 0 3 Bytes - for memories above 64 KB in size 1 1 Reserved 1 Byte - can address 0-255 B Size B - Data Size 0 0 1 Byte 0 1 Word (2 Bytes) 1 0 Reserved 1 1 Reserved ADDRESS_SIZE Synch (0x55) LDS Adr_0 RX Adr_n Data_0 Data_n TX ΔGT When the instruction is decoded, and the address byte(s) are received as dictated by the decoded instruction, the DL layer will synchronize all required information to the ACC layer, which will handle the bus request and synchronize data buffered from the bus back again to the DL layer. This will create a synchronization delay that must be taken into consideration upon receiving the data from the UPDI. 31.3.3.2 STS - Store Data to Data Space Using Direct Addressing The STS instruction is used to store data that are shifted serially into the PHY layer shift register to the system bus address space. The STS instruction is based on direct addressing, and the address must be given as an operand to the instruction for the data transfer to start. The address is the first set of operands, and data are the second set. The size of the address and data operands are given by the size fields presented in Figure 31-9. The maximum size for both address and data is 32 bits. The STS supports repeated memory access when combined with the REPEAT instruction. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 448 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-9. STS Instruction Operation OPCODE 0 STS 1 Size A 0 Size B Size A - Address Size 0 0 0 1 Byte - can address 0-255 B 0 1 Word (2 Bytes) - for memories up to 64 KB in size 1 0 3 Bytes - for memories above 64 KB in size 1 1 Reserved Size B - Data Size 0 0 1 Byte 0 1 Word (2 Bytes) 1 0 Reserved 1 1 Reserved ADDRESS_SIZE Synch (0x55) STS Adr_0 DATA_SIZE Adr_n Data_0 RX Data_n ACK ΔGT ACK TX ΔGT The transfer protocol for an STS instruction is depicted in Figure 31-9, following this sequence: 1. 2. 3. The address is sent. An Acknowledge (ACK) is sent back from the UPDI if the transfer was successful. The number of bytes, as specified in the STS instruction, is sent. 4. A new ACK is received after the data have been successfully transferred. 31.3.3.3 LD - Load Data from Data Space Using Indirect Addressing The LD instruction is used to load data from the data space and into the PHY layer shift register for serial readout. The LD instruction is based on indirect addressing, which means that the Address Pointer in the UPDI needs to be written before the data space read access. Automatic pointer post-increment operation is supported and is useful when the LD instruction is utilized with the REPEAT instruction. It is also possible to do an LD from the UPDI Pointer register. The maximum supported size for address and data load is 32 bits. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 449 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-10. LD Instruction Operation OPCODE LD 0 0 Ptr 1 Size A/B Ptr - Pointer Access 0 Size A - Address Size Synch (0x55) 0 0 * ( ptr) 0 1 * (ptr++) 1 0 ptr 1 1 Reserved Size B - Data Size 0 0 Byte - can address 0-255 B 0 0 Byte 0 1 Word (2 Bytes) - for memories up to 64 KB in size 0 1 Word (2 Bytes) 1 0 3 Bytes - for memories above 64 KB in size 1 0 Reserved 1 1 Reserved 1 1 Reserved LD DATA_SIZE Data_0 RX Data_n TX ΔGT The figure above shows an example of a typical LD sequence, where the data are received after the Guard Time (GT) period. Loading data from the UPDI Pointer register follows the same transmission protocol. For the LD instruction from the data space, the pointer register must be set up by using an ST instruction to the UPDI Pointer register. After the ACK has been received on a successful Pointer register write, the LD instruction must be set up with the desired DATA SIZE operands. An LD to the UPDI Pointer register is done directly with the LD instruction. 31.3.3.4 ST - Store Data from UPDI to Data Space Using Indirect Addressing The ST instruction is used to store data from the UPDI PHY shift register to the data space. The ST instruction is used to store data that are shifted serially into the PHY layer. The ST instruction is based on indirect addressing, which means that the Address Pointer in the UPDI needs to be written before the data space. The automatic pointer post-increment operation is supported and is useful when the ST instruction is utilized with the REPEAT instruction. The ST instruction is also used to store the UPDI Address Pointer into the Pointer register. The maximum supported size for storing address and data is 32 bits. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 450 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-11. ST Instruction Operation OPCODE ST 0 1 Ptr 1 Size A/B Ptr - Pointer Access 0 0 0 * ( ptr) 0 1 * ( ptr++) 1 0 ptr 1 1 Reserved Size A - Address Size Size B - Data Size 0 0 Byte - can address 0-255 B 0 0 1 Byte 0 1 Word (2 Bytes) - for memories up to 64 KB in size 0 1 Word (2 Bytes) 1 0 3 Bytes - for memories above 64 KB in size 1 0 Reserved 1 1 Reserved 1 1 Reserved ADDRESS_SIZE Synch (0x55) ST ADR_0 ADR_n RX ACK TX ΔGT BLOCK_SIZE Synch (0x55) ST Data_0 RX Data_n ACK TX ΔGT The figure above gives an example of an ST instruction to the UPDI Pointer register and the storage of regular data. A SYNCH character is sent before each instruction. In both cases, an Acknowledge (ACK) is sent back by the UPDI if the ST instruction was successful. To write the UPDI Pointer register, the following procedure has to be followed: 1. Set the PTR field in the ST instruction to signature 0x2. 2. 3. Set the address size (Size A) field to the desired address size. After issuing the ST instruction, send Size A bytes of address data. 4. Wait for the ACK character, which signifies a successful write to the Address register. After the Address register is written, sending data is done in a similarly: 1. Set the PTR field in the ST instruction to signature 0x0 to write to the address specified by the UPDI Pointer register. If the PTR field is set to 0x1, the UPDI pointer is automatically updated to the next address according to the data size Size B field of the instruction after the write is executed. 2. Set the Size B field in the instruction to the desired data size. 3. After sending the ST instruction, send Size B bytes of data. 4. Wait for the ACK character, which signifies a successful write to the bus matrix. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 451 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface When used with the REPEAT instruction, it is recommended to set up the Address register with the start address for the block to be written and use the Pointer Post Increment register to automatically increase the address for each repeat cycle. When using the REPEAT instruction, the data frame of Size B data bytes can be sent after each received ACK. 31.3.3.5 LDCS - Load Data from Control and Status Register Space The LDCS instruction is used to load serial readout data from the UPDI Control and the Status register space located in the DL layer into the PHY layer shift register. The LDCS instruction is based on direct addressing, where the address is part of the instruction operands. The LDCS instruction can access only the UPDI CS register space. This instruction supports only byte access, and the data size is not configurable. Figure 31-12. LDCS Instruction Operation OPCODE LDCS 1 0 CS Address 0 CS Address ( CS - Control/Status reg.) 0 Synch (0x55) LDCS RX Data TX Δgt Figure 31-12 shows a typical example of LDCS data transmission. A data byte from the LDCS is transmitted from the UPDI after the guard time is completed. 31.3.3.6 STCS - Store Data to Control and Status Register Space The STCS instruction is used to store data to the UPDI Control and Status register space. Data are shifted in serially into the PHY layer shift register and written as a whole byte to a selected CS register. The STCS instruction is based on direct addressing, where the address is part of the instruction operand. The STCS instruction can access only the internal UPDI register space. This instruction supports only byte access, and the data size is not configurable. Figure 31-13. STCS Instruction Operation OPCODE STCS 1 1 CS Address 0 CS Address ( CS - Control/Status reg.) 0 Synch (0x55) STCS Data RX TX © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 452 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-13 shows the data frame transmitted after the SYNCH character and the instruction frames. The STCS instruction byte can be immediately followed by the data byte. There is no response generated from the STCS instruction, as is the case for the ST and STS instructions. 31.3.3.7 REPEAT - Set Instruction Repeat Counter The REPEAT instruction is used to store the repeat count value into the UPDI Repeat Counter register on the DL layer. When instructions are used with REPEAT, the protocol overhead for SYNCH and instruction frame can be omitted on all instructions except the first instruction after the REPEAT is issued. REPEAT is most useful for memory instructions (LD, ST, LDS, STS), but all instructions can be repeated, except for the REPEAT instruction itself. The DATA_SIZE operand field refers to the size of the repeat value. Only up to 255 repeats are supported. The instruction loaded directly after the REPEAT instruction will be issued for RPT_0 + 1 times. If the Repeat Counter register is ‘0’, the instruction will run just once. An ongoing repeat can be aborted only by sending a BREAK character. Figure 31-14. REPEAT Instruction Operation used with ST Instruction OPCODE REPEAT 1 0 Size B 1 0 0 0 Size B - Data Size 0 0 1 Byte 0 1 Word (2 Bytes) 1 0 Reserved 1 1 Reserved REPEAT_SIZE Synch (0x55) REPEAT RPT_0 Repeat Number of Blocks of DATA_SIZE DATA_SIZE Synch (0x55) ST (ptr++) Data_0 Data_n DATA_SIZE DATA_SIZE DataB_1 DataB_n RX ACK Δd ACK Δd Δd Δd TX Δd Figure 31-14 gives an example of a repeat operation with an ST instruction using pointer post-increment operation. After the REPEAT instruction is sent with RPT_0 = n, the first ST instruction is issued with SYNCH and instruction frame, while the next n ST instructions are executed by only sending data bytes according to the ST operand DATA_SIZE, and maintaining the Acknowledge (ACK) handshake protocol. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 453 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-15. REPEAT used with LD Instruction REPEAT_SIZE Synch (0x55) Synch (0x55) RPT_0 REPEAT RPT_1 LD (ptr++) RX Repeat Number of Blocks of DATA_SIZE DATA_SIZE DATA_SIZE DataB_1 DataB_n TX ΔGT For LD, data will come out continuously after the LD instruction. Note the guard time on the first data block. If using indirect addressing instructions (LD/ST), it is recommended to always use the pointer post-increment option when combined with REPEAT. The ST/LD instruction is necessary only before the first data block (number of data bytes determined by DATA_SIZE). Otherwise, the same address will be accessed in all repeated access operations. For direct addressing instructions (LDS/STS), the address must always be transmitted as specified in the instruction protocol, before data can be received (LDS) or sent (STS). 31.3.3.8 KEY - Set Activation Key or Send System Information Block The KEY instruction is used for communicating key bytes to the UPDI or for providing the programmer with a System Information Block (SIB), opening up for executing protected features on the device. See Key Activation Overview for an overview of functions that are activated by keys. For the KEY instruction, only a 64-bit key size is supported. The maximum supported size for SIB is 128 bits. