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TMS570LS1115
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
TMS570LS1115 16- and 32-Bit RISC Flash Microcontroller
1 Device Overview
1.1
Features
1
• High-Performance Automotive-Grade
Microcontroller for Safety-Critical Applications
– Dual CPUs Running in Lockstep
– ECC on Flash and RAM Interfaces
– Built-In Self-Test (BIST) for CPU and On-chip
RAMs
– Error Signaling Module With Error Pin
– Voltage and Clock Monitoring
• ARM® Cortex®-R4F 32-Bit RISC CPU
– 1.66 DMIPS/MHz With 8-Stage Pipeline
– FPU With Single- and Double-Precision
– 12-Region Memory Protection Unit (MPU)
– Open Architecture With Third-Party Support
• Operating Conditions
– Up to 180-MHz System Clock
– Core Supply Voltage (VCC): 1.14 to 1.32 V
– I/O Supply Voltage (VCCIO): 3.0 to 3.6 V
• Integrated Memory
– 1MB of Program Flash With ECC
– 128KB of RAM With ECC
– 64KB of Flash for Emulated EEPROM With
ECC
• 16-Bit External Memory Interface (EMIF)
• Common Platform Architecture
– Consistent Memory Map Across Family
– Real-Time Interrupt (RTI) Timer (OS Timer)
– 128-Channel Vectored Interrupt Module (VIM)
– 2-Channel Cyclic Redundancy Checker (CRC)
• Direct Memory Access (DMA) Controller
– 16 Channels and 32 Control Packets
– Parity Protection for Control Packet RAM
– DMA Accesses Protected by Dedicated MPU
• Frequency-Modulated Phase-Locked Loop
(FMPLL) With Built-In Slip Detector
• Separate Nonmodulating PLL
• IEEE 1149.1 JTAG, Boundary Scan and ARM
CoreSight™ Components
• Advanced JTAG Security Module (AJSM)
• Calibration Capabilities
– Parameter Overlay Module (POM)
• 16 General-Purpose Input/Output (GPIO) Pins
Capable of Generating Interrupts
• Enhanced Timing Peripherals for Motor Control
– 7 Enhanced Pulse Width Modulator (ePWM)
Modules
– 6 Enhanced Capture (eCAP) Modules
– 2 Enhanced Quadrature Encoder Pulse (eQEP)
Modules
• Two Next Generation High-End Timer (N2HET)
Modules
– N2HET1: 32 Programmable Channels
– N2HET2: 18 Programmable Channels
– 160-Word Instruction RAM Each With Parity
Protection
– Each N2HET Includes Hardware Angle
Generator
– Dedicated High-End Timer Transfer Unit (HTU)
for Each N2HET
• Two 12-Bit Multibuffered Analog-to-Digital
Converter (MibADC) Modules
– ADC1: 24 Channels
– ADC2: 16 Channels Shared With ADC1
– 64 Result Buffers Each With Parity Protection
• Multiple Communication Interfaces
– FlexRay Controller With 2 Channels
• 8KB of Message RAM With Parity Protection
• Dedicated FlexRay Transfer Unit (FTU)
– Three CAN Controllers (DCANs)
• 64 Mailboxes Each With Parity Protection
• Compliant to CAN Protocol Version 2.0A and
2.0B
– Inter-Integrated Circuit (I2C)
– Three Multibuffered Serial Peripheral Interface
(MibSPI) Modules
• 128 Words Each With Parity Protection
• 8 Transfer Groups
– Up to Two Standard Serial Peripheral Interface
(SPI) Modules
– Two UART (SCI) Interfaces, One With Local
Interconnect Network (LIN 2.1) Interface
Support
• Packages
– 144-Pin Quad Flatpack (PGE) [Green]
– 337-Ball Grid Array (ZWT) [Green]
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
TMS570LS1115
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
1.2
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Applications
Braking Systems (ABS and ESC)
Electric Power Steering (EPS)
HEV and EV Inverter Systems
Battery Management Systems
1.3
www.ti.com
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Active Driver Assistance Systems
Aerospace and Avionics
Railway Communications
Off-road Vehicles
Description
The TMS570LS1115 device is a high-performance automotive-grade microcontroller family for safety
systems. The safety architecture includes dual CPUs in lockstep, CPU and memory BIST logic, ECC on
both the flash and the data SRAM, parity on peripheral memories, and loopback capability on peripheral
I/Os.
The TMS570LS1115 device integrates the ARM Cortex-R4F floating-point CPU which offers an efficient
1.66 DMIPS/MHz, and has configurations which can run up to 180 MHz providing up to 298 DMIPS. The
device supports the word-invariant big-endian [BE32] format.
The TMS570LS1115 device has 1MB of integrated flash and 128KB of data RAM with single-bit error
correction and double-bit error detection. The flash memory on this device is a nonvolatile, electrically
erasable and programmable memory, implemented with a 64-bit-wide data bus interface. The flash
operates on a 3.3-V supply input (same level as I/O supply) for all read, program, and erase operations.
When in pipeline mode, the flash operates with a system clock frequency of up to 180 MHz. The SRAM
supports single-cycle read and write accesses in byte, halfword, word, and double-word modes throughout
the supported frequency range.
The TMS570LS1115 device features peripherals for real-time control-based applications, including two
Next Generation High-End Timer (N2HET) timing coprocessors with up to 44 I/O terminals, seven
Enhanced Pulse Width Modulator (ePWM) modules with up to 14 outputs, six Enhanced Capture (eCAP)
modules, two Enhanced Quadrature Encoder Pulse (eQEP) modules, and two 12-bit Analog-to-Digital
Converters (ADCs) supporting up to 24 inputs.
The N2HET is an advanced intelligent timer that provides sophisticated timing functions for real-time
applications. The timer is software-controlled, using a reduced instruction set, with a specialized timer
micromachine and an attached I/O port. The N2HET can be used for pulse-width-modulated outputs,
capture or compare inputs, or general-purpose I/O (GIO). The N2HET is especially well suited for
applications requiring multiple sensor information and drive actuators with complex and accurate time
pulses. A High-End Timer Transfer Unit (HTU) can perform DMA-type transactions to transfer N2HET data
to or from main memory. A Memory Protection Unit (MPU) is built into the HTU.
The ePWM module can generate complex pulse width waveforms with minimal CPU overhead or
intervention. The ePWM is easy to use and it supports both high-side and low-side PWM and deadband
generation. With integrated trip zone protection and synchronization with the on-chip MibADC, the ePWM
module is ideal for digital motor control applications.
The eCAP module is essential in systems where the accurately timed capture of external events is
important. The eCAP can also be used to monitor the ePWM outputs or for simple PWM generation when
the eCAP is not needed for capture applications.
The eQEP module is used for direct interface with a linear or rotary incremental encoder to get position,
direction, and speed information from a rotating machine as used in high-performance motion and
position-control systems.
2
Device Overview
Copyright © 2012–2015, Texas Instruments Incorporated
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
The device has two 12-bit-resolution MibADCs with 24 total inputs and 64 words of parity-protected buffer
RAM each. The MibADC channels can be converted individually or can be grouped by software for
sequential conversion sequences. Sixteen inputs are shared between the two MibADCs. Each MibADC
supports three separate groupings of channels. Each group can be converted once when triggered or
configured for continuous conversion mode. The MibADC has a 10-bit mode for use when compatibility
with older devices or faster conversion time is desired. MibADC1 also supports the use of external analog
multiplexers.
The device has multiple communication interfaces: three MibSPIs, two SPIs, one LIN, one SCI, three
DCANs, one I2C, and one FlexRay controller with two channels. The SPI provides a convenient method of
serial high-speed communications between similar shift-register type devices. The LIN supports the Local
Interconnect standard 2.0 and can be used as a UART in full-duplex mode using the standard NonReturn-to-Zero (NRZ) format. The DCAN supports the CAN 2.0 (A and B) protocol standard and uses a
serial, multimaster communication protocol that efficiently supports distributed real-time control with robust
communication rates of up to 1 Mbps. The DCAN is ideal for systems operating in noisy and harsh
environments (for example, automotive and industrial fields) that require reliable serial communication or
multiplexed wiring. The FlexRay controller uses a dual-channel serial, fixed time base multimaster
communication protocol with communication rates of 10 Mbps per channel. A FlexRay Transfer Unit (FTU)
enables autonomous transfers of FlexRay data to and from main CPU memory. Transfers are protected
by a dedicated, built-in MPU.
The I2C module is a multimaster communication module providing an interface between the
microcontroller and an I2C-compatible device through the I2C serial bus. The I2C supports speeds of 100
and 400 Kbps.
A Frequency-Modulated Phase-Locked Loop (FMPLL) clock module is used to multiply the external
frequency reference to a higher frequency for internal use. The Global Clock Module (GCM) manages the
mapping between the available clock sources and the device clock domains.
The device also has an External Clock Prescaler (ECP) module that when enabled, outputs a continuous
external clock on the ECLK terminal. The ECLK frequency is a user-programmable ratio of the peripheral
interface clock (VCLK) frequency. This low-frequency output can be monitored externally as an indicator of
the device operating frequency.
The Direct Memory Access (DMA) controller has 16 channels, 32 control packets, and parity protection on
its memory. An MPU is built into the DMA to protect memory against erroneous transfers.
The Error Signaling Module (ESM) monitors all device errors and determines whether an interrupt or
external error pin (ball) is triggered when a fault is detected. The nERROR terminal can be monitored
externally as an indicator of a fault condition in the microcontroller.
The External Memory Interface (EMIF) provides a memory extension to asynchronous and synchronous
memories or other slave devices.
A Parameter Overlay Module (POM) enhances the calibration capabilities of application code. The POM
can reroute flash accesses to internal memory or to the EMIF, thus avoiding the reprogramming steps
necessary for parameter updates in flash.
With integrated safety features and a wide choice of communication and control peripherals, the
TMS570LS1115 device is an ideal solution for high-performance real-time control applications with safetycritical requirements.
Table 1-1. Device Information (1)
PACKAGE
BODY SIZE
TMS570LS1115ZWT
PART NUMBER
NFBGA (337)
16.0 mm × 16.0 mm
TMS570LS1115PGE
LQFP (144)
20.0 mm × 20.0 mm
(1)
For more information, see Section 9, Mechanical Packaging and Orderable Information.
Device Overview
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3
TMS570LS1115
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
1.4
www.ti.com
Functional Block Diagram
NOTE
The block diagram reflects the 337BGA package. Some pins are multiplexed or not available
in the 144QFP. For details, see the respective terminal functions tables in Section 4.3.
128kB RAM
with ECC
32K
32K
1MB
Flash
with
ECC
32K
32K
DMA
Dual Cortex-R4F
CPUs in Lockstep
HTU1
POM
FTU
HTU2
Switched Central Resource Switched Central Resource
Main Cross Bar: Arbitration and Prioritization Control
CRC
Switched Central Resource
64 KB Flash
for EEPROM
Emulation
with ECC
EMIF
EMIF_nWAIT
EMIF_CLK
EMIF_CKE
EMIF_nCS[4:2]
EMIF_nCS[0]
EMIF_ADDR[12:0]
EMIF_BA[1:0]
EMIF_DATA[15:0]
EMIF_nDQM[1:0]
EMIF_nOE
EMIF_nWE
EMIF_nRAS
EMIF_nCAS
SYS
eQEPxA
eQEPxB
eQEPxS
eQEPxI
eQEP
1,2
IOMM
ESM
PMM
eCAP
1..6
eCAP[6:1]
ePWM
1..7
nTZ[3:1]
SYNCO
SYNCI
ePWMxA
ePWMxB
always on
DCAN3
MibSPI1
RTI
#1
#2
DCC1
SPI2
DCC2
MibSPI3
#1
#3
#4
#5
SPI4
N2HET1
GIO
FlexRay
I2C
I2C_SCL
I2C_SDA
FRAY_RX2
FRAY_TX2
FRAY_TXEN2
GIOB[7:0]
FRAY_RX1
FRAY_TX1
FRAY_TXEN1
GIOA[7:0]
N2HET2_PIN_nDIS
N2HET2[15:0]
N2HET2[18,16]
N2HET1[31:0]
AD2EVT
N2HET1_PIN_nDIS
AD1IN[23:16] \
AD2IN[7:0]
VCCAD
VSSAD
ADREFHI
ADREFLO
MibADC2
AD1IN[15:8] \
AD2IN[15:8]
AD1EVT
AD1IN[7:0]
MibADC1
N2HET2
nPORRST
nRST
ECLK
nERROR
CAN1_RX
CAN1_TX
CAN2_RX
CAN2_TX
CAN3_RX
CAN3_TX
MIBSPI1_CLK
MIBSPI1_SIMO[1:0]
MIBSPI1_SOMI[1:0]
MIBSPI1_nCS[5:0]
MIBSPI1_nENA
RAM
Core
DCAN1
DCAN2
VIM
Color Legend for Power Domains
Core/RAM
Peripheral Central Resource Bridge
Switched Central Resource
MibSPI5
SPI2_CLK
SPI2_SIMO
SPI2_SOMI
SPI2_nCS[1:0]
SPI2_nENA
MIBSPI3_CLK
MIBSPI3_SIMO
MIBSPI3_SOMI
MIBSPI3_nCS[5:0]
MIBSPI3_nENA
SPI4_CLK
SPI4_SIMO
SPI4_SOMI
SPI4_nCS0
SPI4_nENA
MIBSPI5_CLK
MIBSPI5_SIMO[3:0]
MIBSPI5_SOMI[3:0]
MIBSPI5_nCS[3:0]
MIBSPI5_nENA
LIN
LIN_RX
LIN_TX
SCI
SCI_RX
SCI_TX
Figure 1-1. Functional Block Diagram
4
Device Overview
Copyright © 2012–2015, Texas Instruments Incorporated
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TMS570LS1115
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Table of Contents
1
2
3
4
5
Device Overview ......................................... 1
6.10
Flash Memory ....................................... 77
1.1
Features .............................................. 1
6.11
Tightly Coupled RAM Interface Module ............. 80
1.2
Applications ........................................... 2
6.12
Parity Protection for Accesses to Peripheral RAMs
1.3
Description ............................................ 2
6.13
On-Chip SRAM Initialization and Testing
1.4
Functional Block Diagram ............................ 4
6.14
Revision History ......................................... 6
Device Comparison ..................................... 8
Terminal Configuration and Functions ............. 9
6.15
4.1
PGE QFP Package Pinout (144-Pin) ................. 9
6.18
4.2
ZWT BGA Package Ball-Map (337 Ball Grid Array)
10
6.19
4.3
Terminal Functions
11
6.20
Specifications
6.17
42
6.21
5.1
Absolute Maximum Ratings Over Operating FreeAir Temperature Range ............................ 42
5.2
ESD Ratings
42
7.1
Enhanced Translator PWM Modules (ePWM) ..... 113
5.3
Power-On Hours (POH) ............................. 42
7.2
Enhanced Capture Modules (eCAP) ............... 118
5.4
5.5
Device Recommended Operating Conditions....... 43
Switching Characteristics Over Recommended
Operating Conditions for Clock Domains ........... 44
7.3
Enhanced Quadrature Encoder (eQEP) ........... 120
7.4
Multibuffered 12bit Analog-to-Digital Converter.... 121
7.5
General-Purpose Input/Output ..................... 133
7.6
Enhanced High-End Timer (N2HET)
7.7
FlexRay Interface .................................. 138
7.8
Controller Area Network (DCAN) .................. 140
5.6
5.7
5.8
........................................
7
Wait States Required ............................... 44
Power Consumption Over Recommended
Operating Conditions ................................ 45
Input/Output Electrical Characteristics Over
Recommended Operating Conditions ............... 46
Peripheral Information and Electrical
Specifications ......................................... 113
Local Interconnect Network Interface (LIN) ........ 141
Inter-Integrated Circuit (I2C) ....................... 143
Multibuffered / Standard Serial Peripheral
Interface ............................................ 146
Thermal Resistance Characteristics ................ 46
5.10
Output Buffer Drive Strengths
......................
Input Timings ........................................
Output Timings ......................................
Low-EMI Output Buffers ............................
7.11
7.12
5.12
5.13
48
49
51
8
System Information and Electrical
Specifications ........................................... 52
6.1
Device Power Domains ............................. 52
6.2
Voltage Monitor Characteristics ..................... 52
6.3
Power Sequencing and Power On Reset ........... 54
6.4
Warm Reset (nRST)................................. 56
6.5
ARM Cortex-R4F CPU Information
6.6
6.7
6.8
6.9
.................
Clocks ...............................................
Clock Monitoring ....................................
Glitch Filters .........................................
Device Memory Map ................................
60
68
70
71
Device and Documentation Support .............. 158
8.1
Device and Development-Support Tool
Nomenclature ...................................... 158
8.2
Documentation Support ............................ 160
8.3
Trademarks ........................................ 160
8.4
Electrostatic Discharge Caution
8.5
8.6
57
8.7
9
134
Serial Communication Interface (SCI) ............. 142
5.9
47
..............
7.9
7.10
5.11
6
.................................
..........................................
6.16
80
........... 82
External Memory Interface (EMIF) .................. 84
Vectored Interrupt Manager ......................... 92
DMA Controller ...................................... 96
Real Time Interrupt Module ......................... 98
Error Signaling Module............................. 100
Reset / Abort / Error Sources ...................... 104
Digital Windowed Watchdog ....................... 107
Debug Subsystem ................................. 108
...................
Glossary............................................
Device Identification................................
Module Certifications...............................
160
160
161
163
Mechanical Packaging and Orderable
Information ............................................. 170
9.1
Packaging Information ............................. 170
Table of Contents
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5
TMS570LS1115
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
www.ti.com
2 Revision History
This data manual revision history highlights the technical changes made to the SPNS189A device-specific
data manual addendum to make it an SPNS189B revision.
Scope: Applicable updates to the Hercules™ TMS570 MCU device family, specifically relating to the
TMS570LS1115 devices, which are now in the production data (PD) stage of development have been
incorporated.
Changes from September 1, 2013 to February 28, 2015 (from A Revision (September 2013) to B Revision)
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Updated/Changed section title to "Device Overview" ........................................................................... 1
Updated/changed the N2HET feature ............................................................................................. 1
Added Table 1-1, Device Information .............................................................................................. 3
Added Section 3, Device Comparison ............................................................................................. 8
Updated/Changed section title to "Terminal Configuration and Functions" ................................................... 9
Table 4-2 (PGE Enhanced High-End Timer Modules (N2HET)) Updated/Changed N2HET1 time input capture or
output compare pin description .................................................................................................... 13
Table 4-2 Updated/Changed N2HET2 time input capture or output compare pin description ............................ 14
Table 4-5Updated/Changed the EPWM1SYNCI Signal Type from "Output" to "Input" .................................... 15
Table 4-5Updated/Changed the EPWM1SYNCI pin description from "Output" to "Input" ................................. 15
Table 4-16 (PGE Test and Debug Modules Interface): Updated/Changed TEST pin description ........................ 21
Table 4-22 (ZWT Enhanced High-End Timer Modules (N2HET)) Updated/Changed N2HET1 time input capture
or output compare pin description ................................................................................................ 25
Table 4-22 Updated/Changed N2HET2 time input capture or output compare pin description .......................... 26
Updated/Changed the EPWM1SYNCI pin description from "Output" to "Input" ............................................ 28
Table 4-34 (External Memory Interface (EMIF)): Global: Deleted EMIF_RNW pin function............................... 33
Table 4-37 (ZWT Test and Debug Modules Interface): Updated/Changed TEST pin description ....................... 36
Updated/Changed section title to "Specifications" ............................................................................. 42
Moved Storage temperature range, Tstg back to Section 5.1, Absolute Maximum Ratings Over Operating FreeAir Temperature Range ............................................................................................................ 42
Added Section 5.2, Handling Ratings (Automotive) ............................................................................ 42
Added Section 5.3, Power-On-Hours (POH) .................................................................................... 42
Moved Thermal Data section here. ............................................................................................... 46
Section 5.9 (Thermal Resistance Characteristics): Updated/Changed title from "Thermal Data" to "Thermal
Resistance Characteristics" ........................................................................................................ 46
Added ΘJA test conditions and added ΨJT for PGE package .................................................................. 46
Added ΘJA test conditions and added ΨJT for ZWT package.................................................................. 47
Clarified impact of SPI2PC9 register on drive strength of SPI2SOMI pin .................................................. 48
Changed the number of cycles of tv(RST) from 2252 to 2256 ................................................................... 56
Figure 6-7 (Device Clock Domains): Added VCLK4 (to ePWM, eQEP, eCAP) ............................................. 66
Section 6.9.1 (Memory Map Diagram): Updated/Changed memory map (Figure 6-10 .................................... 71
Table 6-22 (Flash Memory Banks and Sectors): Updated/Changed the BANK 0 Sector No. to support 1MB Flash .. 77
Table 6-22: Added associated footnotes ........................................................................................ 77
Figure 6-11 (TCRAM Block Diagram): Updated/Changed figure ............................................................. 80
Added table notes identifying address ranges of ESRAM PBIST groups ................................................... 82
Updated/Changed N2HET2 RAM ending address from "0xFF57FFFF" to "0xFF45FFFF" in Table 6-26, Memory
Initialization .......................................................................................................................... 83
Updated EMIF Timings ............................................................................................................ 84
Changed maximum addressable size of asynchronous memories from 16MB to 32KB .................................. 84
Updated/Changed the EMIF address bus signals from "EMIF_ADDR[21:0]" to "EMIF_ADDR[12:0]" for all figures
in Section 6.14.2, Electrical and Timing Specifications ........................................................................ 84
Updated/Changed EMIF address from "EMIF_ADDR[21:0]" to "EMIF_ADDR[12:0]" ...................................... 84
Changed EMIF tsu(EMDV-EMOEH) from 30nS to 9nS ................................................................................ 86
Changed EMIF th(EMOEH-EMDIV) from 0.5nS to 0nS ............................................................................... 86
Changed EMIF tsu(EMOEL-EMWAIT) from 4E+30nS to 4E+9nS .................................................................... 86
Changed EMIF tsu(EMWEL-EMWAIT) from 4E+30nS to 4E+14nS................................................................... 86
Changed EMIF tsu(EMCEL-EMOEL) from (RS)*E-5 to (RS)*E-6 ..................................................................... 87
Changed EMIF tsu(EMCEL-EMOEL) from -5 to -6 ..................................................................................... 87
Changed EMIF th(EMOEH-EMCEH) from (RH)*E -4 to (RH)*E -3 ................................................................... 87
Revision History
Copyright © 2012–2015, Texas Instruments Incorporated
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Product Folder Links: TMS570LS1115
TMS570LS1115
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Changed EMIF th(EMOEH-EMCEH) from (RH)*E +4 to (RH)*E +5 .................................................................. 87
Changed EMIF th(EMOEH-EMCEH) from -4 to -3 ...................................................................................... 87
Changed EMIF th(EMOEH-EMCEH) from +4 to +5 .................................................................................... 87
Changed EMIF tsu(EMBAV-EMOEL) from (RS)*E-5 to (RS)*E-6..................................................................... 87
Changed EMIF th(EMOEH-EMBAIV) from (RS)*E-4 to (RS)*E-3 ..................................................................... 87
Changed EMIF tsu(EMAV-EMOEL) from (RS)*E-5 to (RS)*E-6 ...................................................................... 87
Changed EMIF th(EMOEH-EMAIV) from (RS)*E-4 to (RS)*E-3 ...................................................................... 87
Changed EMIF td(EMWAITH-EMOEH) from 3E-3 to 3E+9 ............................................................................ 87
Changed EMIF td(EMWAITH-EMOEH) from 4E+30 to 4E+20 ......................................................................... 87
Changed EMIF tsu(EMDQMV-EMOEL) from (RS)*E-5 to (RS)*E-6 ................................................................... 87
Changed EMIF th(EMOEH-EMDQMIV) from (RS)*E-4 to (RS)*E-3 ................................................................... 87
Changed EMIF tsu(EMCEL-EMWEL) from (WS)*E -4 to (WS)*E -3 ................................................................. 88
Changed EMIF tsu(EMCEL-EMWEL) from -4 to -3 ..................................................................................... 88
Changed EMIF th(EMWEH-EMCEH) from (WS)*E -4 to (WS)*E -3 .................................................................. 88
Changed EMIF th(EMWEH-EMCEH) from -4 to -3 ..................................................................................... 88
Changed EMIF tsu(EMDQMV-EMWEL) from (WS)*E -4 to (WS)*E -3 ................................................................ 88
Changed EMIF th(EMWEH-EMDQMIV) from (WS)*E -4 to (WS)*E -3 ................................................................ 88
Changed EMIF tsu(EMBAV-EMWEL) from (WS)*E -4 to (WS)*E -3 ................................................................. 88
Changed EMIF th(EMWEH-EMBAIV) from (WS)*E -4 to (WS)*E -3 ................................................................. 88
Changed EMIF tsu(EMAV-EMWEL) from (WS)*E -4 to (WS)*E -3 ................................................................... 88
Changed EMIF th(EMWEH-EMAIV) from (WS)*E -4 to (WS)*E -3 ................................................................... 88
Changed EMIF td(EMWAITH-EMWEH) from 3E-4 to 3E+11 ........................................................................... 88
Changed EMIF td(EMWAITH-EMWEH) from 4E+30 to 4E+24 ........................................................................ 88
Changed EMIF tsu(EMDV-EMWEL) from (WS)*E -4 to (WS)*E -3 .................................................................. 88
Changed EMIF th(EMWEH-EMDIV) from (WS)*E -4 to (WS)*E -3 ................................................................... 88
Changed EMIF tsu(EMDQMV-EMWEL) from (WS)*E -4 to (WS)*E -3 ................................................................ 88
Changed EMIF th(EMWEH-EMDQMIV) from (WS)*E -4 to (WS)*E -3 ................................................................ 88
Added JTAG ID for revision C silicon .......................................................................................... 108
Revised description of ePWM Trip Zone Timing Requirement tw(TZ) ........................................................ 117
Corrected SPI table note describing Master mode, phase = 0 condition .................................................. 150
Added Device Identification code for revision C silicon ...................................................................... 161
Changed address of die identification registers ............................................................................... 161
Updated/Changed the section title to "Mechanical Packaging and Orderable Information" ............................. 170
Section 9.1 (Packaging Information): Updated/Changed paragraph ........................................................ 170
Revision History
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7
TMS570LS1115
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www.ti.com
3 Device Comparison
Table 3-1 lists the features of the TMS570LS1115 devices.
Table 3-1. TMS570LS1115 Device Comparison (1) (2)
FEATURES
Generic Part
Number
Package
CPU
DEVICES
TMS570LS3137ZWT
(3)
TMS570LS1227ZWT
(3)
TMS570LS1115ZWT
TMS570LS1115PGE
TMS570LS0714PGE
TMS570LS0714PZ
337 BGA
337 BGA
337 BGA
144 QFP
144 QFP
100 QFP
TMS570LS0432PZ
100 QFP
ARM Cortex-R4F
ARM Cortex-R4F
ARM Cortex-R4F
ARM Cortex-R4F
ARM Cortex-R4F
ARM Cortex-R4F
ARM Cortex-R4
Frequency (MHz)
180
180
180
160
160
100
80
Flash (KB)
3072
1280
1024
1024
768
768
384
RAM (KB)
256
192
128
128
128
128
32
Data Flash
[EEPROM] (KB)
64
64
64
64
64
64
16
10/100
10/100
–
–
–
–
–
2-ch
2-ch
2-ch
2-ch
–
–
–
3
3
3
3
3
2
2
2 (24ch)
2 (24ch)
2 (24ch)
2 (24ch)
2 (24ch)
2 (16ch)
1 (16ch)
EMAC
FlexRay
CAN
MibADC
12-bit (Ch)
N2HET (Ch)
2 (44)
2 (44)
2 (44)
2 (40)
2 (40)
2 (21)
1 (19)
ePWM Channels
–
14
14
14
14
8
–
eCAP Channels
–
6
6
6
6
4
0
eQEP Channels
–
2
2
2
2
1
1
3 (6 + 6 + 4)
3 (6 + 6 + 4)
3 (6 + 6 + 4)
3 (5 + 6 + 1)
3 (5 + 6 + 4)
2 (5 + 1)
1 (4)
MibSPI (CS)
SPI (CS)
2 (2 + 1)
2 (2 + 1)
2 (2 + 1)
1 (1)
1 (1)
1 (1)
2
SCI (LIN)
2 (1 with LIN)
2 (1 with LIN)
2 (1 with LIN)
2 (1 with LIN)
2 (1 with LIN)
1 (with LIN)
1 (with LIN)
I2C
GPIO (INT)
(4)
EMIF
1
1
1
1
1
–
–
144 (with 16 interrupt
capable)
101 (with 16 interrupt
capable)
101 (with 16 interrupt
capable)
58 (with 4 interrupt
capable)
64 (with 10 interrupt
capable)
45 (with 9 interrupt
capable)
45 (with 8 interrupt
capable)
16-bit data
16-bit data
16-bit data
–
–
–
–
ETM (Trace)
32-bit
–
–
–
–
–
–
RTP/DMM
YES
–
–
–
–
–
–
Operating
Temperature
-40ºC to 125ºC
-40ºC to 125ºC
-40ºC to 125ºC
-40ºC to 125ºC
-40ºC to 125ºC
-40ºC to 125ºC
-40ºC to 125ºC
Core Supply (V)
1.14 V – 1.32 V
1.14 V – 1.32 V
1.14 V – 1.32 V
1.14 V – 1.32 V
1.14 V – 1.32 V
1.14 V – 1.32 V
1.14 V – 1.32 V
3.0 V – 3.6 V
3.0 V – 3.6 V
3.0 V – 3.6 V
3.0 V – 3.6 V
3.0 V – 3.6 V
3.0 V – 3.6 V
3.0 V – 3.6 V
I/O Supply (V)
(1)
(2)
(3)
(4)
8
For additional device variants, see www.ti.com/tms570
This table reflects the maximum configuration for each peripheral. Some functions are multiplexed and not all pins are available at the
same time.
Superset device.
Total number of pins that can be used as general purpose input or output when not used as part of a peripheral.
Device Comparison
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
4 Terminal Configuration and Functions
PGE QFP Package Pinout (144-Pin)
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
TMS
N2HET1[28]
N2HET1[8]
MIBSPI1NCS[0]
VCCIO
VSS
VSS
VCC
MIBSPI5CLK
MIBSPI5SIMO[0]
MIBSPI5SOMI[0]
MIBSPI5NENA
MIBSPI1NENA
MIBSPI1CLK
MIBSPI1SOMI
MIBSPI1SIMO
N2HET1[26]
N2HET1[24]
CAN1RX
CAN1TX
VSS
VCC
AD1EVT
AD1IN[15] / AD2IN[15]
AD1IN[23] / AD2IN[7]
AD1IN[8] / AD2IN[8]
AD1IN[14] / AD2IN[14]
AD1IN[22] / AD2IN[6]
AD1IN[6]
AD1IN[13] / AD2IN[13]
AD1IN[5]
AD1IN[12] / AD2IN[12]
AD1IN[4]
AD1IN[11] / AD2IN[11]
AD1IN[3]
AD1IN[2]
4.1
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
AD1IN[10] / AD2IN[10]
AD1IN[1]
AD1IN[9] / AD2IN[9]
VCCAD
VSSAD
ADREFLO
ADREFHI
AD1IN[21] / AD2IN[5]
AD1IN[20] / AD2IN[4]
AD1IN[19] / AD2IN[3]
AD1IN[18] / AD2IN[2]
AD1IN[7]
AD1IN[0]
AD1IN[17] / AD2IN[1]
AD1IN[16] / AD2IN[0]
VCC
VSS
MIBSPI3NCS[0]
MIBSPI3NENA
MIBSPI3CLK
MIBSPI3SIMO
MIBSPI3SOMI
VSS
VCC
VCC
VSS
nPORRST
VCC
VSS
VSS
VCCIO
N2HET1[15]
MIBSPI1NCS[2]
N2HET1[13]
N2HET1[6]
MIBSPI3NCS[1]
FRAYTX2
FRAYRX2
MIBSPI3NCS[3]
MIBSPI3NCS[2]
FRAYTXEN2
N2HET1[11]
FLTP1
FLTP2
GIOA[2]
VCCIO
VSS
CAN3RX
CAN3TX
GIOA[5]
N2HET1[22]
GIOA[6]
VCC
OSCIN
Kelvin_GND
OSCOUT
VSS
GIOA[7]
N2HET1[1]
N2HET1[3]
N2HET1[0]
VCCIO
VSS
VSS
VCC
N2HET1[2]
N2HET1[5]
MIBSPI5NCS[0]
N2HET1[7]
TEST
N2HET1[9]
N2HET1[4]
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
nTRST
TDI
TDO
TCK
RTCK
VCC
VSS
nRST
nERROR
N2HET1[10]
ECLK
VCCIO
VSS
VSS
VCC
N2HET1[12]
N2HET1[14]
FRAYRX1
N2HET1[30]
CAN2TX
CAN2RX
MIBSPI1NCS[1]
LINRX
LINTX
FRAYTX1
VCCP
VSS
VCCIO
VCC
VSS
N2HET1[16]
N2HET1[18]
N2HET1[20]
FRAYTXEN1
VCC
VSS
Figure 4-1. PGE QFP Package Pinout (144-Pin)
Note: Pins can have multiplexed functions. Only the default function is depicted in above diagram.
Terminal Configuration and Functions
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4.2
www.ti.com
ZWT BGA Package Ball-Map (337 Ball Grid Array)
A
B
C
D
E
F
G
H
J
K
MIBSPI5
NCS[0]
MIBSPI1
SIMO
MIBSPI1
NENA
MIBSPI5
CLK
MIBSPI5
SIMO[0]
N2HET1
[28]
L
M
NC
CAN3RX
N
P
R
AD1IN[15] AD1IN[22]
/
/
AD1EVT
AD2IN[15] AD2IN[6]
19
VSS
VSS
TMS
N2HET1
[10]
18
VSS
TCK
TDO
nTRST
N2HET1
[8]
MIBSPI1
CLK
MIBSPI1
SOMI
MIBSPI5
NENA
MIBSPI5
SOMI[0]
N2HET1
[0]
NC
CAN3TX
NC
17
TDI
nRST
NC
EMIF_
nWE
MIBSPI5
SOMI[1]
NC
MIBSPI5
SIMO[3]
MIBSPI5
SIMO[2]
N2HET1
[31]
EMIF_
nCS[3]
EMIF_
nCS[2]
EMIF_
nCS[4]
EMIF_
nCS[0]
NC
16
RTCK
FRAY
TXEN1
NC
EMIF_
BA[1]
MIBSPI5
SIMO[1]
NC
MIBSPI5
SOMI[3]
MIBSPI5
SOMI[2]
NC
NC
NC
NC
NC
NC
15
FRAY
RX1
FRAY
TX1
NC
NC
NC
NC
NC
NC
NC
EMIF_
DATA[0]
EMIF_
DATA[1]
EMIF_
DATA[2]
EMIF_
DATA[3]
NC
NC
14
N2HET1
[26]
nERROR
NC
NC
NC
VCCIO
VCCIO
VCCIO
VCC
VCC
VCCIO
VCCIO
VCCIO
VCCIO
NC
13
N2HET1
[17]
N2HET1
[19]
NC
NC
EMIF_BA[0]
VCCIO
VCCIO
12
ECLK
N2HET1
[4]
NC
NC
EMIF_nOE
VCCIO
VSS
VSS
VCC
VSS
VSS
11
N2HET1
[14]
N2HET1
[30]
NC
NC
EMIF_
nDQM[1]
VCCIO
VSS
VSS
VSS
VSS
10 CAN1TX
CAN1RX
EMIF_
ADDR[12]
NC
EMIF_
nDQM[0]
VCC
VCC
VSS
VSS
T
U
V
W
AD1IN
[6]
AD1IN[11]
/
AD2IN[11]
VSSAD
VSSAD
19
AD1IN
[4]
AD1IN
[2]
VSSAD
18
AD1IN[10]
/
AD2IN[10]
AD1IN
[1]
AD1IN[8] AD1IN[14] AD1IN[13]
/
/
/
AD2IN[8] AD2IN[14] AD2IN[13]
AD1IN
[5]
AD1IN
[3]
AD1IN[9]
/
17
AD2IN[9]
AD1IN[23] AD1IN[12] AD1IN[19]
/
/
/
ADREFLO
AD2IN[7] AD2IN[12] AD2IN[3]
VSSAD
16
AD1IN[21] AD1IN[20]
/
/
ADREFHI
AD2IN[5] AD2IN[4]
VCCAD
15
NC
AD1IN[18]
/
AD2IN[2]
AD1IN
[0]
14
NC
NC
AD1IN[17] AD1IN[16]
/
/
AD2IN[1] AD2IN[0]
NC
13
VCCIO
NC
MIBSPI5
NCS[3]
NC
NC
NC
12
VSS
VCCPLL
NC
NC
NC
NC
NC
11
VSS
VCC
VCC
NC
NC
NC
MIBSPI3
NCS[0]
GIOB[3]
10
AD1IN
[7]
9
N2HET1
[27]
FRAY
TXEN2
EMIF_
ADDR[11]
NC
EMIF_
ADDR[5]
VCC
VSS
VSS
VSS
VSS
VSS
VCCIO
EXTCLKI
N2
NC
NC
MIBSPI3
CLK
MIBSPI3
9
NENA
8
FRAY
RX2
FRAY
TX2
EMIF_
ADDR[10]
NC
EMIF_
ADDR[4]
VCCP
VSS
VSS
VCC
VSS
VSS
VCCIO
EMIF_
DATA[15]
NC
NC
MIBSPI3
SOMI
MIBSPI3
8
SIMO
7
LINRX
LINTX
EMIF_
ADDR[9]
NC
EMIF_
ADDR[3]
VCCIO
VCCIO
EMIF_
DATA[14]
NC
NC
N2HET1
[9]
nPORRST 7
6
GIOA[4]
MIBSPI5
NCS[1]
EMIF_
ADDR[8]
NC
EMIF_
ADDR[2]
VCCIO
VCCIO
VCCIO
VCCIO
VCC
VCC
VCCIO
VCCIO
VCCIO
EMIF_
DATA[13]
NC
NC
N2HET1
[5]
MIBSPI5
6
NCS[2]
5
GIOA[0]
GIOA[5]
EMIF_
ADDR[7]
EMIF_
ADDR[1]
EMIF_
DATA[4]
EMIF_
DATA[5]
EMIF_
DATA[6]
FLTP2
FLTP1
EMIF_
DATA[7]
EMIF_
DATA[8]
EMIF_
DATA[9]
EMIF_
DATA[10]
EMIF_
DATA[11]
EMIF_
DATA[12]
NC
NC
MIBSPI3
NCS[1]
N2HET1
[2]
5
4
N2HET1
[16]
N2HET1
[12]
EMIF_
ADDR[6]
EMIF_
ADDR[0]
NC
NC
NC
N2HET1
[21]
N2HET1
[23]
NC
NC
NC
NC
NC
EMIF_
nCAS
NC
NC
NC
NC
4
3
N2HET1
[29]
N2HET1
[22]
MIBSPI3
NCS[3]
SPI2
NENA
N2HET1
[11]
MIBSPI1
NCS[1]
MIBSPI1
NCS[2]
GIOA[6]
MIBSPI1
NCS[3]
EMIF_
CLK
EMIF_
CKE
N2HET1
[25]
SPI2
NCS[0]
EMIF_
nWAIT
EMIF_
nRAS
NC
NC
NC
N2HET1
[6]
3
2
VSS
MIBSPI3
NCS[2]
GIOA[1]
SPI2
SOMI
SPI2 CLK
GIOB[2]
GIOB[5]
CAN2TX
GIOB[6]
GIOB[1]
KELVIN_
GND
GIOB[0]
N2HET1
[13]
N2HET1
[20]
MIBSPI1
NCS[0]
NC
TEST
N2HET1
[1]
VSS
2
1
VSS
VSS
GIOA[2]
SPI2
SIMO
GIOA[3]
GIOB[7]
GIOB[4]
CAN2RX
N2HET1
[18]
OSCIN
OSCOUT
GIOA[7]
N2HET1
[15]
N2HET1
[24]
NC
N2HET1
[7]
N2HET1
[3]
VSS
VSS
1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Figure 4-2. ZWT Package Pinout. Top View
Note: Balls can have multiplexed functions. Only the default function is depicted in above diagram.
10
Terminal Configuration and Functions
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4.3
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Terminal Functions
Section 4.3.1 and Section 4.3.2 identify the external signal names, the associated pin/ball numbers along
with the mechanical package designator, the pin/ball type (Input, Output, IO, Power or Ground), whether
the pin/ball has any internal pullup/pulldown, whether the pin/ball can be configured as a GPIO, and a
functional pin/ball description. The first signal name listed is the primary function for that terminal. The
signal name in Bold is the function being described. Refer to the I/O Multiplexing Module (IOMM) chapter
of the TMS570LS12x/11x Technical Reference Manual (SPNU515).
NOTE
In the Terminal Functions table below, the "Reset Pull State" is the state of the pull applied to
the terminal while nPORRST is low and immediately after nPORRST goes High. The default
pull direction may change when software configures the pin for an alternate function. The
"Pull Type" is the type of pull asserted when the signal name in bold is enabled for the given
terminal by the IOMM control registers.
All I/O signals except nRST are configured as inputs while nPORRST is low and
immediately after nPORRST goes High. While nPORRST is low, the input buffers
are disabled, and the output buffers are disabled with the default pulls enabled.
All output-only signals have the output buffer disabled and the default pull enabled
while nPORRST is low, and are configured as outputs with the pulls disabled
immediately after nPORRST goes High.
4.3.1
PGE Package
4.3.1.1
Multibuffered Analog-to-Digital Converters (MibADC)
Table 4-1. PGE Multibuffered Analog-to-Digital Converters (MibADC1, MibADC2)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
N/A
None
Description
ADREFHI (1)
66
Power
ADREFLO (1)
67
Power
ADC low reference supply
VCCAD (1)
69
Power
Operating supply for ADC
(1)
VSSAD
ADC high reference
supply
68
Ground
AD1EVT
86
I/O
Pull Down
Programmable,
20 µA
ADC1 event trigger input,
or GPIO
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
55
I/O
Pull Up
Programmable,
20 µA
ADC2 event trigger input,
or GPIO
AD1IN[0]
60
Input
N/A
None
AD1IN[1]
71
AD1IN[2]
73
AD1IN[3]
74
AD1IN[4]
76
AD1IN[5]
78
AD1IN[6]
80
AD1IN[7]
61
(1)
ADC1 analog input
The ADREFHI, ADREFLO, VCCAD and VSSAD connections are common for both ADC cores.
Terminal Configuration and Functions
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www.ti.com
Table 4-1. PGE Multibuffered Analog-to-Digital Converters (MibADC1, MibADC2) (continued)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Description
Input
N/A
None
ADC1/ADC2 shared
analog inputs
AD1IN[8] / AD2IN[8]
83
AD1IN[9] / AD2IN[9]
70
AD1IN[10] / AD2IN[10]
72
AD1IN[11] / AD2IN[11]
75
AD1IN[12] / AD2IN[12]
77
AD1IN[13] / AD2IN[13]
79
AD1IN[14] / AD2IN[14]
82
AD1IN[15] / AD2IN[15]
85
AD1IN[16] / AD2IN[0]
58
AD1IN[17] / AD2IN[1]
59
AD1IN[18] / AD2IN[2]
62
AD1IN[19] / AD2IN[3]
63
AD1IN[20] / AD2IN[4]
64
AD1IN[21] / AD2IN[5]
65
AD1IN[22] / AD2IN[6]
81
AD1IN[23] / AD2IN[7]
84
MIBSPI3SOMI[0]/AWM1_EXT_ENA/ECAP2
51
Output
Pull Up
None
AWM1 external analog
mux enable
MIBSPI3SIMO[0]/AWM1_EXT_SEL[0]/ECAP3
52
Output
Pull Up
None
AWM1 external analog
mux select line0
MIBSPI3CLK/AWM1_EXT_SEL[1]/EQEP1A
53
Output
Pull Up
None
AWM1 external analog
mux select line0
12
Terminal Configuration and Functions
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4.3.1.2
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Enhanced High-End Timer Modules (N2HET)
Table 4-2. PGE Enhanced High-End Timer Modules (N2HET)
Terminal
Signal Name
144
PGE
N2HET1[0]/SPI4CLK/EPWM2B
25
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
23
N2HET1[2]/SPI4SIMO[0]/EPWM3A
30
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
24
N2HET1[4]/EPWM4B
36
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
31
N2HET1[6]/SCIRX/EPWM5A
38
N2HET1[7]/N2HET2[14]/EPWM7B
33
N2HET1[8]/MIBSPI1SIMO[1]
106
N2HET1[9]/N2HET2[16]/EPWM7A
35
N2HET1[10]/nTZ3
118
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/ EPWM1SYNCO
N2HET1[12]
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
Description
N2HET1
time
input
capture
or
output
compare, or GIO.
Each terminal has a
suppression filter with a
programmable duration.
6
124
N2HET1[13]/SCITX/EPWM5B
39
N2HET1[14]
125
N2HET1[15]/MIBSPI1NCS[4]/ECAP1
41
N2HET1[16]/EPWM1SYNCI/EPWM1SYNCO
139
MIBSPI1NCS[1]/N2HET1[17]/EQEP1S
130
Pull Up
N2HET1[18]/EPWM6A
140
Pull Down
MIBSPI1NCS[2]/N2HET1[19]
40
Pull Up
N2HET1[20]/EPWM6B
141
Pull Down
N2HET1[22]
15
MIBSPI1NENA/N2HET1[23]/ECAP4
96
Pull Up
N2HET1[24]/MIBSPI1NCS[5]
91
Pull Down
MIBSPI3NCS[1]/N2HET1[25]/MDCLK
37
Pull Up
N2HET1[26]
92
Pull Down
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
4
Pull Up
107
Pull Down
3
Pull Up
N2HET1[30]/EQEP2S
127
Pull Down
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
54
Pull Up
N2HET1[28]
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
Terminal Configuration and Functions
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Table 4-2. PGE Enhanced High-End Timer Modules (N2HET) (continued)
Terminal
Signal
Type
Reset Pull
State
Pull Type
14
I/O
Pull Down
Programmable,
20 µA (1)
GIOA[2]/N2HET2[0]/ EQEP2I
9
I/O
Pull Down
GIOA[6]/N2HET2[4]/EPWM1B
16
Programmable,
20 µA
GIOA[7]/N2HET2[6]/EPWM2A
22
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
23
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
24
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
31
N2HET1[7]/N2HET2[14]/EPWM7B
33
N2HET1[9]/N2HET2[16]/EPWM7A
35
Signal Name
144
PGE
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/ EPWM1SYNCO
6
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
55
(1)
Description
Disable selected PWM
outputs
N2HET2
time
input
capture
or
output
compare, or GPIO
Each terminal has a
suppression filter with a
programmable duration.
I/O
Pull Up
Programmable,
20 µA (1)
Disable selected PWM
outputs
The N2HETx_PIN_nDIS function is always available on this terminal. There is no mux control to select this function. The pull direction is
controlled by the function which is selected by the output mux control for this terminal.
4.3.1.3
Enhanced Capture Modules (eCAP)
Table 4-3. PGE Enhanced Capture Modules (eCAP) (1)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Down
Fixed 20 µA
Pull Up
Description
N2HET1[15]/MIBSPI1NCS[4]/ECAP1
41
MIBSPI3SOMI[0]/AWM1_EXT_ENA/ECAP2
51
MIBSPI3SIMO[0]/AWM1_EXT_SEL[0]/ECAP3
52
Enhanced Capture
Module 3 I/O
MIBSPI1NENA/N2HET1[23]/ECAP4
96
Enhanced Capture
Module 4 I/O
MIBSPI5NENA/MIBSPI5SOMI[1]/ ECAP5
97
Enhanced Capture
Module 5 I/O
MIBSPI1NCS[0]/MIBSPI1SOMI[1]/ECAP6
105
Enhanced Capture
Module 6 I/O
(1)
14
Pull Up
Enhanced Capture
Module 1 I/O
Enhanced Capture
Module 2 I/O
These signals, when used as inputs, are double-synchronized and then optionally filtered with a 6-cycle VCLK4-based counter.
Terminal Configuration and Functions
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4.3.1.4
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Enhanced Quadrature Encoder Pulse Modules (eQEP)
Table 4-4. PGE Enhanced Quadrature Encoder Pulse Modules (eQEP) (1)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Pull Up
Fixed 20 µA
Pull Up
Description
MIBSPI3CLK/AWM1_EXT_SEL[1]/EQEP1A
53
Input
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
54
Input
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
55
I/O
MIBSPI1NCS[1]/N2HET1[17]/EQEP1S
130
I/O
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
23
Input
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
24
Input
GIOA[2]/N2HET2[0]/ EQEP2I
9
I/O
Enhanced QEP2 Index
127
I/O
Enhanced QEP2 Strobe
N2HET1[30]/EQEP2S
(1)
Enhanced QEP1 Input A
Enhanced QEP1 Input B
Enhanced QEP1 Index
Enhanced QEP1 Strobe
Pull Down
Enhanced QEP2 Input A
Enhanced QEP2 Input B
These signals are double-synchronized and then optionally filtered with a 6-cycle VCLK4-based counter.
4.3.1.5
Enhanced Pulse-Width Modulator Modules (ePWM)
Table 4-5. PGE Enhanced Pulse-Width Modulator Modules (ePWM)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Output
Pull Down
None
Description
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
14
Enhanced PWM1 Output
A
GIOA[6]/N2HET2[4]/EPWM1B
16
Enhanced PWM1 Output
B
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/EPWM1SYNCO
6
External ePWM Sync
Pulse Output
N2HET1[16]/EPWM1SYNCI/EPWM1SYNCO
139
Input
Fixed 20 µA
Pull Up
External ePWM Sync
Pulse Input
GIOA[7]/N2HET2[6]/EPWM2A
22
Output
None
N2HET1[0]/SPI4CLK/EPWM2B
25
Enhanced PWM2 Output
B
N2HET1[2]/SPI4SIMO[0]/EPWM3A
30
Enhanced PWM3 Output
A
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
31
Enhanced PWM3 Output
B
MIBSPI5NCS[0]/EPWM4A
32
Pull Up
Enhanced PWM4 Output
A
N2HET1[4]/EPWM4B
36
Pull Down
Enhanced PWM4 Output
B
N2HET1[6]/SCIRX/EPWM5A
38
Enhanced PWM5 Output
A
N2HET1[13]/SCITX/EPWM5B
39
Enhanced PWM5 Output
B
N2HET1[18]/EPWM6A
140
Enhanced PWM6 Output
A
N2HET1[20]/EPWM6B
141
Enhanced PWM6 Output
B
N2HET1[9]/N2HET2[16]/EPWM7A
35
Enhanced PWM7 Output
A
N2HET1[7]/N2HET2[14]/EPWM7B
33
Enhanced PWM7 Output
B
Enhanced PWM2 Output
A
Terminal Configuration and Functions
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Table 4-5. PGE Enhanced Pulse-Width Modulator Modules (ePWM) (continued)
Terminal
Signal Name
144
PGE
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
3
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
4
N2HET1[10]/nTZ3
4.3.1.6
Signal
Type
Reset Pull
State
Pull Type
Description
Input
Pull Up
Fixed 20 µA
Pull Up
Trip Zone Inputs 1, 2 and
3. These signals are
either connected
asynchronously to the
ePWMx trip zone inputs,
or double-synchronized
with VCLK4, or doublesynchronized and then
filtered with a 6-cycle
VCLK4-based counter
before connecting to the
ePWMx trip zone inputs.
118
Pull Down
General-Purpose Input / Output (GPIO)
Table 4-6. PGE General-Purpose Input / Output (GPIO)
Terminal
Signal Name
144
PGE
GIOA[2]/N2HET2[0]/EQEP2I
9
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
14
GIOA[6]/N2HET2[4]/EPWM1B
16
GIOA[7]/N2HET2[6]/EPWM2A
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
22
55 (1)
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
(1)
Signal
Type
Description
General-purpose I/O.
All GPIO terminals are
capable of generating
interrupts to the CPU on
rising / falling / both
edges.
Pull Up
GIOB[2] cannot output a level on to pin 55. Only the input functionality is supported so that the application can generate an interrupt
whenever the N2HET2_PIN_nDIS is asserted (driven low). Also, a pull up is enabled on the input. This is not programmable using the
GIO module control registers.
4.3.1.7
FlexRay Interface Controller (FlexRay)
Table 4-7. FlexRay Interface Controller (FlexRay)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Description
FRAYRX1
126
Input
Pull Up
Fixed 100 µA
Pull Up
FlexRay data receive
(channel 1)
FRAYTX1
133
Output
N/A
None
FlexRay data transmit
(channel 1)
FRAYTXEN1
142
Output
FRAYRX2
2
Input
Pull Up
Fixed 100 µA
Pull Up
FlexRay data receive
(channel 2)
FRAYTX2
1
Output
N/A
None
FlexRay data transmit
(channel 2)
FRAYTXEN2
5
Output
16
FlexRay transmit enable
(channel 1)
Terminal Configuration and Functions
FlexRay transmit enable
(channel 2)
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4.3.1.8
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Controller Area Network Controllers (DCAN)
Table 4-8. PGE Controller Area Network Controllers (DCAN)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
CAN1RX
90
CAN1TX
89
CAN2RX
129
CAN2 receive, or GPIO
CAN2TX
128
CAN2 transmit, or GPIO
CAN3RX
12
CAN3 receive, or GPIO
CAN3TX
13
CAN3 transmit, or GPIO
4.3.1.9
CAN1 receive, or GPIO
CAN1 transmit, or GPIO
Local Interconnect Network Interface Module (LIN)
Table 4-9. PGE Local Interconnect Network Interface Module (LIN)
Terminal
Signal Name
144
PGE
LINRX
131
LINTX
132
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
LIN receive, or GPIO
LIN transmit, or GPIO
4.3.1.10 Standard Serial Communication Interface (SCI)
Table 4-10. PGE Standard Serial Communication Interface (SCI)
Terminal
Signal Name
144
PGE
N2HET1[6]/SCIRX/EPWM5A
38
N2HET1[13]/SCITX/EPWM5B
39
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
Description
SCI receive, or GPIO
SCI transmit, or GPIO
4.3.1.11 Inter-Integrated Circuit Interface Module (I2C)
Table 4-11. PGE Inter-Integrated Circuit Interface Module (I2C)
Terminal
Signal Name
144
PGE
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
4
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
3
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
I2C serial data, or GPIO
I2C serial clock, or GPIO
Terminal Configuration and Functions
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4.3.1.12 Standard Serial Peripheral Interface (SPI)
Table 4-12. PGE Standard Serial Peripheral Interface (SPI)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
Description
N2HET1[0]/SPI4CLK/EPWM2B
25
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
24
SPI4 clock, or GPIO
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
23
SPI4 enable, or GPIO
N2HET1[2]/SPI4SIMO[0]/EPWM3A
30
SPI4 slave-input masteroutput, or GPIO
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
31
SPI4 slave-output masterinput, or GPIO
SPI4 chip select, or GPIO
4.3.1.13 Multibuffered Serial Peripheral Interface Modules (MibSPI)
Table 4-13. PGE Multibuffered Serial Peripheral Interface Modules (MibSPI)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Description
I/O
Pull Up
Programmable,
20 µA
MibSPI1 clock, or GPIO
Pull Down
Programmable,
20 µA
MibSPI1 chip select, or
GPIO
Pull Up
Programmable,
20 µA
MibSPI1 enable, or GPIO
MIBSPI1CLK
95
MIBSPI1NCS[0]/MIBSPI1SOMI[1]/ECAP6
105
MIBSPI1NCS[1]/N2HET1[17]/EQEP1S
130
MIBSPI1NCS[2]/N2HET1[19]
40
N2HET1[15]/MIBSPI1NCS[4]/ECAP1
41
N2HET1[24]/MIBSPI1NCS[5]
91
MIBSPI1NENA/N2HET1[23]/ECAP4
96
MIBSPI1SIMO[0]
93
N2HET1[8]/MIBSPI1SIMO[1]
106
Pull Down
Programmable,
20 µA
MibSPI1 slave-in masterout, or GPIO
MIBSPI1SOMI[0]
94
Pull Up
MIBSPI1NCS[0]/MIBSPI1SOMI[1]/ECAP6
105
Programmable,
20 µA
MibSPI1 slave-out masterin, or GPIO
MIBSPI3CLK/AWM1_EXT_SEL[1]/EQEP1A
53
Pull Up
55
Programmable,
20 µA
MibSPI3 clock, or GPIO
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
MIBSPI3NCS[1]/N2HET1[25]/MDCLK
37
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
4
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
3
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/EPWM1SYNCO
6
Pull Down
Programmable,
20 µA
MibSPI3 chip select, or
GPIO
MIBSPI3NENA /MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
54
Pull Up
Programmable,
20 µA
MibSPI3 chip select, or
GPIO
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
54
MibSPI3 enable, or GPIO
MIBSPI3SIMO[0]/AWM1_EXT_SEL[0]/ECAP3
52
MibSPI3 slave-in masterout, or GPIO
MIBSPI3SOMI[0]/AWM1_EXT_ENA/ECAP2
51
MibSPI3 slave-out masterin, or GPIO
18
I/O
Terminal Configuration and Functions
MibSPI1 chip select, or
GPIO
MibSPI1 slave-in masterout, or GPIO
MibSPI3 chip select, or
GPIO
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Table 4-13. PGE Multibuffered Serial Peripheral Interface Modules (MibSPI) (continued)
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
MIBSPI5CLK
100
MIBSPI5NCS[0]/EPWM4A
32
MibSPI5 clock, or GPIO
MIBSPI5NENA/MIBSPI5SOMI[1]/ ECAP5
97
MibSPI5 enable, or GPIO
MIBSPI5SIMO[0]/MIBSPI5SOMI[2]
99
MibSPI5 slave-in masterout, or GPIO
MIBSPI5SOMI[0]
98
MibSPI5 slave-out masterin, or GPIO
MIBSPI5NENA/MIBSPI5SOMI[1]/ ECAP5
97
MibSPI5 slave-out masterin, or GPIO
MIBSPI5SIMO[0]/MIBSPI5SOMI[2]
99
MibSPI5 slave-out masterin, or GPIO
MibSPI5 chip select, or
GPIO
Terminal Configuration and Functions
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4.3.1.14 System Module Interface
Table 4-14. PGE System Module Interface
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Description
nPORRST
46
Input
Pull Down
Fixed 100 µA
Pull Down
Power-on reset, cold reset
External power supply
monitor circuitry must
drive nPORRST low when
any of the supplies to the
microcontroller fall out of
the specified range. This
terminal has a glitch filter.
See Section 6.8.
nRST
116
I/O
Pull Up
Fixed 100 µA
Pull Up
System reset, warm reset,
bidirectional.
The internal circuitry
indicates any reset
condition by driving nRST
low.
The external circuitry can
assert a system reset by
driving nRST low. To
ensure that an external
reset is not arbitrarily
generated, TI
recommends that an
external pull-up resistor is
connected to this terminal.
This terminal has a glitch
filter. See Section 6.8.
nERROR
117
I/O
Pull Down
Fixed 20 µA
Pull Down
ESM Error Signal
Indicates error of high
severity. See
Section 6.18.
4.3.1.15 Clock Inputs and Outputs
Table 4-15. PGE Clock Inputs and Outputs
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
N/A
None
OSCIN
18
Input
KELVIN_GND
19
Input
OSCOUT
20
Output
ECLK
119
I/O
Pull Down
Programmable,
20 µA
GIOA[5]/EXTCLKIN/EPWM1A /N2HET1_PIN_nDIS
14
Input
Pull Down
Fixed 20 µA
Pull Down
20
Description
From external
crystal/resonator, or
external clock input
Kelvin ground for oscillator
To external
crystal/resonator
Terminal Configuration and Functions
External prescaled clock
output, or GPIO.
External clock input #1
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4.3.1.16 Test and Debug Modules Interface
Table 4-16. PGE Test and Debug Modules Interface
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Description
Input
Pull Down
Fixed 100 µA
Pull Down
Test enable. This terminal
must be connected to
ground directly or via a
pull-down resistor.
TEST
34
nTRST
109
Input
RTCK
113
Output
N/A
None
TCK
112
Input
Pull Down
Fixed 100 µA
Pull Down
JTAG test clock
TDI
110
Input
Pull Up
Fixed 100 µA
Pull Up
JTAG test data in
TDO
111
Output
100 µA
Pull Down
None
TMS
108
Input
Pull Up
Fixed 100 µA
Pull Up
JTAG test hardware reset
JTAG return test clock
JTAG test data out
JTAG test select
4.3.1.17 Flash Supply and Test Pads
Table 4-17. PGE Flash Supply and Test Pads
Terminal
Signal Name
144
PGE
Signal
Type
Reset Pull
State
Pull Type
Description
VCCP
134
3.3V
Power
N/A
None
Flash pump supply
FLTP1
7
-
N/A-
None
FLTP2
8
Flash test pads. These
terminals are reserved for
TI use only. For proper
operation these terminals
must connect only to a
test pad or not be
connected at all [no
connect (NC)].
Terminal Configuration and Functions
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4.3.1.18 Supply for Core Logic: 1.2V nominal
Table 4-18. PGE Supply for Core Logic: 1.2V nominal
Terminal
Signal Name
144
PGE
VCC
17
VCC
29
VCC
45
VCC
48
VCC
49
VCC
57
VCC
87
VCC
101
VCC
114
VCC
123
VCC
137
VCC
143
Signal
Type
Reset Pull
State
Pull Type
1.2V
Power
N/A
None
Description
Core supply
4.3.1.19 Supply for I/O Cells: 3.3V nominal
Table 4-19. PGE Supply for I/O Cells: 3.3V nominal
Terminal
Signal Name
144
PGE
VCCIO
10
VCCIO
26
VCCIO
42
VCCIO
104
VCCIO
120
VCCIO
136
22
Signal
Type
Reset Pull
State
Pull Type
3.3V
Power
N/A
None
Terminal Configuration and Functions
Description
Operating supply for I/Os
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4.3.1.20 Ground Reference for All Supplies Except VCCAD
Table 4-20. PGE Ground Reference for All Supplies Except VCCAD
Terminal
Signal Name
144
PGE
VSS
11
VSS
21
VSS
27
VSS
28
VSS
43
VSS
44
VSS
47
VSS
50
VSS
56
VSS
88
VSS
102
VSS
103
VSS
115
VSS
121
VSS
122
VSS
135
VSS
138
VSS
144
Signal
Type
Reset Pull
State
Pull Type
Ground
N/A
None
Description
Ground reference
Terminal Configuration and Functions
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4.3.2
www.ti.com
ZWT Package
4.3.2.1
Multibuffered Analog-to-Digital Converters (MibADC)
Table 4-21. ZWT Multibuffered Analog-to-Digital Converters (MibADC1, MibADC2)
Terminal
Signal
Type
Reset Pull
State
Pull Type
V15
Power
N/A
None
ADREFLO (1)
V16
Power
ADC low reference supply
VCCAD (1)
W15
Power
Operating supply for ADC
VSSAD
V19
Ground
N/A
None
VSSAD
W16
VSSAD
W18
VSSAD
W19
AD1EVT
N19
I/O
Pull Down
Programmable,
20 µA
ADC1 event trigger input,
or GPIO
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
V10
I/O
Pull Up
Programmable,
20 µA
ADC2 event trigger input,
or GPIO
AD1IN[0]
W14
Input
N/A
None
ADC1 analog input
AD1IN[1]
V17
AD1IN[2]
V18
Input
N/A
None
ADC1/ADC2 shared
analog inputs
Output
Pull Up
None
AWM1 external analog
mux enable
Signal Name
ADREFHI (1)
337
ZWT
AD1IN[3]
T17
AD1IN[4]
U18
AD1IN[5]
R17
AD1IN[6]
T19
AD1IN[7]
V14
AD1IN[8] / AD2IN[8]
P18
AD1IN[9] / AD2IN[9]
W17
AD1IN[10] / AD2IN[10]
U17
AD1IN[11] / AD2IN[11]
U19
AD1IN[12] / AD2IN[12]
T16
AD1IN[13] / AD2IN[13]
T18
AD1IN[14] / AD2IN[14]
R18
AD1IN[15] / AD2IN[15]
P19
AD1IN[16] / AD2IN[0]
V13
AD1IN[17] / AD2IN[1]
U13
AD1IN[18] / AD2IN[2]
U14
AD1IN[19] / AD2IN[3]
U16
AD1IN[20] / AD2IN[4]
U15
AD1IN[21] / AD2IN[5]
T15
AD1IN[22] / AD2IN[6]
R19
AD1IN[23] / AD2IN[7]
R16
Description
ADC high reference
supply
ADC supply power
MIBSPI3SOMI[0]/AWM1_EXT_ENA/ECAP2
V8
MIBSPI3SIMO[0]/AWM1_EXT_SEL[0]/ECAP3
W8
AWM1 external analog
mux select line0
MIBSPI3CLK/AWM1_EXT_SEL[1]/EQEP1A
V9
AWM1 external analog
mux select line0
(1)
24
The ADREFHI, ADREFLO, VCCAD and VSSAD connections are common for both ADC cores.
Terminal Configuration and Functions
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4.3.2.2
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Enhanced High-End Timer Modules (N2HET)
Table 4-22. ZWT Enhanced High-End Timer Modules (N2HET)
Terminal
Signal Name
337
ZWT
N2HET1[0]/SPI4CLK/EPWM2B
K18
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
V2
N2HET1[2]/SPI4SIMO[0]/EPWM3A
W5
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
U1
N2HET1[4]/EPWM4B
B12
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
V6
N2HET1[6]/SCIRX/EPWM5A
W3
N2HET1[7]/N2HET2[14]/EPWM7B
T1
N2HET1[8]/MIBSPI1SIMO[1]
E18
N2HET1[9]/N2HET2[16]/EPWM7A
E3
N2HET1[12]
B4
N2HET1[13]/SCITX/EPWM5B
N2
N2HET1[14]
A11
N2HET1[15]/MIBSPI1NCS[4]/ECAP1
N1
N2HET1[16]/EPWM1SYNCI/EPWM1SYNCO
A4
N2HET1[17]
A13
MIBSPI1NCS[1]/N2HET1[17]/ EQEP1S
F3
I/O
Pull Down
Programmable,
20 µA
Description
N2HET1
time
capture
or
compare, or GIO.
input
output
Each terminal has a
suppression filter with a
programmable duration.