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 454 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Figure 31-16. KEY Instruction Operation SIB KEY 1 1 1 0 Size C 0 Size C - Key Size 0 0 0 1 128 bits (16 Bytes) (SIB only) 64 bits (8 Bytes) 1 0 Reserved 1 1 Reserved SIB - System Information Block Sel. 0 Send KEY 1 Receive SIB KEY_SIZE Synch (0x55) KEY KEY_0 KEY_n RX TX Synch (0x55) RX KEY SIB_0 Δgt SIB_n TX SIB_SIZE Figure 31-16 shows the transmission of a key and the reception of a SIB. In both cases, the Size C (SIZE_C) field in the operand determines the number of frames being sent or received. There is no response after sending a KEY to the UPDI. When requesting the SIB, data will be transmitted from the UPDI according to the current guard time setting. 31.3.4 CRC Checking of Flash During Boot Some devices support running a CRC check of the Flash contents as part of the boot process. This check can be performed even when the device is locked. The result of this CRC check can be read from the ASI_CRC_STATUS register. Refer to the CRCSCAN section in the device data sheet for more information on this feature. 31.3.5 System Clock Measurement with UPDI It is possible to use the UPDI to get an accurate measurement of the system clock frequency by utilizing the UPDI event connected to TCB with Input Capture capabilities. A recommended setup flow for this feature is given by the following steps: • Set up TCBn.CTRLB with setting CNTMODE = 0x3, Input Capture Frequency Measurement mode • Write CAPTEI = 1 in TCBn.EVCTRL to enable Event Interrupt. Keep EDGE = 0 in TCBn.EVCTRL • • Configure the Event System to route the UPDI SYNCH event (generator) to the TCB (user) For the SYNCH character used to generate the UPDI events, it is recommended to use a slow baud rate in the range of 10-50 kbps to get a more accurate measurement of the value captured by the timer between each UPDI event. One particular thing is that if the capture is set up to trigger an interrupt, the first captured value © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 455 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface • must be ignored. The second captured value based on the input event must be used for the measurement. See Figure 31-17 for an example using 10 kbps UPDI SYNCH character pulses, giving a capture window of 200 µs for the timer. It is possible to read out the captured value directly after the SYNCH character by reading the TCBn.CCMP register, or the value can be written to memory by the CPU once the capture is done. For more details, refer to the TCB - 16-bit Timer/Counter Type B section. Figure 31-17. UPDI System Clock Measurement Events Ignore the first capture event 200 μs UPDI_Input TCB_CCMP 31.3.6 CAPT_1 CAPT_2 CAPT_3 Inter-Byte Delay When performing a multibyte transfer (LD combined with REPEAT), or reading out the System Information Block (SIB), the output data will come out in a continuous stream. Depending on the application, on the receiver side, the data might come out too fast, and there might not be enough time for the data to be processed before the next Start bit arrives. The inter-byte delay works by inserting a fixed number of Idle bits for multibyte transfers. The reason for adding an inter-byte delay is that there is no guard time inserted when all data is going in the same direction. The inter-byte delay feature can be enabled by writing a ‘1’ to the Inter-Byte Delay Enable (IBDLY) bit in the Control A (UPDI.CTRLA) register. As a result, two extra Idle bits will be inserted between each byte to relax the sampling time for the debugger. Figure 31-18. Inter-Byte Delay Example with LD and RPT Too Fast Transmission, no Inter-Byte Delay RX Debugger Data TX RPT CNT LD*(ptr) GT Debugger Processing D0 SB D1 SB D0 D2 SB D1 lost D3 SB D3 lost D2 D4 SB D5 SB D4 Data Sampling OK with Inter-Byte Delay RX Debugger Data TX RPT CNT Debugger Processing © 2021 Microchip Technology Inc. LD*(ptr) GT D0 SB IB D0 D1 SB IB D1 Preliminary Datasheet D2 SB IB D2 D3 SB D3 DS40002311A-page 456 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface Notes:  1. GT denotes the guard time insertion. 2. SB is for Stop bit. 3. IB is the inserted inter-byte delay. 4. The rest of the frames are data and instructions. 31.3.7 System Information Block The System Information Block (SIB) can be read out at any time by setting the SIB bit according to the KEY instruction from 31.3.3.8 KEY - Set Activation Key or Send System Information Block. The SIB is always accessible to the debugger, regardless of lock bit settings, and provides a compact form of supplying information about the device and system parameters for the debugger. The information is vital in identifying and setting up the proper communication channel with the device. The output of the SIB is interpreted as ASCII symbols. The key size field must be set to 16 bytes when reading out the complete SIB, and an 8-byte size can be used to read out only the Family_ID. See Figure 31-19 for SIB format description and which data are available at different readout sizes. Figure 31-19. System Information Block Format 16 8 31.3.8 [Byte][Bits] [6:0] [55:0] [7][7:0] [10:8][23:0] [13:11][23:0] [14][7:0] [15][7:0] Field Name Family_ID Reserved NVM_VERSION OCD_VERSION RESERVED DBG_OSC_FREQ Enabling of Key Protected Interfaces The access to some internal interfaces and features is protected by the UPDI key mechanism. To activate a key, the correct key data must be transmitted by using the KEY instruction, as described in 31.3.3.8 KEY - Set Activation Key or Send System Information Block. Table 31-4 describes the available keys and the condition required when doing the operation with the key active. Table 31-4. Key Activation Overview Key Name Description Requirements for Operation Chip Erase Start NVM chip erase. Clear lock bits NVMPROG Activate NVM Programming Lock bits cleared. ASI_SYS_STATUS.NVMPROG set USERROW-Write Program the user row on the locked device Lock bits set. Write to key Status bit/ ASI_SYS_STATUS.UROWPROG set UPDI Reset - Conditions for Key Invalidation UPDI Disable/UPDI Reset Programming done/UPDI Reset Table 31-5 gives an overview of the available key signatures that must be shifted in to activate the interfaces. Table 31-5. Key Activation Signatures Key Name Key Signature (LSB Written First) Size Chip Erase 0x4E564D4572617365 64 bits NVMPROG 0x4E564D50726F6720 64 bits USERROW-Write 0x4E564D5573267465 64 bits 31.3.8.1 Chip Erase The following steps should be followed to issue a chip erase: 1. Enter the Chip Erase key by using the KEY instruction. See Table 31-5 for the CHIPERASE signature. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 457 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 2. 3. 4. 5. 6. Optional: Read the Chip Erase (CHIPERASE) bit in the ASI Key Status (UPDI.ASI_KEY_STATUS) register to see that the key is successfully activated. Write the signature to the Reset Request (RSTREQ) bit in the ASI Reset Request (UPDI.ASI_RESET_REQ) register. This will issue a System Reset. Write 0x00 to the ASI Reset Request (UPDI.ASI_RESET_REQ) register to clear the System Reset. Read the NVM Lock Status (LOCKSTATUS) bit from the ASI System Status (UPDI.ASI_SYS_STATUS) register. The chip erase is done when LOCKSTATUS bit is ‘0’. If the LOCKSTATUS bit is ‘1’, return to step 5. After a successful Chip Erase, the Lockbits will be cleared, and the UPDI will have full access to the system. Until Lockbits are cleared, the UPDI cannot access the system bus, and only CS-space operations can be performed. CAUTION During chip erase, the BOD is forced in ON state by writing to the Active (ACTIVE) bit field from the Control A (BOD.CTRLA) register and uses the BOD Level (LVL) bit field from the BOD Configuration (FUSE.BODCFG) fuse and the BOD Level (LVL) bit field from the Control B (BOD.CTRLB) register. If the supply voltage VDD is below that threshold level, the device is unavailable until VDD is increased adequately. See the BOD section for more details. 31.3.8.2 NVM Programming If the device is unlocked, it is possible to write directly to the NVM Controller or to the Flash memory using the UPDI. This will lead to unpredictable code execution if the CPU is active during the NVM programming. To avoid this, the following NVM Programming sequence has to be executed. 1. 2. 3. 4. 5. 6. 7. Follow the chip erase procedure, as described in Chip Erase. If the part is already unlocked, this point can be skipped. Enter the NVMPROG key by using the KEY instruction. See Table 31-5 for the NVMPROG signature. Optional: Read the NVM Programming Key Status (NVMPROG) bit from the ASI Key Status (UPDI.KEY_STATUS) register to see if the key has been activated. Write the signature to the Reset Request (RSTREQ) bit in the ASI Reset Request (UPDI.ASI_RESET_REQ) register. This will issue a System Reset. Write 0x00 to the ASI Reset Request (UPDI.ASI_RESET_REQ) register to clear the System Reset. Read the NVM Programming Key Status (NVMPROG) bit from the ASI System Status (UPDI.ASI_SYS_STATUS) register. NVM Programming can start when the NVMPROG bit is ‘1’. If the NVMPROG bit is ‘0’, return to step 6. 8. 9. Write data to NVM through the UPDI. Write the signature to the Reset Request (RSTREQ) bit in the ASI Reset Request (UPDI.ASI_RESET_REQ) register. This will issue a System Reset. 10. Write 0x00 to the ASI Reset Request (UPDI.ASI_RESET_REQ) register to clear the System Reset. 11. Programming is complete. 31.3.8.3 User Row Programming The User Row Programming feature allows programming new values to the user row (USERROW) on a locked device. To program with this functionality enabled, the following sequence must be followed: 1. 2. 3. 4. 5. 6. Enter the USERROW-Write key located in Table 31-5 by using the KEY instruction. See Table 31-5 for the USERROW-Write signature. Optional: Read the User Row Write Key Status (UROWWRITE) bit from the ASI Key Status (UPDI.ASI_KEY_STATUS) register to see if the key has been activated. Write the signature to the Reset Request (RSTREQ) bit in the ASI Reset Request (UPDI.ASI_RESET_REQ) register. This will issue a System Reset. Write 0x00 to the ASI Reset Request (UPDI.ASI_RESET_REQ) register to clear the System Reset. Read the Start User Row Programming (UROWPROG) bit from the ASI System Status (UPDI.ASI_SYS_STATUS) register. User Row Programming can start when the UROWPROG bit is ‘1’. If UROWPROG is ‘0’, return to step 5. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 458 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 7. 8. 9. 10. 11. 12. 13. The data to be written to the User Row must first be written to a buffer in the RAM. The writable area in the RAM has a size of 32 bytes, and it is only possible to write user row data to the first 32 byte addresses of the RAM. Addressing outside this memory range will result in a nonexecuted write. The data will map 1:1 with the user row space when the data is copied into the user row upon completion of the Programming sequence. When all user row data has been written to the RAM, write the User Row Programming Done (UROWDONE) bit in the ASI System Control A (UPDI.ASI_SYS_CTRLA) register. Read the Start User Row Programming (UROWPROG) bit from the ASI System Status (UPDI.ASI_SYS_STATUS) register. The User Row Programming is completed when UROWPROG bit is ‘0’. If UROWPROG bit is ‘1’, return to step 9. Write to the User Row Write Key Status (UROWWRITE) bit in the ASI Key Status (UPDI.ASI_KEY_STATUS) register. Write the signature to the Reset Request (RSTREQ) bit in the ASI Reset Request (UPDI.ASI_RESET_REQ) register. This will issue a System Reset. Write 0x00 to the ASI Reset Request (UPDI.ASI_RESET_REQ) register to clear the System Reset. 14. The User Row Programming is complete. It is not possible to read back data from the RAM in this mode. Only writes to the first 32 bytes of the RAM are allowed. 31.3.9 Events The UPDI can generate the following events: Table 31-6. Event Generators in UPDI Generator Name Module Event UPDI SYNCH Description SYNCH character Event Type Level Generating Clock Domain CLK_UPDI Length of Event SYNCH char on UPDI pin synchronized to CLK_UPDI This event is set on the UPDI clock for each detected positive edge in the SYNCH character, and it is not possible to disable this event from the UPDI. The UPDI has no event users. Refer to the Event System section for more details regarding event types and Event System configuration. 