J1
N2HET1[19]
B13
MIBSPI1NCS[2]/N2HET1[19]
G3
N2HET1[20]/EPWM6B
P2
N2HET1[21]
H4
MIBSPI1NCS[3]/N2HET1[21]
J3
N2HET1[22]
B3
MIBSPI1NENA/N2HET1[23]/ECAP4
Pull Type
D19
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/EPWM1SYNCO
N2HET1[23]
Reset Pull
State
V7
N2HET1[10]/nTZ3
N2HET1[18]/EPWM6A
Signal
Type
J4
G19
Pull Up
N2HET1[24]/MIBSPI1NCS[5]
P1
Pull Down
N2HET1[25]
M3
MIBSPI3NCS[1]/N2HET1[25]/MDCLK
V5
N2HET1[26]
A14
N2HET1[27]
A9
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
B2
Pull Up
N2HET1[28]
K19
Pull Down
N2HET1[29]
A3
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
C3
Terminal Configuration and Functions
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Table 4-22. ZWT Enhanced High-End Timer Modules (N2HET) (continued)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
N2HET1[30]/EQEP2S
B11
N2HET1[31]
J17
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
W9
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
B5
input
Pull Down
Programmable,
20 µA (1)
GIOA[2]/N2HET2[0] /EQEP2I
C1
I/O
Pull Down
EMIF_ADDR[0]/N2HET2[1]
D4
Programmable,
20 µA
GIOA[3]/N2HET2[2]
E1
EMIF_ADDR[1]/N2HET2[3]
D5
GIOA[6]/N2HET2[4]/EPWM1B
H3
EMIF_BA[1]/N2HET2[5]
D16
GIOA[7]/N2HET2[6]/EPWM2A
M1
EMIF_nCS[0]/N2HET2[7]
N17
N2HET1[1]/SPI4NENA/ N2HET2[8]/EQEP2A
V2
EMIF_nCS[3]/N2HET2[9]
K17
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
U1
EMIF_ADDR[6]/N2HET2[11]
C4
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
V6
EMIF_ADDR[7]/N2HET2[13]
C5
N2HET1[7]/N2HET2[14]/EPWM7B
T1
EMIF_ADDR[8]/N2HET2[15]
C6
N2HET1[9]/N2HET2[16]/EPWM7A
V7
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/EPWM1SYNCO
E3
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
V10
(1)
26
Description
Pull Up
Disable selected PWM
outputs
N2HET2
time
capture
or
compare, or GIO.
input
output
Each terminal has a
suppression filter with a
programmable duration.
I/O
Pull Up
Programmable,
20 µA (1)
Disable selected PWM
outputs
The N2HETx_PIN_nDIS function is always available on this terminal. There is no mux control to select this function. The pull direction is
controlled by the function which is selected by the output mux control for this terminal.
Terminal Configuration and Functions
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4.3.2.3
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Enhanced Capture Modules (eCAP)
Table 4-23. ZWT Enhanced Capture Modules (eCAP) (1)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Fixed 20 µA
Pull Up
Description
N2HET1[15]/MIBSPI1NCS[4]/ECAP1
N1
I/O
Pull Down
MIBSPI3SOMI[0]/AWM1_EXT_ENA/ECAP2
V8
I/O
Pull Up
MIBSPI3SIMO[0]/AWM1_EXT_SEL[0]/ECAP3
W8
I/O
Enhanced Capture
Module 3 I/O
MIBSPI1NENA/N2HET1[23]/ECAP4
G19
I/O
Enhanced Capture
Module 4 I/O
MIBSPI5NENA/MIBSPI5SOMI[1]/ ECAP5
H18
I/O
Enhanced Capture
Module 5 I/O
MIBSPI1NCS[0]/MIBSPI1SOMI[1]/ ECAP6
R2
I/O
Enhanced Capture
Module 6 I/O
(1)
Enhanced Capture
Module 1 I/O
Enhanced Capture
Module 2 I/O
These signals, when used as inputs, are double-synchronized and then optionally filtered with a 6-cycle VCLK4-based counter.
4.3.2.4
Enhanced Quadrature Encoder Pulse Modules (eQEP)
Table 4-24. ZWT Enhanced Quadrature Encoder Pulse Modules (eQEP) (1)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Pull Up
Fixed 20 µA
Pull Up
MIBSPI3CLK/AWM1_EXT_SEL[1]/EQEP1A
V9
Input
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
W9
Input
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
V10
I/O
Description
Enhanced QEP1 Input A
Enhanced QEP1 Input B
Enhanced QEP1 Index
MIBSPI1NCS[1]/N2HET1[17]/ EQEP1S
F3
I/O
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
V2
Input
Pull Down
Enhanced QEP2 Input A
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
U1
Input
Pull Down
Enhanced QEP2 Input B
GIOA[2]/N2HET2[0]/ EQEP2I
C1
I/O
Pull Down
Enhanced QEP2 Index
N2HET1[30]/EQEP2S
B11
I/O
Pull Down
Enhanced QEP2 Strobe
(1)
Enhanced QEP1 Strobe
These signals are double-synchronized and then optionally filtered with a 6-cycle VCLK4-based counter.
Terminal Configuration and Functions
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Enhanced Pulse-Width Modulator Modules (ePWM)
Table 4-25. ZWT Enhanced Pulse-Width Modulator Modules (ePWM)
TERMINAL
337
ZWT
SIGNAL NAME
SIGNA Reset Pull
L TYPE
State
B5
GIOA[6]/N2HET2[4]/EPWM1B
H3
Enhanced PWM1 Output B
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/EPWM1SYNCO
E3
External ePWM Sync Pulse
Output
N2HET1[16]/EPWM1SYNCI/EPWM1SYNCO
A4
Input
Fixed 20 µA
Pull Up
External ePWM Sync Pulse
Input
GIOA[7]/N2HET2[6]/EPWM2A
M1
Output
None
Enhanced PWM2 Output A
N2HET1[0]/SPI4CLK/EPWM2B
K18
Enhanced PWM2 Output B
N2HET1[2]/SPI4SIMO[0]/EPWM3A
W5
Enhanced PWM3 Output A
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
V6
Enhanced PWM3 Output B
MIBSPI5NCS[0]/EPWM4A
E19
Pull Up
Enhanced PWM4 Output A
N2HET1[4]/EPWM4B
B12
Pull Down
Enhanced PWM4 Output B
N2HET1[6]/SCIRX/EPWM5A
W3
Enhanced PWM5 Output A
N2HET1[13]/SCITX/EPWM5B
N2
Enhanced PWM5 Output B
N2HET1[18]/EPWM6A
J1
Enhanced PWM6 Output A
N2HET1[20]/EPWM6B
P2
Enhanced PWM6 Output B
N2HET1[9]/N2HET2[16]/EPWM7A
V7
Enhanced PWM7 Output A
N2HET1[7]/N2HET2[14]/EPWM7B
T1
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
C3
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
B2
28
D19
Pull Down
None
DESCRIPTION
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
N2HET1[10]/nTZ3
Output
PULL TYPE
Enhanced PWM1 Output A
Enhanced PWM7 Output B
Input
Pull Up
Pull Down
Terminal Configuration and Functions
Fixed 20 µA
Pull Up
Trip Zone Inputs 1, 2 and 3.
These signals are either
connected asynchronously to
the ePWMx trip zone inputs,
or double-synchronized with
VCLK4, or doublesynchronized and then
filtered with a 6-cycle
VCLK4-based counter before
connecting to the ePWMx
trip zone inputs.
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4.3.2.6
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
General-Purpose Input / Output (GPIO)
Table 4-26. ZWT General-Purpose Input / Output (GPIO)
Terminal
Signal Name
337
ZWT
GIOA[0]
A5
GIOA[1]
C2
GIOA[2]/N2HET2[0] /EQEP2I
C1
GIOA[3]/N2HET2[2]
E1
GIOA[4]
A6
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
B5
GIOA[6]/N2HET2[4]/EPWM1B
H3
GIOA[7]/N2HET2[6]/EPWM2A
M1
GIOB[0]
M2
GIOB[1]
K2
GIOB[2]
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
Description
General-purpose I/O.
All GPIO terminals are
capable of generating
interrupts to the CPU on
rising / falling / both
edges.
F2
V10 (1)
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
GIOB[3]
W10
GIOB[4]
G1
GIOB[5]
G2
GIOB[6]
J2
GIOB[7]
F1
(1)
Signal
Type
GIOB[2] cannot output a level on to terminal V10. Only the input functionality is supported so that the application can generate an
interrupt whenever the N2HET2_PIN_nDIS is asserted (driven low). Also, a pull up is enabled on the input. This is not programmable
using the GIO module control registers.
4.3.2.7
FlexRay Interface Controller (FlexRay)
Table 4-27. FlexRay Interface Controller (FlexRay)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
FRAYRX1
A15
Input
Pull Up
Fixed 100 µA
Pull Up
FlexRay data receive
(channel 1)
FRAYTX1
B15
Output
N/A
None
FlexRay data transmit
(channel 1)
FRAYTXEN1
B16
Output
FRAYRX2
A8
Input
Pull Up
Fixed 100 µA
Pull Up
FlexRay data receive
(channel 2)
FRAYTX2
B8
Output
N/A
None
FlexRay data transmit
(channel 2)
FRAYTXEN2
B9
Output
FlexRay transmit enable
(channel 1)
FlexRay transmit enable
(channel 2)
Terminal Configuration and Functions
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4.3.2.8
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Controller Area Network Controllers (DCAN)
Table 4-28. ZWT Controller Area Network Controllers (DCAN)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
CAN1RX
B10
CAN1TX
A10
CAN2RX
H1
CAN2 receive, or GPIO
CAN2TX
H2
CAN2 transmit, or GPIO
CAN3RX
M19
CAN3 receive, or GPIO
CAN3TX
M18
CAN3 transmit, or GPIO
4.3.2.9
CAN1 receive, or GPIO
CAN1 transmit, or GPIO
Local Interconnect Network Interface Module (LIN)
Table 4-29. ZWT Local Interconnect Network Interface Module (LIN)
Terminal
Signal Name
337
ZWT
LINRX
A7
LINTX
B7
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
LIN receive, or GPIO
LIN transmit, or GPIO
4.3.2.10 Standard Serial Communication Interface (SCI)
Table 4-30. ZWT Standard Serial Communication Interface (SCI)
Terminal
Signal Name
337
ZWT
N2HET1[6]/SCIRX/EPWM5A
W3
N2HET1[13]/SCITX/EPWM5B
N2
30
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Down
Programmable,
20 µA
Terminal Configuration and Functions
Description
SCI receive, or GPIO
SCI transmit, or GPIO
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4.3.2.11 Inter-Integrated Circuit Interface Module (I2C)
Table 4-31. ZWT Inter-Integrated Circuit Interface Module (I2C)
Terminal
Signal Name
337
ZWT
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
B2
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
C3
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
I2C serial data, or GPIO
I2C serial clock, or GPIO
4.3.2.12 Standard Serial Peripheral Interface (SPI)
Table 4-32. ZWT Standard Serial Peripheral Interface (SPI)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
Description
SPI2CLK
E2
SPI2NCS[0]
N3
SPI2NENA/SPI2NCS[1]
D3
SPI2 chip select, or GPIO
SPI2NENA/SPI2NCS[1]
D3
SPI2 enable, or GPIO
SPI2SIMO[0]
D1
SPI2 slave-input masteroutput, or GPIO
SPI2SOMI[0]
D2
SPI2 slave-output masterinput, or GPIO
N2HET1[0]/SPI4CLK/EPWM2B
K18
N2HET1[3]/SPI4NCS[0]/N2HET2[10]/EQEP2B
U1
N2HET1[1]/SPI4NENA/N2HET2[8]/EQEP2A
V2
SPI4 enable, or GPIO
N2HET1[2]/SPI4SIMO[0]/EPWM3A
W5
SPI4 slave-input masteroutput, or GPIO
N2HET1[5]/SPI4SOMI[0]/N2HET2[12]/EPWM3B
V6
SPI4 slave-output masterinput, or GPIO
I/O
Pull Down
Programmable,
20 µA
SPI2 clock, or GPIO
SPI2 chip select, or GPIO
SPI4 clock, or GPIO
SPI4 chip select, or GPIO
Terminal Configuration and Functions
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4.3.2.13 Multibuffered Serial Peripheral Interface Modules (MibSPI)
Table 4-33. ZWT Multibuffered Serial Peripheral Interface Modules (MibSPI)
Terminal
Signal Name
337
ZWT
MIBSPI1CLK
F18
MIBSPI1NCS[0]/MIBSPI1SOMI[1]/ECAP6
R2
MIBSPI1NCS[1]/N2HET1[17]/EQEP1S
F3
MIBSPI1NCS[2]/N2HET1[19]
G3
MIBSPI1NCS[3]/N2HET1[21]
J3
N2HET1[15]/MIBSPI1NCS[4]/ECAP1
N1
N2HET1[24]/MIBSPI1NCS[5]
Signal
Type
Reset Pull
State
Pull Type
I/O
Pull Up
Programmable,
20 µA
MibSPI1 clock, or GPIO
Pull Down
Programmable,
20 µA
MibSPI1 chip select, or
GPIO
Pull Up
Programmable,
20 µA
MibSPI1 enable, or GPIO
P1
Description
MibSPI1 chip select, or
GPIO
MIBSPI1NENA/N2HET1[23]/ECAP4
G19
MIBSPI1SIMO[0]
F19
N2HET1[8]/MIBSPI1SIMO[1]
E18
Pull Down
Programmable,
20 µA
MibSPI1 slave-in masterout, or GPIO
MIBSPI1SOMI[0]
G18
Pull Up
Programmable,
20 µA
MibSPI1 slave-out masterin, or GPIO
Pull Up
Programmable,
20 µA
MibSPI3 clock, or GPIO
MIBSPI1NCS[0]/MIBSPI1SOMI[1]/ECAP6
R2
MIBSPI3CLK/AWM1_EXT_SEL[1]/EQEP1A
V9
MIBSPI3NCS[0]/AD2EVT/GIOB[2]/
EQEP1I/N2HET2_PIN_nDIS
V10
MIBSPI3NCS[1]/N2HET1[25]/MDCLK
V5
I/O
MibSPI1 slave-in masterout, or GPIO
MibSPI3 chip select, or
GPIO
MIBSPI3NCS[2]/I2C_SDA/N2HET1[27]/nTZ2
B2
MIBSPI3NCS[3]/I2C_SCL/N2HET1[29]/nTZ1
C3
N2HET1[11]/MIBSPI3NCS[4]/N2HET2[18]/EPWM1SYNCO
E3
Pull Down
Programmable,
20 µA
MibSPI3 chip select, or
GPIO
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
W9
Pull Up
Programmable,
20 µA
MibSPI3 chip select, or
GPIO
MIBSPI3NENA/MIBSPI3NCS[5]/N2HET1[31]/EQEP1B
W9
MibSPI3 enable, or GPIO
MIBSPI3SIMO[0]/AWM1_EXT_SEL[0]/ECAP3
W8
MibSPI3 slave-in masterout, or GPIO
MIBSPI3SOMI[0]/AWM1_EXT_ENA/ECAP2
V8
MibSPI3 slave-out masterin, or GPIO
MIBSPI5CLK
H19
MIBSPI5NCS[0]/EPWM4A
E19
MIBSPI5NCS[1]
B6
MIBSPI5NCS[2]
W6
I/O
Pull Up
Programmable,
20 µA
MibSPI5 clock, or GPIO
MibSPI5 chip select, or
GPIO
MIBSPI5NCS[3]
T12
MIBSPI5NENA/MIBSPI5SOMI[1]/ECAP5
H18
MibSPI5 enable, or GPIO
MIBSPI5SIMO[0]/MIBSPI5SOMI[2]
J19
MIBSPI5SIMO[1]
E16
MibSPI5 slave-in masterout, or GPIO
MIBSPI5SIMO[2]
H17
MIBSPI5SIMO[3]
G17
MIBSPI5SOMI[0]
J18
MIBSPI5SOMI[1]
E17
MIBSPI5NENA/MIBSPI5SOMI[1]/ECAP5
H18
MIBSPI5SOMI[2]
H16
MIBSPI5SIMO[0]/MIBSPI5SOMI[2]
J19
MIBSPI5SOMI[3]
G16
32
Terminal Configuration and Functions
MibSPI5 slave-out masterin, or GPIO
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4.3.2.14 External Memory Interface (EMIF)
Table 4-34. External Memory Interface (EMIF)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
Pull Up
None
EMIF Clock Enable
None
EMIF clock. This is an
output signal in functional
mode. It is gated off by
default, so that the signal
is pulled up. PINMUX29[8]
must be cleared to enable
this output.
EMIF Read Enable
EMIF_CKE
L3
Output
EMIF_CLK
K3
I/O
EMIF_nOE
E12
Output
Pull Up
None
EMIF_nWAIT
P3
I/O
Pull Up
Fixed 20 µA
Pull Up
EMIF_nWE
D17
Output
Pull Up
None
EMIF_nCAS
R4
Output
EMIF column address
strobe
EMIF_nRAS
R3
Output
EMIF row address strobe
EMIF_nCS[0]/N2HET2[7] (1)
N17
Output
EMIF chip select,
synchronous
EMIF_nCS[2]
L17
Output
EMIF_nCS[3]/N2HET2[9] (1)
K17
Output
EMIF_nCS[4]
M17
Output
EMIF chip selects,
asynchronous
This applies to chip
selects 2, 3 and 4
EMIF_nDQM[0]
E10
Output
EMIF_nDQM[1]
E11
Output
EMIF_BA[0]
E13
Output
EMIF bank address or
address line
EMIF_BA[1]/N2HET2[5] (1)
D16
Output
EMIF bank address or
address line
EMIF_ADDR[0]/N2HET2[1] (1)
D4
Output
EMIF address
(1)
EMIF_ADDR[1]/N2HET2[3]
D5
Output
EMIF_ADDR[2]
E6
Output
EMIF_ADDR[3]
E7
Output
EMIF_ADDR[4]
E8
Output
EMIF_ADDR[5]
E9
Output
EMIF_ADDR[6]/N2HET2[11] (1)
C4
Output
EMIF_ADDR[7]/N2HET2[13] (1)
C5
Output
(1)
EMIF_ADDR[8]/N2HET2[15]
C6
Output
EMIF_ADDR[9]
C7
Output
EMIF_ADDR[10]
C8
Output
EMIF_ADDR[11]
C9
Output
EMIF_ADDR[12]
C10
Output
(1)
EMIF Extended Wait
Signal
EMIF Write Enable
EMIF Data Mask or Write
Strobe.
Data mask for SDRAM
devices, write strobe for
connected asynchronous
devices.
These signals are tri-stated and pulled up by default after power-up. Any application that requires the EMIF must set the bit 31 of the
system module general-purpose register GPREG1.
Terminal Configuration and Functions
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Table 4-34. External Memory Interface (EMIF) (continued)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Pull Up
Fixed 20 µA
Pull Up
EMIF_DATA[0]
K15
I/O
EMIF_DATA[1]
L15
I/O
EMIF_DATA[2]
M15
I/O
EMIF_DATA[3]
N15
I/O
EMIF_DATA[4]
E5
I/O
EMIF_DATA[5]
F5
I/O
EMIF_DATA[6]
G5
I/O
EMIF_DATA[7]
K5
I/O
EMIF_DATA[8]
L5
I/O
EMIF_DATA[9]
M5
I/O
EMIF_DATA[10]
N5
I/O
EMIF_DATA[11]
P5
I/O
EMIF_DATA[12]
R5
I/O
EMIF_DATA[13]
R6
I/O
EMIF_DATA[14]
R7
I/O
EMIF_DATA[15]
R8
I/O
34
Terminal Configuration and Functions
Description
EMIF Data
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4.3.2.15 System Module Interface
Table 4-35. ZWT System Module Interface
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
nPORRST
W7
Input
Pull Down
Fixed 100 µA
Pull Down
Power-on reset, cold reset
External power supply
monitor circuitry must
drive nPORRST low when
any of the supplies to the
microcontroller fall out of
the specified range. This
terminal has a glitch filter.
See Section 6.8.
nRST
B17
I/O
Pull Up
Fixed 100 µA
Pull Up
System reset, warm reset,
bidirectional.
The internal circuitry
indicates any reset
condition by driving nRST
low.
The external circuitry can
assert a system reset by
driving nRST low. To
ensure that an external
reset is not arbitrarily
generated, TI
recommends that an
external pull-up resistor is
connected to this terminal.
This terminal has a glitch
filter. See Section 6.8.
nERROR
B14
I/O
Pull Down
Fixed 20 µA
Pull Down
ESM Error Signal
Indicates error of high
severity. See
Section 6.18.
4.3.2.16 Clock Inputs and Outputs
Table 4-36. ZWT Clock Inputs and Outputs
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
N/A
None
OSCIN
K1
Input
KELVIN_GND
L2
Input
OSCOUT
L1
Output
A12
I/O
Pull Down
Programmable,
20 µA
GIOA[5]/EXTCLKIN/EPWM1A/N2HET1_PIN_nDIS
B5
Input
Pull Down
20 µA
EXTCLKIN2
R9
Input
VCCPLL
P11
1.2V
Power
N/A
None
ECLK
Description
From external
crystal/resonator, or
external clock input
Kelvin ground for oscillator
To external
crystal/resonator
External prescaled clock
output, or GIO.
External clock input #1
External clock input #2
Dedicated core supply for
PLL's
Terminal Configuration and Functions
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4.3.2.17 Test and Debug Modules Interface
Table 4-37. ZWT Test and Debug Modules Interface
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
Input
Pull Down
Fixed 100 µA
Pull Down
Test enable. This terminal
must be connected to
ground directly or via a
pull-down resistor.
TEST
U2
nTRST
D18
Input
RTCK
A16
Output
N/A
None
TCK
B18
Input
Pull Down
Fixed 100 µA
Pull Down
JTAG test clock
TDI
A17
Input
Pull Up
Fixed 100 µA
Pull Up
JTAG test data in
TDO
C18
Output
100 µA
Pull Down
None
TMS
C19
Input
Pull Up
Fixed 100 µA
Pull Up
JTAG test hardware reset
JTAG return test clock
JTAG test data out
JTAG test select
4.3.2.18 Flash Supply and Test Pads
Table 4-38. ZWT Flash Supply and Test Pads
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
VCCP
F8
3.3V
Power
N/A
None
Flash pump supply
FLTP1
J5
-
N/A
None
FLTP2
H5
Flash test pads. These
terminals are reserved for
TI use only. For proper
operation these terminals
must connect only to a
test pad or not be
connected at all [no
connect (NC)].
36
Terminal Configuration and Functions
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4.3.2.19 No Connects
Table 4-39. No Connects
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
No Connects. These balls
are not connected to any
internal logic and can be
connected to the PCB
ground without affecting
the functionality of the
device.
NC
C11
-
N/A
None
NC
C12
-
N/A
None
NC
C13
-
N/A
None
NC
C14
-
N/A
None
NC
C15
-
N/A
None
NC
C16
-
N/A
None
NC
C17
-
N/A
None
NC
D6
-
N/A
None
NC
D7
-
N/A
None
NC
D8
-
N/A
None
NC
D9
-
N/A
None
NC
D10
-
N/A
None
NC
D11
-
N/A
None
NC
D12
-
N/A
None
NC
D13
-
N/A
None
NC
D14
-
N/A
None
NC
D15
-
N/A
None
NC
E4
-
N/A
None
NC
E14
-
N/A
None
NC
E15
-
N/A
None
NC
F4
-
N/A
None
NC
F15
-
N/A
None
NC
F16
-
N/A
None
NC
F17
-
N/A
None
NC
G4
-
N/A
None
NC
G15
-
N/A
None
NC
H15
-
N/A
None
NC
J15
-
N/A
None
NC
J16
-
N/A
None
NC
K4
-
N/A
None
NC
K16
-
N/A
None
NC
L4
-
N/A
None
NC
L16
-
N/A
None
NC
L18
-
N/A
None
NC
L19
-
N/A
None
NC
M4
-
N/A
None
NC
M16
-
N/A
None
NC
N4
-
N/A
None
NC
N16
-
N/A
None
NC
N18
-
N/A
None
NC
P4
-
N/A
None
Terminal Configuration and Functions
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Table 4-39. No Connects (continued)
Terminal
Signal Name
337
ZWT
Signal
Type
Reset Pull
State
Pull Type
Description
No Connects. These balls
are not connected to any
internal logic and can be
connected to the PCB
ground without affecting
the functionality of the
device.
NC
P15
-
N/A
None
NC
P16
-
N/A
None
NC
P17
-
N/A
None
NC
R1
-
N/A
None
NC
R10
-
N/A
None
NC
R11
-
N/A
None
NC
R12
-
N/A
None
NC
R13
-
N/A
None
NC
R14
-
N/A
None
NC
R15
-
N/A
None
NC
T2
-
N/A
None
NC
T3
-
N/A
None
NC
T4
-
N/A
None
NC
T5
-
N/A
None
NC
T6
-
N/A
None
NC
T7
-
N/A
None
NC
T8
-
N/A
None
NC
T9
-
N/A
None
NC
T10
-
N/A
None
NC
T11
-
N/A
None
NC
T13
-
N/A
None
NC
T14
-
N/A
None
NC
U3
-
N/A-
None
NC
U4
-
N/A
None
NC
U5
-
N/A
None
NC
U6
-
N/A
None
NC
U7
-
N/A
None
NC
U8
-
N/A
None
NC
U9
-
N/A
None
NC
U10
-
N/A
None
NC
U11
-
N/A
None
NC
U12
-
N/A
None
NC
V3
-
N/A
None
NC
V4
-
N/A
None
NC
V11
-
N/A
None
NC
V12
-
N/A
None
NC
W4
-
N/A
None
NC
W11
-
N/A
None
NC
W12
-
N/A
None
NC
W13
-
N/A
None
38
Terminal Configuration and Functions
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4.3.2.20 Supply for Core Logic: 1.2V nominal
Table 4-40. ZWT Supply for Core Logic: 1.2V nominal
Terminal
Signal Name
337
ZWT
VCC
F9
VCC
F10
VCC
H10
VCC
J14
VCC
K6
VCC
K8
VCC
K12
VCC
K14
VCC
L6
VCC
M10
VCC
P10
Signal
Type
Reset Pull
State
Pull Type
1.2V
Power
N/A
None
Description
Core supply
Terminal Configuration and Functions
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4.3.2.21 Supply for I/O Cells: 3.3V nominal
Table 4-41. ZWT Supply for I/O Cells: 3.3V nominal
Terminal
Signal Name
337
ZWT
VCCIO
F6
VCCIO
F7
VCCIO
F11
VCCIO
F12
VCCIO
F13
VCCIO
F14
VCCIO
G6
VCCIO
G14
VCCIO
H6
VCCIO
H14
VCCIO
J6
VCCIO
L14
VCCIO
M6
VCCIO
M14
VCCIO
N6
VCCIO
N14
VCCIO
P6
VCCIO
P7
VCCIO
P8
VCCIO
P9
VCCIO
P12
VCCIO
P13
VCCIO
P14
40
Signal
Type
Reset Pull
State
Pull Type
3.3V
Power
N/A
None
Terminal Configuration and Functions
Description
Operating supply for I/Os
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4.3.2.22 Ground Reference for All Supplies Except VCCAD
Table 4-42. ZWT Ground Reference for All Supplies Except VCCAD
Terminal
Signal Name
337
ZWT
VSS
A1
VSS
A2
VSS
A18
VSS
A19
VSS
B1
VSS
B19
VSS
H8
VSS
H9
VSS
H11
VSS
H12
VSS
J8
VSS
J9
VSS
J10
VSS
J11
VSS
J12
VSS
K9
VSS
K10
VSS
K11
VSS
L8
VSS
L9
VSS
L10
VSS
L11
VSS
L12
VSS
M8
VSS
M9
VSS
M11
VSS
M12
VSS
V1
VSS
W1
VSS
W2
Signal
Type
Reset Pull
State
Pull Type
Ground
N/A
None
Description
Ground reference
Terminal Configuration and Functions
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5 Specifications
5.1
Absolute Maximum Ratings Over Operating Free-Air Temperature Range
VCC (2)
Supply voltage range:
VCCIO, VCCP
Input voltage range:
Input clamp current:
(2)
(1)
MIN
MAX
UNIT
-0.3
1.43
V
-0.3
4.6
V
VCCAD
-0.3
6.25
V
All input pins, with exception of ADC pins
-0.3
4.6
V
ADC input pins
-0.3
6.25
V
IIK (VI < 0 or VI > VCCIO)
All pins, except AD1IN[23:0] or AD2IN[15:0]
-20
+20
mA
IIK (VI < 0 or VI > VCCAD)
AD1IN[23:0] or AD2IN[15:0]
-10
+10
mA
Total
-40
+40
mA
Operating free-air temperature range, TA:
-40
125
°C
Operating junction temperature range, TJ:
-40
150
°C
Storage temperature range, Tstg
-65
150
°C
(1)
(2)
Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under “recommended operating
conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Maximum-rated conditions for extended periods may affect device reliability. All voltage values are with respect to their associated
grounds.
5.2
ESD Ratings
VALUE
UNIT
±2
kV
All pins
±500
V
Corner pins on 144-pin PGE
(1, 36, 37, 72, 73, 108, 109, 144)
±750
V
Corner balls on 337-ball ZWT
(A1, A19, W1, W19)
±750
V
Human body model (HBM), per AEC Q100-002 (1)
VESD
(1)
5.3
(1)
(2)
42
Electrostatic discharge
(ESD) performance:
Charged device model (CDM),
per AEC Q100-011
AEC Q100-002 indicates HBM stressing is done in accordance with the ANSI/ESDA/JEDEC JS‑001 specification.
Power-On Hours (POH) (1) (2)
NOMINAL CORE VOLTAGE (VCC)
JUNCTION
TEMPERATURE (Tj)
LIFETIME POH
1.2
105ºC
100K
This information is provided solely for your convenience and does not extend or modify the warranty provided under TI's standard terms
and conditions for TI semiconductor products.
To avoid significant degradation, the device power-on hours (POH) must be limited to those specified in this table. To convert to
equivalent POH for a specific temperature profile, see the Calculating Equivalent Power-on-Hours for Hercules Safety MCUs Application
Report (SPNA207).
Specifications
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Device Recommended Operating Conditions (1)
5.4
MIN
NOM
MAX
UNIT
VCC
Digital logic supply voltage (Core)
1.14
1.2
1.32
V
VCCPLL
PLL Supply Voltage
1.14
1.2
1.32
V
VCCIO
Digital logic supply voltage (I/O)
3
3.3
3.6
V
VCCAD
MibADC supply voltage
3
5.25
V
VCCP
Flash pump supply voltage
3
3.6
V
VSS
Digital logic supply ground
VSSAD
MibADC supply ground
VADREFHI
VADREFLO
VSLEW
Maximum positive slew rate for VCCIO, VCCAD and VCCP supplies
TA
Operating free-air temperature
TJ
(1)
(2)
3.3
0
V
-0.1
0.1
V
A-to-D high-voltage reference source
VSSAD
VCCAD
V
A-to-D low-voltage reference source
VSSAD
VCCAD
Operating junction temperature
(2)
1
V
V/µs
-40
125
°C
-40
150
°C
All voltages are with respect to VSS, except VCCAD, which is with respect to VSSAD
Reliability data is based upon a temperature profile that is equivalent to 100,000 power-on hours at 105°C junction temperature.
Specifications
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5.5
www.ti.com
Switching Characteristics Over Recommended Operating Conditions for Clock Domains
Table 5-1. Clock Domain Timing Specifications
PARAMETER
DESCRIPTION
CONDITIONS
PGE
fHCLK
HCLK - System clock frequency
ZWT
MAX
UNIT
Pipeline mode
enabled
160
MHz
Pipeline mode
disabled
50
MHz
Pipeline mode
enabled
180
MHz
Pipeline mode
disabled
50
MHz
fGCLK
GCLK - CPU clock frequency
fHCLK
MHz
fVCLK
VCLK - Primary peripheral clock frequency
100
MHz
fVCLK2
VCLK2 - Secondary peripheral clock
frequency
100
MHz
fVCLK3
VCLK3 - Secondary peripheral clock
frequency
100
MHz
fVCLK4
VCLK4 - Secondary peripheral clock
frequency
150
MHz
fVCLKA1
VCLKA1 - Primary asynchronous
peripheral clock frequency
100
MHz
fVCLKA2
VCLKA2 - Secondary asynchronous
peripheral clock frequency
100
MHz
fVCLKA3
VCLKA3 - Primary asynchronous
peripheral clock frequency
100
MHz
fVCLKA4
VCLKA4 - Secondary asynchronous
peripheral clock frequency
100
MHz
fRTICLK
RTICLK - clock frequency
fVCLK
MHz
5.6
Wait States Required
RAM
0
Address Wait States
fHCLK(max)
0MHz
Data Wait States
0
0MHz
fHCLK(max)
Flash (Main Memory)
Address Wait States
1
0
Data Wait States
0
0MHz
Flash (Data Memory)
Data Wait States
1
2
100MHz
50MHz
0
0MHz
fHCLK(max)
150MHz
0MHz
1
50MHz
3
150MHz
3
2
100MHz
fHCLK(max)
150MHz
fHCLK(max)
Figure 5-1. Wait States Scheme
As shown in the figure above, the TCM RAM can support program and data fetches at full CPU speed without
any address or data wait states required.
The TCM flash can support zero address and data wait states up to a CPU speed of 50 MHz in nonpipelined
mode. The flash supports a maximum CPU clock speed of 160 MHz in pipelined mode for the PGE Package and
180 MHz for the ZWT package, with one address wait state and three data wait states.
The flash wrapper defaults to non-pipelined mode with zero address wait state and one random-read data wait
state.
44
Specifications
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5.7
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Power Consumption Over Recommended Operating Conditions
PARAMETER
TEST CONDITIONS
VCC digital supply current (operating mode)
fVCLK = fHCLK/2; Flash in pipelined mode; VCCmax
ICC
VCC Digital supply current (LBIST/PBIST mode)
fHCLK = 160MHz
MIN
TYP
175
(1)
MAX UNIT
350
(2)
mA
fHCLK = 180MHz
195
(1)
370 (2)
LBIST/PBIST clock
frequency = 80MHz
215 (1)
465 (3) (4)
mA
(3) (4)
mA
LBIST/PBIST clock
frequency = 90MHz
240 (1)
465
ICCPLL
VCCPLL digital supply current (operating mode)
VCCPLL = VCCPLLmax
10
mA
ICCIO
VCCIO Digital supply current (operating mode.
No DC load, VCCmax
10
mA
Single ADC
operational,
VCCADmax
15
Both ADCs
operational,
VCCADmax
30
Single ADC
operational,
ADREFHImax
3
Both ADCs
operational,
ADREFHImax
6
ICCAD
IADREFHI
ICCP
(1)
(2)
(3)
(4)
VCCAD supply current (operating mode)
ADREFHI supply current (operating mode)
VCCP supply current
read from 1 bank
and program
another bank,
VCCPmax
mA
mA
55
mA
The typical value is the average current for the nominal process corner and junction temperature of 25C.
The maximum ICC, value can be derated
• linearly with voltage
• by 1 ma/MHz for lower operating frequency when fHCLK= 2 * fVCLK
• for lower junction temperature by the equation below where TJK is the junction temperature in Kelvin and the result is in milliamperes.
164 - 0.07 0.01813TJK
The maximum ICC, value can be derated
• linearly with voltage
• by 1.5 ma/MHz for lower operating frequency
• for lower junction temperature by the equation below where TJK is the junction temperature in Kelvin and the result is in milliamperes.
164 - 0.07 0.01813TJK
LBIST and PBIST currents are for a short duration, typically less than 10ms. They are usually ignored for thermal calculations for the
device and the voltage regulator
Specifications
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5.8
Input/Output Electrical Characteristics Over Recommended Operating Conditions (1)
PARAMETER
Vhys
www.ti.com
Input hysteresis
TEST CONDITIONS
MIN
TYP
MAX
UNIT
All inputs (except
FRAYRX1,
FRAYRX2)
180
mV
FRAYRX1, FRAYRX2
100
mV
(2)
VIL
Low-level input voltage
All inputs (except
FRAYRX1,
FRAYRX2)
-0.3
FRAYRX1, FRAYRX2
0.8
V
0.4 VCCIO
V
VCCIO + 0.3
V
(2)
VIH
High-level input voltage
All inputs (except
FRAYRX1,
FRAYRX2)
2
FRAYRX1, FRAYRX2
0.6 VCCIO
V
IOL = IOLmax
VOL
Low-level output voltage
0.2
IOL = 50 µA, low-EMI
output mode (see
Section 5.13)
0.2 VCCIO
IOH = IOHmax
VOH
IIK
II
High-level output voltage
Input clamp current (I/O pins) (3)
Input current (I/O pins)
0.2 VCCIO
IOL = 50 µA, standard
output mode
V
0.8 VCCIO
IOH = 50 µA, standard
output mode
VCCIO -0.3
IOH = 50 µA, low-EMI
output mode (see
Section 5.13)
0.8 VCCIO
VI < VSSIO - 0.3 or VI
> VCCIO + 0.3
-3.5
V
3.5
IIH Pulldown 20µA
VI = VCCIO
5
40
IIH Pulldown 100µA
VI = VCCIO
40
195
IIL Pullup 20µA
VI = VSS
-40
-5
IIL Pullup 100µA
VI = VSS
-195
-40
All other pins
No pullup or pulldown
-1
mA
µA
1
CI
Input capacitance
2
pF
CO
Output capacitance
3
pF
(1)
(2)
(3)
5.9
Source currents (out of the device) are negative while sink currents (into the device) are positive.
This does not apply to the nPORRST pin.
If the input voltage extends outside of the range VIL to VIH then the input current must be limited to IIK to maintain proper operation. See
the application note SPNA201 for more information on limiting input clamp currents.
Thermal Resistance Characteristics
Table 5-2 shows the thermal resistance characteristics for the QFP - PGE mechanical package.
Table 5-3 shows the thermal resistance characteristics for the BGA - ZWT mechanical package.
Table 5-2. Thermal Resistance Characteristics (PGE Package)
°C/W
46
RΘJA
Junction-to-free air thermal resistance, Still
air using JEDEC 2S2P test board
RΘJB
Junction-to-board thermal resistance
RΘJC
Junction-to-case thermal resistance
7.3
ΨJT
Junction-to-package top, Still air
0.10
Specifications
40
27.2
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Table 5-3. Thermal Resistance Characteristics (ZWT Package)
°C/W
RΘJA
Junction-to-free air thermal resistance, Still
air (includes 5x5 thermal via cluster in 2s2p
PCB connected to 1st ground plane)
18.8
RΘJB
Junction-to-board thermal resistance
14.1
RΘJC
Junction-to-case thermal resistance
7.1
ΨJT
Junction-to-package top, Still air (includes
5x5 thermal via cluster in 2s2p PCB
connected to 1st ground plane)
0.33
5.10 Output Buffer Drive Strengths
Table 5-4. Output Buffer Drive Strengths
LOW-LEVEL OUTPUT CURRENT,
IOL for VI=VOLmax
or
HIGH-LEVEL OUTPUT CURRENT,
IOH for VI=VOHmin
SIGNALS
FRAYTX2, FRAYTX1, FRAYTXEN1, FRAYTXEN2,
MIBSPI5CLK, MIBSPI5SOMI[0], MIBSPI5SOMI[1], MIBSPI5SOMI[2], MIBSPI5SOMI[3],
MIBSPI5SIMO[0], MIBSPI5SIMO[1], MIBSPI5SIMO[2], MIBSPI5SIMO[3],
TMS, TDI, TDO, RTCK,
SPI4CLK, SPI4SIMO, SPI4SOMI, nERROR,
8 mA
N2HET2[1], N2HET2[3], N2HET2[5], N2HET2[7], N2HET2[9], N2HET2[11], N2HET2[13],
N2HET2[15]
ECAP1, ECAP4, ECAP5, ECAP6
EQEP1I, EQEP1S, EQEP2I, EQEP2S
EPWM1A, EPWM1B, EPWM1SYNCO, ETPW2A, EPWM2B, EPWM3A, EPWM3B,
EPWM4A, EPWM4B, EPWM5A, EPWM5B, EPWM6A, EPWM6B, EPWM7A, EPWM7B
EMIF_ADDR[0:12], EMIF_BA[0:1], EMIF_CKE, EMIF_CLK, EMIF_DATA[0:15], EMIF_nCAS,
EMIF_nCS[0:4], EMIF_nDQM[0:1], EMIF_nOE, EMIF_nRAS, EMIF_nWAIT, EMIF_nWE,
EMIF_RNW
TEST,
4 mA
MIBSPI3SOMI, MIBSPI3SIMO, MIBSPI3CLK, MIBSPI1SIMO, MIBSPI1SOMI, MIBSPI1CLK,
ECAP2, ECAP3
nRST
AD1EVT,
CAN1RX, CAN1TX, CAN2RX, CAN2TX, CAN3RX, CAN3TX,
GIOA[0-7], GIOB[0-7],
LINRX, LINTX,
2 mA zero-dominant
MIBSPI1nCS[0], MIBSPI1nCS[1-3],
MIBSPI5nCS[0-3], MIBSPI5nENA,
MIBSPI1nENA,
MIBSPI3nCS[0-3],
MIBSPI3nENA,
N2HET1[0-31], N2HET2[0], N2HET2[2], N2HET2[4], N2HET2[5], N2HET2[6], N2HET2[7],
N2HET2[8], N2HET2[9], N2HET2[10], N2HET2[11], N2HET2[12], N2HET2[13], N2HET2[14],
N2HET2[15], N2HET2[16], N2HET2[18],
SPI2nCS[0], SPI2nENA, SPI4nCS[0], SPI4nENA
ECLK,
selectable 8 mA / 2 mA
SPI2CLK, SPI2SIMO, SPI2SOMI
The default output buffer drive strength is 8 mA for these signals.
Specifications
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Table 5-5. Selectable 8 mA/2 mA Control
Signal
Control Bit
Address
8 mA
2 mA
ECLK
SYSPC10[0]
0xFFFF FF78
0
1
SPI2CLK
SPI2PC9[9]
0xFFF7 F668
0
1
SPI2SIMO
SPI2PC9[10]
0xFFF7 F668
0
1
0xFFF7 F668
0
1
SPI2SOMI
(1)
SPI2PC9[11]
(1)
Either SPI2PC9[11] or SPI2PC9[24] can change the output strength of the SPI2SOMI pin. In case of a 32-bit write where these two bits
differ, SPI2PC9[11] determines the drive strength.
5.11 Input Timings
t pw
Input
VCCIO
VIH
V IH
VIL
V IL
0
Figure 5-2. TTL-Level Inputs
Table 5-6. Timing Requirements for Inputs (1)
Parameter
tpw
tin_slew
(1)
(2)
MIN
MAX
tc(VCLK) + 10 (2)
Input minimum pulse width
Time for input signal to go from VIL to VIH or from VIH to VIL
Unit
ns
1
ns
MAX
Unit
tc(VCLK) = peripheral VBUS clock cycle time = 1 / f(VCLK)
The timing shown above is only valid for pin used in general-purpose input mode.
t pw
Input
0.6*VCCIO
0.6*VCCIO
0.4*VCCIO
VCCIO
0.4*VCCIO
0
Figure 5-3. Flexray Inputs
Table 5-7. Timing Requirements for FlexRay Inputs (1)
Parameter
tpw
(1)
48
MIN
Input minimum pulse width to meet the Flexray sampling
requirement
tc(VCLKA2) + 2.5
ns
tc(VCLKA2) = sample clock cycle time for FlexRay = 1 / f(VCLKA2)
Specifications
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5.12 Output Timings
Table 5-8. Switching Characteristics for Output Timings versus Load Capacitance ©L)
Parameter
Rise time, tr
8 mA low EMI pins
(see Table 5-4)
Fall time, tf
Rise time, tr
4 mA low EMI pins
(see Table 5-4)
Fall time, tf
Rise time, tr
2 mA-z low EMI pins
(see Table 5-4)
Fall time, tf
Rise time, tr
Selectable 8 mA / 2 mA-z
pins
(see Table 5-4)
8 mA mode
Fall time, tf
Rise time, tr
Fall time, tf
2 mA-z mode
MIN
MAX
Unit
CL = 15 pF
2.5
ns
CL = 50 pF
4
CL = 100 pF
7.2
CL = 150 pF
12.5
CL = 15 pF
2.5
CL = 50 pF
4
CL = 100 pF
7.2
CL = 150 pF
12.5
CL = 15 pF
5.6
CL = 50 pF
10.4
CL = 100 pF
16.8
CL = 150 pF
23.2
CL = 15 pF
5.6
CL= 50 pF
10.4
CL = 100 pF
16.8
CL = 150 pF
23.2
CL = 15 pF
8
CL = 50 pF
15
CL = 100 pF
23
CL = 150 pF
33
CL = 15 pF
8
CL = 50 pF
15
CL = 100 pF
23
CL = 150 pF
33
CL = 15 pF
2.5
CL = 50 pF
4
CL = 100 pF
7.2
CL = 150 pF
12.5
CL = 15 pF
2.5
CL = 50 pF
4
CL = 100 pF
7.2
CL = 150 pF
12.5
CL = 15 pF
8
CL = 50 pF
15
CL = 100 pF
23
CL = 150 pF
33
CL = 15 pF
8
CL = 50 pF
15
CL = 100 pF
23
CL = 150 pF
33
Specifications
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ns
ns
ns
ns
ns
ns
ns
ns
ns
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tr
tf
V OH
Output
VCCIO
VOH
VOL
VOL
0
Figure 5-4. CMOS-Level Outputs
Table 5-9. Timing Requirements for Outputs (1)
Parameter
td(parallel_out)
(1)
50
MIN
Delay between low to high, or high to low transition of general-purpose output signals
that can be configured by an application in parallel, e.g. all signals in a GIOA port, or
all N2HET1 signals, etc.
MAX
UNIT
6
ns
This specification does not account for any output buffer drive strength differences or any external capacitive loading differences. Check
Table 5-4 for output buffer drive strength information on each signal.
Specifications
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5.13 Low-EMI Output Buffers
The low-EMI output buffer has been designed explicitly to address the issue of decoupling sources of
emissions from the pins which they drive. This is accomplished by adaptively controlling the impedance of
the output buffer, and is particularly effective with capacitive loads.
This is not the default mode of operation of the low-EMI output buffers and must be enabled by setting the
system module GPCR1 register for the desired module or signal, as shown in . The adaptive impedance
control circuit monitors the DC bias point of the output signal. The buffer internally generates two
reference levels, VREFLOW and VREFHIGH, which are set to approximately 10% and 90% of VCCIO,
respectively.
Once the output buffer has driven the output to a low level, if the output voltage is below VREFLOW, then
the output buffer’s impedance will increase to hi-Z. A high degree of decoupling between the internal
ground bus and the output pin will occur with capacitive loads, or any load in which no current is flowing,
e.g. the buffer is driving low on a resistive path to ground. Current loads on the buffer which attempt to pull
the output voltage above VREFLOW will be opposed by the buffer’s output impedance so as to maintain
the output voltage at or below VREFLOW.
Conversely, once the output buffer has driven the output to a high level, if the output voltage is above
VREFHIGH then the output buffer’s impedance will again increase to hi-Z. A high degree of decoupling
between internal power bus ad output pin will occur with capacitive loads or any loads in which no current
is flowing, e.g. buffer is driving high on a resistive path to VCCIO. Current loads on the buffer which
attempt to pull the output voltage below VREFHIGH will be opposed by the buffer’s output impedance so
as to maintain the output voltage at or above VREFHIGH.
The bandwidth of the control circuitry is relatively low, so that the output buffer in adaptive impedance
control mode cannot respond to high-frequency noise coupling into the buffer’s power buses. In this
manner, internal bus noise approaching 20% peak-to-peak of VCCIO can be rejected.
Unlike standard output buffers which clamp to the rails, an output buffer in impedance control mode will
allow a positive current load to pull the output voltage up to VCCIO + 0.6V without opposition. Also, a
negative current load will pull the output voltage down to VSSIO – 0.6V without opposition. This is not an
issue since the actual clamp current capability is always greater than the IOH / IOL specifications.
The low-EMI output buffers are automatically configured to be in the standard buffer mode when the
device enters a low-power mode.
Table 5-10. Low-EMI Output Buffer Hookup
Module or Signal Name
Control Register to Enable Low-EMI Mode
Module: MibSPI1
GPREG1.0
Module: SPI2
GPREG1.1
Module: MibSPI3
GPREG1.2
Reserved
GPREG1.3
Module: MibSPI5
GPREG1.4
Module: FlexRay
GPREG1.5
Module: EMIF
GPREG1.6
Reserved
GPREG1.7
Signal: TMS
GPREG1.8
Signal: TDI
GPREG1.9
Signal: TDO
GPREG1.10
Signal: RTCK
GPREG1.11
Signal: TEST
GPREG1.12
Signal: nERROR
GPREG1.13
Signal: AD1EVT
GPREG1.14
Specifications
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6 System Information and Electrical Specifications
6.1
Device Power Domains
The device core logic is split up into multiple power domains to optimize the Self-Test Clock Configuration
power for a given application use case. There are 7 power domains in total: PD1, PD2, PD3, PD4, PD5,
and RAM_PD1. Refer to Section 1.4 for more information.
PD1 is an "always-ON" power domain, which cannot be turned off. Each of the other power domains can
be turned OFF one time during device initialization as per the application requirement. Refer to the Power
Management Module (PMM) chapter of TMS570LS12x/11x Technical Reference Manual (SPNU515) for
more details.
NOTE
The clocks to a module must be turned off before powering down the core domain that
contains the module.
NOTE
The logic in the modules that are powered down loses its power completely. Any access to
modules that are powered down results in an abort being generated. When power is
restored, the modules power-up to their default states (after normal power-up). No register or
memory contents are preserved in the core domains that are turned off.
6.2
Voltage Monitor Characteristics
A voltage monitor is implemented on this device. The purpose of this voltage monitor is to eliminate the
requirement for a specific sequence when powering up the core and I/O voltage supplies.
6.2.1
Important Considerations
•
•
6.2.2
The voltage monitor does not eliminate the need of a voltage supervisor circuit to ensure that the device is held in
reset when the voltage supplies are out of range.
The voltage monitor only monitors the core supply (VCC) and the I/O supply (VCCIO). The other supplies are not
monitored by the VMON. For example, if the VCCAD or VCCP are supplied from a source different from that for
VCCIO, then there is no internal voltage monitor for the VCCAD and VCCP supplies.
Voltage Monitor Operation
The voltage monitor generates the Power Good MCU signal (PGMCU) as well as the I/Os Power Good IO
signal (PGIO) on the device. During power-up or power-down, the PGMCU and PGIO are driven low when
the core or I/O supplies are lower than the specified minimum monitoring thresholds. The PGIO and
PGMCU being low isolates the core logic as well as the I/O controls during the power-up or power-down
of the supplies. This allows the core and I/O supplies to be powered up or down in any order.
When the voltage monitor detects a low voltage on the I/O supply, it will assert a power-on reset. When
the voltage monitor detects an out-of-range voltage on the core supply, it asynchronously makes all output
pins high impedance, and asserts a power-on reset. The voltage monitor is disabled when the device
enters a low power mode.
The VMON also incorporates a glitch filter for the nPORRST input. Refer to Section 6.3.3.1 for the timing
information on this glitch filter.
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Table 6-1. Voltage Monitoring Specifications
PARAMETER
VMON
6.2.3
Voltage monitoring
thresholds
MIN
TYP
MAX
UNIT
VCC low - VCC level below this
threshold is detected as too low.
0.75
0.9
1.13
V
VCC high - VCC level above this
threshold is detected as too high.
1.40
1.7
2.1
VCCIO low - VCCIO level below this
threshold is detected as too low.
1.85
2.4
2.9
Supply Filtering
The VMON has the capability to filter glitches on the VCC and VCCIO supplies.
The following table shows the characteristics of the supply filtering. Glitches in the supply larger than the
maximum specification cannot be filtered.
Table 6-2. VMON Supply Glitch Filtering Capability
Parameter
MIN
MAX
Width of glitch on VCC that can be filtered
250 ns
1 µs
Width of glitch on VCCIO that can be filtered
250 ns
1 µs
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6.3
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Power Sequencing and Power On Reset
6.3.1
Power-Up Sequence
There is no timing dependency between the ramp of the VCCIO and the VCC supply voltage. The powerup sequence starts with the I/O voltage rising above the minimum I/O supply threshold, (see Table 6-4 for
more details), core voltage rising above the minimum core supply threshold and the release of power-on
reset. The high frequency oscillator will start up first and its amplitude will grow to an acceptable level. The
oscillator start up time is dependent on the type of oscillator and is provided by the oscillator vendor. The
different supplies to the device can be powered up in any order.
The device goes through the following sequential phases during power up.
Table 6-3. Power-Up Phases
Oscillator start-up and validity check
1032 oscillator cycles
eFuse autoload
1160 oscillator cycles
Flash pump power-up
688 oscillator cycles
Flash bank power-up
617 oscillator cycles
Total
3497 oscillator cycles
The CPU reset is released at the end of the above sequence and fetches the first instruction from address
0x00000000.
6.3.2
Power-Down Sequence
The different supplies to the device can be powered down in any order.
6.3.3
Power-On Reset: nPORRST
This is the power-on reset. This reset must be asserted by an external circuitry whenever the I/O or core
supplies are outside the specified recommended range. This signal has a glitch filter on it. It also has an
internal pulldown.
6.3.3.1
nPORRST Electrical and Timing Requirements
Table 6-4. Electrical Requirements for nPORRST
NO Parameter
MIN
MAX
Unit
0.5
V
VCCPORL
VCC low supply level when nPORRST must be active during powerup
VCCPORH
VCC high supply level when nPORRST must remain active during
power-up and become active during power down
VCCIOPORL
VCCIO / VCCP low supply level when nPORRST must be active during
power-up
VCCIOPORH
VCCIO / VCCP high supply level when nPORRST must remain active
during power-up and become active during power down
VIL(PORRST)
Low-level input voltage of nPORRST VCCIO > 2.5V
0.2 * VCCIO
V
Low-level input voltage of nPORRST VCCIO < 2.5V
0.5
V
1.14
V
1.1
3.0
V
V
3
tsu(PORRST)
Setup time, nPORRST active before VCCIO and VCCP > VCCIOPORL
during power-up
0
ms
6
th(PORRST)
Hold time, nPORRST active after VCC > VCCPORH
1
ms
7
tsu(PORRST)
Setup time, nPORRST active before VCC < VCCPORH during power
down
2
µs
8
th(PORRST)
Hold time, nPORRST active after VCCIO and VCCP > VCCIOPORH
1
ms
9
th(PORRST)
Hold time, nPORRST active after VCC < VCCPORL
0
ms
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Table 6-4. Electrical Requirements for nPORRST (continued)
NO Parameter
tf(nPORRST)
Filter time nPORRST pin;
MIN
MAX
Unit
475
2000
ns
pulses less than MIN will be filtered out, pulses greater than MAX
will generate a reset.
3.3 V
1.2 V
VCCIOPORH
VCCPORH
6
VCCIOPORL
VCC (1.2 V)
VCCIO / VCCP(3.3 V)
nPORRST
VCCIOPORH
VCCIO / VCCP
8
VCCPORH
VCC
7
6
7
VCCPORL
VCCPORL
3
VIL(PORRST)
VCCIOPORL
9
VIL
VIL
VIL
VIL(PORRST)
NOTE: There is no timing dependency between the ramp of the VCCIO and the VCC supply voltage; this is just an exemplary drawing.
Figure 6-1. nPORRST Timing Diagram
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Warm Reset (nRST)
This is a bidirectional reset signal. The internal circuitry drives the signal low on detecting any device reset
condition. An external circuit can assert a device reset by forcing the signal low. On this terminal, the
output buffer is implemented as an open drain (drives low only). To ensure an external reset is not
arbitrarily generated, TI recommends that an external pullup resistor is connected to this terminal.
This terminal has a glitch filter. It also has an internal pullup.
6.4.1
Causes of Warm Reset
Table 6-5. Causes of Warm Reset
DEVICE EVENT
SYSTEM STATUS FLAG
Power-Up Reset
Exception Status Register, bit 15
Oscillator fail
Global Status Register, bit 0
PLL slip
Global Status Register, bits 8 and 9
Watchdog exception / Debugger reset
Exception Status Register, bit 13
Software Reset
Exception Status Register, bit 4
External Reset
Exception Status Register, bit 3
6.4.2
nRST Timing Requirements
Table 6-6. nRST Timing Requirements
PARAMETER
tv(RST)
Valid time, nRST active after
nPORRST inactive
Valid time, nRST active (all other
System reset conditions)
tf(nRST)
Filter time nRST pin;
MIN
2256 tc(OSC)
MAX
(1)
UNIT
ns
32 tc(VCLK)
475
2000
ns
pulses less than MIN will be
filtered out, pulses greater than
MAX will generate a reset
(1)
56
Assumes the oscillator has started up and stabilized before nPORRST is released ..
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6.5
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
ARM Cortex-R4F CPU Information
6.5.1
Summary of ARM Cortex-R4F CPU Features
The features of the ARM Cortex-R4F CPU include:
• An integer unit with integral Embedded ICE-RT logic.
• High-speed Advanced Microprocessor Bus Architecture (AMBA) Advanced eXtensible Interfaces (AXI)
for Level two (L2) master and slave interfaces.
• Floating Point Coprocessor
• Dynamic branch prediction with a global history buffer, and a 4-entry return stack
• Low interrupt latency.
• Non-maskable interrupt.
• A Harvard Level one (L1) memory system with:
– Tightly-Coupled Memory (TCM) interfaces with support for error correction or parity checking
memories
– ARMv7-R architecture Memory Protection Unit (MPU) with 12 regions
• Dual core logic for fault detection in safety-critical applications.
• An L2 memory interface:
– Single 64-bit master AXI interface
– 64-bit slave AXI interface to TCM RAM blocks
• A debug interface to a CoreSight Debug Access Port (DAP).
• A Performance Monitoring Unit (PMU).
• A Vectored Interrupt Controller (VIC) port.
For more information on the ARM Cortex-R4F CPU, see www.arm.com.
6.5.2
ARM Cortex-R4F CPU Features Enabled by Software
The following CPU features are disabled on reset and must be enabled by the application if required.
• ECC On Tightly-Coupled Memory (TCM) Accesses
• Hardware Vectored Interrupt (VIC) Port
• Floating Point Coprocessor
• Memory Protection Unit (MPU)
6.5.3
Dual Core Implementation
The device has two Cortex-R4F cores, where the output signals of both CPUs are compared in the CCMR4 unit. To avoid common mode impacts the signals of the CPUs to be compared are delayed by 2 clock
cycles as shown in Figure 6-3.
The CPUs have a diverse CPU placement given by following requirements:
different orientation; for example, CPU1 = "north" orientation, CPU2 = "flip west" orientation
dedicated guard ring for each CPU
North
F
Flip West
F
•
•
Figure 6-2. Dual - CPU Orientation
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6.5.4
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Duplicate clock tree after GCLK
The CPU clock domain is split into two clock trees, one for each CPU, with the clock of the 2nd CPU
running at the same frequency and in phase to the clock of CPU1. See Figure 6-3.
6.5.5
ARM Cortex-R4F CPU Compare Module (CCM-R4) for Safety
This device has two ARM Cortex-R4F CPU cores, where the output signals of both CPUs are compared in
the CCM-R4 unit. To avoid common mode impacts the signals of the CPUs to be compared are delayed in
a different way as shown in the figure below.
Output + Control
CCM-R4
2 cycle delay
CCM-R4
compare
CPU1CLK
CPU 1
compare
error
CPU 2
2 cycle delay
CPU2CLK
Input + Control
Figure 6-3. Dual Core Implementation
To avoid an erroneous CCM-R4 compare error, the application software must initialize the registers of
both CPUs before the registers are used, including function calls where the register values are pushed
onto the stack.
6.5.6
CPU Self-Test
The CPU STC (Self-Test Controller) is used to test the two Cortex-R4F CPU Cores using the
Deterministic Logic BIST Controller as the test engine.
The main features of the self-test controller are:
• Ability to divide the complete test run into independent test intervals
• Capable of running the complete test as well as running few intervals at a time
• Ability to continue from the last executed interval (test set) as well as ability to restart from the
beginning (First test set)
• Complete isolation of the self-tested CPU core from rest of the system during the self-test run
• Ability to capture the Failure interval number
• Timeout counter for the CPU self-test run as a fail-safe feature
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6.5.6.1
1.
2.
3.
4.
5.
6.
7.
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Application Sequence for CPU Self-Test
Configure clock domain frequencies.
Select number of test intervals to be run.
Configure the timeout period for the self-test run.
Enable self-test.
Wait for CPU reset.
In the reset handler, read CPU self-test status to identify any failures.
Retrieve CPU state if required.
For more information see TMS570LS12x/11x Technical Reference Manual (SPNU515).
6.5.6.2
CPU Self-Test Clock Configuration
The maximum clock rate for the self-test is 90MHz. The STCCLK is divided down from the CPU clock.
This divider is configured by the STCCLKDIV register at address 0xFFFFE108.
For more information see TMS570LS12x/11x Technical Reference Manual (SPNU515).
6.5.6.3
CPU Self-Test Coverage
Table 6-7 shows CPU test coverage achieved for each self-test interval. It also lists the cumulative test
cycles. The test time can be calculated by multiplying the number of test cycles with the STC clock period.
Table 6-7. CPU Self-Test Coverage
INTERVALS
TEST COVERAGE, %
TEST CYCLES
0
0
0
1
62.13
1365
2
70.09
2730
3
74.49
4095
4
77.28
5460
5
79.28
6825
6
80.90
8190
7
82.02
9555
8
83.10
10920
9
84.08
12285
10
84.87
13650
11
85.59
15015
12
86.11
16380
13
86.67
17745
14
87.16
19110
15
87.61
20475
16
87.98
21840
17
88.38
23205
18
88.69
24570
19
88.98
25935
20
89.28
27300
21
89.50
28665
22
89.76
30030
23
90.01
31395
24
90.21
32760
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6.6
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Clocks
6.6.1
Clock Sources
The table below lists the available clock sources on the device. Each of the clock sources can be enabled
or disabled using the CSDISx registers in the system module. The clock source number in the table
corresponds to the control bit in the CSDISx register for that clock source.
The table also shows the default state of each clock source.
Table 6-8. Available Clock Sources
Clock
Source #
Name
0
OSCIN
Main Oscillator
Enabled
1
PLL1
Output From PLL1
Disabled
Description
Default State
2
Reserved
Reserved
Disabled
3
EXTCLKIN1
External Clock Input #1
Disabled
4
LFLPO
Low Frequency Output of Internal Reference Oscillator
Enabled
HFLPO
High Frequency Output of Internal Reference
Oscillator
Enabled
5
6
PLL2
Output From PLL2
Disabled
7
EXTCLKIN2
External Clock Input #2
Disabled
6.6.1.1
Main Oscillator
The oscillator is enabled by connecting the appropriate fundamental resonator/crystal and load capacitors
across the external OSCIN and OSCOUT pins as shown in Figure 6-4. The oscillator is a single stage
inverter held in bias by an integrated bias resistor. This resistor is disabled during leakage test
measurement and low power modes.
TI strongly encourages each customer to submit samples of the device to the resonator/crystal
vendors for validation. The vendors are equipped to determine what load capacitors will best tune
their resonator/crystal to the microcontroller device for optimum start-up and operation over
temperature/voltage extremes.
An external oscillator source can be used by connecting a 3.3 V clock signal to the OSCIN pin and leaving
the OSCOUT pin unconnected (open) as shown in the figure below.
OSCIN
(see Note B)
Kelvin_GND
C1
OSCIN
OSCOUT
OSCOUT
C2
(see Note A)
External
Clock Signal
(toggling 0 V to 3.3 V)
Crystal
(a)
(b)
Note A: The values of C1 and C2 should be provided by the resonator/crystal vendor.
Note B: Kelvin_GND should not be connected to any other GND.
Figure 6-4. Recommended Crystal/Clock Connection
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6.6.1.1.1 Timing Requirements for Main Oscillator
Table 6-9. Timing Requirements for Main Oscillator
MAX
Unit
tc(OSC)
Cycle time, OSCIN (when using a sine-wave input)
Parameter
50
200
ns
tc(OSC_SQR)
Cycle time, OSCIN, (when input to the OSCIN is a
square wave )
50
200
ns
tw(OSCIL)
Pulse duration, OSCIN low (when input to the OSCIN
is a square wave)
15
ns
tw(OSCIH)
Pulse duration, OSCIN high (when input to the OSCIN
is a square wave)
15
ns
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6.6.1.2
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Low Power Oscillator
The Low Power Oscillator (LPO) is comprised of two oscillators — HF LPO and LF LPO, in a single
macro.
6.6.1.2.1 Features
The main features of the LPO are:
• Supplies a clock at extremely low power for power-saving modes. This is connected as clock source #
4 of the Global Clock Module.
• Supplies a high-frequency clock for non-timing-critical systems. This is connected as clock source # 5
of the Global Clock Module.
• Provides a comparison clock for the crystal oscillator failure detection circuit.
BIAS_EN
LFLPO
LFEN
LF_TRIM
Low
Power
Oscillator
HFEN
HFLPO
HF_TRIM
HFLPO_VALID
nPORRST
Figure 6-5. LPO Block Diagram
Figure 6-5 shows a block diagram of the internal reference oscillator. This is a low power oscillator (LPO)
and provides two clock sources: one nominally 80KHz and one nominally 10MHz.
Table 6-10. LPO Specifications
Parameter
Clock Detection
LPO - HF oscillator
(fHFLPO)
LPO - LF oscillator
62
MIN
Typical
MAX
Unit
oscillator fail frequency - lower threshold, using
untrimmed LPO output
1.375
2.4
4.875
MHz
oscillator fail frequency - higher threshold, using
untrimmed LPO output
22
38.4
78
MHz
untrimmed frequency
5.5
9
19.5
MHz
8
9.6
11
MHz
startup time from STANDBY (LPO BIAS_EN High for
at least 900µs)
10
µs
cold startup time
900
µs
trimmed frequency
untrimmed frequency
180
kHz
startup time from STANDBY (LPO BIAS_EN High for
at least 900µs)
36
85
100
µs
cold startup time
2000
µs
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6.6.1.3
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Phase Locked Loop (PLL) Clock Modules
The PLL is used to multiply the input frequency to some higher frequency.
The main features of the PLL are:
• Frequency modulation can be optionally superimposed on the synthesized frequency of PLL1. The
frequency modulation capability of PLL2 is permanently disabled.
• Configurable frequency multipliers and dividers.
• Built-in PLL Slip monitoring circuit.
• Option to reset the device on a PLL slip detection.