31.3.10 Sleep Mode Operation The UPDI PHY layer runs independently of all sleep modes, and the UPDI is always accessible for a connected debugger independent of the device’s sleep state. If the system enters a sleep mode that turns the system clock off, the UPDI will not be able to access the system bus and read memories and peripherals. When enabled, the UPDI will request the system clock so that the UPDI always has contact with the rest of the device. Thus, the UPDI PHY layer clock is unaffected by the sleep mode’s settings. By reading the System Domain in Sleep (INSLEEP) bit in the ASI System Status (UPDI.ASI_SYS_STATUS) register, it is possible to monitor if the system domain is in a sleep mode. It is possible to prevent the system clock from stopping when going into a sleep mode, by writing to the Request System Clock (CLKREQ) bit in the ASI System Control A (UPDI.ASI_SYS_CTRLA) register. If this bit is set, the system sleep mode state is emulated, and the UPDI can access the system bus and read the peripheral registers even in the deepest sleep modes. The CLKREQ bit is by default ‘1’ when the UPDI is enabled, which means that the default operation is keeping the system clock in ON state during the sleep modes. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 459 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.4 Register Summary Offset Name Bit Pos. 0x00 0x01 0x02 0x03 0x04 ... 0x06 0x07 0x08 0x09 STATUSA STATUSB CTRLA CTRLB 7:0 7:0 7:0 7:0 ASI_KEY_STATUS ASI_RESET_REQ ASI_CTRLA 7:0 7:0 7:0 0x0A ASI_SYS_CTRLA 7:0 0x0B 0x0C ASI_SYS_STATUS ASI_CRC_STATUS 7:0 7:0 31.5 7 6 5 4 3 DTD NACKDIS RSD CCDETDIS 2 1 0 UPDIREV[3:0] IBDLY PARD PESIG[2:0] GTVAL[2:0] UPDIDIS Reserved UROWWRITE NVMPROG CHIPERASE RSTREQ[7:0] RSTSYS INSLEEP UPDICLKSEL[1:0] UROWWRITE CLKREQ _FINAL NVMPROG UROWPROG LOCKSTATUS CRC_STATUS[2:0] Register Description These registers are readable only through the UPDI with special instructions and are not readable through the CPU. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 460 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.1 Status A Name:  Offset:  Reset:  Property:  Bit 7 STATUSA 0x00 0x40 - 6 5 4 R 0 R 0 3 2 1 0 UPDIREV[3:0] Access Reset R 0 R 1 Bits 7:4 – UPDIREV[3:0] UPDI Revision This bit field contains the revision of the current UPDI implementation. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 461 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.2 Status B Name:  Offset:  Reset:  Property:  Bit 7 STATUSB 0x01 0x00 - 6 5 4 3 Access Reset 2 R 0 1 PESIG[2:0] R 0 0 R 0 Bits 2:0 – PESIG[2:0] UPDI Error Signature This bit field describes the UPDI error signature and is set when an internal UPDI Error condition occurs. The PESIG bit field is cleared on a read from the debugger. Table 31-7. Valid Error Signatures PESIG[2:0] Error Type Error Description 0x0 0x1 0x2 0x3 0x4 0x5 0x6 0x7 No error Parity error Frame error Access Layer Time-Out Error Clock Recovery error Bus error Contention error No error detected (Default) Wrong sampling of the Parity bit Wrong sampling of the Stop bits UPDI can get no data or response from the Access layer Wrong sampling of the Start bit Reserved Address error or access privilege error Signalize Driving Contention on the UPDI pin © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 462 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.3 Control A Name:  Offset:  Reset:  Property:  Bit Access Reset 7 IBDLY R/W 0 CTRLA 0x02 0x00 - 6 5 PARD R/W 0 4 DTD R/W 0 3 RSD R/W 0 2 R/W 0 1 GTVAL[2:0] R/W 0 0 R/W 0 Bit 7 – IBDLY Inter-Byte Delay Enable Writing a ‘1’ to this bit enables a fixed-length inter-byte delay between each data byte transmitted from the UPDI when doing multibyte LD(S). The fixed length is two IDLE bits. Bit 5 – PARD Parity Disable Writing a ‘1’ to this bit will disable the parity detection in the UPDI by ignoring the Parity bit. This feature is recommended to be used only during testing. Bit 4 – DTD Disable Time-Out Detection Writing a ‘1’ to this bit will disable the time-out detection on the PHY layer, which requests a response from the ACC layer within a specified time (65536 UPDI clock cycles). Bit 3 – RSD Response Signature Disable Writing a ‘1’ to this bit will disable any response signatures generated by the UPDI. This reduces the protocol overhead to a minimum when writing large blocks of data to the NVM space. When accessing the system bus, the UPDI may experience delays. If the delay is predictable, the response signature may be disabled. Otherwise, a loss of data may occur. Bits 2:0 – GTVAL[2:0] Guard Time Value This bit field selects the guard time value that will be used by the UPDI when the transmission direction switches from RX to TX. Value Description 0x0 UPDI guard time: 128 cycles (default) 0x1 UPDI guard time: 64 cycles 0x2 UPDI guard time: 32 cycles 0x3 UPDI guard time: 16 cycles 0x4 UPDI guard time: 8 cycles 0x5 UPDI guard time: 4 cycles 0x6 UPDI guard time: 2 cycles 0x7 Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 463 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.4 Control B Name:  Offset:  Reset:  Property:  Bit 7 CTRLB 0x03 0x00 - 6 Access Reset 5 4 NACKDIS R/W 0 3 CCDETDIS R/W 0 2 UPDIDIS R/W 0 1 0 Bit 4 – NACKDIS Disable NACK Response Writing a ‘1’ to this bit disables the NACK signature sent by the UPDI when a System Reset is issued during ongoing LD(S) and ST(S) operations. Bit 3 – CCDETDIS Collision and Contention Detection Disable Writing a ‘1’ to this bit disables the contention detection. Writing a ‘0’ to this bit enables the contention detection. Bit 2 – UPDIDIS UPDI Disable Writing a ‘1’ to this bit disables the UPDI PHY interface. The clock request from the UPDI is lowered, and the UPDI is reset. All the UPDI PHY configurations and keys will be reset when the UPDI is disabled. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 464 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.5 ASI Key Status Name:  Offset:  Reset:  Property:  Bit 7 ASI_KEY_STATUS 0x07 0x00 - 6 Access Reset 5 UROWWRITE R/W 0 4 NVMPROG R 0 3 CHIPERASE R 0 2 1 0 Bit 5 – UROWWRITE User Row Write Key Status This bit is set to ‘1’ if the UROWWRITE key is successfully decoded. This bit must be written as the final part of the user row write procedure to correctly reset the programming session. Bit 4 – NVMPROG NVM Programming Key Status This bit is set to ‘1’ if the NVMPROG key is successfully decoded. The bit is cleared when the NVM Programming sequence is initiated, and the NVMPROG bit in ASI_SYS_STATUS is set. Bit 3 – CHIPERASE Chip Erase Key Status This bit is set to ‘1’ if the Chip Erase key is successfully decoded. The bit is cleared by the Reset Request issued as part of the Chip Erase sequence described in the Chip Erase section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 465 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.6 ASI Reset Request Name:  Offset:  Reset:  Property:  ASI_RESET_REQ 0x08 0x00 - A Reset is signalized to the System when writing the Reset signature to this register. Bit Access Reset 7 6 5 R/W 0 R/W 0 R/W 0 4 3 RSTREQ[7:0] R/W R/W 0 0 2 1 0 R/W 0 R/W 0 R/W 0 Bits 7:0 – RSTREQ[7:0] Reset Request The UPDI will not be reset when issuing a System Reset from this register. Value Name Description 0x00 RUN Clear Reset condition 0x59 RESET Normal Reset Other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 466 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.7 ASI Control A Name:  Offset:  Reset:  Property:  Bit 7 ASI_CTRLA 0x09 0x03 - 6 5 4 3 Access Reset 2 1 0 UPDICLKSEL[1:0] R/W R/W 1 1 Bits 1:0 – UPDICLKSEL[1:0] UPDI Clock Divider Select Writing these bits selects the UPDI clock output frequency. The default setting after Reset and enable is 4 MHz. Any other clock output selection is only recommended when the BOD is at the highest level. For all other BOD settings, the default 4 MHz selection is recommended. Value Description 0x0 Reserved 0x1 16 MHz UPDI clock 0x2 8 MHz UPDI clock 0x3 4 MHz UPDI clock (Default Setting) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 467 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.8 ASI System Control A Name:  Offset:  Reset:  Property:  ASI_SYS_CTRLA 0x0A 0x00 - Bit 7 6 5 4 3 2 Access Reset R 0 R 0 R 0 R 0 R 0 R 0 1 UROWWRITE_ FINAL R/W 0 0 CLKREQ R/W 0 Bit 1 – UROWWRITE_FINAL  User Row Programming Done This bit must be written when the user row data have been written to the RAM. Writing a ‘1’ to this bit will start the process of programming the user row data to the Flash. If this bit is written before the user row data is written to the RAM by the UPDI, the CPU will proceed without the written data. This bit is writable only if the USERROW-Write key is successfully decoded. Bit 0 – CLKREQ Request System Clock If this bit is written to ‘1’, the ASI is requesting the system clock, independent of the system sleep modes. This makes it possible for the UPDI to access the ACC layer, also if the system is in a sleep mode. Writing a ‘0’ to this bit will lower the clock request. This bit will be reset when the UPDI is disabled. This bit is set by default when the UPDI is enabled in any programming mode (Fuse, high-voltage). © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 468 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.9 ASI System Status Name:  Offset:  Reset:  Property:  Bit 7 ASI_SYS_STATUS 0x0B 0x01 - 6 Access Reset 5 RSTSYS R 0 4 INSLEEP R 0 3 NVMPROG R 0 2 UROWPROG R 0 1 0 LOCKSTATUS R 1 Bit 5 – RSTSYS System Reset Active When this bit is set to ‘1’, there is an active Reset on the system domain. When this bit is set to ‘0’, the system is not in the Reset state. This bit is set to ‘0’ on read. A Reset held from the ASI_RESET_REQ register will also affect this bit. Bit 4 – INSLEEP System Domain in Sleep When this bit is set to ‘1’, the system domain is in Idle or deeper Sleep mode. When this bit is set to ‘0’, the system is not in any sleep mode. Bit 3 – NVMPROG Start NVM Programming When this bit is set to ‘1’, NVM Programming can start from the UPDI. When the programming is complete, reset the system through the UPDI Reset register. Bit 2 – UROWPROG  Start User Row Programming When this bit is set to ‘1’, User Row Programming can start from the UPDI. When the User Row data have been written to the RAM, the UROWDONE bit in the ASI_SYS_CTRLA register must be written. Bit 0 – LOCKSTATUS NVM Lock Status When this bit is set to ‘1’, the device is locked. If a chip erase is done, and the lock bits are set to ‘0’, this bit will be read as ‘0’. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 469 ATtiny424/426/427 ATtiny824/826/827 UPDI - Unified Program and Debug Interface 31.5.10 ASI CRC Status Name:  Offset:  Reset:  Property:  Bit 7 ASI_CRC_STATUS 0x0C 0x00 - 6 5 4 3 Access Reset 2 R 0 1 CRC_STATUS[2:0] R 0 0 R 0 Bits 2:0 – CRC_STATUS[2:0] CRC Execution Status This bit field signalizes the status of the CRC conversion. This bit field is one-hot encoded. Value Description 0x0 Not enabled 0x1 CRC enabled, busy 0x2 CRC enabled, done with OK signature 0x4 CRC enabled, done with FAILED signature Other Reserved © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 470 ATtiny424/426/427 ATtiny824/826/827 Instruction Set Summary 32. Instruction Set Summary The instruction set summary is part of the AVR Instruction Set Manual, located at www.microchip.com/DS40002198. Refer to the CPU version called AVRxt, for details regarding the devices documented in this data sheet. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 471 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics 33. Electrical Characteristics 33.1 Disclaimer All typical values are measured at T = 25°C and VDD = 3V unless otherwise specified. All minimum and maximum values are valid across operating temperature and voltage unless otherwise specified. Typical values given should be considered for design guidance only, and actual part variation around these values is expected. 