6.6.1.3.1 Block Diagram
Figure 6-6 shows a high-level block diagram of the two PLL macros on this microcontroller. PLLCTL1 and
PLLCTL2 are used to configure the multiplier and dividers for the PLL1. PLLCTL3 is used to configure the
multiplier and dividers for PLL2.
OSCIN
/NR
INTCLK
VCOCLK
PLL
/1 to /64
/OD
post_ODCLK
/1 to /8
/R
PLLCLK
/1 to /32
fPLLCLK = (fOSCIN / NR) * NF / (OD * R)
/NF
/1 to /256
OSCIN
/NR2
VCOCLK2
INTCLK2
/1 to /64
PLL#2
/NF2
/OD2
post_ODCLK2
/1 to /8
/R2
PLL2CLK
/1 to /32
f PLL2CLK = (fOSCIN / NR2) * NF2 / (OD2 * R2)
/1 to /256
Figure 6-6. PLLx Block Diagram
6.6.1.3.2 PLL Timing Specifications
Table 6-11. PLL Timing Specifications
PARAMETER
fINTCLK
fpost_ODCLK
PLL1 Reference Clock frequency
VCOCLK – PLL1 Output Divider (OD) input
clock frequency
fINTCLK2
PLL2 Reference Clock frequency
fVCOCLK2
MAX
1
f(OSC_SQR)
MHz
400
MHz
150
550
MHz
1
f(OSC_SQR)
MHz
400
MHz
550
MHz
Post-ODCLK – PLL1 Post-divider input
clock frequency
fVCOCLK
fpost_ODCLK2
MIN
Post-ODCLK – PLL2 Post-divider input
clock frequency
VCOCLK – PLL2 Output Divider (OD) input
clock frequency
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External Clock Inputs
The device supports up to two external clock inputs. This clock input must be a square wave input. The
electrical and timing requirements for these clock inputs are specified below. The external clock sources
are not checked for validity. They are assumed valid when enabled.
Table 6-12. External Clock Timing and Electrical Specifications
Parameter
Description
Min
Max
Unit
80
MHz
fEXTCLKx
External clock input frequency
tw(EXTCLKIN)H
EXTCLK high-pulse duration
6
ns
tw(EXTCLKIN)L
EXTCLK low-pulse duration
6
ns
viL(EXTCLKIN)
Low-level input voltage
-0.3
0.8
V
viH(EXTCLKIN)
High-level input voltage
2
VCCIO + 0.3
V
6.6.2
Clock Domains
6.6.2.1
Clock Domain Descriptions
The table below lists the device clock domains and their default clock sources. The table also shows the
system module control register that is used to select an available clock source for each clock domain.
Table 6-13. Clock Domain Descriptions
Clock Domain Name
Default Clock
Source
Clock Source
Selection Register
Description
HCLK
OSCIN
GHVSRC
•
•
Is disabled through the CDDISx registers bit 1
Used for all system modules including DMA, ESM
GCLK
OSCIN
GHVSRC
•
•
•
Always the same frequency as HCLK
In phase with HCLK
Is disabled separately from HCLK through the CDDISx registers
bit 0
Can be divided by 1up to 8 when running CPU self-test (LBIST)
using the CLKDIV field of the STCCLKDIV register at address
0xFFFFE108
•
64
GCLK2
OSCIN
GHVSRC
•
•
•
•
Always the same frequency as GCLK
2 cycles delayed from GCLK
Is disabled along with GCLK
Gets divided by the same divider setting as that for GCLK when
running CPU self-test (LBIST)
VCLK
OSCIN
GHVSRC
•
•
•
Divided down from HCLK
Can be HCLK/1, HCLK/2, ... or HCLK/16
Is disabled separately from HCLK through the CDDISx registers
bit 2
VCLK2
OSCIN
GHVSRC
•
•
•
•
Divided down from HCLK
Can be HCLK/1, HCLK/2, ... or HCLK/16
Frequency must be an integer multiple of VCLK frequency
Is disabled separately from HCLK through the CDDISx registers
bit 3
VCLK3
OSCIN
GHVSRC
•
•
•
Divided down from HCLK
Can be HCLK/1, HCLK/2, ... or HCLK/16
Is disabled separately from HCLK through the CDDISx registers
bit 8
VCLK4
OSCIN
GHVSRC
•
•
•
Divided down from HCLK
Can be HCLK/1, HCLK/2, ... or HCLK/16
Is disabled separately from HCLK through the CDDISx registers
bit 9
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Table 6-13. Clock Domain Descriptions (continued)
Clock Domain Name
Default Clock
Source
Clock Source
Selection Register
Description
VCLKA1
VCLK
VCLKASRC
•
•
Defaults to VCLK as the source
Is disabled through the CDDISx registers bit 4
VCLKA2
VCLK
VCLKASRC
•
•
Defaults to VCLK as the source
Is disabled through the CDDISx registers bit 5
VCLKA4_S
VCLK
VCLKACON1
•
•
•
Defaults to VCLK as the source
Frequency can be as fast as HCLK frequency
Is disabled through the CDDISx registers bit 11
VCLKA4_DIVR
VCLK
VCLKACON1
•
Divided down from the VCLKA4_S using the VCLKA4R field of
the VCLKACON1 register at address 0xFFFFE140
Frequency can be VCLKA4_S/1, VCLKA4_S/2, ..., or
VCLKA4_S/8
Default frequency is VCLKA4_S/2
Is disabled separately through the VCLKACON1 register
VCLKA4_DIV_CDDIS bit only if the VCLKA4_S clock is not
disabled
•
•
•
RTICLK
VCLK
RCLKSRC
•
•
•
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Defaults to VCLK as the source
If a clock source other than VCLK is selected for RTICLK, then
the RTICLK frequency must be less than or equal to VCLK/3
– Application can ensure this by programming the RTI1DIV
field of the RCLKSRC register, if necessary
Is disabled through the CDDISx registers bit 6
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Mapping of Clock Domains to Device Modules
Each clock domain has a dedicated functionality as shown in the figures below.
GCM
0
OSCIN
PLL #1
X1..256
/1..64
Low Power
Oscillator
PLL #2
/1..64
X1..256
* the frequency at this node must not
exceed the maximum HCLK specifiation.
GCLK, GCLK2 (to CPU)
(FMzPLL)
/1..32
/1..8
1
*
80kHz
4
10MHz
5
/1..16
HCLK (to SYSTEM)
VCLK _peri (VCLK to peripherals on PCR1)
VCLK_sys (VCLK to system modules)
/1..16
VCLK2 (to N2HETx and HTUx)
/1..16
VCLK3 (to EMIF)
/1..16
VCLK4 (to ePWM, eQEP, eCAP)
(FMzPLL)
/1..8
/1..32
6
*
3
EXTCLKIN 1
7
EXTCLKIN2
VCLK3
0
1
3
4
5
6
7
VCLK
VCLKA1 (to DCANx)
0
1
3
4
5
6
7
VCLK
VCLKA2 (to FlexRay)
VCLKA4_S (left open)
0
1
3
4
5
6
7
EMIF
0
1
3
4
5
6
7
VCLK
/1, 2, 4, or 8
RTICLK (to RTI, DWWD)
VCLK
VCLKA1
VCLK
VCLK2
VCLKA2
/1,2,..1024
/1,2,..4
GTUC1,2
Prop_seg
Phase_seg2
Phase_seg1
FlexRay
Baud
Rate
FlexRay
CAN Baud Rate
DCANx
VCLKA2
VCLK2
/1,2,..256
/2,3..224
/1,2..32
/1,2..65536
HRP
/1..64
/1,2..256
N2HETx
TU
FlexRay
TU
SPI
Baud Rate
SPIx,MibSPIx
LIN / SCI
Baud Rate
ADCLK
ECLK
I2C baud
rate
LIN, SCI
MibADCx
External Clock
I2C
EXTCLKIN1
PLL#2 output
Start of cycle
Macro Tick
NTU[3]
NTU[2]
NTU[1]
RTI
LRP
/20 ..2 5
Loop
High
Resolution Clock
N2HETx
NTU[0]
Figure 6-7. Device Clock Domains
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6.6.3
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Clock Test Mode
The RM4x platform architecture defines a special mode that allows various clock signals to be brought out
on to the ECLK pin and N2HET1[12] device outputs. This mode is called the Clock Test mode. It is very
useful for debugging purposes and can be configured through the CLKTEST register in the system
module.
Table 6-14. Clock Test Mode Options
SEL_ECP_PIN
=
CLKTEST[3-0]
SIGNAL ON ECLK
SEL_GIO_PIN
=
CLKTEST[11-8]
SIGNAL ON N2HET1[12]
0000
Oscillator
0000
Oscillator Valid Status
0001
Main PLL free-running clock output
0001
Main PLL Valid status
0010
Reserved
0010
Reserved
0011
EXTCLKIN1
0011
Reserved
0100
LFLPO
0100
Reserved
0101
HFLPO
0101
HFLPO Valid status
0110
Secondary PLL free-running clock output
0110
Secondary PLL Valid Status
0111
EXTCLKIN2
0111
Reserved
1000
GCLK
1000
LFLPO
1001
RTI Base
1001
Oscillator Valid status
1010
Reserved
1010
Oscillator Valid status
1011
VCLKA1
1011
Oscillator Valid status
1100
VCLKA2
1100
Oscillator Valid status
1101
Reserved
1101
Reserved
1110
VCLKA4_DIVR
1110
VCLKA4_S
1111
Reserved
1111
Oscillator Valid status
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Clock Monitoring
The LPO Clock Detect (LPOCLKDET) module consists of a clock monitor (CLKDET) and an internal low
power oscillator (LPO).
The LPO provides two different clock sources – a low frequency (LFLPO) and a high frequency (HFLPO).
The CLKDET is a supervisor circuit for an externally supplied clock signal (OSCIN). In case the OSCIN
frequency falls out of a frequency window, the CLKDET flags this condition in the global status register
(GLBSTAT bit 0: OSC FAIL) and switches all clock domains sourced by OSCIN to the HFLPO clock (limp
mode clock).
The valid OSCIN frequency range is defined as: fHFLPO / 4 < fOSCIN < fHFLPO * 4.
6.7.1
Clock Monitor Timings
For more information on LPO and Clock detection, refer to Table 6-10.
lower
threshold
fail
1.375
upper
threshold
pass
4.875
22
fail
f[MHz]
78
Figure 6-8. LPO and Clock Detection, Untrimmed HFLPO
6.7.2
External Clock (ECLK) Output Functionality
The ECLK pin can be configured to output a pre-scaled clock signal indicative of an internal device clock.
This output can be externally monitored as a safety diagnostic.
6.7.3
Dual Clock Comparators
The Dual Clock Comparator (DCC) module determines the accuracy of selectable clock sources by
counting the pulses of two independent clock sources (counter 0 and counter 1). If one clock is out of
spec, an error signal is generated. For example, the DCC1 can be configured to use HFLPO as the
reference clock (for counter 0) and VCLK as the "clock under test" (for counter 1). This configuration
allows the DCC1 to monitor the PLL output clock when VCLK is using the PLL output as its source.
An additional use of this module is to measure the frequency of a selectable clock source, using the input
clock as a reference, by counting the pulses of two independent clock sources. Counter 0 generates a
fixed-width counting window after a preprogrammed number of pulses. Counter 1 generates a fixed-width
pulse (1 cycle) after a pre-programmed number of pulses. This pulse sets as an error signal if counter 1
does not reach 0 within the counting window generated by counter 0.
6.7.3.1
•
•
•
•
6.7.3.2
Features
Takes two different clock sources as input to two independent counter blocks.
One of the clock sources is the known-good, or reference clock; the second clock source is the "clock under test."
Each counter block is programmable with initial, or seed values.
The counter blocks start counting down from their seed values at the same time; a mismatch from the expected
frequency for the clock under test generates an error signal which is used to interrupt the CPU.
Mapping of DCC Clock Source Inputs
Table 6-15. DCC1 Counter 0 Clock Sources
CLOCK SOURCE [3:0]
68
CLOCK NAME
others
oscillator (OSCIN)
0x5
high frequency LPO
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Table 6-15. DCC1 Counter 0 Clock Sources (continued)
CLOCK SOURCE [3:0]
CLOCK NAME
0xA
test clock (TCK)
Table 6-16. DCC1 Counter 1 Clock Sources
KEY [3:0]
CLOCK SOURCE [3:0]
others
0xA
CLOCK NAME
-
N2HET1[31]
0x0
Main PLL free-running clock output
0x1
PLL #2 free-running clock output
0x2
low frequency LPO
0x3
high frequency LPO
0x4
reserved
0x5
EXTCLKIN1
0x6
EXTCLKIN2
0x7
reserved
0x8 - 0xF
VCLK
Table 6-17. DCC2 Counter 0 Clock Sources
CLOCK SOURCE [3:0]
CLOCK NAME
others
oscillator (OSCIN)
0xA
test clock (TCK)
Table 6-18. DCC2 Counter 1 Clock Sources
KEY [3:0]
CLOCK SOURCE [3:0]
CLOCK NAME
others
-
N2HET2[0]
0xA
00x0 - 0x7
Reserved
0x8 - 0xF
VCLK
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Glitch Filters
A glitch filter is present on the following signals.
Table 6-19. Glitch Filter Timing Specifications
Pin
nPORRST
Parameter
tf(nPORRST)
Filter time nPORRST pin;
MIN
MAX
Unit
475
2000
ns
475
2000
ns
475
2000
ns
pulses less than MIN will be filtered out, pulses greater than
MAX will generate a reset (1)
nRST
tf(nRST)
Filter time nRST pin;
pulses less than MIN will be filtered out, pulses greater than
MAX will generate a reset
TEST
tf(TEST)
Filter time TEST pin;
pulses less than MIN will be filtered out, pulses greater than
MAX will pass through
(1)
70
The glitch filter design on the nPORRST signal is designed such that no size pulse will reset any part of the microcontroller (flash pump,
I/O pins, etc.) without also generating a valid reset signal to the CPU.
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6.9
6.9.1
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Device Memory Map
Memory Map Diagram
The figure below shows the device memory map.
Figure 6-9. Memory Map
0xFFFFFFFF
SYSTEM Modules
0xFFF80000
Peripherals - Frame 1
0xFF000000
0xFE000000
CRC
RESERVED
0xFCFFFFFF
0xFC000000
Peripherals - Frame 2
RESERVED
0xF07FFFFF
Flash Module Bus2 Interface
(Flash ECC, OTP and
EEPROM Emulation accesses)
0xF0000000
RESERVED
0x87FFFFFF
0x80000000
0x6FFFFFFF
0x60000000
EMIF (128MB)
SDRAM
RESERVED
CS0
reserved
0x6C000000
CS4
0x68000000
CS3
0x64000000
CS2
EMIF (32KB * 3)
Async RAM
RESERVED
0x200FFFFF
0x20000000
Flash (1MB) (Mirrored Image)
RESERVED
0x0841FFFF
0x08400000
RAM - ECC
RESERVED
0x0801FFFF
0x08000000
0x000FFFFF
0x00000000
RAM (128KB)
RESERVED
Flash (1MB)
Figure 6-10. Memory Map
The Flash memory is mirrored to support ECC logic testing. The base address of the mirrored Flash
image is 0x2000 0000.
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Memory Map Table
Table 6-20. Device Memory Map
FRAME ADDRESS RANGE
MODULE NAME
FRAME CHIP
SELECT
TCM Flash
CS0
0x0000_0000
0x00FF_FFFF
16MB
1MB
TCM RAM + RAM
ECC
CSRAM0
0x0800_0000
0x0BFF_FFFF
64MB
128KB
Mirrored Flash
Flash mirror
frame
0x2000_0000
0x20FF_FFFF
16MB
1MB
START
END
FRAME ACTUAL
SIZE
SIZE
RESPNSE FOR ACCESS TO
UNIMPLEMENTED LOCATIONS IN
FRAME
Memories tightly coupled to the ARM Cortex-R4F CPU
Abort
External Memory Accesses
EMIF Chip Select
2 (asynchronous)
EMIF select 2
0x6000_0000
0x63FF_FFFF
64MB
32KB
EMIF Chip Select
3 (asynchronous)
EMIF select 3
0x6400_0000
0x67FF_FFFF
64MB
32KB
EMIF Chip Select
4 (asynchronous)
EMIF select 4
0x6800_0000
0x6BFF_FFFF
64MB
32KB
EMIF Chip Select
0 (synchronous)
EMIF select 0
0x8000_0000
0x87FF_FFFF
128MB
128MB
Access to "Reserved" space will
generate Abort
Flash Module Bus2 Interface
Customer OTP,
TCM Flash Banks
0xF000_0000
0xF000_1FFF
8KB
4KB
Customer OTP,
Bank 7
0xF000_E000
0xF000_FFFF
8KB
2KB
Customer
OTP–ECC, TCM
Flash Banks
0xF004_0000
0xF004_03FF
1KB
512B
Customer
OTP–ECC,
Bank 7
0xF004_1C00
0xF004_1FFF
1KB
256B
TI OTP, TCM
Flash Banks
0xF008_0000
0xF008_1FFF
8KB
4KB
TI OTP,
Bank 7
0xF008_E000
0xF008_FFFF
8KB
2KB
TI OTP–ECC,
TCM Flash Banks
0xF00C_0000
0xF00C_03FF
1KB
512B
TI OTP–ECC,
Bank 7
0xF00C_1C00
0xF00C_1FFF
1KB
256B
Bank 7 – ECC
0xF010_0000
0xF013_FFFF
256KB
8KB
Abort
Bank 7
0xF020_0000
0xF03F_FFFF
2MB
64KB
Flash Data Space
ECC
0xF040_0000
0xF04F_FFFF
1MB
128KB
EMIF Registers
0xFCFF_E800
256B
256B
Abort
EMIF slave interfaces
0xFCFF_E8FF
SCR5: Enhanced Timer Peripherals
72
ePWM1
0xFCF7_8C00
0xFCF7_8CFF
256B
256B
Abort
ePWM2
0xFCF7_8D00
0xFCF7_8DFF
256B
256B
Abort
ePWM3
0xFCF7_8E00
0xFCF7_8EFF
256B
256B
Abort
ePWM4
0xFCF7_8F00
0xFCF7_8FFF
256B
256B
Abort
ePWM5
0xFCF7_9000
0xFCF7_90FF
256B
256B
Abort
ePWM6
0xFCF7_9100
0xFCF7_91FF
256B
256B
Abort
ePWM7
0xFCF7_9200
0xFCF7_92FF
256B
256B
Abort
eCAP1
0xFCF7_9300
0xFCF7_93FF
256B
256B
Abort
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Table 6-20. Device Memory Map (continued)
MODULE NAME
FRAME CHIP
SELECT
FRAME ADDRESS RANGE
FRAME ACTUAL
SIZE
SIZE
RESPNSE FOR ACCESS TO
UNIMPLEMENTED LOCATIONS IN
FRAME
START
END
eCAP2
0xFCF7_9400
0xFCF7_94FF
256B
256B
Abort
eCAP3
0xFCF7_9500
0xFCF7_95FF
256B
256B
Abort
eCAP4
0xFCF7_9600
0xFCF7_96FF
256B
256B
Abort
eCAP5
0xFCF7_9700
0xFCF7_97FF
256B
256B
Abort
eCAP6
0xFCF7_9800
0xFCF7_98FF
256B
256B
Abort
eQEP1
0xFCF7_9900
0xFCF7_99FF
256B
256B
Abort
0xFCF7_9A00
0xFCF7_9AFF
256B
256B
Abort
eQEP2
Cyclic Redundancy Checker (CRC) Module Registers
16MB
512B
Accesses above 0x200 generate
abort.
0xFF0B_FFFF
128KB
2KB
Abort for accesses above 2KB
0xFF0D_FFFF
128KB
2KB
Abort for accesses above 2KB
0xFF0F_FFFF
128KB
2KB
Abort for accesses above 2KB
0xFF1B_FFFF
128KB
2KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x7FF. Abort generated for
accesses beyond offset 0x800.
2KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x7FF. Abort generated for
accesses beyond offset 0x800.
2KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x7FF. Abort generated for
accesses beyond offset 0x800.
8KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x1FFF. Abort generated for
accesses beyond 0x1FFF.
MIBADC2 LookUp Table
384B
Look-Up Table for ADC2 wrapper.
Starts at address offset 0x2000 and
ends at address offset 0x217F. Wrap
around for accesses between offsets
0x0180 and 0x3FFF. Abort generated
for accesses beyond offset 0x4000.
MIBADC1 RAM
8KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x1FFF. Abort generated for
accesses beyond 0x1FFF.
384B
Look-Up Table for ADC1 wrapper.
Starts at address offset 0x2000 and
ends at address offset 0x217F. Wrap
around for accesses between offsets
0x0180 and 0x3FFF. Abort generated
for accesses beyond offset 0x4000.
16KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x3FFF. Abort generated for
accesses beyond 0x3FFF.
CRC
CRC frame
0xFE00_0000
MIBSPI5 RAM
PCS[5]
0xFF0A_0000
MIBSPI3 RAM
PCS[6]
0xFF0C_0000
MIBSPI1 RAM
PCS[7]
0xFF0E_0000
DCAN3 RAM
PCS[13]
0xFF1A_0000
0xFEFF_FFFF
Peripheral Memories
DCAN2 RAM
DCAN1 RAM
PCS[14]
PCS[15]
0xFF1C_0000
0xFF1E_0000
0xFF1D_FFFF
0xFF1F_FFFF
128KB
128KB
MIBADC2 RAM
PCS[29]
PCS[31]
0xFF3A_0000
0xFF3E_0000
0xFF3B_FFFF
0xFF3F_FFFF
128KB
128KB
MibADC1 LookUp Table
N2HET2 RAM
PCS[34]
0xFF44_0000
0xFF45_FFFF
128KB
N2HET1 RAM
PCS[35]
0xFF46_0000
0xFF47_FFFF
128KB
16KB
Wrap around for accesses to
unimplemented address offsets lower
than 0x3FFF. Abort generated for
accesses beyond 0x3FFF.
HTU2 RAM
PCS[38]
0xFF4C_0000
0xFF4D_FFFF
128KB
1KB
Abort
HTU1 RAM
PCS[39]
0xFF4E_0000
0xFF4F_FFFF
128KB
1KB
Abort
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Table 6-20. Device Memory Map (continued)
MODULE NAME
FRAME CHIP
SELECT
FlexRay TU RAM
PCS[40]
FRAME ADDRESS RANGE
START
END
0xFF50_0000
FRAME ACTUAL
SIZE
SIZE
0xFF51_FFFF
RESPNSE FOR ACCESS TO
UNIMPLEMENTED LOCATIONS IN
FRAME
128KB
1KB
Abort
Debug Components
CoreSight Debug
ROM
CSCS0
0xFFA0_0000
0xFFA0_0FFF
4KB
4KB
Reads return zeros, writes have no
effect
Cortex-R4F
Debug
CSCS1
0xFFA0_1000
0xFFA0_1FFF
4KB
4KB
Reads return zeros, writes have no
effect
POM
CSCS4
0xFFA0_4000
0xFFA0_4FFF
4KB
4KB
Abort
Peripheral Control Registers
FTU
PS[23]
0xFFF7_A000
0xFFF7_A1FF
512B
512B
Reads return zeros, writes have no
effect
HTU1
PS[22]
0xFFF7_A400
0xFFF7_A4FF
256B
256B
Reads return zeros, writes have no
effect
HTU2
PS[22]
0xFFF7_A500
0xFFF7_A5FF
256B
256B
Reads return zeros, writes have no
effect
N2HET1
PS[17]
0xFFF7_B800
0xFFF7_B8FF
256B
256B
Reads return zeros, writes have no
effect
N2HET2
PS[17]
0xFFF7_B900
0xFFF7_B9FF
256B
256B
Reads return zeros, writes have no
effect
GIO
PS[16]
0xFFF7_BC00
0xFFF7_BDFF
512B
256B
Reads return zeros, writes have no
effect
MIBADC1
PS[15]
0xFFF7_C000
0xFFF7_C1FF
512B
512B
Reads return zeros, writes have no
effect
MIBADC2
PS[15]
0xFFF7_C200
0xFFF7_C3FF
512B
512B
Reads return zeros, writes have no
effect
FlexRay
PS[12]+PS[13]
0xFFF7_C800
0xFFF7_CFFF
2KB
2KB
Reads return zeros, writes have no
effect
I2C
PS[10]
0xFFF7_D400
0xFFF7_D4FF
256B
256B
Reads return zeros, writes have no
effect
DCAN1
PS[8]
0xFFF7_DC00
0xFFF7_DDFF
512B
512B
Reads return zeros, writes have no
effect
DCAN2
PS[8]
0xFFF7_DE00
0xFFF7_DFFF
512B
512B
Reads return zeros, writes have no
effect
DCAN3
PS[7]
0xFFF7_E000
0xFFF7_E1FF
512B
512B
Reads return zeros, writes have no
effect
LIN
PS[6]
0xFFF7_E400
0xFFF7_E4FF
256B
256B
Reads return zeros, writes have no
effect
SCI
PS[6]
0xFFF7_E500
0xFFF7_E5FF
256B
256B
Reads return zeros, writes have no
effect
MibSPI1
PS[2]
0xFFF7_F400
0xFFF7_F5FF
512B
512B
Reads return zeros, writes have no
effect
SPI2
PS[2]
0xFFF7_F600
0xFFF7_F7FF
512B
512B
Reads return zeros, writes have no
effect
MibSPI3
PS[1]
0xFFF7_F800
0xFFF7_F9FF
512B
512B
Reads return zeros, writes have no
effect
SPI4
PS[1]
0xFFF7_FA00
0xFFF7_FBFF
512B
512B
Reads return zeros, writes have no
effect
MibSPI5
PS[0]
0xFFF7_FC00
0xFFF7_FDFF
512B
512B
Reads return zeros, writes have no
effect
System Modules Control Registers and Memories
DMA RAM
VIM RAM
74
PPCS0
PPCS2
0xFFF8_0000
0xFFF8_2000
0xFFF8_0FFF
0xFFF8_2FFF
4KB
4KB
4KB
Abort
1KB
Wrap around for accesses to
unimplemented address offsets
between 1KB and 4KB.
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Table 6-20. Device Memory Map (continued)
MODULE NAME
FRAME CHIP
SELECT
FRAME ADDRESS RANGE
START
END
FRAME ACTUAL
SIZE
SIZE
RESPNSE FOR ACCESS TO
UNIMPLEMENTED LOCATIONS IN
FRAME
Flash Module
PPCS7
0xFFF8_7000
0xFFF8_7FFF
4KB
4KB
Abort
eFuse Controller
PPCS12
0xFFF8_C000
0xFFF8_CFFF
4KB
4KB
Abort
Power
Management
Module (PMM)
PPSE0
0xFFFF_0000
0xFFFF_01FF
512B
512B
Abort
PCR registers
PPS0
0xFFFF_E000
0xFFFF_E0FF
256B
256B
Reads return zeros, writes have no
effect
System Module Frame 2 (see
SPNU515)
PPS0
0xFFFF_E100
0xFFFF_E1FF
256B
256B
Reads return zeros, writes have no
effect
PBIST
PPS1
0xFFFF_E400
0xFFFF_E5FF
512B
512B
Reads return zeros, writes have no
effect
STC
PPS1
0xFFFF_E600
0xFFFF_E6FF
256B
256B
Generates address error interrupt, if
enabled
IOMM
Multiplexing
Control Module
PPS2
0xFFFF_EA00
0xFFFF_EBFF
512B
512B
Reads return zeros, writes have no
effect
DCC1
PPS3
0xFFFF_EC00
0xFFFF_ECFF
256B
256B
Reads return zeros, writes have no
effect
DMA
PPS4
0xFFFF_F000
0xFFFF_F3FF
1KB
1KB
Reads return zeros, writes have no
effect
DCC2
PPS5
0xFFFF_F400
0xFFFF_F4FF
256B
256B
Reads return zeros, writes have no
effect
ESM
PPS5
0xFFFF_F500
0xFFFF_F5FF
256B
256B
Reads return zeros, writes have no
effect
CCMR4
PPS5
0xFFFF_F600
0xFFFF_F6FF
256B
256B
Reads return zeros, writes have no
effect
RAM ECC even
PPS6
0xFFFF_F800
0xFFFF_F8FF
256B
256B
Reads return zeros, writes have no
effect
RAM ECC odd
PPS6
0xFFFF_F900
0xFFFF_F9FF
256B
256B
Reads return zeros, writes have no
effect
RTI + DWWD
PPS7
0xFFFF_FC00
0xFFFF_FCFF
256B
256B
Reads return zeros, writes have no
effect
VIM Parity
PPS7
0xFFFF_FD00
0xFFFF_FDFF
256B
256B
Reads return zeros, writes have no
effect
VIM
PPS7
0xFFFF_FE00
0xFFFF_FEFF
256B
256B
Reads return zeros, writes have no
effect
System Module Frame 1 (see
SPNU515)
PPS7
0xFFFF_FF00
0xFFFF_FFFF
256B
256B
Reads return zeros, writes have no
effect
6.9.3
Special Consideration for CPU Access Errors Resulting in Imprecise Aborts
Any CPU write access to a Normal or Device type memory, which generates a fault, will generate an
imprecise abort. The imprecise abort exception is disabled by default and must be enabled for the CPU to
handle this exception. The imprecise abort handling is enabled by clearing the "A" bit in the CPU’s
program status register (CPSR).
6.9.4
Master/Slave Access Privileges
The table below lists the access permissions for each bus master on the device. A bus master is a module
that can initiate a read or a write transaction on the device.
Each slave module on the main interconnect is listed in the table. A "Yes" indicates that the module listed
in the "MASTERS" column can access that slave module.
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Table 6-21. Master / Slave Access Matrix
MASTERS
ACCESS MODE
SLAVES ON MAIN SCR
Flash Module
Bus2 Interface:
OTP, ECC, Bank
7
Non-CPU
Accesses to
Program Flash
and CPU Data
RAM
CRC
EMIF Slave
Interface
Peripheral
Control
Registers, All
Peripheral
Memories, And
All System
Module Control
Registers And
Memories
CPU READ
User/Privilege
Yes
Yes
Yes
Yes
Yes
CPU WRITE
User/Privilege
No
Yes
Yes
Yes
Yes
DMA
User
Yes
Yes
Yes
Yes
Yes
POM
User
Yes
Yes
Yes
Yes
Yes
DAP
Privilege
Yes
Yes
Yes
Yes
Yes
HTU1
Privilege
No
Yes
Yes
Yes
Yes
HTU2
Privilege
No
Yes
Yes
Yes
Yes
FTU
User
No
Yes
Yes
Yes
Yes
6.9.5
Special Notes on Accesses to Certain Slaves
Write accesses to the Power Domain Management Module (PMM) control registers are limited to the CPU
(master id = 1). The other masters can only read from these registers.
A debugger can also write to the PMM registers. The master-id check is disabled in debug mode.
The device contains dedicated logic to generate a bus error response on any access to a module that is in
a power domain that has been turned OFF.
6.9.6
Parameter Overlay Module (POM) Considerations
•
•
•
•
76
The POM can map onto up to 8MB of the internal or external memory space. The starting address and the size of
the memory overlay are configurable through the POM control registers. Care must be taken to ensure that the
overlay is mapped on to available memory.
ECC must be disabled by software through CP15 in case POM overlay is enabled; otherwise ECC errors will be
generated.
POM overlay must not be enabled when the flash and internal RAM memories are swapped through the MEM
SWAP field of the Bus Matrix Module Control Register 1 (BMMCR1).
When POM is used to overlay the flash on to internal or external RAM, there is a bus contention possibility when
another master accesses the TCM flash. This results in a system hang.
– The POM implements a timeout feature to detect this exact scenario. The timeout needs to be enabled
whenever POM overlay is enabled.
– The timeout can be enabled by writing 1010 to the Enable TimeOut (ETO) field of the POM Global Control
register (POMGLBCTRL, address = 0xFFA04000).
– In case a read request by the POM cannot be completed within 32 HCLK cycles, the timeout (TO) flag is set in
the POM Flag register (POMFLG, address = 0xFFA0400C). Also, an abort is generated to the CPU. This can
be a prefetch abort for an instruction fetch or a data abort for a data fetch.
– The prefetch- and data-abort handlers must be modified to check if the TO flag in the POM is set. If so, then
the application can assume that the timeout is caused by a bus contention between the POM transaction and
another master accessing the same memory region. The abort handlers need to clear the TO flag, so that any
further aborts are not misinterpreted as having been caused due to a timeout from the POM.
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6.10 Flash Memory
6.10.1 Flash Memory Configuration
Flash Bank: A separate block of logic consisting of 1 to 16 sectors. Each flash bank normally has a
customer-OTP and a TI-OTP area. These flash sectors share input/output buffers, data paths, sense
amplifiers, and control logic.
Flash Sector: A contiguous region of flash memory which must be erased simultaneously due to physical
construction constraints.
Flash Pump: A charge pump which generates all the voltages required for reading, programming, or
erasing the flash banks.
Flash Module: Interface circuitry required between the host CPU and the flash banks and pump module.
Table 6-22. Flash Memory Banks and Sectors
Memory Arrays (or Banks)
Sector
No.
Segment
Low Address
High Address
BANK0 (1MByte) (1)
0
16K Bytes
0x0000_0000
0x0000_3FFF
1
16K Bytes
0x0000_4000
0x0000_7FFF
2
16K Bytes
0x0000_8000
0x0000_BFFF
3
16K Bytes
0x0000_C000
0x0000_FFFF
4
16K Bytes
0x0001_0000
0x0001_3FFF
5
16K Bytes
0x0001_4000
0x0001_7FFF
6
32K Bytes
0x0001_8000
0x0001_FFFF
7
128K Bytes
0x0002_0000
0x0003_FFFF
8
128K Bytes
0x0004_0000
0x0005_FFFF
9
128K Bytes
0x0006_0000
0x0007_FFFF
10
128K Bytes
0x0008_0000
0x0009_FFFF
11
128K Bytes
0x000A_0000
0x000B_FFFF
12
128K Bytes
0x000C_0000
0x000D_FFFF
13
128K Bytes
0x000E_0000
0x000F_FFFF
0
16K Bytes
0xF020_0000
0xF020_3FFF
1
16K Bytes
0xF020_4000
0xF020_7FFF
2
16K Bytes
0xF020_8000
0xF020_BFFF
3
16K Bytes
0xF020_C000
0xF020_FFFF
BANK7 (64KBytes) for EEPROM emulation
(1)
(2)
(3)
(2) (3)
The Flash banks are 144-bit wide bank with ECC support.
The flash bank7 can be programmed while executing code from flash bank0.
Code execution is not allowed from flash bank7.
6.10.2 Main Features of Flash Module
•
•
•
•
•
•
Support for multiple flash banks for program and/or data storage
Simultaneous read access on a bank while performing program or erase operation on any other bank
Integrated state machines to automate flash erase and program operations
Pipelined mode operation to improve instruction access interface bandwidth
Support for Single Error Correction Double Error Detection (SECDED) block inside Cortex-R4F CPU
– Error address is captured for host system debugging
Support for a rich set of diagnostic features
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6.10.3 ECC Protection for Flash Accesses
All accesses to the program flash memory are protected by Single Error Correction Double Error Detection
(SECDED) logic embedded inside the CPU. The flash module provides 8 bits of ECC code for 64 bits of
instructions or data fetched from the flash memory. The CPU calculates the expected ECC code based on
the 64 bits received and compares it with the ECC code returned by the flash module. A single-bit error is
corrected and flagged by the CPU, while a multibit error is only flagged. The CPU signals an ECC error
through its Event bus. This signaling mechanism is not enabled by default and must be enabled by setting
the "X" bit of the Performance Monitor Control Register, c9.
MRC
ORR
MCR
MRC
p15,#0,r1,c9,c12,#0
r1, r1, #0x00000010
p15,#0,r1,c9,c12,#0
p15,#0,r1,c9,c12,#0
;Enabling Event monitor states
;Set 4th bit (‘X’) of PMNC register
The application must also explicitly enable the CPU's ECC checking for accesses on the CPU's ATCM
and BTCM interfaces. These are connected to the program flash and data RAM respectively. ECC
checking for these interfaces can be done by setting the B1TCMPCEN, B0TCMPCEN and ATCMPCEN
bits of the System Control coprocessor's Auxiliary Control Register, c1.
MRC p15, #0, r1, c1, c0, #1
ORR r1, r1, #0x0e000000
DMB
MCR p15, #0, r1, c1, c0, #1
;Enable ECC checking for ATCM and BTCMs
6.10.4 Flash Access Speeds
For information on flash memory access speeds and the relevant wait states required, refer to Section 5.6.
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6.10.5 Program Flash
Table 6-23. Timing Requirements for Program Flash
Parameter
MIN
tprog(144bit)
Wide Word (144bit) programming time
tprog(Total)
1MByte programming time (1)
terase(bank0)
(1)
(2)
MAX
Unit
40
300
µs
11
s
5.5
s
-40°C to 125°C
Sector/Bank erase time (2)
0°C to 60°C, for first
25 cycles
2.8
-40°C to 125°C
0.03
4
s
16
100
ms
1000
cycles
0°C to 60°C, for first
25 cycles
twec
NOM
Write/erase cycles with 15 year Data Retention -40°C to 125°C
requirement
This programming time includes overhead of state machine, but does not include data transfer time. The programming time assumes
programming 144 bits at a time at the maximum specified operating frequency.
During bank erase, the selected sectors are erased simultaneously. The time to erase the bank is specified as equal to the time to erase
a sector.
6.10.6 Data Flash
Table 6-24. Timing Requirements for Data Flash
Parameter
MIN
NOM
MAX
Unit
40
300
µs
660
ms
330
ms
0.2
8
s
14
100
ms
100000
cycles
tprog(144bit)
Wide Word (144bit) programming time
tprog(Total)
EEPROM Emulation (bank 7) 64KByte
programming time (1)
-40°C to 125°C
0°C to 60°C, for first
25 cycles
165
EEPROM Emulation (bank 7) Sector/Bank
erase time (2)
-40°C to 125°C
0°C to 60°C, for first
25 cycles
terase(bank7)
twec
(1)
(2)
Write/erase cycles with 15 year Data Retention -40°C to 125°C
requirement
This programming time includes overhead of state machine, but does not include data transfer time. The programming time assumes
programming 144 bits at a time at the maximum specified operating frequency.
During bank erase, the selected sectors are erased simultaneously. The time to erase the bank is specified as equal to the time to erase
a sector.
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6.11 Tightly Coupled RAM Interface Module
Figure 6-11 illustrates the connection of the Tightly Coupled RAM (TCRAM) to the Cortex-R4F CPU.
Upper 32 bits data &
4 ECC bits
Cortex-R4F
B0
TCM
TCM BUS
TCRAM
Interface 1
72 Bit data + ECC
Lower 32 bits data &
4 ECC bits
B1
TCM
Upper 32 bits data &
4 ECC bits
TCM BUS
72 Bit data + ECC
TCRAM
Interface 2
Lower 32 bits data &
4 ECC bits
36 Bit
Bit
3636
Bit
wide
wide
wideRAM
RAM
RAM
36 Bit
Bit
3636
Bit
wide
wide
wideRAM
RAM
RAM
36 Bit
Bit
3636
Bit
wide
wide
wideRAM
RAM
RAM
36 Bit
Bit
3636
Bit
wide
wide
wide
RAM
RAM
RAM
Figure 6-11. TCRAM Block Diagram
6.11.1 Features
The features of the Tightly Coupled RAM (TCRAM) Module are:
•
•
•
•
•
•
•
•
•
Acts as slave to the BTCM interface of the Cortex-R4F CPU
Supports the internal ECC scheme of the CPU by providing 64-bit data and 8-bit ECC code
Monitors CPU Event Bus and generates single or multibit error interrupts
Stores addresses for single and multibit errors
Supports RAM trace module
Provides CPU address bus integrity checking by supporting parity checking on the address bus
Performs redundant address decoding for the RAM bank chip select and ECC select generation logic
Provides enhanced safety for the RAM addressing by implementing two 36-bit-wide byte-interleaved RAM banks
and generating independent RAM access control signals to the two banks
Supports auto-initialization of the RAM banks along with the ECC bits
6.11.2 TCRAM ECC Support
The TCRAM interface passes on the ECC code for each data read by the Cortex-R4F CPU from the RAM.
It also stores the contents of the CPU ECC port in the ECC RAM when the CPU does a write to the RAM.
The TCRAM interface monitors the CPU event bus and provides registers for indicating single/multibit
errors and also for identifying the address that caused the single or multibit error. The event signaling and
the ECC checking for the RAM accesses must be enabled inside the CPU.
For more information see TMS570LS12x/11x Technical Reference Manual (SPNU515).
6.12
Parity Protection for Accesses to Peripheral RAMs
Accesses to some peripheral RAMs are protected by odd/even parity checking. During a read access the
parity is calculated based on the data read from the peripheral RAM and compared with the good parity
value stored in the parity RAM for that peripheral. If any word fails the parity check, the module generates
a parity error signal that is mapped to the Error Signaling Module. The module also captures the
peripheral RAM address that caused the parity error.
The parity protection for peripheral RAMs is not enabled by default and must be enabled by the
application. Each individual peripheral contains control registers to enable the parity protection for
accesses to its RAM.
80
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NOTE
The CPU read access gets the actual data from the peripheral. The application can choose
to generate an interrupt whenever a peripheral RAM parity error is detected.
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6.13 On-Chip SRAM Initialization and Testing
6.13.1 On-Chip SRAM Self-Test Using PBIST
6.13.1.1 Features
•
•
•
Extensive instruction set to support various memory test algorithms
ROM-based algorithms allow application to run TI production-level memory tests
Independent testing of all on-chip SRAM
6.13.1.2 PBIST RAM Groups
Table 6-25. PBIST RAM Grouping
Test Pattern (Algorithm)
Memory
RAM Group
Test Clock
triple read
slow read
triple read
fast read
March 13N (1)
two port
(cycles)
March 13N (1)
single port
(cycles)
ALGO MASK
0x1
ALGO MASK
0x2
ALGO MASK
0x4
ALGO MASK
0x8
ROM
24578
8194
19586
6530
MEM Type
PBIST_ROM
1
ROM CLK
STC_ROM
2
ROM CLK
ROM
DCAN1
3
VCLK
Dual Port
25200
DCAN2
4
VCLK
Dual Port
25200
DCAN3
5
VCLK
Dual Port
25200
ESRAM1
(2)
6
HCLK
Single Port
MIBSPI1
7
VCLK
Dual Port
33440
266280
MIBSPI3
8
VCLK
Dual Port
33440
MIBSPI5
9
VCLK
Dual Port
33440
VIM
10
VCLK
Dual Port
12560
MIBADC1
11
VCLK
Dual Port
4200
DMA
12
HCLK
Dual Port
18960
N2HET1
13
VCLK
Dual Port
31680
HTU1
14
VCLK
Dual Port
6480
FLEXRAY I/O
buffer,
Transient
Buffer, FTU
Control Packet
16 (3)
VCLK
Dual Port
75400
FLEXRAY
Message RAM
17 (4)
VCLK
Single Port
MIBADC2
18
VCLK
Dual Port
4200
N2HET2
19
VCLK
Dual Port
31680
HTU2
20
VCLK
Dual Port
6480
ESRAM5 (5)
21
HCLK
Single Port
(1)
(2)
(3)
(4)
(5)
133160
266280
There are several memory testing algorithms stored in the PBIST ROM. However, TI recommends the March13N algorithm for
application testing.
ESRAM1: Address 0x08000000 - 0x0800FFFF
This RAM group includes the FTU control packet RAM, the FlexRay controller's I/O buffer, and the transient buffer.
This RAM group inclludes the FlexRay controller's message RAM
ESRAM5: Address 0x08010000 - 0x0801FFFF
The PBIST ROM clock frequency is limited to 100MHz, if 100MHz < HCLK NMI => nERROR
2.6
B0 TCM (even) address bus parity error
User/Privilege
ESM => NMI => nERROR
2.10
B1 TCM (odd) ECC single error (correctable)
User/Privilege
ESM
1.28
B1 TCM (odd) ECC double error (non-correctable)
User/Privilege
Abort (CPU), ESM =>
nERROR
3.5
B1 TCM (odd) uncorrectable error (for example, redundant
address decode)
User/Privilege
ESM => NMI => nERROR
2.8
B1 TCM (odd) address bus parity error
User/Privilege
ESM => NMI => nERROR
2.12
Illegal instruction
MPU access violation
SRAM
B0 TCM (even) ECC single error (correctable)
FLASH WITH CPU BASED ECC
FMC correctable error - Bus1 and Bus2 interfaces (does not
include accesses to Bank 7)
User/Privilege
ESM
1.6
FMC uncorrectable error - Bus1 and Bus2 accesses
(does not include address parity error)
User/Privilege
Abort (CPU), ESM =>
nERROR
3.7
FMC uncorrectable error - address parity error on Bus1
accesses
User/Privilege
ESM => NMI => nERROR
2.4
FMC correctable error - Accesses to Bank 7
User/Privilege
ESM
1.35
FMC uncorrectable error - Accesses to Bank 7
User/Privilege
ESM
1.36
DMA TRANSACTIONS
External imprecise error on read (Illegal transaction with ok
response)
User/Privilege
ESM
1.5
External imprecise error on write (Illegal transaction with ok
response)
User/Privilege
ESM
1.13
Memory access permission violation
User/Privilege
ESM
1.2
Memory parity error
User/Privilege
ESM
1.3
High-End Timer Transfer Unit 1 (HTU1)
NCNB (Strongly Ordered) transaction with slave error response
User/Privilege
Interrupt => VIM
n/a
External imprecise error (Illegal transaction with ok response)
User/Privilege
Interrupt => VIM
n/a
Memory access permission violation
User/Privilege
ESM
1.9
Memory parity error
User/Privilege
ESM
1.8
High-End Timer Transfer Unit 2 (HTU2)
NCNB (Strongly Ordered) transaction with slave error response
User/Privilege
Interrupt => VIM
n/a
External imprecise error (Illegal transaction with ok response)
User/Privilege
Interrupt => VIM
n/a
Memory access permission violation
User/Privilege
ESM
1.9
Memory parity error
User/Privilege
ESM
1.8
(1)
104
The Undefined Instruction TRAP is NOT detectable outside the CPU. The trap is taken only if the instruction reaches the execute stage
of the CPU.
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Table 6-36. Reset/Abort/Error Sources (continued)
ERROR SOURCE
SYSTEM MODE
ERROR RESPONSE
ESM HOOKUP
group.channel
ESM
1.7
ESM
1.34
ESM
1.12
n/a
N2HET1
Memory parity error
User/Privilege
N2HET2
Memory parity error
User/Privilege
FLEXRAY
Memory parity error
User/Privilege
FLEXRAY Transfer Unit (FTU)
NCNB (Strongly Ordered) transaction with slave error response
User/Privilege
Interrupt => VIM
External imprecise error (Illegal transaction with ok response)
User/Privilege
Interrupt => VIM
n/a
Memory access permission violation
User/Privilege
ESM
1.16
User/Privilege
ESM
1.14
Memory parity error
MIBSPI
MibSPI1 memory parity error
User/Privilege
ESM
1.17
MibSPI3 memory parity error
User/Privilege
ESM
1.18
MibSPI5 memory parity error
User/Privilege
ESM
1.24
User/Privilege
ESM
1.19
User/Privilege
ESM
1.1
MIBADC
MibADC1 Memory parity error
MibADC2 Memory parity error
DCAN
DCAN1 memory parity error
User/Privilege
ESM
1.21
DCAN2 memory parity error
User/Privilege
ESM
1.23
DCAN3 memory parity error
User/Privilege
ESM
1.22
PLL
PLL slip error
User/Privilege
ESM
1.10
PLL #2 slip error
User/Privilege
ESM
1.42
ESM
1.11
CLOCK MONITOR
Clock monitor interrupt
User/Privilege
DCC
DCC1 error
User/Privilege
ESM
1.30
DCC2 error
User/Privilege
ESM
1.62
CCM-R4
Self test failure
User/Privilege
ESM
1.31
Compare failure
User/Privilege
ESM => NMI => nERROR
2.2
ESM
1.15
Reset
n/a
ESM
1.27
ESM
1.37
User/Privilege
ESM
1.38
User/Privilege
ESM
1.39
VIM
Memory parity error
User/Privilege
VOLTAGE MONITOR
VMON out of voltage range
n/a
CPU SELFTEST (LBIST)
CPU Selftest (LBIST) error
User/Privilege
PIN MULTIPLEXING CONTROL
Mux configuration error
User/Privilege
POWER DOMAIN CONTROL
PSCON compare error
PSCON self-test error
eFuse CONTROLLER
eFuse Controller Autoload error
User/Privilege
ESM => nERROR
3.1
eFuse Controller - Any bit set in the error status register
User/Privilege
ESM
1.40
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Table 6-36. Reset/Abort/Error Sources (continued)
ERROR SOURCE
eFuse Controller self-test error
SYSTEM MODE
ERROR RESPONSE
ESM HOOKUP
group.channel
User/Privilege
ESM
1.41
ESM => NMI => nERROR
2.24
WINDOWED WATCHDOG
WWD Non-Maskable Interrupt exception
n/a
ERRORS REFLECTED IN THE SYSESR REGISTER
Power-Up Reset
n/a
Reset
n/a
Oscillator fail / PLL slip (2)
n/a
Reset
n/a
Watchdog exception
n/a
Reset
n/a
CPU Reset (driven by the CPU STC)
n/a
Reset
n/a
Software Reset
n/a
Reset
n/a
External Reset
n/a
Reset
n/a
(2)
106
Oscillator fail/PLL slip can be configured in the system register (SYS.PLLCTL1) to generate a reset.
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6.20 Digital Windowed Watchdog
This device includes a digital windowed watchdog (DWWD) module that protects against runaway code
execution.
The DWWD module allows the application to configure the time window within which the DWWD module
expects the application to service the watchdog. A watchdog violation occurs if the application services the
watchdog outside of this window, or fails to service the watchdog at all. The application can choose to
generate a system reset or an ESM group2 error signal in case of a watchdog violation.
The watchdog is disabled by default and must be enabled by the application. Once enabled, the watchdog
can only be disabled upon a system reset.
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6.21 Debug Subsystem
6.21.1 Block Diagram
The device contains an ICEPICK module to allow JTAG access to the scan chains.
Boundary Scan
BSR/BSDL
Boundary Scan I/F
TRST
TMS
TCK
RTCK
TDI
TDO
Debug
ROM1
Debug APB
DAP
Secondary Tap 0
APB Mux
AHB-AP
POM
ICEPICK_C
to SCR1 via A2A
from
PCR1/Bridge
APB slave
Cortex
R4F
Secondary Tap 2
AJSM
Test Tap 0
eFuse Farm
Test Tap 1
PSCON
Figure 6-20. Debug Subsystem Block Diagram
6.21.2 Debug Components Memory Map
Table 6-37. Debug Components Memory Map
MODULE NAME
FRAME CHIP
SELECT
CoreSight Debug
ROM
Cortex-R4F
Debug
FRAME ADDRESS RANGE
FRAME ACTUA
SIZE
L SIZE
RESPNSE FOR ACCESS TO
UNIMPLEMENTED LOCATIONS IN
FRAME
START
END
CSCS0
0xFFA0_0000
0xFFA0_0FFF
4KB
4KB
Reads return zeros, writes have no
effect
CSCS1
0xFFA0_1000
0xFFA0_1FFF
4KB
4KB
Reads return zeros, writes have no
effect
6.21.3 JTAG Identification Code
The JTAG ID code for this device is the same as the device ICEPick Identification Code.
Table 6-38. JTAG ID Code
108
Silicon Revision
ID
Rev A
0x0B95502F
Rev B
0x2B95502F
Rev C
0x3B95502F
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6.21.4 Debug ROM
The Debug ROM stores the location of the components on the Debug APB bus:
Table 6-39. Debug ROM table
ADDRESS
DESCRIPTION
VALUE
0x000
pointer to Cortex-R4F
0x0000 1003
0x001
Reserved
0x0000 2002
0x002
Reserved
0x0000 3002
0x003
POM
0x0000 4003
0x004
end of table
0x0000 0000
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6.21.5 JTAG Scan Interface Timings
Table 6-40. JTAG Scan Interface Timing (1)
No.
Parameter
fTCK
fRTCK
1
td(TCK -RTCK)
2
tsu(TDI/TMS - RTCKr)
3
th(RTCKr -TDI/TMS)
4
th(RTCKr -TDO)
5
td(TCKf -TDO)
(1)
Min
TCK frequency (at HCLKmax)
RTCK frequency (at TCKmax and HCLKmax)
MAX
Unit
12
MHz
10
Delay time, TCK to RTCK
MHz
24
ns
Setup time, TDI, TMS before RTCK rise (RTCKr)
26
ns
Hold time, TDI, TMS after RTCKr
0
ns
Hold time, TDO after RTCKf
0
Delay time, TDO valid after RTCK fall (RTCKf)
ns
12
ns
Timings for TDO are specified for a maximum of 50pF load on TDO
TCK
RTCK
1
1
TMS
TDI
2
3
TDO
4
5
Figure 6-21. JTAG Timing
110
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6.21.6 Advanced JTAG Security Module
This device includes a an Advanced JTAG Security Module (AJSM). which provides maximum security to
the device’s memory content by allowing users to secure the device after programming.
Flash Module Output
OTP Contents
(example)
H
L
H
...
...
L
Unlock By Scan
Register
Internal Tie-Offs
(example only)
L
L
H
H
L
H
H
L
H
H
L
L
UNLOCK
128-bit comparator
Internal Tie-Offs
(example only)
H
L
L
H
H
L
L
H
Figure 6-22. AJSM Unlock
The device is unsecure by default by virtue of a 128-bit visible unlock code programmed in the OTP
address 0xF0000000.The OTP contents are XOR-ed with the "Unlock By Scan" register contents. The
outputs of these XOR gates are again combined with a set of secret internal tie-offs. The output of this
combinational logic is compared against a secret hard-wired 128-bit value. A match results in the
UNLOCK signal being asserted, so that the device is now unsecure.
A user can secure the device by changing at least one bit in the visible unlock code from 1 to 0. Changing
a 0 to 1 is not possible since the visible unlock code is stored in the One Time Programmable (OTP) flash
region. Also, changing all the 128 bits to zeros is not a valid condition and will permanently secure the
device.
Once secured, a user can unsecure the device by scanning an appropriate value into the "Unlock By
Scan" register of the AJSM module. This register is accessible by configuring an IR value of 0b1011 on
the AJSM TAP. The value to be scanned is such that the XOR of the OTP contents and the Unlock-ByScan register contents results in the original visible unlock code.
The Unlock-By-Scan register is reset only upon asserting power-on reset (nPORRST).
A secure device only permits JTAG accesses to the AJSM scan chain through the Secondary Tap # 2 of
the ICEPick module. All other secondary taps, test taps and the boundary scan interface are not
accessible in this state.
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6.21.7 Boundary Scan Chain
The device supports BSDL-compliant boundary scan for testing pin-to-pin compatibility. The boundary
scan chain is connected to the Boundary Scan Interface of the ICEPICK module.
Device Pins (conceptual)
RTCK
TDI
TDO
IC E P ICK
TRST
TMS
TCK
Boundary Scan Interface
Boundary
Scan
TDI
TDO
BSDL
Figure 6-23. Boundary Scan Implementation (Conceptual Diagram)
Data is serially shifted into all boundary-scan buffers through TDI, and out through TDO.
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7 Peripheral Information and Electrical Specifications
7.1
Enhanced Translator PWM Modules (ePWM)
Figure 7-1 illustrates the connections between the seven ePWM modules (ePWM1,2,3,4,5,6,7) on the
device.
PINMMR36[25]
NHET1_LOOP_SYNC
EPWMSYNCI
VIM
EPWM1TZINTn
VIM
EPWM1INTn
ADC Wrapper
EPWM1A
EPWM1B
TZ1/2/3n
Mux
Selector
SOCA1, SOCB1
EPWM1
VBus32
EQEP1 + EQEP2 EQEP1ERR / EQEP2ERR /
EQEP1ERR or EQEP2ERR
System Module OSC FAIL or PLL Slip
Debug Mode Entry
CPU
TZ4n
VCLK4, SYS_nRST
EPWM1ENCLK
TBCLKSYNC
TZ5n
TZ6n
VIM
EPWM2/3/4/5/6TZINTn
VIM
EPWM2/3/4/5/6INTn
EPWM2/3/4/5/6A
TZ1/2/3n
ADC Wrapper
Mux
Selector
SOCA2/3/4/5/6
SOCB2/3/4/5/6
EQEP1 + EQEP2 EQEP1ERR / EQEP2ERR /
EQEP1ERR or EQEP2ERR
System Module OSC FAIL or PLL Slip
VBus32
TZ4n
VCLK4, SYS_nRST
EPWM2/3/4/5/6ENCLK
TZ5n
Debug Mode Entry
CPU
EPWM
2/3/4/5/6
IOMUX
EPWM2/3/4/5/6B
TBCLKSYNC
TZ6n
VIM
EPWM7TZINTn
VIM
EPWM7INTn
EPWM7A
EPWM7B
ADC Wrapper
EQEP1 + EQEP2
System Module
Mux
Selector
EPWM
7
EQEP1ERR / EQEP2ERR /
EQEP1ERR or EQEP2ERR
OSC FAIL or PLL SLip
VBus32
TZ4n
VCLK4, SYS_nRST
EPWM7ENCLK
TBCLKSYNC
TZ5n
Debug Mode Entry
CPU
TZ1/2/3n
SOCA7, SOCB7
TZ6n
Pulse
Stretch, EPWMSYNCO
8 VCLK4
cycles
VBus32 / VBus32DP
VIM
ECAP1INTn
ECAP
1
ECAP1
Figure 7-1. ePWMx Module Interconnections
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ePWM Clocking and Reset
Each ePWM module has a clock enable (EPWMxENCLK). When SYS_nRST is active low, the clock
enables are ignored and the ePWM logic is clocked so that it can reset to a proper state. When
SYS_nRST goes in-active high, the state of clock enable is respected.
Table 7-1. ePWMx Clock Enable Control
ePWM Module Instance
Control Register to Enable Clock
Default Value
ePWM1
PINMMR37[8]
1
ePWM2
PINMMR37[16]
1
ePWM3
PINMMR37[24]
1
ePWM4
PINMMR38[0]
1
ePWM5
PINMMR38[8]
1
ePWM6
PINMMR38[16]
1
ePWM7
PINMMR38[24]
1
The default value of the control registers to enable the clocks to the ePWMx modules is 1. This means
that the VCLK4 clock connections to the ePWMx modules are enabled by default. The application can
choose to gate off the VCLK4 clock to any ePWMx module individually by clearing the respective control
register bit.
7.1.2
Synchronization of ePWMx Time Base Counters
A time-base synchronization scheme connects all of the ePWM modules on a device. Each ePWM
module has a synchronization input (EPWMxSYNCI) and a synchronization output (EPWMxSYNCO). The
input synchronization for the first instance (ePWM1) comes from an external pin. Figure 7-1 shows the
synchronization connections for all the ePWMx modules. Each ePWM module can be configured to use or
ignore the synchronization input. Refer to the ePWM chapter in the TMS570LS12x/11x Technical
Reference Manual (SPNU515) for more information.
7.1.3
Synchronizing all ePWM Modules to the N2HET1 Module Time Base
The connection between the N2HET1_LOOP_SYNC and SYNCI input of ePWM1 module is implemented
as shown in Figure 7-2.
N2HET1
N2HET1_LOOP_SYNC
EXT_LOOP_SYNC
2 VCLK4 cycles
Pulse Strength
SYNCI
N2HET2
ePWM1
ePWM1_SYNCI
ePWM1_SYNCI_SYNCED
ePWM1_SYNCI_FILTERED
PINMMR36[25]
PINMMR47[8,9,10]
Figure 7-2. Synchronizing Time Bases Between N2HET1, N2HET2 and ePWMx Modules
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Phase-Locking the Time-Base Clocks of Multiple ePWM Modules
The TBCLKSYNC bit can be used to globally synchronize the time-base clocks of all enabled ePWM
modules on a device. This bit is implemented as PINMMR37 register bit 1.
When TBCLKSYNC = 0, the time-base clock of all ePWM modules is stopped. This is the default
condition.
When TBCLKSYNC = 1, all ePWM time-base clocks are started with the rising edge of TBCLK aligned.
For perfectly synchronized TBCLKs, the prescaler bits in the TBCTL register of each ePWM module must
be set identically. The proper procedure for enabling the ePWM clocks is as follows:
1. Enable the individual ePWM module clocks (if disable) using the control registers shown in Table 7-1.
2. Configure TBCLKSYNC = 0. This will stop the time-base clock within any enabled ePWM module.
3. Configure the prescaler values and desired ePWM modes.
4. Configure TBCLKSYNC = 1.
7.1.5
ePWM Synchronization with External Devices
The output sync from EPWM1 Module is also exported to a device output terminal so that multiple devices
can be synchronized together. The signal pulse is stretched by eight VCLK4 cycles before being exported
on the terminal as the EPWM1SYNCO signal.
7.1.6
ePWM Trip Zones
The ePWMx modules have six trip zone inputs each. These are active-low signals. The application can
control the ePWMx module response to each of the trip zone input separately. The timing requirements
from the assertion of the trip zone inputs to the actual response are specified in Section 7.1.8.
7.1.6.1
Trip Zones TZ1n, TZ2n, TZ3n
These three trip zone inputs are driven by external circuits and are connected to device-level inputs.
These signals are either connected asynchronously to the ePWMx trip zone inputs, or doublesynchronized with VCLK4, or double-synchronized and then filtered with a 6-cycle VCLK4-based counter
before connecting to the ePWMx. By default, the trip zone inputs are asynchronously connected to the
ePWMx modules.
Table 7-2. Connection to ePWMx Modules for Device-Level Trip Zone Inputs
Trip Zone Input
Control for
Asynchronous
Connection to ePWMx
Control for Double-Synchronized
Connection to ePWMx
Control for Double-Synchronized and Filtered
Connection to ePWMx
TZ1n
PINMMR46[16] = 1
PINMMR46[16] = 0 AND
PINMMR46[17] = 1
PINMMR46[16] = 0 AND PINMMR46[17] = 0
AND PINMMR46[18] = 1
TZ2n
PINMMR46[24] = 1
PINMMR46[24] = 0 AND
PINMMR46[25] = 1
PINMMR46[24] = 0 AND PINMMR46[25] = 0
AND PINMMR46[26] = 1
TZ3n
PINMMR47[0] = 1
PINMMR47[0] = 0 AND PINMMR47[1]
=1
PINMMR47[0] = 0 AND PINMMR47[1] = 0 AND
PINMMR47[2] = 1
7.1.6.2
Trip Zone TZ4n
This trip zone input is dedicated to eQEPx error indications. There are two eQEP modules on this device.
Each eQEP module indicates a phase error by driving its EQEPxERR output High. The following control
registers allow the application to configure the trip zone input (TZ4n) to each ePWMx module based on
the application’s requirements.
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Table 7-3. TZ4n Connections for ePWMx Modules
ePWMx
Control for TZ4n =
not(EQEP1ERR OR
EQEP2ERR)
Control for TZ4n = not(EQEP1ERR)
Control for TZ4n = not(EQEP2ERR)
ePWM1
PINMMR41[0] = 1
PINMMR41[0] = 0 AND PINMMR41[1]
=1
PINMMR41[0] = 1 AND PINMMR41[1] = 0 AND
PINMMR41[2] = 1
ePWM2
PINMMR41[8]
PINMMR41[8] = 0 AND PINMMR41[9]
=1
PINMMR41[8] = 1 AND PINMMR41[9] = 0 AND
PINMMR41[10] = 1
ePWM3
PINMMR41[16]
PINMMR41[16] = 0 AND
PINMMR41[17] = 1
PINMMR41[16] = 1 AND PINMMR41[17] = 0
AND PINMMR41[18] = 1
ePWM4
PINMMR41[24]
PINMMR41[24] = 0 AND
PINMMR41[25] = 1
PINMMR41[24] = 1 AND PINMMR41[25] = 0
AND PINMMR41[26] = 1
ePWM5
PINMMR42[0]
PINMMR42[0] = 0 AND PINMMR42[1]
=1
PINMMR42[0] = 1 AND PINMMR42[1] = 0 AND
PINMMR42[2] = 1
ePWM6
PINMMR42[8]
PINMMR42[8] = 0 AND PINMMR42[9]
=1
PINMMR42[8] = 1 AND PINMMR42[9] = 0 AND
PINMMR42[10] = 1
ePWM7
PINMMR42[16]
PINMMR42[16] = 0 AND
PINMMR42[17] = 1
PINMMR42[16] = 1 AND PINMMR42[17] = 0
AND PINMMR42[18] = 1
7.1.6.3
Trip Zone TZ5n
This trip zone input is dedicated to a clock failure on the device. That is, this trip zone input is asserted
whenever an oscillator failure or a PLL slip is detected on the device. The application can use this trip
zone input for each ePWMx module in order to prevent the external system from going out of control when
the device clocks are not within expected range (system running at limp clock).
The oscillator failure and PLL slip signals used for this trip zone input are taken from the status flags in the
system module. These are level signals are set until cleared by the application.
7.1.6.4
Trip Zone TZ6n
This trip zone input to the ePWMx modules is dedicated to a debug mode entry of the CPU. If enabled,
the user can force the PWM outputs to a known state when the emulator stops the CPU. This prevents the
external system from going out of control when the CPU is stopped.
7.1.7
Triggering of ADC Start of Conversion Using ePWMx SOCA and SOCB Outputs
A special scheme is implemented in order to select the actual signal used for triggering the start of
conversion on the two ADCs on this device. This scheme is defined in Section 7.4.2.3.
7.1.8
Enhanced Translator-Pulse Width Modulator (ePWMx) Timings
Table 7-4. ePWMx Timing Requirements
PARAMETER
tw(SYNCIN)
Synchronization input pulse width
TEST CONDITIONS
MIN
Asynchronous
2 tc(VCLK4)
MAX
cycles
UNIT
Synchronous
2 tc(VCLK4)
cycles
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
Table 7-5. ePWMx Switching Characteristics
PARAMETER
tw(PWM)
TEST CONDITIONS
Pulse duration, ePWMx output high or low
tw(SYNCOUT Synchronization Output Pulse Width
MIN
MAX
UNIT
33.33
ns
8 tc(VCLK4)
cycles
)
td(PWM)tza
116
Delay time, trip input active to PWM forced high,
OR Delay time, trip input active to PWM forced
low
no pin load
25
ns
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Table 7-5. ePWMx Switching Characteristics (continued)
PARAMETER
td(TZ-
TEST CONDITIONS
MIN
Delay time, trip input active to PWM Hi-Z
MAX
UNIT
20
ns
MAX
UNIT
PWM)HZ
Table 7-6. ePWMx Trip-Zone Timing Requirements
PARAMETER
tw(TZ)
(1)
Pulse duration, TZn input low
TEST CONDITIONS
MIN
Asynchronous
2 * HSPCLKDIV *
CLKDIV * tc(VCLK4) (1)
ns
Synchronous
2 tc(VCLK4)
ns
Synchronous, with input
filter
8 tc(VCLK4)
ns
Refer to the ePWM chapter of the TMS570LS12x/11x Technical Reference Manual (SPNU515) for more information on the clock divider
fields HSPCLKDIV and CLKDIV.