33.2 Absolute Maximum Ratings Stresses beyond those listed in this section 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 33-1. Absolute Maximum Ratings Symbol Description VDD Power supply voltage IVDD Current into a VDD pin IGND Conditions Current out of a GND pin Min. Max. Unit -0.5 6 V T = [-40, 85]°C - 200 mA T = [85, 125]°C - 100 mA T = [-40, 85]°C - 200 mA T = [85, 125]°C - 100 mA VRST RESET pin voltage with respect to GND -0.5 13 V VPIN Pin voltage with respect to GND -0.5 VDD+0.5 V IPIN I/O pin sink/source current -40 40 mA Ic1 (1) I/O pin injection current except RESET pin VPIN < GND – 0.6V or 5.5V < VPIN ≤ 6.1V 4.9V < VDD ≤ 5.5V -1 1 mA Ic2(1) I/O pin injection current except RESET pin VPIN < GND – 0.6V or VPIN ≤ 5.5V VDD ≤ 4.9V -15 15 mA Ictot Sum of I/O pin injection current except RESET pin -45 45 mA Tstorage Storage temperature -65 150 °C Note:  1. – If the VPIN is lower than GND – 0.6V, then a current limiting resistor is required. The negative DC injection current limiting resistor is calculated as R = (GND – 0.6V – VPIN)/ICn. – If the VPIN is greater than VDD+0.6V, then a current limiting resistor is required. The positive DC injection current limiting resistor is calculated as R = (VPIN – (VDD + 0.6))/ICn. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 472 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics CAUTION 33.3 VRSTMAX = 13V Care should be taken to avoid overshoot (overvoltage) when connecting the RESET pin to a 12V source. Exposing the pin to a voltage above the rated absolute maximum can activate the pin’s ESD protection circuitry, which will remain activated until the voltage has been brought below approximately 10V. A 12V driver can keep the ESD protection in an activated state (if activated by an overvoltage condition) while driving currents through it, potentially causing permanent damage to the part. General Operating Ratings The device must operate within the ratings listed in this section for all other electrical characteristics and typical characteristics of the device to be valid. Table 33-2. General Operating Conditions Symbol Description Condition Min. VDD Industrial 1.8(1,2) 5.5 V VAO - Auto Grade and Extended Operating temperature range 2.7(2,3) 5.5 V Operating temperature range Extended -40 125 Industrial -40 85 TA Operating supply voltage Max. Unit °C Notes:  1. Operation is ensured down to 1.8V or BOD triggering level VBOD when BOD is active. 2. During Chip Erase, the BOD is forced ON. If the supply voltage VDD is below the configured VBOD, the erase attempt will fail. 3. Operation is ensured down to 2.7V or BOD triggering level VBOD when BOD is active. Table 33-3. Operating Voltage and Frequency Symbol Description Condition fCLK_CPU Nominal operating system clock frequency TA = [-40, 85]°C Min. Max. Unit VDD = [1.8, 2.7]V(1,4) 0 5 4.5]V(2) 0 10 VDD = [4.5, 5.5]V(3) 0 20 VDD = [2.7, 4.5]V(2) 0 8 5.5]V(3) 0 16 VDD = [2.7, TA = [85, 125]°C VDD = [4.5, MHz Notes:  1. Operation is ensured down to BOD triggering level, VBOD with BODLEVEL0. 2. Operation is ensured down to BOD triggering level, VBOD with BODLEVEL2. 3. Operation is ensured down to BOD triggering level, VBOD with BODLEVEL7. 4. These specifications do not apply to automotive range parts (-VAO). The maximum CPU clock frequency depends on VDD. As shown in the figure below, the Maximum Frequency vs. VDD is linear between 1.8V < VDD < 2.7V and 2.7V < VDD < 4.5V. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 473 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Figure 33-1. Maximum Frequency vs. VDD for [-40, 85]°C 20 MHz 10 MHz Safe Operating Area 5 MHz 1.8V 2.7V 4.5V 5.5V Figure 33-2. Maximum Frequency vs. VDD for [85, 125]°C 16 MHz 8 MHz Safe Operating Area 2.7V 33.4 4.5V 5.5V Power Considerations The average die junction temperature, TJ (in °C) is given from the formula: TJ = TA + PD × RθJA where PD is the total power dissipation. The total thermal resistance of a package (RθJA) can be separated into two components, RθJC and RθCA, representing the barrier to heat flow from the semiconductor junction to the package (case) surface (RθJC) and from the case to the outside ambient air (RθCA). These terms are related by the equation: RθJA = RθJC + RθCA. RθJC is device-related and cannot be influenced by the user. However, RθCA is user-dependent and can be minimized by thermal management techniques such as PCB thermal design, heat sinks, and thermal convection. Thus, good thermal management on the part of the user can significantly reduce RθCA so that RθJA approximately equals RθJC. Power usage can be calculated by adding together the system power consumption and the I/O module power consumption. The current drawn from pins with a capacitive load may be estimated (for one pin) as follows: Icp ≈ VDD × Cload × fsw Where Cload = pin load capacitance and fsw = average switching frequency of I/O pin. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 474 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Table 33-4. Power Dissipation and Junction Temperature vs. Temperature 33.5 Pin Count Package Type RθJA (°C/W) RθJC (°C/W) 14 SOIC 58 26 14 TSSOP 95 20 20 SOIC 44 21 20 SSOP 60.6 25 20 VQFN 79.7 36 24 VQFN 60.6 25 Power Consumption Operating conditions: • VDD = 3V • T = 25°C • OSC20M used as the system clock source, unless otherwise specified • System power consumption measured with peripherals disabled and without I/O drive Table 33-5. Power Consumption in Active, Idle, Power-Down, Standby and Reset Mode Mode Description Condition Min. Typ. Max. Unit Active Active power consumption CLK_CPU = 20 MHz (OSC20M) VDD = 5V - 10.2 - mA CLK_CPU = 10 MHz (OSC20M div2) VDD = 5V - 5.5 - mA VDD = 3V - 3.1 - mA CLK_CPU = 5 MHz (OSC20M div4) VDD = 5V - 3.2 - mA VDD = 3V - 1.8 - mA VDD = 2V - 1.2 - mA VDD = 5V - 13.5 - µA VDD = 3V - 7.5 - µA VDD = 2V - 5.0 - µA CLK_CPU = 20 MHz (OSC20M) VDD = 5V - 4.3 mA CLK_CPU = 10 MHz (OSC20M div2) VDD = 5V - 2.5 mA VDD = 3V - 1.4 mA CLK_CPU = 5 MHz (OSC20M div4) VDD = 5V - 1.6 mA VDD = 3V - 0.9 mA VDD = 2V - 0.6 mA VDD = 5V - 8.2 µA VDD = 3V - 4.2 µA VDD = 2V - 2.6 µA CLK_CPU = 32.768 kHz (OSCULP32K) Idle Idle power consumption CLK_CPU = 32.768 kHz (OSCULP32K) © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 475 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Mode Description Condition Min. Typ. Max. Unit Standby Standby power consumption RTC running at 1.024 kHz from external XOSC32K (CL = 7.5 pF) - 0.69 - µA T = 25°C - 1.0 µA T = 85°C - - µA T = 125°C - - µA T = 25°C - 0.1 µA T = 85°C - - µA T = 125°C - - µA - 100 RTC running at 1.024 kHz from internal OSCULP32K PowerDown/ Standby Reset 33.6 Power-down/ Standby power consumption are the same when all peripherals are stopped All peripherals stopped Reset power consumption Reset line pulled low - µA Wake-Up Time The following table shows wake-up time from various sleep modes with various system clock sources. It also shows the start-up time from reset with no Unified Programming Interface (UPDI) connection active and with 0 ms start-up time (SUT) setting. Table 33-6. Start-Up and Wake-Up Time Symbol tstartup Description The start-up time from the release of any Reset source. Execution of first instruction. (Excluding CRCSCAN) twakeup(1) Wake-up from Idle Clock Source Any PDIV Division Any Any - 200 - 20 MHz 5V - 1 - 10 MHz 3V - 2 - 5 MHz 2V - 4 - OSC20M 1 FREQSEL = 2 0x1 16 MHz 5V - 1.2 - 8 MHz 3V - 2.4 - OSCULP32K 1 32.768 kHz OSC20M 1 FREQSEL = 2 0x2 20 MHz 5V - 12 - 10 MHz 3V - 13 - 5 MHz 2V - 15 - OSC20M 1 FREQSEL = 2 0x1 16 MHz 5V - 16 - 8 MHz 3V - 15 - OSCULP32K 1 32.768 kHz - 750 - OSC20M 1 FREQSEL = 2 0x2 4 © 2021 Microchip Technology Inc. VDD Min. Typ. Max. Unit Any 4 Wake-up time from Standby or Power-down when clock source is stopped fCLK_CPU Preliminary Datasheet µs 700 DS40002311A-page 476 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Note:  1. The wake-up time is the time from the wake-up request is given until the peripheral clock is available on the clock output (CLKOUT) pin. All peripherals and modules start execution from the first clock cycle, except the CPU that is halted for four clock cycles before program execution starts. Figure 33-3. Wake-Up Time Definition Wake-Up Time Wake-Up Request CLKOUT 33.7 Peripherals Power Consumption The table below can be used to calculate the additional current consumption for the different I/O peripherals in the various operating modes. Some peripherals will request the clock to be enabled when operating in STANDBY. See the peripheral section for further information. Operating conditions: • VDD = 3V • T = 25°C • OSC20M at 1 MHz used as the system clock source, unless otherwise specified • In Idle sleep mode, unless otherwise specified Table 33-7. Peripherals Power Consumption Typ.(1) Unit Continuous 19 µA Sampling @ 1 kHz 1.2 TCA 16-bit count @ 1 MHz 13.0 µA TCB 16-bit count @ 1 MHz 7.4 µA RTC 16-bit count @ OSCULP32K 1.2 µA 0.7 µA Peripheral BOD Conditions WDT (including OSCULP32K) OSC20M 130 µA disabled(2) 92 µA Low-Power mode enabled(2) 45 ADC(3) CLK_ADC = 1MHz 260 µA XOSC32K CL = 7.5 pF 0.5 µA 0.4 µA AC Low-Power mode OSCULP32K USART Enable @ 9600 Baud 13.0 µA SPI (Host) Enable @ 100 kHz 2.1 µA © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 477 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Peripheral Conditions Typ.(1) Unit TWI (Host) Enable @ 100 kHz 24.0 µA TWI (Client) Enable @ 100 kHz 17.0 µA Flash programming Erase Operation 1.5 mA Write Operation 3.0 Notes:  1. Current consumption of the module only. To calculate the total internal power consumption of the microcontroller, add this value to the base power consumption given in the “Power Consumption” section in electrical characteristics. 2. CPU in Standby mode. 3. Average power consumption with ADC active in Free-Running mode. 33.8 BOD and POR Characteristics Table 33-8. Power Supply Characteristics Symbol SRON Description Condition Min. Power-on Slope - Typ. Max. Unit - 100(1,2) V/ms Notes:  1. For design guidance only and not tested in production. 2. A slope faster than the maximum rating can trigger a Reset of the device if changing the voltage level after an initial power-up. Table 33-9. Power-on Reset (POR) Characteristics Symbol VPOR Description Condition POR threshold voltage on VDD falling VDD falls/rises at 0.5 V/ms or slower POR threshold voltage on VDD rising Min. Typ. Max. Unit 0.8(1) - 1.6(1) 1.4(1) - 1.8 V Note:  1. For design guidance only. Not tested in production. Table 33-10. Brown-out Detector (BOD) Characteristics Symbol VBOD VHYS tBOD Description BOD detection level (falling/rising) Hysteresis Detection time © 2021 Microchip Technology Inc. Condition Min. Typ. Max. Unit BODLEVEL0 1.7 1.8 2.0 BODLEVEL2 2.4 2.6 2.9 BODLEVEL7 3.9 4.3 4.5 BODLEVEL0 - 25 - BODLEVEL2 - 40 - BODLEVEL7 - 80 - Continuous - 7 - µs Sampled, 1 kHz - 1 - ms Sampled, 125 Hz - 8 - Preliminary Datasheet V mV DS40002311A-page 478 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol 33.9 Description Condition Min. Typ. Max. Unit tstartup Start-up time Time from enable to ready - 40 - µs VINT Interrupt level 0 Percentage above the selected BOD level - 4 - % Interrupt level 1 - 13 - Interrupt level 2 - 25 - External Reset Characteristics Table 33-11. External Reset Characteristics Mode Description Condition VVIH_RST Input Voltage for RESET VVIL_RST Input Low Voltage for RESET tMIN_RST Minimum pulse width on RESET pin Rp_RST RESET pull-up resistor VReset = 0V Min. Typ. Max. Unit 0.7 × VDD - VDD + 0.2 V -0.2 - 0.3 × VDD - - 0.5(1) µs 20 35 50 kΩ Note:  1. These parameters are for design guidance only and are not production tested. 33.10 Oscillators and Clocks Operating conditions: • VDD = 3V, unless otherwise specified • Oscillator frequencies above speed specification must be divided, so the CPU clock is always within specification Table 33-12. 