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Enhanced Capture Modules (eCAP)
Figure 7-3 shows how the eCAP modules are interconnected on this microcontroller.
EPWM1SYNCO
ECAP1SYNCI
ECAP1
VIM
ECAP1INTn
ECAP1
VBus32
VCLK4, SYS_nRST
ECAP1ENCLK
ECAP1SYNCO
ECAP2SYNCI
VIM
ECAP2INTn
ECAP
2/3/4/5
IOMUX
ECAP2
VBus32
VCLK4, SYS_nRST
ECAP2SYNCO
ECAP2ENCLK
ECAP6
VIM
ECAP6INTn
ECAP
6
VBus32
VCLK4, SYS_nRST
ECAP6ENCLK
Figure 7-3. eCAP Module Connections
7.2.1
Clock Enable Control for eCAPx Modules
Each of the ECAPx modules have a clock enable (ECAPxENCLK). These signals need to be generated
from a device-level control register. When SYS_nRST is active low, the clock enables are ignored and the
ECAPx logic is clocked so that it can reset to a proper state. When SYS_nRST goes in-active high, the
state of clock enable is respected.
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Table 7-7. eCAPx Clock Enable Control
ePWM Module Instance
Control Register to Enable Clock
Default Value
eCAP1
PINMMR39[0]
1
eCAP2
PINMMR39[8]
1
eCAP3
PINMMR39[16]
1
eCAP4
PINMMR39[24]
1
eCAP5
PINMMR40[0]
1
eCAP6
PINMMR40[8]
1
The default value of the control registers to enable the clocks to the eCAPx modules is 1. This means that
the VCLK4 clock connections to the eCAPx modules are enabled by default. The application can choose
to gate off the VCLK4 clock to any eCAPx module individually by clearing the respective control register
bit.
7.2.2
PWM Output Capability of eCAPx
When not used in capture mode, each of the eCAPx modules can be used as a single-channel PWM
output. This is called the auxiliary PWM (APWM) mode of operation of the eCAP modules. Refer to the
eCAP chapter of the TMS570LS12x/11x Technical Reference Manual (SPNU515) for more information.
7.2.3
Input Connection to eCAPx Modules
The input connection to each of the eCAP modules can be selected between a double-VCLK4synchronized input or a double-VCLK4-synchronized and filtered input, as shown in Table 7-8.
Table 7-8. Device-Level Input Connection to eCAPx Modules
Input Signal
Control for Double-Synchronized Connection to
eCAPx
Control for Double-Synchronized and Filtered
Connection to eCAPx
eCAP1
PINMMR43[0] = 1
PINMMR43[0] = 0 AND PINMMR43[1] = 1
eCAP2
PINMMR43[8] = 1
PINMMR43[8] = 0 AND PINMMR43[9] = 1
eCAP3
PINMMR43[16] = 1
PINMMR43[16] = 0 AND PINMMR43[17] = 1
eCAP4
PINMMR43[24] = 1
PINMMR43[24] = 0 AND PINMMR43[25] = 1
eCAP5
PINMMR44[0] = 1
PINMMR44[0] = 0 AND PINMMR44[1] = 1
eCAP6
PINMMR44[8] = 1
PINMMR44[8] = 0 AND PINMMR44[9] = 1
7.2.4
Enhanced Capture Module (eCAP) Timings
Table 7-9. eCAPx Timing Requirements
PARAMETER
tw(CAP)
Capture input pulse width
TEST CONDITIONS
MIN
Synchronous
2 tc(VCLK4)
MAX
cycles
UNIT
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
Table 7-10. eCAPx Switching Characteristics
PARAMETER
tw(APWM)
TEST CONDITIONS
Pulse duration, APWMx output high or low
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MIN
MAX
UNIT
20
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Enhanced Quadrature Encoder (eQEP)
Figure 7-4 shows the eQEP module interconnections on the device.
VBus32
EQEP1A
EQEP1B
EQEP1ENCLK
VCLK4
SYS_nRST
EPWM1/../7
VIM
EQEP1INTn
EQEP1
Module
EQEP1ERR
EQEP1I
EQEP1IO
EQEP1IOE
TZ4n
EQEP1S
EQEP1SO
EQEP1SOE
IO
Mux
VBus32
EQEP2A
EQEP2B
EQEP2ENCLK
VCLK4
SYS_nRST
VIM
Connection
Selection
Mux
EQEP2INTn
EQEP2
Module
EQEP2ERR
EQEP2I
EQEP2IO
EQEP2IOE
EQEP2S
EQEP2SO
EQEP2SOE
Figure 7-4. eQEP Module Interconnections
7.3.1
Clock Enable Control for eQEPx Modules
Device-level control registers are implemented to generate the EQEPxENCLK signals. When SYS_nRST
is active low, the clock enables are ignored and the eQEPx logic is clocked so that it can reset to a proper
state. When SYS_nRST goes in-active high, the state of clock enable is respected.
Table 7-11. eQEPx Clock Enable Control
ePWM Module Instance
Control Register to Enable Clock
Default Value
eQEP1
PINMMR40[16]
1
eQEP2
PINMMR40[24]
1
The default value of the control registers to enable the clocks to the eQEPx modules is 1. This means that
the VCLK4 clock connections to the eQEPx modules are enabled by default. The application can choose
to gate off the VCLK4 clock to any eQEPx module individually by clearing the respective control register
bit.
7.3.2
Using eQEPx Phase Error to Trip ePWMx Outputs
The eQEP module sets the EQEPERR signal output whenever a phase error is detected in its inputs
EQEPxA and EQEPxB. This error signal from both the eQEP modules is input to the connection selection
multiplexor. This multiplexor is defined in Table 7-3. As shown in Figure 7-1, the output of this selection
multiplexor is inverted and connected to the TZ4n trip-zone input of all EPWMx modules. This connection
allows the application to define the response of each ePWMx module on a phase error indicated by the
eQEP modules.
7.3.3
Input Connections to eQEPx Modules
The input connections to each of the eQEP modules can be selected between a double-VCLK4synchronized input or a double-VCLK4-synchronized and filtered input, as shown in Table 7-12.
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Table 7-12. Device-Level Input Connection to eCAPx Modules
Input Signal
Control for Double-Synchronized Connection to
eQEPx
Control for Double-Synchronized and Filtered
Connection to eQEPx
eQEP1A
PINMMR44[16] = 1
PINMMR44[16] = 0 and PINMMR44[17] = 1
eQEP1B
PINMMR44[24] = 1
PINMMR44[24] = 0 and PINMMR44[25] = 1
PINMMR45[0] = 0 and PINMMR45[1] = 1
eQEP1I
PINMMR45[0] = 1
eQEP1S
PINMMR45[8] = 1
PINMMR45[8] = 0 and PINMMR45[9] = 1
eQEP2A
PINMMR45[16] = 1
PINMMR45[16] = 0 and PINMMR45[17] = 1
eQEP2B
PINMMR45[24] = 1
PINMMR45[24] = 0 and PINMMR45[25] = 1
eQEP2I
PINMMR46[0] = 1
PINMMR46[0] = 0 and PINMMR46[1] = 1
eQEP2S
PINMMR46[8] = 1
PINMMR46[8] = 0 and PINMMR46[9] = 1
7.3.4
Enhanced Quadrature Encoder Pulse (eQEPx) Timing
Table 7-13. eQEPx Timing Requirements
PARAMETER
tw(QEPP)
tw(INDEXH)
tw(INDEXL)
tw(STROBH)
tw(STROBL)
TEST CONDITIONS
MIN
Synchronous
2 tc(VCLK4)
cycles
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
Synchronous
2 tc(VCLK4)
cycles
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
Synchronous
2 tc(VCLK4)
cycles
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
QEP input period
QEP Index Input High Time
QEP Index Input Low Time
QEP Strobe Input High Time
MAX
UNIT
Synchronous
2 tc(VCLK4)
cycles
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
Synchronous
2 tc(VCLK4)
cycles
Synchronous, with input
filter
2 tc(VCLK4) + filter width
cycles
QEP Strobe Input Low Time
Table 7-14. eQEPx Switching Characteristics
MAX
UNIT
td(CNTR)xin
Delay time, external clock to counter increment
PARAMETER
4 tc(VCLK4)
cycles
td(PCS-OUT)QEP
Delay time, QEP input edge to position compare sync output
6 tc(VCLK4)
cycles
7.4
MIN
Multibuffered 12bit Analog-to-Digital Converter
The multibuffered A-to-D converter (MibADC) has a separate power bus for its analog circuitry that
enhances the A-to-D performance by preventing digital switching noise on the logic circuitry which could
be present on VSS and VCC from coupling into the A-to-D analog stage. All A-to-D specifications are given
with respect to ADREFLO unless otherwise noted.
Table 7-15. MibADC Overview
Description
Value
Resolution
12 bits
Monotonic
Assured
Output conversion code
00h to 3FFh [00 for VAI ≤ ADREFLO; 3FFh for VAI ≥ ADREFHI]
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Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
12-bit resolution
ADREFHI and ADREFLO pins (high and low reference voltages)
Total Sample/Hold/Convert time: 600ns Minimum at 30MHz ADCLK
One memory region per conversion group is available (event, group 1, group 2)
Allocation of channels to conversion groups is completely programmable
Supports flexible channel conversion order
Memory regions are serviced either by interrupt or by DMA
Programmable interrupt threshold counter is available for each group
Programmable magnitude threshold interrupt for each group for any one channel
Option to read either 8-bit, 10-bit or 12-bit values from memory regions
Single or continuous conversion modes
Embedded self-test
Embedded calibration logic
Enhanced power-down mode
– Optional feature to automatically power down ADC core when no conversion is in progress
External event pin (ADxEVT) programmable as general-purpose I/O
•
7.4.2
Event Trigger Options
The ADC module supports 3 conversion groups: Event Group, Group1 and Group2. Each of these 3
groups can be configured to be hardware event-triggered. In that case, the application can select from
among 8 event sources to be the trigger for a group's conversions.
7.4.2.1
MIBADC1 Event Trigger Hookup
Table 7-16. MIBADC1 Event Trigger Hookup
Trigger Event Signal
Group Source
Select, G1SRC,
G2SRC or
EVSRC
Event #
000
1
122
PINMMR30[0] = 0 and PINMMR30[1] = 1
PINMMR30[0] = 1
(default)
Option A
Control for
Option A
Option B
AD1EVT
AD1EVT
—
AD1EVT
—
PINMMR30[8] = 0
and
PINMMR30[9] = 1
Control for
Option B
001
2
N2HET1[8]
N2HET2[5]
PINMMR30[8] = 1
ePWM_B
010
3
N2HET1[10]
N2HET1[27]
—
N2HET1[27]
—
011
4
RTI Compare 0
Interrupt
RTI Compare 0
Interrupt
PINMMR30[16] =
1
ePWM_A1
PINMMR30[16] =
0 and
PINMMR30[17] =
1
100
5
N2HET1[12]
N2HET1[17]
—
N2HET1[17]
—
101
6
N2HET1[14]
N2HET1[19]
PINMMR30[24] =
1
N2HET2[1]
PINMMR30[24] =
0 and
PINMMR30[25] =
1
110
7
GIOB[0]
N2HET1[11]
PINMMR31[0] = 1
ePWM_A2
PINMMR31[0] = 0
and
PINMMR31[1] = 1
111
8
GIOB[1]
N2HET2[13]
PINMMR32[16] =
1
ePWM_AB
PINMMR31[8] = 0
and
PINMMR31[9] = 1
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NOTE
If ADEVT, N2HET1 or GIOB is used as a trigger source, the connection to the MibADC1
module trigger input is made from the output side of the input buffer. This way, a trigger
condition can be generated either by configuring the function as output onto the pad (through
the mux control), or by driving the function from an external trigger source as input. If the
mux control module is used to select different functionality instead of the ADEVT, N2HET1[x]
or GIOB[x] signals, then care must be taken to disable these signals from triggering
conversions; there is no multiplexing on the input connections.
If ePWM_B, ePWM_S2, ePWM_AB, N2HET2[1], N2HET2[5], N2HET2[13],
N2HET1[11], N2HET1[17] or N2HET1[19] is used to trigger the ADC the connection
to the ADC is made directly from the N2HET or ePWM module outputs. As a result,
the ADC can be triggered without having to enable the signal from being output on
a device terminal.
NOTE
For the RTI compare 0 interrupt source, the connection is made directly from the output of
the RTI module. That is, the interrupt condition can be used as a trigger source even if the
actual interrupt is not signaled to the CPU.
7.4.2.2
MIBADC2 Event Trigger Hookup
Table 7-17. MIBADC2 Event Trigger Hookup
Trigger Event Signal
Group Source
Select, G1SRC,
G2SRC or
EVSRC
Event #
000
1
PINMMR30[0] = 0 and PINMMR30[1] = 1
PINMMR30[0] = 1
(default)
Option A
Control for
Option A
Option B
AD2EVT
AD2EVT
—
AD2EVT
—
Control for
Option B
001
2
N2HET1[8]
N2HET2[5]
PINMMR31[16] =
1
ePWM_B
PINMMR31[16] =
0 and
PINMMR31[17] =
1
010
3
N2HET1[10]
N2HET1[27]
—
N2HET1[27]
—
011
4
RTI Compare 0
Interrupt
RTI Compare 0
Interrupt
PINMMR31[24] =
1
ePWM_A1
PINMMR31[24] =
0 and
PINMMR31[25] =
1
100
5
N2HET1[12]
N2HET1[17]
—
N2HET1[17]
—
101
6
N2HET1[14]
N2HET1[19]
PINMMR32[0] = 1
N2HET2[1]
PINMMR32[0] = 0
and
PINMMR32[1] = 1
110
7
GIOB[0]
N2HET1[11]
PINMMR32[8] = 1
ePWM_A2
PINMMR32[8] = 0
and
PINMMR32[9] = 1
111
8
GIOB[1]
N2HET2[13]
PINMMR32[16] =
1
ePWM_AB
PINMMR32[16] =
0 and
PINMMR32[17] =
1
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NOTE
If AD2EVT, N2HET1 or GIOB is used as a trigger source, the connection to the MibADC2
module trigger input is made from the output side of the input buffer. This way, a trigger
condition can be generated either by configuring the function as output onto the pad (through
the mux control), or by driving the function from an external trigger source as input. If the
mux control module is used to select different functionality instead of the AD2EVT,
N2HET1[x] or GIOB[x] signals, then care must be taken to disable these signals from
triggering conversions; there is no multiplexing on the input connections.
If ePWM_B, ePWM_S2, ePWM_AB, N2HET2[5], N2HET2[1], N2HET2[13],
N2HET1[11], N2HET1[17] or N2HET1[19] is used to trigger the ADC the connection
to the ADC is made directly from the N2HET or ePWM module outputs. As a result,
the ADC can be triggered without having to enable the signal from being output on
a device terminal.
NOTE
For the RTI compare 0 interrupt source, the connection is made directly from the output of
the RTI module. That is, the interrupt condition can be used as a trigger source even if the
actual interrupt is not signaled to the CPU.
7.4.2.3
Controlling ADC1 and ADC2 Event Trigger Options Using SOC Output from ePWM Modules
As shown in Figure 7-5, the ePWMxSOCA and ePWMxSOCB outputs from each ePWM module are used
to generate 4 signals – ePWM_B, ePWM_A1, ePWM_A2 and ePWM_AB, that are available to trigger the
ADC based on the application requirement.
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SOCAEN, SOCBEN bits
inside ePWMx modules
Controlled by PINMMR
EPWM1SOCA
EPWM1
module
EPWM1SOCB
EPWM2SOCA
EPWM2
module
EPWM2SOCB
EPWM3SOCA
EPWM3
module
EPWM3SOCB
EPWM4SOCA
EPWM4
module
EPWM4SOCB
EPWM5SOCA
EPWM5
module
EPWM5SOCB
EPWM6SOCA
EPWM6
module
EPWM6SOCB
EPWM7SOCA
EPWM7
module
EPWM7SOCB
ePWM_B
ePWM_A1
ePWM_A2 ePWM_AB
Figure 7-5. ADC Trigger Source Generation from ePWMx
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Table 7-18. Control Bit to SOC Output
Control Bit
SOC Output
PINMMR35[0]
SOC1A_SEL
PINMMR35[8]
SOC2A_SEL
PINMMR35[16]
SOC3A_SEL
PINMMR35[24]
SOC4A_SEL
PINMMR36[0]
SOC5A_SEL
PINMMR36[8]
SOC6A_SEL
PINMMR36[16]
SOC7A_SEL
The SOCA output from each ePWM module is connected to a "switch" shown in Figure 7-5.
The logic equations for the 4 outputs from the combinational logic shown in Figure 7-5 are:
ePWM_
SOC1B or SOC2B or SOC3B or SOC4B or SOC5B or SOC6B or SOC7B
B=
ePWM_
[ SOC1A and not(SOC1A_SEL) ] or [ SOC2A and not(SOC2A_SEL) ] or [ SOC3A and not(SOC3A_SEL) ] or
A1 =
[ SOC4A and not(SOC4A_SEL) ] or [ SOC5A and not(SOC5A_SEL) ] or [ SOC6A and not(SOC6A_SEL) ] or
[ SOC7A and not(SOC7A_SEL) ]
ePWM_
[ SOC1A and SOC1A_SEL ] or [ SOC2A and SOC2A_SEL ] or [ SOC3A and SOC3A_SEL ] or
A2 =
[ SOC4A and SOC4A_SEL ] or [ SOC5A and SOC5A_SEL ] or [ SOC6A and SOC6A_SEL ] or
[ SOC7A and SOC7A_SEL ]
ePWM_
ePWM_B or ePWM_A2
AB =
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7.4.3
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
ADC Electrical and Timing Specifications
Table 7-19. MibADC Recommended Operating Conditions
Parameter
MIN
MAX
Unit
(1)
V
V
ADREFHI
A-to-D high-voltage reference source
ADREFLO
VCCAD
ADREFLO
A-to-D low-voltage reference source
VSSAD (1)
ADREFHI
VAI
Analog input voltage
ADREFLO
ADREFHI
V
IAIK
Analog input clamp current (2)
(VAI < VSSAD – 0.3 or VAI > VCCAD + 0.3)
-2
2
mA
(1)
(2)
For VCCAD and VSSAD recommended operating conditions, see Section 5.4.
Input currents into any ADC input channel outside the specified limits could affect conversion results of other channels.
Table 7-20. MibADC Electrical Characteristics Over Full Ranges of Recommended Operating Conditions
Parameter
MAX
Unit
Rmux
Analog input mux onresistance
See Figure 7-6
250
Ω
Rsamp
ADC sample switch onresistance
See Figure 7-6
250
Ω
Cmux
Input mux capacitance
See Figure 7-6
16
pF
Csamp
ADC sample capacitance
See Figure 7-6
13
pF
IAIL
Analog off-state input
leakage current
VCCAD = 3.6V
maximum
IAIL
Description/Conditions
Analog off-state input
leakage current
IAOSB1 (1)
IAOSB2 (1)
IAOSB1 (1)
IAOSB2 (1)
ADC1 Analog on-state input
bias current
ADC2 Analog on-state input
bias current
ADC1 Analog on-state input
bias current
VCCAD = 5.5V
maximum
VCCAD = 3.6V
maximum
VCCAD = 3.6V
maximum
VCCAD = 5.5V
maximum
MIN
Nom
VSSAD ≤ VIN < VSSAD + 100mV
-300
200
nA
VSSAD + 100mV ≤ VIN ≤ VCCAD - 200mV
-200
200
nA
VCCAD - 200mV < VIN ≤ VCCAD
-200
500
nA
VSSAD ≤ VIN < VSSAD + 300mV
-1000
250
nA
VSSAD + 300mV ≤ VIN ≤ VCCAD - 300mV
-250
250
nA
VCCAD - 300mV < VIN ≤ VCCAD
-250
1000
nA
VSSAD ≤ VIN < VSSAD + 100mV
-8
2
µA
VSSAD + 100mV < VIN < VCCAD - 200mV
-4
2
µA
VCCAD - 200mV < VIN < VCCAD
-4
12
µA
VSSAD ≤ VIN < VSSAD + 100mV
-7
2
µA
VSSAD + 100mV ≤ VIN ≤ VCCAD - 200mV
-4
2
µA
VCCAD - 200mV < VIN ≤ VCCAD
-4
10
µA
VSSAD ≤ VIN < VSSAD + 300mV
-10
3
µA
VSSAD + 300mV ≤ VIN ≤ VCCAD - 300mV
-5
3
µA
VCCAD - 300mV < VIN ≤ VCCAD
-5
14
µA
VSSAD ≤ VIN < VSSAD + 300mV
-8
3
µA
VSSAD + 300mV ≤ VIN ≤ VCCAD - 300mV
-5
3
µA
VCCAD - 300mV < VIN ≤ VCCAD
-5
ADC2 Analog on-state input
bias current
VCCAD = 5.5V
maximum
12
µA
IADREFHI
ADREFHI input current
ADREFHI = VCCAD, ADREFLO = VSSAD
3
mA
ICCAD
Static supply current
Normal operating mode
15
mA
ADC core in power down mode
5
µA
(1)
If a shared channel is being converted by both ADC converters at the same time, the on-state leakage is equal to IAOSB1 + IAOSB2
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Rext
Pin
VS1
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Smux
Rmux
Smux
Rmux
IAOSB
Cext
On-State
Bias Current
Rext
Pin
VS2
IAIL
Cext
IAIL
IAIL
Off-State
Leakages
Rext
Pin
Smux
Rmux
Ssamp
Rsamp
VS24
IAIL
Csamp
Cmux
Cext
IAIL
IAIL
Figure 7-6. MibADC Input Equivalent Circuit
Table 7-21. MibADC Timing Specifications
Parameter
tc(ADCLK) (1)
td(SH)
(2)
MIN
Cycle time, MibADC clock
Delay time, sample and hold
time
NOM
MAX
Unit
0.033
µs
0.2
µs
1
µs
td(PU-ADV)
Delay time from ADC power on
until first input can be sampled
td©)
Delay time, conversion time
0.4
µs
td(SHC) (3)
Delay time, total sample/hold
and conversion time
0.6
µs
td©)
Delay time, conversion time
0.33
µs
td(SHC) (3)
Delay time, total sample/hold
and conversion time
0.53
µs
12-bit mode
10-bit mode
(1)
(2)
(3)
128
The MibADC clock is the ADCLK, generated by dividing down the VCLK by a prescale factor defined by the ADCLOCKCR register bits
4:0.
The sample and hold time for the ADC conversions is defined by the ADCLK frequency and the ADSAMP register for each
conversion group. The sample time needs to be determined by accounting for the external impedance connected to the input channel as
well as the ADC’s internal impedance.
This is the minimum sample/hold and conversion time that can be achieved. These parameters are dependent on many factors, for
example, the prescale settings.
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Table 7-22. MibADC Operating Characteristics Over Full Ranges of Recommended Operating
Conditions (1) (2)
Parameter
Description/Conditions
CR
Conversion range over ADREFHI - ADREFLO
which specified
accuracy is
maintained
ZSET
Zero Scale Offset
FSET
EDNL
EINL
Differential
nonlinearity error
Integral nonlinearity
error
ETOT
(1)
(2)
Full Scale Offset
Total unadjusted error
MIN
3
Type
MAX
Unit
5.5
V
Difference between the first ideal transition
(from code 000h to 001h) and the actual
transition
10-bit
mode
1
LSB
12-bit
mode
2
LSB
Difference between the range of the
measured code transitions (from first to last)
and the range of the ideal code transitions
10-bit
mode
2
LSB
12-bit
mode
3
LSB
Difference between the actual step width and
the ideal value. (See Figure 7-7)
10-bit
mode
± 1.5
LSB
12-bit
mode
±2
LSB
Maximum deviation from the best straight line 10-bit
through the MibADC. MibADC transfer
mode
characteristics, excluding the quantization
12-bit
error.
mode
±2
LSB
±2
LSB
Maximum value of the difference between an
analog value and the ideal midstep value.
10-bit
mode
±2
LSB
12-bit
mode
±4
LSB
1 LSB = (ADREFHI – ADREFLO)/ 212 for 12-bit mode
1 LSB = (ADREFHI – ADREFLO)/ 210 for 10-bit mode
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Performance (Accuracy) Specifications
7.4.4.1
MibADC Nonlinearity Errors
The differential nonlinearity error shown in Figure 7-7 (sometimes referred to as differential linearity) is the
difference between an actual step width and the ideal value of 1 LSB.
0 ... 110
Digital Output Code
0 ... 101
0 ... 100
0 ... 011
Differential Linearity
Error (–½ LSB)
1 LSB
0 ... 010
Differential Linearity
Error (–½ LSB)
0 ... 001
1 LSB
0 ... 000
0
1
3
4
2
Analog Input Value (LSB)
5
12
NOTE A: 1 LSB = (ADREFHI – ADREFLO)/2
Figure 7-7. Differential Nonlinearity (DNL) Error
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The integral nonlinearity error shown in Figure 7-8 (sometimes referred to as linearity error) is the
deviation of the values on the actual transfer function from a straight line.
0 ... 111
0 ... 110
Ideal
Transition
Digital Output Code
0 ... 101
Actual
Transition
0 ... 100
At Transition
011/100
(–½ LSB)
0 ... 011
0 ... 010
End-Point Lin. Error
0 ... 001
At Transition
001/010 (–1/4 LSB)
0 ... 000
0
1
2
3
4
5
6
7
Analog Input Value (LSB)
12
NOTE A: 1 LSB = (ADREFHI – ADREFLO)/2
Figure 7-8. Integral Nonlinearity (INL) Error
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MibADC Total Error
The absolute accuracy or total error of an MibADC as shown in Figure 7-9 is the maximum value of the
difference between an analog value and the ideal midstep value.
0 ... 111
0 ... 110
Digital Output Code
0 ... 101
0 ... 100
Total Error
At Step 0 ... 101
(–1 1/4 LSB)
0 ... 011
0 ... 010
Total Error
At Step
0 ... 001 (1/2 LSB)
0 ... 001
0 ... 000
0
1
2
3
4
5
6
7
Analog Input Value (LSB)
12
NOTE A: 1 LSB = (ADREFHI – ADREFLO)/2
Figure 7-9. Absolute Accuracy (Total) Error
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7.5
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
General-Purpose Input/Output
The GPIO module on this device supports two ports, GIOA and GIOB. The I/O pins are bidirectional and
bit-programmable. Both GIOA and GIOB support external interrupt capability.
7.5.1
Features
The GPIO module has the following features:
• Each IO pin can be configured as:
– Input
– Output
– Open Drain
• The interrupts have the following characteristics:
– Programmable interrupt detection either on both edges or on a single edge (set in GIOINTDET)
– Programmable edge-detection polarity, either rising or falling edge (set in GIOPOL register)
– Individual interrupt flags (set in GIOFLG register)
– Individual interrupt enables, set and cleared through GIOENASET and GIOENACLR registers
respectively
– Programmable interrupt priority, set through GIOLVLSET and GIOLVLCLR registers
• Internal pullup/pulldown allows unused I/O pins to be left unconnected
For information on input and output timings see Section 5.11 and Section 5.12
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Enhanced High-End Timer (N2HET)
The N2HET is an advanced intelligent timer that provides sophisticated timing functions for real-time
applications. The timer is software-controlled, using a reduced instruction set, with a specialized timer
micromachine and an attached I/O port. The N2HET can be used for pulse width modulated outputs,
capture or compare inputs, or general-purpose I/O. It is especially well suited for applications requiring
multiple sensor information and drive actuators with complex and accurate time pulses.
7.6.1
Features
The N2HET module has the following features:
• Programmable timer for input and output timing functions
• Reduced instruction set (30 instructions) for dedicated time and angle functions
• 160 words of instruction RAM protected by parity
• User defined number of 25-bit virtual counters for timer, event counters and angle counters
• 7-bit hardware counters for each pin allow up to 32-bit resolution in conjunction with the 25-bit virtual
counters
• Up to 32 pins usable for input signal measurements or output signal generation
• Programmable suppression filter for each input pin with adjustable limiting frequency
• Low CPU overhead and interrupt load
• Efficient data transfer to or from the CPU memory with dedicated High-End-Timer Transfer Unit (HTU)
or DMA
• Diagnostic capabilities with different loopback mechanisms and pin status read back functionality
7.6.2
N2HET RAM Organization
The timer RAM uses 4 RAM banks, where each bank has two port access capability. This means that one
RAM address may be written while another address is read. The RAM words are 96-bits wide, which are
split into three 32-bit fields (program, control, and data).
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Input Timing Specifications
All of the N2HET channels have an enhanced pulse capture circuit. The N2HET instructions PCNT and
WCAP use this circuit to achieve the input timing requirements shown in Figure 7-10 and Table 7-23
below.
1
N2HETx
3
4
2
Figure 7-10. N2HET Input Capture Timings
Table 7-23. Input Timing Requirements for N2HET Channels with Enhanced Pulse Capture
PARAMETER
1, 2
MIN
25
MAX
UNIT
Input signal period, PCNT or WCAP
(HRP) (LRP) tc(VCLK2) + 2
2
(HRP) (LRP) tc(VCLK2) - 2
ns
3
Input signal high phase, PCNT or WCAP
2 (HRP) tc(VCLK2) + 2
225 (HRP) (LRP) tc(VCLK2) - 2
ns
4
Input signal low phase, PCNT or WCAP
2 (HRP) tc(VCLK2) + 2
225 (HRP) (LRP) tc(VCLK2) - 2
ns
7.6.4
N2HET1-N2HET2 Synchronization
In some applications the N2HET resolutions must be synchronized. Some other applications require a
single time base to be used for all PWM outputs and input timing captures.
The N2HET provides such a synchronization mechanism. The Clk_master/slave (HETGCR.16) configures
the N2HET in master or slave mode (default is slave mode). A N2HET in master mode provides a signal
to synchronize the prescalers of the slave N2HET. The slave N2HET synchronizes its loop resolution to
the loop resolution signal sent by the master. The slave does not require this signal after it receives the
first synchronization signal. However, anytime the slave receives the re-synchronization signal from the
master, the slave must synchronize itself again..
N2HET1
N2HET2
EXT_LOOP_SYNC
NHET_LOOP_SYNC
NHET_LOOP_SYNC
EXT_LOOP_SYNC
Figure 7-11. N2HET1 – N2HET2 Synchronization Hookup
7.6.5
N2HET Checking
7.6.5.1
Internal Monitoring
To assure correctness of the high-end timer operation and output signals, the two N2HET modules can be
used to monitor each other’s signals as shown in Figure 7-12. The direction of the monitoring is controlled
by the I/O multiplexing control module.
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N2HET1[1,3,5,7,9,11]
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IOMM mux control signal x
N2HET1[1,3,5,7,9,11] / N2HET2[8,10,12,14,16,18]
N2HET1
N2HET2[8,10,12,14,16,18]
N2HET2
Figure 7-12. N2HET Monitoring
7.6.5.2
Output Monitoring using Dual Clock Comparator (DCC)
N2HET1[31] is connected as a clock source for counter 1 in DCC1. This allows the application to measure
the frequency of the pulse-width modulated (PWM) signal on N2HET1[31].
Similarly, N2HET2[0] is connected as a clock source for counter 1 in DCC2. This allows the application to
measure the frequency of the pulse-width modulated (PWM) signal on N2HET2[0].
Both N2HET1[31] and N2HET2[0] can be configured to be internal-only channels. That is, the connection
to the DCC module is made directly from the output of the N2HETx module (from the input of the output
buffer).
For more information on DCC see Section 6.7.3.
7.6.6
Disabling N2HET Outputs
Some applications require the N2HET outputs to be disabled under some fault condition. The N2HET
module provides this capability through the "Pin Disable" input signal. This signal, when driven low,
causes the N2HET outputs identified by a programmable register (HETPINDIS) to be tri-stated. For more
details on the "N2HET Pin Disable" feature, see the device-specific Terminal Reference Manual.
GIOA[5] is connected to the "Pin Disable" input for N2HET1, and GIOB[2] is connected to the "Pin
Disable" input for N2HET2.
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
High-End Timer Transfer Unit (HTU)
A High End Timer Transfer Unit (HTU) can perform DMA type transactions to transfer N2HET data to or
from main memory. A Memory Protection Unit (MPU) is built into the HTU.