20 MHz Internal Oscillator (OSC20M) Characteristics Symbol fOSC20M Description Factory calibration frequency Condition FREQSEL = 0x01 Min. Typ. Max. Unit TA = 25°C, 3.0V 16 FREQSEL = 0x02 fCAL ETOTAL Frequency calibration range Total error with 16 MHz and 20 MHz frequency selection MHz 20 OSC20M FREQSEL = 0x01 14.5 17.5 MHz OSC20M FREQSEL = 0x02 18.5 21.5 MHz TA = 25°C, 3.0V -1.5 1.5 % TA = [0, 70]°C, VDD = [1.8, 3.6]V -2.0 2.0 % Full operation range -4.0 4.0 From target frequency ΔfOSC20M Calibration step size - 0.75 - % DOSC20M Duty cycle - 50 - % - 12 - µs tstartup Start-up time © 2021 Microchip Technology Inc. Within 2% accuracy Preliminary Datasheet DS40002311A-page 479 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Table 33-13. 32.768 kHz Internal Oscillator (OSCULP32K) Characteristics Symbol Description fOSCULP32K Condition Min. Factory calibration frequency ETOTAL Typ. Max. Unit 32.768 kHz Factory calibration accuracy TA = 25°C, 3.0V -3 3 % Total error from target frequency TA = [0, 70]°C, VDD = [1.8, 3.6]V -10 +10 % Full operation range -20 +20 DOSCULP32K Duty cycle tstartup Start-up time 50 - % 250 - µs Table 33-14. 32.768 kHz External Crystal Oscillator (XOSC32K) Characteristics Symbol Description fout Frequency tstartup Start-up time Condition CL = 7.5 pF CL Crystal load capacitance ESR Equivalent Series Resistance - Safety Factor=3 Min. Typ. Max. Unit - 32.768 - kHz - 300 - ms 7.5(1) - 12.5(1) pF - - 80(1) kΩ - 40(1) CL = 7.5 pF   CL = 12.5  pF - Note:  1. This parameter is for design guidance only. Not production tested. Figure 33-4. External Clock Waveform Characteristics V IH1 V IL1 Table 33-15. External Clock Characteristics Symbol fCLCL Frequency tCLCL Condition VDD=[1.8, 5.5]V VDD=[2.7, 5.5]V VDD=[4.5, 5.5]V Unit Min. Max. Min. Max. Min. Max. 0 5.0 0.0 10.0 0.0 20.0 MHz Clock Period 200 - 100 - 50 - ns (1) High Time 80 - 40 - 20 - ns tCLCX(1) Low Time 80 - 40 - 20 - ns tCLCH(1) Rise Time (for maximum frequency) - 40 - 20 - 10 ns tCHCL(1) Fall Time (for maximum frequency) - 40 - 20 - 10 ns ΔtCLCL(1) Change in period from one clock cycle to the next - 20 - 20 - 20 % tCHCX  Description © 2021 Microchip Technology Inc. Preliminary Datasheet  DS40002311A-page 480 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Note:  1. This parameter is for design guidance only. Not production tested. 33.11 I/O Pin Characteristics Operating conditions: • TA = [-40, 125]°C • VDD = [1.8, 5.5]V, unless otherwise specified Table 33-16. I/O Pin Characteristics Symbol Description VIL Min. Typ. Max. Unit Input low-voltage, except RESET pin as I/O -0.2 - 0.3 × VDD V VIH Input high-voltage, except RESET pin as I/O 0.7 × VDD - VDD + 0.2V V IIH / IIL I/O pin Input leakage current, except RESET pin as I/O VDD = 5.5V, Pin high - < 0.05 - µA VDD = 5.5V, Pin low - < 0.05 - VDD = 1.8V, IOL = 1.5 mA - - 0.36 VDD = 3.0V, IOL = 7.5 mA - - 0.6 VDD = 5.0V, IOL = 15 mA - - 1 VDD = 1.8V, IOH = 1.5 mA 1.44 - - VDD = 3.0V, IOH = 7.5 mA 2.4 - - VDD = 5.0V, IOH = 15 mA 4 - - Maximum combined I/O sink current per pin group(1) - - 100 Maximum combined I/O source current per pin group(1) - - 100 VIL2 Input low-voltage on RESET pin as I/O -0.2 - 0.3 × VDD V VIH2 Input high-voltage on RESET pin as I/O 0.7 × VDD - VDD + 0.2V V VOL2 I/O pin drive strength on RESET pin as I/O VDD = 1.8V, IOL = 0.1 mA - - 0.36 V VDD = 3.0V, IOL = 0.25 mA - - 0.6 VDD = 5.0V, IOL = 0.5 mA - - 1 VDD = 1.8V, IOH = 0.1 mA 1.44 - - VDD = 3.0V, IOH = 0.25 mA 2.4 - - VDD = 5.0V, IOH = 0.5 mA 4 - - VDD = 3.0V, load = 20 pF - 2.5 - VDD = 5.0V, load = 20 pF - 1.5 - VDD = 3.0V, load = 20 pF - 2.0 - VDD = 5.0V, load = 20 pF - 1.3 - VOL I/O pin drive strength VOH I/O pin drive strength Itotal VOH2 I/O pin drive strength on RESET pin as I/O tRISE Rise time tFALL Fall time Condition V V mA V ns ns CPIN I/O pin capacitance, unless otherwise specified - 3 - pF CPIN_TOSC I/O pin capacitance on TOSC pins(2) - 5.5 - pF CPIN_TWI I/O pin capacitance on TWI pins(2) - 10 - pF CPIN_AC I/O pin capacitance on AC pins(2) - - pF - - © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 481 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol Description Condition RP Pull-up resistor Min. Typ. Max. Unit 20 35 50 kΩ Notes:  1. Pin group x (Px[7:0]). The combined continuous sink/source current for all I/O ports should not exceed the limits. 2. This capacitance is valid for pins with this functionality, even when that functionality is not used. 33.12 USART Figure 33-5. USART in SPI Mode - Timing Requirements in Host Mode SS tSCKR tMOS tSCKF SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSb LSb tMOH tMOH MOSI (Data Output) MSb LSb Table 33-17. USART in SPI Host Mode - Timing Characteristics(1) Symbol Description Condition Min. Typ. Max. Unit fSCK SCK clock frequency Host - - 10 MHz tSCK SCK period Host 100 - - ns tSCKW SCK high/low width Host - 0.5 × tSCK - ns tSCKR SCK rise time Host - 2.7 - ns tSCKF SCK fall time Host - 2.7 - ns tMIS MISO setup to SCK Host - 10 - ns tMIH MISO hold after SCK Host - 10 - ns tMOS MOSI setup to SCK Host - 0.5 × tSCK - ns tMOH MOSI hold after SCK Host - 1.0 - ns Note:  1. These parameters are for design guidance only and are not production tested. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 482 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics 33.13 SPI Figure 33-6. SPI - Timing Requirements in Host Mode SS tSCKR tMOS tSCKF SCK (CPOL = 0) tSCKW SCK (CPOL = 1) tSCKW tMIS MISO (Data Input) tMIH tSCK MSb LSb tMOH tMOH MOSI (Data Output) MSb LSb Figure 33-7. SPI - Timing Requirements in Client Mode SS tSSCKR tSSS tSSCKF tSSH SCK (CPOL = 0) tSSCKW SCK (CPOL = 1) tSSCKW tSIS MOSI (Data Input) tSIH tSSCK MSb tSOSS LSb tSOS MISO (Data Output) tSOSH MSb LSb Table 33-18. SPI - Timing Characteristics(1) Symbol Description Condition Min. Typ. Max. Unit fSCK SCK clock frequency Host - - 10 MHz tSCK SCK period Host 100 - - ns tSCKW SCK high/low width Host - 0.5 × SCK - ns tSCKR SCK rise time Host - 2.7 - ns tSCKF SCK fall time Host - 2.7 - ns tMIS MISO setup to SCK Host - 10 - ns tMIH MISO hold after SCK Host - 10 - ns tMOS MOSI setup to SCK Host - 0.5 × SCK - ns tMOH MOSI hold after SCK Host - 1.0 - ns fSSCK Client SCK clock frequency Client - - 5 MHz © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 483 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol Description Condition Min. Typ. Max. Unit tSSCK Client SCK period Client 4 × t CLK_PER - - ns tSSCKW SCK high/low width Client 2 × t CLK_PER - - ns tSSCKR SCK rise time Client - - 1600 ns tSSCKF SCK fall time Client - - 1600 ns tSIS MOSI setup to SCK Client 3.0 - - ns tSIH MOSI hold after SCK Client t CLK_PER - - ns tSSS SS setup to SCK Client 21 - - ns tSSH SS hold after SCK Client 20 - - ns tSOS MISO setup to SCK Client - 8.0 - ns tSOH MISO hold after SCK Client - 13 - ns tSOSS MISO setup after SS low Client - 11 - ns tSOSH MISO hold after SS low Client - 8.0 - ns Note:  1. These parameters are for design guidance only and are not production tested. 33.14 TWI Figure 33-8. TWI - Timing Requirements tHIGH tOF SCL tSU;STA tHD ;STA tSU ;DAT tLOW tSP tR tHD ;DAT tSU ;STO tBUF SDA S Table 33-19. TWI Symbol P S Specifications(1) Description Condition Typ. Max. Unit 0 - 1000 kHz fSCL SCL clock frequency VIH Input high voltage 0.7 × VDD - - V VIL Input low voltage - - 0.3 × VDD V VHYS Hysteresis of Schmitt Trigger inputs 0.4 × VDD V © 2021 Microchip Technology Inc. Max. frequency requires system clock at 10 MHz Min. 0.1 × VDD Preliminary Datasheet DS40002311A-page 484 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol VOL IOL CB tR Description Output low voltage Low-level output current Capacitive load for each bus line Rise time for both SDA and SCL Condition Min. Typ. Max. Unit Iload = 20 mA, Fast mode+ - - 0.2 × VDD V Iload = 3 mA, Normal mode, VDD > 2V - - 0.4V Iload = 3 mA, Normal mode, VDD ≤ 2V - - 0.2 × VDD fSCL ≤ 400 kHz, VOL = 0.4V 3 - - fSCL ≤ 1 MHz, VOL = 0.4V 20 - - fSCL ≤ 100 kHz - - 400 fSCL ≤ 400 kHz - - 400 fSCL ≤ 1 MHz - - 550 fSCL ≤ 100 kHz - - 1000 fSCL ≤ 400 kHz 20 - 300 - - 120 - 250 fSCL ≤ 1 MHz tOF Output fall time from VIHmin to VILmax 10 pF < capacitance fSCL ≤ 100 of bus line < 400 pF kHz tSP Spikes suppressed by the input filter IL Input current for each I/O pin CI Capacitance for each I/O pin RP_TWI Value of external pull- fSCL ≤ 100 kHz up resistor mA pF ns ns fSCL ≤ 400 kHz 20 × (VDD/ 5.5V) - 250 fSCL ≤ 1 MHz 20 × (VDD/ 5.5V) - 120 0 - 50 ns - - 1 µA - - 10 pF (VDD VOL(max)) /IO - 1000 ns/ (0.8473 × CB) Ω 0.1×VDD < VI < 0.9×VDD L tHD;STA Hold time (repeated) Start condition © 2021 Microchip Technology Inc. fSCL ≤ 400 kHz - - 300 ns/ (0.8473 × CB) fSCL ≤ 1 MHz - - 120 ns/ (0.8473 × CB) fSCL ≤ 100 kHz 4.0 - - fSCL ≤ 400 kHz 0.6 - - fSCL ≤ 1 MHz 0.26 - - Start - 2.1 - Repeated start - 3.1 - Preliminary Datasheet µs TSCL DS40002311A-page 485 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol tLOW tHIGH tSU;STA tHD;DAT tSU;DAT tSU;STO tBUF Description Low period of SCL Clock High period of SCL Clock Setup time for a repeated Start condition Data hold time Data setup time Setup time for Stop condition Bus free time between a Stop and Start condition Condition Min. Typ. Max. Unit fSCL ≤ 100 kHz 4.7 - - µs fSCL ≤ 400 kHz 1.3 - - fSCL ≤ 1 MHz 0.5 - - fSCL ≤ 100 kHz 4.0 - - fSCL ≤ 400 kHz 0.6 - - fSCL ≤ 1 MHz 0.26 - - fSCL ≤ 100 kHz 4.7 - - fSCL ≤ 400 kHz 0.6 - - fSCL ≤ 1 MHz 0.26 - - - 3 - TSCL fSCL ≤ 100 kHz 0 - 3.45 µs fSCL ≤ 400 kHz 0 - 0.9 fSCL ≤ 1 MHz 0 - 0.45 fSCL ≤ 100 kHz 250 - - fSCL ≤ 400 kHz 100 - - fSCL ≤ 1 MHz 50 - - fSCL ≤ 100 kHz 4 - - fSCL ≤ 400 kHz 0.6 - - fSCL ≤ 1 MHz 0.26 - - - 2 - TSCL fSCL ≤ 100 kHz 4.7 - - µs fSCL ≤ 400 kHz 1.3 - - fSCL ≤ 1 MHz 0.5 - - - 2 - µs µs ns µs TSCL Note:  1. These parameters are for design guidance only and are not production tested. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 486 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Table 33-20. SDA Hold Time(1,2) Symbol tHD;DAT Description Condition Data hold time Host(3) fCLK_PER = 5 MHz fCLK_PER = 10 MHz fCLK_PER = 20 MHz tHD;DAT Data hold time Client(4) All Frequencies Min. Typ. Max. Unit SDAHOLD = 0x00 - 800 - ns SDAHOLD = 0x01 830 850 950 SDAHOLD = 0x02 830 850 950 SDAHOLD = 0x03 830 850 1270 SDAHOLD = 0x00 - 400 - SDAHOLD = 0x01 430 450 550 SDAHOLD = 0x02 430 450 580 SDAHOLD = 0x03 430 550 1270 SDAHOLD = 0x00 - 200 220 SDAHOLD = 0x01 230 250 350 SDAHOLD = 0x02 260 450 580 SDAHOLD = 0x03 380 600 1270 SDAHOLD = 0x00 90 150 220 SDAHOLD = 0x01 130 200 350 SDAHOLD = 0x02 260 400 580 SDAHOLD = 0x03 390 550 1270 ns Notes:  1. These parameters are for design guidance only and are not covered by production test limits. 2. SDAHOLD is the data hold time after the SCL signal is detected as being low. The actual hold time is, therefore, higher than the configured hold time. 3. For Host mode, the data hold time is whatever is largest of the following: – 4×tCLK_PER + 50 ns (typical) – SDAHOLD configuration + SCL filter delay 4. For Client mode, the hold time is given by: – SDAHOLD configuration + SCL filter delay 33.15 VREF Table 33-21. Internal Voltage Reference Characteristics(1) Symbol Description Min. Typ. Max. Unit - 25 - µs V tstart Start-up time VDD Power supply voltage range for 1V024 1.8 - 5.5 Power supply voltage range for 2V048 2.6 - 5.5 Power supply voltage range for 2V500 3.0 - 5.5 Power supply voltage range for 4V096 4.6 - 5.5 Note:  1. These parameters are for design guidance only and are not production tested. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 487 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Table 33-22. ADC Internal Voltage Reference Characteristics(1) Symbol(2) Description Condition Min. Typ. Max. Unit % 1V024 Internal reference voltage VDD = [1.8, 5.5]V T = [0, 85]°C -2.0 2.0 2V048 2V500 4V096 Internal reference voltage VDD = [1.8, 5.5]V T = [0, 85]°C -3.0 3.0 1V024 2V048 2V500 4V096 Internal reference voltage VDD = [1.8, 5.5]V T = [-40, 125]°C -5.0 5.0 Notes:  1. These values are based on characterization and not covered by production test limits. 2. The symbols xVxxx refer to the respective values of the REFSEL bit field in the ADC0.CTRLC register. Table 33-23. AC Internal Voltage Reference Characteristics(1) Symbol(2) Description Condition Min. Typ. Max. Unit % 1V024 2V048 2V500 4V096 Internal reference voltage VDD = [1.8, 5.5]V T = [0, 85]°C -3.0 3.0 1V024 2V048 2V500 4V096 Internal reference voltage VDD = [1.8, 5.5]V T = [-40, 125]°C -5.0 5.0 Notes:  1. These values are based on characterization and not covered by production test limits. 2. The symbols xVxxx refer to the respective values of the AC0REFSEL bit field in the VREF.CTRLA register. 33.16 ADC Operating conditions: • TA = [-40, 125]°C • Sample rate defined for SAMPDUR = 0x02 with ADC in Free-Running mode • • Applies for all allowed combinations of VREF selections and sample rates, unless otherwise specified Characteristics are identical with and without PGA enabled, unless otherwise specified Table 33-24. Power Supply, Reference and Input Range Symbol Description VDD Supply Voltage VREF Reference voltage CIN Input capacitance © 2021 Microchip Technology Inc. Conditions Min. Typ. Max. Unit 1.8 - 5.5 V REFSEL = Internal Reference 1.024 - VDD - 0.5 REFSEL = External Reference 1 - 5.5 REFSEL = VDD 1.8 - 5.5 PGA disabled - 8 - PGA enabled - 7 - Preliminary Datasheet pF DS40002311A-page 488 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol Description RIN Input resistance VIN Input voltage range Conditions Min. Typ. Max. Unit - 10 - kΩ Single-ended mode 0 - VREF V Differential mode -0.1 - VDD + 0.1 Table 33-25. Clock and Timing Characteristics Symbol Description Conditions Min. Typ. Max. Unit fCLK_ADC Conversion rate PGA disabled REFSEL = Internal Reference - - 187 ksps - - 375 - - 107 - - 181 300 - 3000 300 - 6000 PGA disabled 0.5 - 255.5 CLK_ADC cycles PGA enabled 1 - 256 REFSEL = External Reference REFSEL = VDD PGA enabled REFSEL = Internal Reference REFSEL = External Reference REFSEL = VDD CLK_ADC ADC clock frequency REFSEL = Internal Reference REFSEL = External Reference kHz REFSEL = VDD TS Sampling time Table 33-26. Accuracy Characteristics External Reference Symbol Description Conditions Res Resolution EINL Integral nonlinearity EDNL Differential nonlineraty EOFF Offset error ±10 EGAIN Gain error ±1 ET Total unadjusted error VDD = 3.0V VREF = 3.0V CLK_ADC = 1 MHz Min. Typ. Max. Unit - - 12 bit - ±1.5 LSb -0.99/+1 - ±10 Min. Typ. Max. Unit - - 12 bit Table 33-27. Accuracy Characteristics Internal Reference Symbol Description Res Resolution © 2021 Microchip Technology Inc. Conditions Preliminary Datasheet DS40002311A-page 489 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics ...........continued Symbol Description Conditions Min. Typ. EINL Integral nonlinearity - ±1.5 EDNL Differential nonlineraty VDD = 5.0V VREF = 4.096V CLK_ADC = 1 MHz EOFF Offset error ±10 EGAIN Gain error ±20 ET Total unadjusted error Max. Unit LSb -0.99/+1 - ±30 Table 33-28. Accuracy Characteristics with PGA Enabled Symbol Description Conditions Min. Typ. Max. Unit NRMS Input Noise PGA Gain = 1V/V - 32 - µVRMS PGA Gain = 2V/V - 63 - PGA Gain = 4V/V - 125 - PGA Gain = 8V/V - 250 - PGA Gain = 16V/V - 500 - PGA Gain = 1V/V - -0.06 - PGA Gain = 2V/V - -0.12 - PGA Gain = 4V/V - -0.25 - PGA Gain = 8V/V - -0.5 - PGA Gain = 16V/V - -1 - Min. Typ. Max. Unit 1.8 - 5.5 V EGAIN 33.17 Gain error % TEMPSENSE Operating Conditions: • VDD = 3V • TA = 25°C, unless otherwise specified Table 33-29. Temperature Sensor, Accuracy Characteristics Symbol Description Condition VDD Supply voltage TACC Sensor accuracy(1,2) TA = 25°C - ±3 - °C TRES Conversion resolution 10 bits - 0.55 - °C tCONV Conversion time 1 MHz ADC clock - 13 - µs Notes:  1. These values are based on characterization and not covered by production test limits. 2. Characteristics over temperature can be found in the Typical Characteristics section. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 490 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics 33.18 AC Table 33-30. Analog Comparator Characteristics, Low-Power Mode Disabled Symbol Description VIN Input voltage VOFF Input offset voltage Condition Min. Typ. Max. Unit -0.2 - VDD V 0.7V < VIN < (VDD - 0.7V) ±5 VIN = [-0.2V, VDD] ±20 mV IL Input leakage current - 5 - nA TSTART Start-up time - 1.3 - µs VHYS Hysteresis tPD Propagation delay HYSMODE = 0x0 0 HYSMODE = 0x1 10 HYSMODE = 0x2 30 HYSMODE = 0x3 60 25 mV Overdrive, VDD ≥ 2.7V mV - 50 - ns Min. Typ. Max. Unit -0.2 - VDD V Table 33-31. Analog Comparator Characteristics, Low-Power Mode Enabled Symbol Description VIN Input voltage VOFF Input offset voltage Condition 0.7V < VIN < (VDD - 0.7V) ±10 VIN = [0V, VDD] ±30 mV IL Input leakage current - 5 - nA TSTART Start-up time - 1.3 - µs VHYS Hysteresis tPD Propagation delay © 2021 Microchip Technology Inc. HYSMODE = 0x0 0 HYSMODE = 0x1 10 HYSMODE = 0x2 25 HYSMODE = 0x3 50 25 mV overdrive, VDD ≥ 2.7V Preliminary Datasheet - 150 mV - ns DS40002311A-page 491 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics 33.19 UPDI Figure 33-9. UPDI Enable Sequence (1) 1 Drive low from debugger to request UPDI clock 2 UPDI clock ready; Communication channel ready. 1 UPDIPAD St D0 D1 D2 UPDI.txd D4 D5 D6 D7 Sp SYNC (0x55) (Autobaud) Handshake / BREAK t RES UPDI.rxd D3 (Ignore) 2 Hi-Z Hi-Z UPDI.txd = 0 t UPDI debugger. UPDI.txd Hi-Z Hi-Z Debugger.txd = 0 t Deb0 Debugger.txd = z. t DebZ Table 33-32. UPDI Timing(1) Symbol Description Min. Max. Unit TRES Duration of Handshake/Break on RESET 10 200 µs TUPDI Duration of UPDI.txd = 0 10 200 µs TDeb0 Duration of Debugger.txd = 0 0.2 1 µs TDebZ Duration of Debugger.txd = z 200 14000 µs Note:  1. These parameters are for design guidance only and are not covered by production test limits. Table 33-33. UPDI Max. Bit Rates vs. VDD(1) Symbol Description Condition Max Unit fUPDI UPDI baud rate VDD = [1.8, 5.5]V TA = [0, 50]°C 225 kbps VDD = [2.2, 5.5]V TA = [0, 50]°C 450 kbps VDD = [2.7, 5.5]V TA = [0, 50]°C 0.9 Mbps Note:  1. These parameters are for design guidance only and are not covered by production test limits. 33.20 Programming Time See the table below for typical programming times for Flash and EEPROM. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 492 ATtiny424/426/427 ATtiny824/826/827 Electrical Characteristics Table 33-34. Programming Times Symbol Typical Programming Time Page Buffer Clear (PBC) Seven CLK_CPU cycles Page Write (WP) 2 ms Page Erase (ER) 2 ms Page Erase-Write (ERWP) 4 ms Chip Erase with UDPI 20 ms(1) 15 ms(2) EEPROM Erase 4 ms Notes:  1. This is the typical chip erase time for devices with 8 KB of Flash. 2. This is the typical chip erase time for devices with 4 KB of Flash. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 493 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics 34. Typical Characteristics 34.1 Power Consumption Plots are not available at this time. 34.2 GPIO 34.2.1 GPIO Input Characteristics Figure 34-1. I/O Pin Input Hysteresis vs. VDD Temperature [°C] 2.0 -40 0 25 70 85 105 125 1.8 1.6 Threshold [V] 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] Figure 34-2. I/O Pin Input Threshold Voltage vs. VDD (T = 25°C) Treshold 75 VIH VIL 70 65 Threshold [%] 60 55 50 45 40 35 30 25 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 494 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-3. I/O Pin Input Threshold Voltage vs. VDD (VIH) Temperature [°C] 75 -40 0 25 70 85 105 125 70 65 Threshold [%] 60 55 50 45 40 35 30 25 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] Figure 34-4. I/O Pin Input Threshold Voltage vs. VDD (VIL) Temperature [°C] 75 -40 0 25 70 85 105 125 70 65 Threshold [%] 60 55 50 45 40 35 30 25 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 495 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics GPIO Output Characteristics Figure 34-5. I/O Pin Output Voltage vs. Sink Current (VDD = 1.8V) Temperature [°C] 0.50 -40 -20 0 25 70 85 105 125 0.45 0.40 0.35 VOutput [V] 0.30 0.25 0.20 0.15 0.10 0.05 0.00 0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 Sink current [mA] Figure 34-6. I/O Pin Output Voltage vs. Sink Current (VDD = 3.0V) Temperature [°C] 0.50 -40 -20 0 25 70 85 105 125 0.45 0.40 0.35 VOutput [V] 34.2.2 0.30 0.25 0.20 0.15 0.10 0.05 0.00 0 1 2 3 4 5 6 7 8 9 10 Sink current [mA] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 496 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-7. I/O Pin Output Voltage vs. Sink Current (VDD = 5.0V) Temperature [°C] 1.0 -40 -20 0 25 70 85 105 125 0.9 0.8 0.7 VOutput [V] 0.6 0.5 0.4 0.3 0.2 0.1 0.0 0 2 4 6 8 10 12 14 16 18 20 Sink current [mA] Figure 34-8. I/O Pin Output Voltage vs. Sink Current (T = 25°C) VDD [V] 1.0 1.8 2 2.2 3 4 5 0.9 0.8 0.7 VOutput [V] 0.6 0.5 0.4 0.3 0.2 0.1 0.0 0 2 4 6 8 10 12 14 16 18 20 Sink current [mA] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 497 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-9. I/O Pin Output Voltage vs. Source Current (VDD = 1.8V) Temperature [°C] 1.80 -40 -20 0 25 70 85 105 125 1.75 1.70 1.65 VOutput [V] 1.60 1.55 1.50 1.45 1.40 1.35 1.30 0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 Source current [mA] Figure 34-10. I/O Pin Output Voltage vs. Source Current (VDD = 3.0V) Temperature [°C] 3.0 -40 -20 0 25 70 85 105 125 2.9 2.8 2.7 VOutput [V] 2.6 2.5 2.4 2.3 2.2 2.1 2.0 0 1 2 3 4 5 6 7 8 9 10 Source current [mA] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 498 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-11. I/O Pin Output Voltage vs. Source Current (VDD = 5.0V) Temperature [°C] 5.0 -40 -20 0 25 70 85 105 125 4.9 4.8 4.7 VOutput [V] 4.6 4.5 4.4 4.3 4.2 4.1 4.0 0 2 4 6 8 10 12 14 16 18 20 Source current [mA] Figure 34-12. I/O Pin Output Voltage vs. Source Current (T = 25°C) VDD [V] 5.0 1.8 2 2.2 3 4 5 4.5 4.0 VOutput [V] 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 0 2 4 6 8 10 12 14 16 18 20 Source current [mA] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 499 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics 34.2.3 GPIO Pull-Up Characteristics Figure 34-13. I/O Pin Pull-Up Resistor Current vs. Input Voltage (VDD = 1.8V) Temperature [°C] 2.0 -40 -20 0 25 70 85 105 125 1.8 1.5 1.3 1.0 0.8 0.5 0.3 0.0 0 5 10 15 20 25 30 35 40 45 50 Pull-up resistor current [µA] Figure 34-14. I/O Pin Pull-Up Resistor Current vs. Input Voltage (VDD = 3.0V) Temperature [°C] 3.0 -40 -20 0 25 70 85 105 125 2.8 2.5 2.3 2.0 1.8 1.5 1.3 1.0 0 5 10 15 20 25 30 35 40 45 50 Pull-up resistor current [µA] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 500 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-15. I/O Pin Pull-Up Resistor Current vs. Input Voltage (VDD = 5.0V) Temperature [°C] 5.0 -40 -20 0 25 70 85 105 125 4.8 4.5 4.3 4.0 3.8 3.5 3.3 3.0 0 5 10 15 20 25 30 35 40 45 50 Pull-up resistor current [µA] 34.3 VREF Characteristics Plots are not available at this time. 34.4 BOD Characteristics 34.4.1 BOD Current vs. VDD Figure 34-20. BOD Current vs. VDD (Continuous Mode enabled) Temperature [°C] 50 -40 0 25 70 85 105 125 45 40 35 IDD [µA] 30 25 20 15 10 5 0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 501 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-21. BOD Current vs. VDD (Sampled BOD at 125 Hz) Temperature [°C] 5.0 -40 0 25 70 85 105 125 4.5 4.0 3.5 IDD [µA] 3.0 2.5 2.0 1.5 1.0 0.5 0.0 1.5 2.0 2.5 3.0 3.5 VDD [V] 4.0 4.5 5.0 5.5 Figure 34-22. BOD Current vs. VDD (Sampled BOD at 1 kHz) Temperature [°C] 5.0 -40 0 25 70 85 105 125 4.5 4.0 IDD [µA] 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 502 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics BOD Threshold vs. Temperature Figure 34-23. BOD Threshold vs. Temperature (BODLEVEL0) 1.90 Falling VDD Rising VDD 1.88 1.86 BOD level [V] 1.84 1.82 1.80 1.78 1.76 1.74 1.72 1.70 -40 -20 0 20 40 60 80 100 120 Temperature [°C] Figure 34-24. BOD Threshold vs. Temperature (BODLEVEL2) Falling VDD Rising VDD 2.74 2.72 2.70 2.68 BOD level [V] 34.4.2 2.66 2.64 2.62 2.60 2.58 2.56 -40 -20 0 20 40 60 80 100 120 Temperature [°C] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 503 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-25. BOD Threshold vs. Temperature (BODLEVEL7) Falling VDD Rising VDD 4.34 4.32 4.30 BOD level [V] 4.28 4.26 4.24 4.22 4.20 4.18 4.16 -40 -20 0 20 40 60 80 100 120 Temperature [°C] 34.5 ADC Characteristics Plots are not available at this time. 34.6 TEMPSENSE Characteristics Plots are not available at this time. 34.7 AC Characteristics Plots are not available at this time. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 504 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics OSC20M Characteristics Figure 34-51. OSC20M Internal Oscillator: Calibration Stepsize vs. Calibration Value (VDD = 3V) Temperature [°C] 1.4 -40 -20 0 25 70 85 105 125 1.2 Step size from 20 MHz [%] 34.8 1.0 0.8 0.6 0.4 0.2 0.0 0 16 32 48 64 80 96 112 128 OSCCAL [x1] Figure 34-52. OSC20M Internal Oscillator: Frequency vs. Calibration Value (VDD = 3V) Temperature [°C] 32 -40 -20 0 25 70 85 105 125 30 28 26 24 22 20 18 16 14 12 10 0 16 32 48 64 80 96 112 128 OSCCAL [x1] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 505 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics Figure 34-53. OSC20M Internal Oscillator: Frequency vs. Temperature VDD [V] 20.5 1.8 2.2 2.7 3 3.6 5 5.5 20.4 20.3 20.2 20.1 20.0 19.9 19.8 19.7 19.6 19.5 -40 -20 0 20 40 60 80 100 120 Temperature [°C] Figure 34-54. OSC20M Internal Oscillator: Frequency vs. VDD Temperature [°C] 20.5 -40 -20 0 25 70 85 105 125 20.4 20.3 20.2 20.1 20.0 19.9 19.8 19.7 19.6 19.5 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 506 ATtiny424/426/427 ATtiny824/826/827 Typical Characteristics OSCULP32K Characteristics Figure 34-55. OSCULP32K Internal Oscillator: Frequency vs. Temperature VDD [V] 40.0 1.8 2.2 2.7 3 3.6 5 5.5 39.0 38.0 Frequency [kHz] 37.0 36.0 35.0 34.0 33.0 32.0 31.0 30.0 -40 -20 0 20 40 60 80 100 120 Temperature [°C] Figure 34-56. OSCULP32K Internal Oscillator: Frequency vs. VDD Temperature [°C] 40.0 -40 -20 0 25 70 85 105 125 39.0 38.0 37.0 Frequency [kHz] 34.9 36.0 35.0 34.0 33.0 32.0 31.0 30.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD [V] © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 507 ATtiny424/426/427 ATtiny824/826/827 Ordering Information 35. Ordering Information Available ordering options can be found by: • • • Clicking on one of the following product page links – ATtiny427 Product Page – ATtiny426 Product Page – ATtiny424 Product Page – ATtiny827 Product Page – ATtiny826 Product Page – ATtiny824 Product Page Searching by product name at microchipdirect.com Contacting your local sales representative Table 35-1. Available Product Numbers Ordering Code(1) Flash/SRAM Pin Count Package Type(2) Supply Voltage Temperature Range Carrier Type ATTINY424-SSF 4 KB/512B 14 SOIC 1.8V-5.5V -40°C to +125°C Tube ATTINY424-SSFR 4 KB/512B 14 SOIC 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY424-SSU 4 KB/512B 14 SOIC 1.8V-5.5V -40°C to +85°C Tube ATTINY424-SSUR 4 KB/512B 14 SOIC 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY424-XF 4 KB/512B 14 TSSOP 1.8V-5.5V -40°C to +125°C Tube ATTINY424-XFR 4 KB/512B 14 TSSOP 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY424-XU 4 KB/512B 14 TSSOP 1.8V-5.5V -40°C to +85°C Tube ATTINY424-XUR 4 KB/512B 14 TSSOP 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY426-MF 4 KB/512B 20 VQFN 1.8V-5.5V -40°C to +125°C Tray ATTINY426-MFR 4 KB/512B 20 VQFN 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY426-MU 4 KB/512B 20 VQFN 1.8V-5.5V -40°C to +85°C Tray ATTINY426-MUR 4 KB/512B 20 VQFN 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY426-SF 4 KB/512B 20 SOIC 1.8V-5.5V -40°C to +125°C Tube ATTINY426-SFR 4 KB/512B 20 SOIC 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY426-SU 4 KB/512B 20 SOIC 1.8V-5.5V -40°C to +85°C Tube ATTINY426-SUR 4 KB/512B 20 SOIC 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY426-XF 4 KB/512B 20 SSOP 1.8V-5.5V -40°C to +125°C Tube ATTINY426-XFR 4 KB/512B 20 SSOP 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY426-XU 4 KB/512B 20 SSOP 1.8V-5.5V -40°C to +85°C Tube ATTINY426-XUR 4 KB/512B 20 SSOP 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY427-MF 4 KB/512B 24 VQFN 1.8V-5.5V -40°C to +125°C Tray ATTINY427-MFR 4 KB/512B 24 VQFN 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY427-MU 4 KB/512B 24 VQFN 1.8V-5.5V -40°C to +85°C Tray ATTINY427-MUR 4 KB/512B 24 VQFN 1.8V-5.5V -40°C to +85°C Tape & Reel Ordering Code(1) Flash/SRAM Pin Count Package Type(2) Supply Voltage Temperature Range Carrier Type ATTINY824-SSF 8 KB/1 KB 14 SOIC 1.8V-5.5V -40°C to +125°C Tube ATTINY824-SSFR 8 KB/1 KB 14 SOIC 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY824-SSU 8 KB/1 KB 14 SOIC 1.8V-5.5V -40°C to +85°C Tube ATTINY824-SSUR 8 KB/1 KB 14 SOIC 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY824-XF 8 KB/1 KB 14 TSSOP 1.8V-5.5V -40°C to +125°C Tube ATTINY824-XFR 8 KB/1 KB 14 TSSOP 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY824-XU 8 KB/1 KB 14 TSSOP 1.8V-5.5V -40°C to +85°C Tube ATTINY824-XUR 8 KB/1 KB 14 TSSOP 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY826-MF 8 KB/1 KB 20 VQFN 1.8V-5.5V -40°C to +125°C Tray © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 508 ATtiny424/426/427 ATtiny824/826/827 Ordering Information ...........continued Ordering Code(1) Flash/SRAM Pin Count Package Type(2) Supply Voltage Temperature Range ATTINY826-MFR 8 KB/1 KB 20 VQFN 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY826-MU 8 KB/1 KB 20 VQFN 1.8V-5.5V -40°C to +85°C Tray Carrier Type ATTINY826-MUR 8 KB/1 KB 20 VQFN 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY826-SF 8 KB/1 KB 20 SOIC 1.8V-5.5V -40°C to +125°C Tube ATTINY826-SF 8 KB/1 KB 20 SSOP 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY826-SFR 8 KB/1 KB 20 SOIC 1.8V-5.5V -40°C to +125°C Tube ATTINY826-SU 8 KB/1 KB 20 SOIC 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY826-SUR 8 KB/1 KB 20 SOIC 1.8V-5.5V -40°C to +85°C Tube ATTINY826-XFR 8 KB/1 KB 20 SSOP 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY826-xU 8 KB/1 KB 20 SSOP 1.8V-5.5V -40°C to +85°C Tube ATTINY826-XUR 8 KB/1 KB 20 SSOP 1.8V-5.5V -40°C to +85°C Tape & Reel ATTINY827-MF 8 KB/1 KB 24 VQFN 1.8V-5.5V -40°C to +125°C Tray ATTINY827-MFR 8 KB/1 KB 24 VQFN 1.8V-5.5V -40°C to +125°C Tape & Reel ATTINY827-MU 8 KB/1 KB 24 VQFN 1.8V-5.5V -40°C to +85°C Tray ATTINY827-MUR 8 KB/1 KB 24 VQFN 1.8V-5.5V -40°C to +85°C Tape & Reel Notes:  1. Pb-free packing complies with the European Directive for Restrictions of Hazardous Substances (RoHS directive). Also halide-free and fully green. 2. Package outline drawings can be found in the Package Drawings section. Figure 35-1. Product Identification System To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office. AT tiny 827 - MUR - VAO ® Variant Suffix AVR product family Flash size in KB Family number Pin count 7=24 pins 6=20 pins 4=14 pins VAO = Automotive Blank = Standard Carrier Type R = Tape & Reel Blank = Tube or Tray Temperature Range Package Type M=VQFN S=SOIC300 SS=SOIC150 X=TSSOP, SSOP U = -40°C to +85°C F = -40°C to +125°C Note:  The Tape & Reel identifier only appears in the catalog part number description. This identifier is used for ordering purposes. Check with your Microchip Sales Office for package availability with the Tape and Reel option. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 509 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 36. Package Drawings 36.1 Online Package Drawings For the most recent package drawings: 1. Go to www.microchip.com/packaging. 2. Go to the package type-specific page, for example VQFN. 3. Search for the Drawing Number and Style to find the most recent package drawings. Table 36-1. Drawing Numbers Pin Count Package Type Drawing Number Style 14 SOIC C04-00065 SL 14 TSSOP C04-00087 ST 20 SOIC C04-00094 SO 20 SSOP C04-00072 SS 20 VQFN C04-21380 REB 24 VQFN C04-21386 RLB © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 510 ATtiny424/426/427 ATtiny824/826/827 R Package Drawings 36.2 14-Pin SOIC 14-Lead Plastic Small Outline (SL) - Narrow, 3.90 mm Body [SOIC] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging 2X 0.10 C A–B D A NOTE 5 D N E 2 E2 2 E1 E 2X 0.10 C D NOTE 1 1 2 2X N/2 TIPS 0.20 C 3 e NX b B 0.25 NOTE 5 C A–B D TOP VIEW 0.10 C C A A2 SEATING PLANE 14X 0.10 C SIDE VIEW A1 h h R0.13 H R0.13 c SEE VIEW C L VIEW A–A (L1) VIEW C Microchip Technology Drawing No. C04-065-SL Rev D Sheet 1 of 2 © 2017 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 511 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 14-Lead Plastic Small Outline (SL) - Narrow, 3.90 mm Body [SOIC] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging Units Dimension Limits Number of Pins N e Pitch Overall Height A Molded Package Thickness A2 § Standoff A1 Overall Width E Molded Package Width E1 Overall Length D Chamfer (Optional) h Foot Length L Footprint L1 Lead Angle Foot Angle c Lead Thickness Lead Width b Mold Draft Angle Top Mold Draft Angle Bottom MIN 1.25 0.10 0.25 0.40 0° 0° 0.10 0.31 5° 5° MILLIMETERS NOM 14 1.27 BSC 6.00 BSC 3.90 BSC 8.65 BSC 1.04 REF - MAX 1.75 0.25 0.50 1.27 8° 0.25 0.51 15° 15° Notes: 1. Pin 1 visual index feature may vary, but must be located within the hatched area. 2. § Significant Characteristic 3. Dimension D does not include mold flash, protrusions or gate burrs, which shall not exceed 0.15 mm per end. Dimension E1 does not include interlead flash or protrusion, which shall not exceed 0.25 mm per side. 4. 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. 5. Datums A & B to be determined at Datum H. Microchip Technology Drawing No. C04-065-SL Rev D Sheet 2 of 2 © 2017 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 512 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 14-Lead Plastic Small Outline (SL) - Narrow, 3.90 mm Body [SOIC] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging 14 SILK SCREEN C Y 1 2 X E RECOMMENDED LAND PATTERN Units Dimension Limits E Contact Pitch Contact Pad Spacing C Contact Pad Width (X14) X Contact Pad Length (X14) Y MIN MILLIMETERS NOM 1.27 BSC 5.40 MAX 0.60 1.55 Notes: 1. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. Microchip Technology Drawing No. C04-2065-SL Rev D © 2017 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 513 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 36.3 14-Pin TSSOP 14Lead Thin Shrink Small Outline Package [ST] 4.4 mm Body [TSSOP] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging D A B N E 2 E1 2 E1 E 1 2X 7 TIPS 0.20 C B A 2 e TOP VIEW A C A2 A SEATING PLANE 14X 0.10 C 14X b 0.10 A1 C B A A SIDE VIEW SEE DETAIL B VIEW A–A Microchip Technology Drawing C04-087 Rev D Sheet 1 of 2 © 2020 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 514 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 14Lead Thin Shrink Small Outline Package [ST] 4.4 mm Body [TSSOP] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging (θ2) R1 H R2 c L θ1 (L1) (θ3) DETAIL B Notes: Number of Terminals Pitch Overall Height Standoff Molded Package Thickness Overall Length Overall Width Molded Package Width Terminal Width Terminal Thickness Terminal Length Footprint Lead Bend Radius Lead Bend Radius Foot Angle Mold Draft Angle Mold Draft Angle Units Dimension Limits N e A A1 A2 D E E1 b c L L1 R1 R2 θ1 θ2 θ3 MIN – 0.05 0.80 4.90 4.30 0.19 0.09 0.45 0.09 0.09 0° – – MILLIMETERS NOM 14 0.65 BSC – – 1.00 5.00 6.40 BSC 4.40 – – 0.60 1.00 REF – – – 12° REF 12° REF MAX 1.20 0.15 1.05 5.10 4.50 0.30 0.20 0.75 – – 8° – – 1. Pin 1 visual index feature may vary, but must be located within the hatched area. 2. 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 C04-087 Rev D Sheet 2 of 2 © 2020 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 515 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 14Lead Thin Shrink Small Outline Package [ST] 4.4 mm Body [TSSOP] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging G SILK SCREEN C Y X E RECOMMENDED LAND PATTERN Units Dimension Limits Contact Pitch E Contact Pad Spacing C Contact Pad Width (Xnn) X Contact Pad Length (Xnn) Y Contact Pad to Contact Pad (Xnn) G MIN MILLIMETERS NOM 0.65 BSC 5.90 MAX 0.45 1.45 0.20 Notes: 1. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. Microchip Technology Drawing C04-2087 Rev D © 2020 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 516 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 36.4 20-Pin SOIC 20-Lead Plastic Small Outline (SO) - Wide, 7.50 mm Body [SOIC] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging D A E 2 E1 2 E1 E 2X 10 TIPS 0.33 C NOTE 1 20X b 0.25 B e C A-B D TOP VIEW A 0.10 C A2 A C SEATING PLANE 20X A1 SIDE VIEW 0.10 C A h SEE DETAIL B h VIEW A–A Microchip Technology Drawing C04-094 Rev D Sheet 1 of 2 © 2020 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 517 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 20-Lead Plastic Small Outline (SO) - Wide, 7.50 mm Body [SOIC] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging θ2 θ1 R1 R H c θ3 θ L (L1) DETAIL B Notes: Number of Terminals Pitch Overall Height Standoff § Molded Package Thickness Overall Length Overall Width Molded Package Width Terminal Width Terminal Thickness Corner Chamfer Terminal Length Footprint Lead Bend Radius Lead Bend Radius Foot Angle Lead Angle Mold Draft Angle Mold Draft Angle Units Dimension Limits N e A A1 A2 D E E1 b c h L L1 R1 R2 θ θ1 θ2 θ3 MIN 0.10 2.05 0.31 0.25 0.25 0.41 0.07 0.07 0° 0° 5° 5° MILLIMETERS NOM 20 1.27 BSC 12.80 BSC 10.30 BSC 7.50 BSC 0.65 1.40 REF - MAX 2.65 0.30 - 0.51 0.75 0.41 0.89 8° 15° 15° 1. Pin 1 visual index feature may vary, but must be located within the hatched area. 2. 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. 3. Dimension D does not include mold flash, protrusions or gate burrs, which shall not exceed 0.15 mm per end. Dimension E1 does not include interlead flash or protrusion, which shall not exceed 0.25 mm per side. 4. § Significant Characteristic Microchip Technology Drawing C04-094 Rev D Sheet 2 of 2 © 2020 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 518 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 20-Lead Plastic Small Outline (SO) - Wide, 7.50 mm Body [SOIC] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging G1 20 SILK SCREEN C G Y 1 2 X E RECOMMENDED LAND PATTERN Units Dimension Limits Contact Pitch E Contact Pad Spacing C Contact Pad Width (X20) X Contact Pad Length (X20) Y Contact Pad to Contact Pad G Contact Pad to Contact Pad G1 MIN MILLIMETERS NOM 1.27 BSC 9.40 MAX 0.60 1.95 0.67 7.45 Notes: 1. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. 2. For best soldering results, thermal vias, if used, should be filled or tented to avoid solder loss during reflow process Microchip Technology Drawing C04-2094 Rev D © 2020 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 519 M ATtiny424/426/427 ATtiny824/826/827 Package Drawings Packaging Diagrams and Parameters 36.5 20-Pin SSOP 20-Lead Plastic Shrink Small Outline (SS) – 5.30 mm Body [SSOP] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging D N E E1 NOTE 1 1 2 e b c A2 A φ A1 L1 Units Dimension Limits Number of Pins L MILLIMETERS MIN N NOM MAX 20 Pitch e Overall Height A – 0.65 BSC – 2.00 Molded Package Thickness A2 1.65 1.75 1.85 Standoff A1 0.05 – – Overall Width E 7.40 7.80 8.20 Molded Package Width E1 5.00 5.30 5.60 Overall Length D 6.90 7.20 7.50 Foot Length L 0.55 0.75 0.95 Footprint L1 1.25 REF Lead Thickness c 0.09 – Foot Angle φ 0° 4° 0.25 8° Lead Width b 0.22 – 0.38 Notes: 1. Pin 1 visual index feature may vary, but must be located within the hatched area. 2. Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed 0.20 mm per side. 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 C04-072B © 2007 Microchip Technology Inc. DS00049AR-page 114 © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 520 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 20-Lead Plastic Shrink Small Outline (SS) - 5.30 mm Body [SSOP] Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging 0.65 0.45 SILK SCREEN c Y1 G X1 E RECOMMENDED LAND PATTERN Units Dimension Limits E Contact Pitch Contact Pad Spacing C Contact Pad Width (X20) X1 Contact Pad Length (X20) Y1 Distance Between Pads G MIN MILLIMETERS NOM 0.65 BSC 7.20 MAX 0.45 1.75 0.20 Notes: 1. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. Microchip Technology Drawing No. C04-2072B © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 521 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 36.6 20-Pin VQFN 20-Lead Very Thin Plastic Quad Flat, No Lead Package (REB) - 3x3 mm Body [VQFN] With 1.7 mm Exposed Pad; Atmel Legacy Global Package Code ZCL Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging 16X 0.08 C D NOTE 1 A 0.10 C B N 1 2 E (DATUM B) (DATUM A) 2X 0.10 C 2X A1 TOP VIEW 0.10 C 0.10 (A3) C A B A SEATING C PLANE D2 SIDE VIEW 0.10 C A B E2 2 (CH) 1 NOTE 1 K N L e BOTTOM VIEW 20X b 0.10 0.05 C A B C Microchip Technology Drawing C04-21380 Rev A Sheet 1 of 2 © 2018 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 522 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 20-Lead Very Thin Plastic Quad Flat, No Lead Package (REB) - 3x3 mm Body [VQFN] With 1.7 mm Exposed Pad; Atmel Legacy Global Package Code ZCL Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging Notes: Units Dimension Limits Number of Terminals N e Pitch A Overall Height 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 Pin 1 Index Chamfer CH MIN 0.80 0.00 1.60 1.60 0.15 0.35 0.20 MILLIMETERS NOM 20 0.40 BSC 0.85 0.035 0.203 REF 3.00 BSC 1.70 3.00 BSC 1.70 0.20 0.40 0.35 REF MAX 0.90 0.05 1.80 1.80 0.25 0.45 - 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 C04-21380 Rev A Sheet 2 of 2 © 2018 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 523 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 20-Lead Very Thin Plastic Quad Flat, No Lead Package (REB) - 3x3 mm Body [VQFN] With 1.7 mm Exposed Pad; Atmel Legacy Global Package Code ZCL Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging C1 X2 EV ØV G2 C2 Y2 EV G1 Y1 X1 SILK SCREEN E RECOMMENDED LAND PATTERN Units Dimension Limits E Contact Pitch Optional Center Pad Width X2 Optional Center Pad Length Y2 Contact Pad Spacing C1 Contact Pad Spacing C2 Contact Pad Width (X20) X1 Contact Pad Length (X20) Y1 Contact Pad to Center Pad (X20) G1 Contact Pad to Contact Pad (X16) G2 Thermal Via Diameter V Thermal Via Pitch EV MIN MILLIMETERS NOM 0.40 BSC MAX 1.80 1.80 3.00 3.00 0.20 0.80 0.20 0.20 0.30 1.00 Notes: 1. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. 2. For best soldering results, thermal vias, if used, should be filled or tented to avoid solder loss during reflow process Microchip Technology Drawing C04-23380 Rev A © 2018 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 524 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 36.7 24-Pin VQFN 24-Lead Very Thin Plastic Quad Flat, No Lead Package (RLB) - 4x4 mm Body [VQFN] Atmel Legacy Global Package Code ZHA 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 0.10 C A B N 1 2 E (DATUM B) (DATUM A) 2X 0.15 C 2X TOP VIEW 0.15 C A1 0.10 (A3) C A B A SEATING C PLANE D2 0.10 C A B SIDE VIEW E2 e 2 2 NOTE 1 1 K N L e BOTTOM VIEW 24X b 0.10 0.05 C A B C Microchip Technology Drawing C04-21386 Rev A Sheet 1 of 2 © 2019 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 525 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 24-Lead Very Thin Plastic Quad Flat, No Lead Package (RLB) - 4x4 mm Body [VQFN] Atmel Legacy Global Package Code ZHA Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging Notes: 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 E2 Exposed Pad Width Terminal Width b Terminal Length L Terminal-to-Exposed-Pad K MIN 0.80 0.00 2.45 2.45 0.18 0.35 0.20 MILLIMETERS NOM 24 0.50 BSC 0.85 0.203 REF 4.00 BSC 2.60 4.00 BSC 2.60 0.25 0.40 - MAX 0.90 0.05 2.75 2.75 0.30 0.45 - 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 C04-21386 Rev A Sheet 2 of 2 © 2019 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 526 ATtiny424/426/427 ATtiny824/826/827 Package Drawings 24-Lead Very Thin Plastic Quad Flat, No Lead Package (RLB) - 4x4 mm Body [VQFN] Atmel Legacy Global Package Code ZHA Note: For the most current package drawings, please see the Microchip Packaging Specification located at http://www.microchip.com/packaging C1 X2 EV 24 ØV 1 2 C2 G2 Y2 EV G1 Y1 X1 SILK SCREEN E RECOMMENDED LAND PATTERN Units Dimension Limits E Contact Pitch Optional Center Pad Width X2 Optional Center Pad Length Y2 Contact Pad Spacing C1 Contact Pad Spacing C2 Contact Pad Width (X24) X1 Contact Pad Length (X24) Y1 Contact Pad to Center Pad (X24) G1 Contact Pad to Contact Pad (X20) G2 Thermal Via Diameter V Thermal Via Pitch EV MIN MILLIMETERS NOM 0.50 BSC MAX 2.75 2.75 4.00 4.00 0.30 0.85 0.20 0.20 0.30 1.00 Notes: 1. Dimensioning and tolerancing per ASME Y14.5M BSC: Basic Dimension. Theoretically exact value shown without tolerances. 2. For best soldering results, thermal vias, if used, should be filled or tented to avoid solder loss during reflow process Microchip Technology Drawing C04-23386 Rev A © 2019 Microchip Technology Inc. © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 527 ATtiny424/426/427 ATtiny824/826/827 Data Sheet Revision History 37. Data Sheet Revision History Note:  The data sheet revision is independent of the die revision and the device variant (last letter of the ordering number). 37.1 Rev. A - 03/2021 Section Changes Document Initial release of preliminary data sheet © 2021 Microchip Technology Inc. Preliminary Datasheet DS40002311A-page 528 ATtiny424/426/427 ATtiny824/826/827 The Microchip Website Microchip provides online support via our website at www.microchip.com/. This website is used to make files and information easily available to customers. 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AT tiny 827 - MUR - VAO ® Variant Suffix AVR product family Flash size in KB Family number Pin count 7=24 pins 6=20 pins 4=14 pins VAO = Automotive Blank = Standard Carrier Type R = Tape & Reel Blank = Tube or Tray Temperature Range Package Type M=VQFN S=SOIC300 SS=SOIC150 X=TSSOP, SSOP U = -40°C to +85°C F = -40°C to +125°C Note:  The Tape & Reel identifier only appears in the catalog part number description. This identifier is used for ordering purposes. Check with your Microchip Sales Office for package availability with the Tape and Reel option. Microchip Devices Code Protection Feature Note the following details of the code protection feature on Microchip devices: • • • • • Microchip products meet the specifications contained in their particular Microchip Data Sheet. Microchip believes that its family of products is secure when used in the intended manner and under normal conditions. 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Adjacent Key Suppression, AKS, Analog-for-the-Digital Age, Any Capacitor, AnyIn, AnyOut, Augmented Switching, BlueSky, BodyCom, CodeGuard, CryptoAuthentication, CryptoAutomotive, CryptoCompanion, CryptoController, dsPICDEM, dsPICDEM.net, Dynamic Average Matching, DAM, ECAN, Espresso T1S, EtherGREEN, IdealBridge, In-Circuit Serial Programming, ICSP, INICnet, Intelligent Paralleling, Inter-Chip Connectivity, JitterBlocker, maxCrypto, maxView, memBrain, Mindi, MiWi, MPASM, MPF, MPLAB Certified logo, MPLIB, MPLINK, MultiTRAK, NetDetach, Omniscient Code Generation, PICDEM, PICDEM.net, PICkit, PICtail, PowerSmart, PureSilicon, QMatrix, REAL ICE, Ripple Blocker, RTAX, RTG4, SAM-ICE, Serial Quad I/O, simpleMAP, SimpliPHY, SmartBuffer, SMART-I.S., storClad, SQI, SuperSwitcher, SuperSwitcher II, Switchtec, SynchroPHY, Total Endurance, TSHARC, USBCheck, VariSense, VectorBlox, VeriPHY, ViewSpan, WiperLock, XpressConnect, 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. The Adaptec logo, Frequency on Demand, Silicon Storage Technology, and Symmcom are registered trademarks 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. © 2021, Microchip Technology Incorporated, Printed in the U.S.A., All Rights Reserved. ISBN: 978-1-5224-7910-9 Quality Management System For information regarding Microchip’s Quality Management Systems, please visit www.microchip.com/quality. © 2021 Microchip Technology Inc. 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