7.6.7.1
•
•
•
•
•
•
•
•
•
7.6.7.2
Features
CPU and DMA independent
Master Port to access system memory
8 control packets supporting dual buffer configuration
Control packet information is stored in RAM protected by parity
Event synchronization (HET transfer requests)
Supports 32 or 64 bit transactions
Addressing modes for HET address (8 byte or 16 byte) and system memory address (fixed, 32 bit or 64bit)
One shot, circular and auto switch buffer transfer modes
Request lost detection
Trigger Connections
Table 7-24. HTU1 Request Line Connection
Modules
Request Source
HTU1 Request
N2HET1
HTUREQ[0]
HTU1 DCP[0]
N2HET1
HTUREQ[1]
HTU1 DCP[1]
N2HET1
HTUREQ[2]
HTU1 DCP[2]
N2HET1
HTUREQ[3]
HTU1 DCP[3]
N2HET1
HTUREQ[4]
HTU1 DCP[4]
N2HET1
HTUREQ[5]
HTU1 DCP[5]
N2HET1
HTUREQ[6]
HTU1 DCP[6]
N2HET1
HTUREQ[7]
HTU1 DCP[7]
Table 7-25. HET TU2 Request Line Connection
Modules
Request Source
HET TU2 Request
N2HET2
HTUREQ[0]
HTU2 DCP[0]
N2HET2
HTUREQ[1]
HTU2 DCP[1]
N2HET2
HTUREQ[2]
HTU2 DCP[2]
N2HET2
HTUREQ[3]
HTU2 DCP[3]
N2HET2
HTUREQ[4]
HTU2 DCP[4]
N2HET2
HTUREQ[5]
HTU2 DCP[5]
N2HET2
HTUREQ[6]
HTU2 DCP[6]
N2HET2
HTUREQ[7]
HTU2 DCP[7]
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FlexRay Interface
The FlexRay module performs communication according to the FlexRay protocol specification v2.1. The
sample clock bitrate can be programmed to values up to 10 MBit per second. Additional bus driver (BD)
hardware is required for connection to the physical layer.
For communication on a FlexRay network, individual message buffers with up to 254 data bytes are
configurable. The message storage consists of a single-ported message RAM that holds up to 128
message buffers. All functions concerning the handling of messages are implemented in the message
handler. Those functions are the acceptance filtering, the transfer of messages between the two FlexRay
Channel Protocol Controllers and the message RAM, maintaining the transmission schedule as well as
providing message status information.
The register set of the FlexRay module can be accessed directly by the CPU via the VBUS interface.
These registers are used to control, configure and monitor the FlexRay channel protocol controllers,
message handler, global time unit, system universal control, frame/symbol processing, network
management, interrupt control, and to access the message RAM via the input / output buffer.
7.7.1
Features
The FlexRay module has the following features:
• Conformance with FlexRay protocol specification v2.1
• Data rates of up to 10 Mbit/s on each channel
• Up to 128 message buffers
• 8 Kbyte of message RAM for storage of, for example, 128 message buffers with a maximum 48 byte
data section or up to 30 message buffers with 254 byte data section
• Configuration of message buffers with different payload lengths
• One configurable receive FIFO
• Each message buffer can be configured as receive buffer, as transmit buffer or as part of the receive
FIFO
• CPU access to message buffers via input and output buffer
• FlexRay Transfer Unit (FTU) for automatic data transfer between data memory and message buffers
without CPU interaction
• Filtering for slot counter, cycle counter, and channel ID
• Maskable module interrupts
• Supports Network Management
7.7.2
Electrical and Timing Specifications
Table 7-26. Timing Requirements for FlexRay Inputs
Parameter
tpw
(1)
MIN
Input minimum pulse width to meet the FlexRay sampling
requirement
tc(VCLKA2) + 2.5 (1)
MAX
UNIT
ns
tRxAsymDelay parameter
t pw
Input
0.6*V CCIO
0.6*V CCIO
0.4*V CCIO
VCCIO
0.4*VCCIO
0
Figure 7-13. FlexRay Inputs
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Table 7-27. FlexRay Jitter Timing (1)
MIN
MAX
Unit
tTx1bit
Clock jitter and signal symmetry
Parameter
98
102
ns
tTx10bit
FlexRay BSS (byte start sequence) to BSS
999
1001
ns
tTx10bitAvg
Average over 10000 samples
999.5
1000.5
ns
Delay difference between rise and fall from Rx pin to sample
point in FlexRay core
–
2.5
ns
Jitter for the 80MHz Sample Clock generated by the PLL
–
0.5
ns
tRxAsymDelay
tjit(SCLK)
(1)
(2)
(2)
This parameter will be characterized, but not production-tested.
This value is based on design simulation.
7.7.3
FlexRay Transfer Unit
The FlexRay Transfer Unit is able to transfer data between the input buffer (IBF) and output buffer (OBF)
of the communication controller and the system memory without CPU interaction.
Because the FlexRay module is accessed through the FTU, the FTU must be powered up by the setting
bit 23 in the Peripheral Power Down Registers of the System Module before accessing any FlexRay
module register.
For more information on the FTU refer to the TMS570LS12x/11x Technical Reference Manual
(SPNU515).
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Controller Area Network (DCAN)
The DCAN supports the CAN 2.0B protocol standard and uses a serial, multimaster communication
protocol that efficiently supports distributed real-time control with robust communication rates of up to 1
megabit per second (Mbps). The DCAN is ideal for applications operating in noisy and harsh
environments (for example, automotive and industrial fields) that require reliable serial communication or
multiplexed wiring.
7.8.1
Features
Features of the DCAN module include:
• Supports CAN protocol version 2.0 part A, B
• Bit rates up to 1 MBit/s
• The CAN kernel can be clocked by the oscillator for baud-rate generation.
• 64 mailboxes on each DCAN
• Individual identifier mask for each message object
• Programmable FIFO mode for message objects
• Programmable loop-back modes for self-test operation
• Automatic bus on after Bus-Off state by a programmable 32-bit timer
• Message RAM protected by parity
• Direct access to Message RAM during test mode
• CAN Rx / Tx pins configurable as general purpose IO pins
• Message RAM Auto Initialization
• DMA support
For more information on the DCAN see the TMS570LS12x/11x Technical Reference Manual (SPNU515).
7.8.2
Electrical and Timing Specifications
Table 7-28. Dynamic Characteristics for the DCANx TX and RX pins
MAX
Unit
td(CANnTX)
Delay time, transmit shift register to CANnTX pin (1)
Parameter
15
ns
td(CANnRX)
Delay time, CANnRX pin to receive shift register
5
ns
(1)
140
MIN
These values do not include rise/fall times of the output buffer.
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Local Interconnect Network Interface (LIN)
The SCI/LIN module can be programmed to work either as an SCI or as a LIN. The core of the module is
an SCI. The SCI’s hardware features are augmented to achieve LIN compatibility.
The SCI module is a universal asynchronous receiver-transmitter that implements the standard nonreturn
to zero format. The SCI can be used to communicate, for example, through an RS-232 port or over a Kline.
The LIN standard is based on the SCI (UART) serial data link format. The communication concept is
single-master/multiple-slave with a message identification for multi-cast transmission between any network
nodes.
7.9.1
LIN Features
The following are features of the LIN module:
• Compatible to LIN 1.3, 2.0 and 2.1 protocols
• Multibuffered receive and transmit units DMA capability for minimal CPU intervention
• Identification masks for message filtering
• Automatic Master Header Generation
– Programmable Synch Break Field
– Synch Field
– Identifier Field
• Slave Automatic Synchronization
– Synch break detection
– Optional baudrate update
– Synchronization Validation
• 231 programmable transmission rates with 7 fractional bits
• Error detection
• 2 Interrupt lines with priority encoding
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7.10 Serial Communication Interface (SCI)
7.10.1 Features
•
•
•
•
•
•
•
•
•
•
•
142
Standard universal asynchronous receiver-transmitter (UART) communication
Supports full- or half-duplex operation
Standard nonreturn to zero (NRZ) format
Double-buffered receive and transmit functions
Configurable frame format of 3 to 13 bits per character based on the following:
– Data word length programmable from one to eight bits
– Additional address bit in address-bit mode
– Parity programmable for zero or one parity bit, odd or even parity
– Stop programmable for one or two stop bits
Asynchronous or isosynchronous communication modes
Two multiprocessor communication formats allow communication between more than two devices.
Sleep mode is available to free CPU resources during multiprocessor communication.
The 24-bit programmable baud rate supports 224 different baud rates provide high accuracy baud rate selection.
Four error flags and Five status flags provide detailed information regarding SCI events.
Capability to use DMA for transmit and receive data.
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7.11 Inter-Integrated Circuit (I2C)
The inter-integrated circuit (I2C) module is a multi-master communication module providing an interface
between the RM4x microcontroller and devices compliant with Philips Semiconductor I2C-bus specification
version 2.1 and connected by an I2C-bus. This module will support any slave or master I2C compatible
device.
7.11.1 Features
The I2C has the following features:
• Compliance to the Philips I2C bus specification, v2.1 (The I2C Specification, Philips document number
9398 393 40011)
– Bit/Byte format transfer
– 7-bit and 10-bit device addressing modes
– General call
– START byte
– Multi-master transmitter/ slave receiver mode
– Multi-master receiver/ slave transmitter mode
– Combined master transmit/receive and receive/transmit mode
– Transfer rates of 10 kbps up to 400 kbps (Phillips fast-mode rate)
• Free data format
• Two DMA events (transmit and receive)
• DMA event enable/disable capability
• Seven interrupts that can be used by the CPU
• Module enable/disable capability
• The SDA and SCL are optionally configurable as general purpose I/O
• Slew rate control of the outputs
• Open drain control of the outputs
• Programmable pullup/pulldown capability on the inputs
• Supports Ignore NACK mode
NOTE
This I2C module does not support:
• High-speed (HS) mode
• C-bus compatibility mode
• The combined format in 10-bit address mode (the I2C sends the slave address second
byte every time it sends the slave address first byte)
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7.11.2 I2C I/O Timing Specifications
Table 7-29. I2C Signals (SDA and SCL) Switching Characteristics (1)
Parameter
Standard Mode
Fast Mode
Unit
MIN
MAX
MIN
MAX
75.2
149
75.2
149
ns
0
100
0
400
kHz
tc(I2CCLK)
Cycle time, Internal Module clock for I2C,
prescaled from VCLK
f(SCL)
SCL Clock frequency
tc(SCL)
Cycle time, SCL
10
2.5
µs
tsu(SCLH-SDAL)
Setup time, SCL high before SDA low (for a
repeated START condition)
4.7
0.6
µs
th(SCLL-SDAL)
Hold time, SCL low after SDA low (for a repeated
START condition)
4
0.6
µs
tw(SCLL)
Pulse duration, SCL low
4.7
1.3
µs
tw(SCLH)
Pulse duration, SCL high
4
0.6
µs
tsu(SDA-SCLH)
Setup time, SDA valid before SCL high
th(SDA-SCLL)
Hold time, SDA valid after SCL low (for I2C bus
devices)
tw(SDAH)
Pulse duration, SDA high between STOP and
START conditions
4.7
1.3
µs
tsu(SCLH-SDAH)
Setup time, SCL high before SDA high (for STOP
condition)
4.0
0.6
µs
tw(SP)
Pulse duration, spike (must be suppressed)
Cb (3)
Capacitive load for each bus line
(1)
(2)
(3)
250
100
3.45 (2)
0
ns
0
0.9
0
400
µs
50
ns
400
pF
The I2C pins SDA and SCL do not feature fail-safe I/O buffers. These pins could potentially draw current when the device is powered
down.
The maximum th(SDA-SCLL) for I2C bus devices has only to be met if the device does not stretch the low period (tw(SCLL)) of the SCL
signal.
Cb = The total capacitance of one bus line in pF.
SDA
tw(SDAH)
tsu(SDA-SCLH)
tw(SCLL)
tw(SP)
tsu(SCLH-SDAH)
tw(SCLH)
tr(SCL)
SCL
tc(SCL)
tf(SCL)
th(SCLL-SDAL)
th(SDA-SCLL)
tsu(SCLH-SDAL)
th(SCLL-SDAL)
Stop
Start
Repeated Start
Stop
Figure 7-14. I2C Timings
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NOTE
•
•
•
•
A device must internally provide a hold time of at least 300 ns for the SDA signal
(referred to the VIHmin of the SCL signal) to bridge the undefined region of the falling
edge of SCL.
The maximum th(SDA-SCLL) has only to be met if the device does not stretch the LOW
period (tw(SCLL)) of the SCL signal.
A Fast-mode I2C-bus device can be used in a Standard-mode I2C-bus system, but the
requirement tsu(SDA-SCLH) ≥ 250 ns must then be met. This will automatically be the case if
the device does not stretch the LOW period of the SCL signal. If such a device does
stretch the LOW period of the SCL signal, it must output the next data bit to the SDA line
tr max + tsu(SDA-SCLH).
Cb = total capacitance of one bus line in pF. If mixed with fast-mode devices, faster falltimes are allowed.
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7.12 Multibuffered / Standard Serial Peripheral Interface
The MibSPI is a high-speed synchronous serial input/output port that allows a serial bit stream of
programmed length (2 to 16 bits) to be shifted in and out of the device at a programmed bit-transfer rate.
Typical applications for the SPI include interfacing to external peripherals, such as I/Os, memories, display
drivers, and analog-to-digital converters.
7.12.1 Features
Both Standard and MibSPI modules have the following features:
• 16-bit shift register
• Receive buffer register
• 8-bit baud clock generator
• SPICLK can be internally-generated (master mode) or received from an external clock source (slave
mode)
• Each word transferred can have a unique format
• SPI I/Os not used in the communication can be used as digital input/output signals
Table 7-30. MibSPI/SPI Configurations PGE Package
MibSPIx/SPIx
I/Os
MibSPI1
MIBSPI1SIMO[1:0], MIBSPI1SOMI[1:0], MIBSPI1CLK, MIBSPI1nCS[5:4,2:0], MIBSPI1nENA
MibSPI3
MIBSPI3SIMO[0], MIBSPI3SOMI[0], MIBSPI3CLK, MIBSPI3nCS[5:0], MIBSPI3nENA
MibSPI5
MIBSPI5SIMO[0], MIBSPI5SOMI[2:0], MIBSPI5CLK, MIBSPI5nCS[0], MIBSPI5nENA
SPI4
SPI4SIMO[0], SPI4SOMI[0], SPI4CLK, SPI4nCS[0], SPI4nENA
Table 7-31. MibSPI/SPI Configurations ZWT Package
MibSPIx/SPIx
I/Os
MibSPI1
MIBSPI1SIMO[1:0], MIBSPI1SOMI[1:0], MIBSPI1CLK, MIBSPI1nCS[5:0], MIBSPI1nENA
MibSPI3
MIBSPI3SIMO[0], MIBSPI3SOMI[0], MIBSPI3CLK, MIBSPI3nCS[5:0], MIBSPI3nENA
MibSPI5
MIBSPI5SIMO[3:0], MIBSPI5SOMI[3:0], MIBSPI5CLK, MIBSPI5nCS[3:0], MIBSPI5nENA
SPI2
SPI2SIMO[0], SPI2SOMI[0], SPI2CLK, SPI2nCS[1:0], SPI2nENA
SPI4
SPI4SIMO[0], SPI4SOMI[0], SPI4CLK, SPI4nCS[0], SPI4nENA
7.12.2 MibSPI Transmit and Receive RAM Organization
The Multibuffer RAM is comprised of 128 buffers. Each entry in the Multibuffer RAM consists of 4 parts: a
16-bit transmit field, a 16-bit receive field, a 16-bit control field and a 16-bit status field. The Multibuffer
RAM can be partitioned into multiple transfer group with variable number of buffers each. Each MibSPIx
module supports 8 transfer groups.
7.12.3 MibSPI Transmit Trigger Events
Each of the transfer groups can be configured individually. For each of the transfer groups a trigger event
and a trigger source can be chosen. A trigger event can be for example a rising edge or a permanent low
level at a selectable trigger source. For example, up to 15 trigger sources are available for use by each
transfer group. These trigger options are listed in Table 7-32 and Section 7.12.3.2 for MibSPI1 and
MibSPi3 respectively.
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7.12.3.1 MIBSPI1 Event Trigger Hookup
Table 7-32. MIBSPI1 Event Trigger Hookup
Event #
TGxCTRL TRIGSRC[3:0]
Trigger
Disabled
0000
No trigger source
EVENT0
0001
GIOA[0]
EVENT1
0010
GIOA[1]
EVENT2
0011
GIOA[2]
EVENT3
0100
GIOA[3]
EVENT4
0101
GIOA[4]
EVENT5
0110
GIOA[5]
EVENT6
0111
GIOA[6]
EVENT7
1000
GIOA[7]
EVENT8
1001
N2HET1[8]
EVENT9
1010
N2HET1[10]
EVENT10
1011
N2HET1[12]
EVENT11
1100
N2HET1[14]
EVENT12
1101
N2HET1[16]
EVENT13
1110
N2HET1[18]
EVENT14
1111
Internal Tick counter
NOTE
For N2HET1 trigger sources, the connection to the MibSPI1 module trigger input is made
from the input side of the output buffer (at the N2HET1 module boundary). This way, a
trigger condition can be generated even if the N2HET1 signal is not selected to be output on
the pad.
NOTE
For GIOx trigger sources, the connection to the MibSPI1 module trigger input is made from
the output side of the input buffer. This way, a trigger condition can be generated either by
selecting the GIOx pin as an output pin and selecting the pin to be a GIOx pin, or by driving
the GIOx pin from an external trigger source. If the mux control module is used to select
different functionality instead of the GIOx signal, then care must be taken to disable GIOx
from triggering MibSPI1 transfers; there is no multiplexing on the input connections.
7.12.3.2 MIBSPI3 Event Trigger Hookup
Table 7-33. MIBSPI3 Event Trigger Hookup
Event #
TGxCTRL TRIGSRC[3:0]
Trigger
Disabled
0000
No trigger source
EVENT0
0001
GIOA[0]
EVENT1
0010
GIOA[1]
EVENT2
0011
GIOA[2]
EVENT3
0100
GIOA[3]
EVENT4
0101
GIOA[4]
EVENT5
0110
GIOA[5]
EVENT6
0111
GIOA[6]
EVENT7
1000
GIOA[7]
EVENT8
1001
N2HET1[8]
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Table 7-33. MIBSPI3 Event Trigger Hookup (continued)
Event #
TGxCTRL TRIGSRC[3:0]
Trigger
EVENT9
1010
N2HET1[10]
EVENT10
1011
N2HET1[12]
EVENT11
1100
N2HET1[14]
EVENT12
1101
N2HET1[16]
EVENT13
1110
N2HET1[18]
EVENT14
1111
Internal Tick counter
NOTE
For N2HET1 trigger sources, the connection to the MibSPI3 module trigger input is made
from the input side of the output buffer (at the N2HET1 module boundary). This way, a
trigger condition can be generated even if the N2HET1 signal is not selected to be output on
the pad.
NOTE
For GIOx trigger sources, the connection to the MibSPI3 module trigger input is made from
the output side of the input buffer. This way, a trigger condition can be generated either by
selecting the GIOx pin as an output pin and selecting the pin to be a GIOx pin, or by driving
the GIOx pin from an external trigger source. If the mux control module is used to select
different functionality instead of the GIOx signal, then care must be taken to disable GIOx
from triggering MibSPI3 transfers; there is no multiplexing on the input connections.
7.12.3.3 MIBSPI5 Event Trigger Hookup
Table 7-34. MIBSPI5 Event Trigger Hookup
Event #
TGxCTRL TRIGSRC[3:0]
Trigger
Disabled
0000
No trigger source
EVENT0
0001
GIOA[0]
EVENT1
0010
GIOA[1]
EVENT2
0011
GIOA[2]
EVENT3
0100
GIOA[3]
EVENT4
0101
GIOA[4]
EVENT5
0110
GIOA[5]
EVENT6
0111
GIOA[6]
EVENT7
1000
GIOA[7]
EVENT8
1001
N2HET1[8]
EVENT9
1010
N2HET1[10]
EVENT10
1011
N2HET1[12]
EVENT11
1100
N2HET1[14]
EVENT12
1101
N2HET1[16]
EVENT13
1110
N2HET1[18]
EVENT14
1111
Internal Tick counter
NOTE
For N2HET1 trigger sources, the connection to the MibSPI5 module trigger input is made
from the input side of the output buffer (at the N2HET1 module boundary). This way, a
trigger condition can be generated even if the N2HET1 signal is not selected to be output on
the pad.
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NOTE
For GIOx trigger sources, the connection to the MibSPI5 module trigger input is made from
the output side of the input buffer. This way, a trigger condition can be generated either by
selecting the GIOx pin as an output pin and selecting the pin to be a GIOx pin, or by driving
the GIOx pin from an external trigger source. If the mux control module is used to select
different functionality instead of the GIOx signal, then care must be taken to disable GIOx
from triggering MibSPI5 transfers; there is no multiplexing on the input connections.
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7.12.4 MibSPI/SPI Master Mode I/O Timing Specifications
Table 7-35. SPI Master Mode External Timing Parameters (CLOCK PHASE = 0, SPICLK = output, SPISIMO
= output, and SPISOMI = input) (1) (2) (3)
NO.
1
2 (5)
3 (5)
4 (5)
5 (5)
6 (5)
7 (5)
8 (6)
9 (6)
Parameter
MIN
MAX
Unit
40
256tc(VCLK)
ns
Pulse duration, SPICLK high (clock
polarity = 0)
0.5tc(SPC)M – tr(SPC)M – 3
0.5tc(SPC)M + 3
ns
tw(SPCL)M
Pulse duration, SPICLK low (clock
polarity = 1)
0.5tc(SPC)M – tf(SPC)M – 3
0.5tc(SPC)M + 3
tw(SPCL)M
Pulse duration, SPICLK low (clock
polarity = 0)
0.5tc(SPC)M – tf(SPC)M – 3
0.5tc(SPC)M + 3
tw(SPCH)M
Pulse duration, SPICLK high (clock
polarity = 1)
0.5tc(SPC)M – tr(SPC)M – 3
0.5tc(SPC)M + 3
td(SPCH-SIMO)M
Delay time, SPISIMO valid before
SPICLK low (clock polarity = 0)
0.5tc(SPC)M – 6
td(SPCL-SIMO)M
Delay time, SPISIMO valid before
SPICLK high (clock polarity = 1)
0.5tc(SPC)M – 6
tv(SPCL-SIMO)M
Valid time, SPISIMO data valid after
SPICLK low (clock polarity = 0)
0.5tc(SPC)M – tf(SPC) – 4
tv(SPCH-SIMO)M
Valid time, SPISIMO data valid after
SPICLK high (clock polarity = 1)
0.5tc(SPC)M – tr(SPC) – 4
tsu(SOMI-SPCL)M
Setup time, SPISOMI before SPICLK
low (clock polarity = 0)
tf(SPC) + 2.2
tsu(SOMI-SPCH)M Setup time, SPISOMI before SPICLK
high (clock polarity = 1)
tr(SPC) + 2.2
tc(SPC)M
Cycle time, SPICLK (4)
tw(SPCH)M
ns
10
th(SPCH-SOMI)M
Hold time, SPISOMI data valid after
SPICLK high (clock polarity = 1)
10
tC2TDELAY
Setup time CS active
until SPICLK high
(clock polarity = 0)
CSHOLD = 0
C2TDELAY*tc(VCLK) + 2*tc(VCLK)
- tf(SPICS) + tr(SPC) – 7
(C2TDELAY+2) * tc(VCLK) tf(SPICS) + tr(SPC) + 5.5
CSHOLD = 1
C2TDELAY*tc(VCLK) + 3*tc(VCLK)
- tf(SPICS) + tr(SPC) – 7
(C2TDELAY+3) * tc(VCLK) tf(SPICS) + tr(SPC) + 5.5
Setup time CS active
until SPICLK low
(clock polarity = 1)
CSHOLD = 0
C2TDELAY*tc(VCLK) + 2*tc(VCLK)
- tf(SPICS) + tf(SPC) – 7
(C2TDELAY+2) * tc(VCLK) tf(SPICS) + tf(SPC) + 5.5
CSHOLD = 1
C2TDELAY*tc(VCLK) + 3*tc(VCLK)
- tf(SPICS) + tf(SPC) – 7
(C2TDELAY+3) * tc(VCLK) tf(SPICS) + tf(SPC) + 5.5
Hold time SPICLK low until CS inactive
(clock polarity = 0)
0.5*tc(SPC)M +
T2CDELAY*tc(VCLK) + tc(VCLK) tf(SPC) + tr(SPICS) - 7
0.5*tc(SPC)M +
T2CDELAY*tc(VCLK) + tc(VCLK) tf(SPC) + tr(SPICS) + 11
ns
Hold time SPICLK high until CS
inactive (clock polarity = 1)
0.5*tc(SPC)M +
T2CDELAY*tc(VCLK) + tc(VCLK) tr(SPC) + tr(SPICS) - 7
0.5*tc(SPC)M +
T2CDELAY*tc(VCLK) + tc(VCLK) tr(SPC) + tr(SPICS) + 11
ns
(C2TDELAY+1) * tc(VCLK) tf(SPICS) – 29
(C2TDELAY+1)*tc(VCLK)
ns
(C2TDELAY+2)*tc(VCLK)
ns
tT2CDELAY
SPIENAn Sample point
11
tSPIENAW
SPIENAn Sample point from write to
buffer
150
ns
Hold time, SPISOMI data valid after
SPICLK low (clock polarity = 0)
tSPIENA
(5)
(6)
ns
th(SPCL-SOMI)M
10
(1)
(2)
(3)
(4)
ns
ns
ns
ns
The MASTER bit (SPIGCR1.0) is set and the CLOCK PHASE bit (SPIFMTx.16) is cleared.
tc(VCLK) = interface clock cycle time = 1 / f(VCLK)
For rise and fall timings, see Table 5-8.
When the SPI is in Master mode, the following must be true:
For PS values from 1 to 255: tc(SPC)M ≥ (PS +1)tc(VCLK) ≥ 40ns, where PS is the prescale value set in the SPIFMTx.[15:8] register bits.
For PS values of 0: tc(SPC)M = 2tc(VCLK) ≥ 40ns.
The external load on the SPICLK pin must be less than 60pF.
The active edge of the SPICLK signal referenced is controlled by the CLOCK POLARITY bit (SPIFMTx.17).
C2TDELAY and T2CDELAY is programmed in the SPIDELAY register
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1
SPICLK
(clock polarity = 0)
2
3
SPICLK
(clock polarity = 1)
4
SPISIMO
5
Master Out Data Is Valid
6
7
Master In Data
Must Be Valid
SPISOMI
Figure 7-15. SPI Master Mode External Timing (CLOCK PHASE = 0)
Write to buffer
SPICLK
(clock polarity=0)
SPICLK
(clock polarity=1)
SPISIMO
Master Out Data Is Valid
8
9
SPICSn
10
11
SPIENAn
Figure 7-16. SPI Master Mode Chip Select Timing (CLOCK PHASE = 0)
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Table 7-36. SPI Master Mode External Timing Parameters (CLOCK PHASE = 1, SPICLK = output, SPISIMO
= output, and SPISOMI = input) (1) (2) (3)
NO.
Parameter
MIN
MAX
Unit
40
256tc(VCLK)
ns
Pulse duration, SPICLK high (clock
polarity = 0)
0.5tc(SPC)M – tr(SPC)M – 3
0.5tc(SPC)M + 3
ns
tw(SPCL)M
Pulse duration, SPICLK low (clock
polarity = 1)
0.5tc(SPC)M – tf(SPC)M – 3
0.5tc(SPC)M + 3
tw(SPCL)M
Pulse duration, SPICLK low (clock
polarity = 0)
0.5tc(SPC)M – tf(SPC)M – 3
0.5tc(SPC)M + 3
tw(SPCH)M
Pulse duration, SPICLK high (clock
polarity = 1)
0.5tc(SPC)M – tr(SPC)M – 3
0.5tc(SPC)M + 3
tv(SIMO-SPCH)M
Valid time, SPICLK high after
SPISIMO data valid (clock polarity =
0)
0.5tc(SPC)M – 6
tv(SIMO-SPCL)M
Valid time, SPICLK low after
SPISIMO data valid (clock polarity =
1)
0.5tc(SPC)M – 6
tv(SPCH-SIMO)M
Valid time, SPISIMO data valid after
SPICLK high (clock polarity = 0)
0.5tc(SPC)M – tr(SPC) – 4
tv(SPCL-SIMO)M
Valid time, SPISIMO data valid after
SPICLK low (clock polarity = 1)
0.5tc(SPC)M – tf(SPC) – 4
tsu(SOMI-SPCH)M
Setup time, SPISOMI before
SPICLK high (clock polarity = 0)
tr(SPC) + 2.2
tsu(SOMI-SPCL)M
Setup time, SPISOMI before
SPICLK low (clock polarity = 1)
tf(SPC) + 2.2
tv(SPCH-SOMI)M
Valid time, SPISOMI data valid after
SPICLK high (clock polarity = 0)
10
tv(SPCL-SOMI)M
Valid time, SPISOMI data valid after
SPICLK low (clock polarity = 1)
10
tC2TDELAY
Setup time CS
CSHOLD = 0
active until SPICLK
high (clock polarity =
0)
CSHOLD = 1
0.5*tc(SPC)M +
(C2TDELAY+2) * tc(VCLK) tf(SPICS) + tr(SPC) – 7
0.5*tc(SPC)M +
(C2TDELAY+2) * tc(VCLK) tf(SPICS) + tr(SPC) + 5.5
0.5*tc(SPC)M +
(C2TDELAY+3) * tc(VCLK) tf(SPICS) + tr(SPC) – 7
0.5*tc(SPC)M +
(C2TDELAY+3) * tc(VCLK) tf(SPICS) + tr(SPC) + 5.5
Setup time CS
active until SPICLK
low (clock polarity =
1)
CSHOLD = 0
0.5*tc(SPC)M +
(C2TDELAY+2) * tc(VCLK) tf(SPICS) + tf(SPC) – 7
0.5*tc(SPC)M +
(C2TDELAY+2) * tc(VCLK) tf(SPICS) + tf(SPC) + 5.5
CSHOLD = 1
0.5*tc(SPC)M +
(C2TDELAY+3) * tc(VCLK) tf(SPICS) + tf(SPC) – 7
0.5*tc(SPC)M +
(C2TDELAY+3) * tc(VCLK) tf(SPICS) + tf(SPC) + 5.5
Hold time SPICLK low until CS
inactive (clock polarity = 0)
T2CDELAY*tc(VCLK) +
tc(VCLK) - tf(SPC) + tr(SPICS) 7
T2CDELAY*tc(VCLK) +
tc(VCLK) - tf(SPC) + tr(SPICS) +
11
ns
Hold time SPICLK high until CS
inactive (clock polarity = 1)
T2CDELAY*tc(VCLK) +
tc(VCLK) - tr(SPC) + tr(SPICS) 7
T2CDELAY*tc(VCLK) +
tc(VCLK) - tr(SPC) + tr(SPICS) +
11
ns
(C2TDELAY+1)* tc(VCLK) tf(SPICS) – 29
(C2TDELAY+1)*tc(VCLK)
ns
(C2TDELAY+2)*tc(VCLK)
ns
1
tc(SPC)M
Cycle time, SPICLK
(5)
tw(SPCH)M
2
3 (5)
4 (5)
5 (5)
6 (5)
7 (5)
8 (6)
9 (6)
tT2CDELAY
(4)
10
tSPIENA
SPIENAn Sample Point
11
tSPIENAW
SPIENAn Sample point from write to
buffer
(1)
(2)
(3)
(4)
(5)
(6)
152
ns
ns
ns
ns
ns
ns
ns
The MASTER bit (SPIGCR1.0) is set and the CLOCK PHASE bit (SPIFMTx.16) is set.
tc(VCLK) = interface clock cycle time = 1 / f(VCLK)
For rise and fall timings, see the Table 5-8.
When the SPI is in Master mode, the following must be true:
For PS values from 1 to 255: tc(SPC)M ≥ (PS +1)tc(VCLK) ≥ 40ns, where PS is the prescale value set in the SPIFMTx.[15:8] register bits.
For PS values of 0: tc(SPC)M = 2tc(VCLK) ≥ 40ns.
The external load on the SPICLK pin must be less than 60pF.
The active edge of the SPICLK signal referenced is controlled by the CLOCK POLARITY bit (SPIFMTx.17).
C2TDELAY and T2CDELAY is programmed in the SPIDELAY register
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1
SPICLK
(clock polarity = 0)
2
3
SPICLK
(clock polarity = 1)
5
4
Master Out Data Is Valid
SPISIMO
6
Data Valid
7
Master In Data
Must Be Valid
SPISOMI
Figure 7-17. SPI Master Mode External Timing (CLOCK PHASE = 1)
Write to buffer
SPICLK
(clock polarity=0)
SPICLK
(clock polarity=1)
SPISIMO
Master Out Data Is Valid
8
9
SPICSn
10
11
SPIENAn
Figure 7-18. SPI Master Mode Chip Select Timing (CLOCK PHASE = 1)
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7.12.5 SPI Slave Mode I/O Timings
Table 7-37. SPI Slave Mode External Timing Parameters (CLOCK PHASE = 0, SPICLK = input, SPISIMO =
input, and SPISOMI = output) (1) (2) (3) (4)
NO.
1
2 (6)
3 (6)
4 (6)
5 (6)
6 (6)
7 (6)
8
9
(1)
(2)
(3)
(4)
(5)
(6)
154
Parameter
MIN
MAX
Unit
tc(SPC)S
Cycle time, SPICLK (5)
40
ns
tw(SPCH)S
Pulse duration, SPICLK high (clock polarity = 0)
14
ns
tw(SPCL)S
Pulse duration, SPICLK low (clock polarity = 1)
14
tw(SPCL)S
Pulse duration, SPICLK low (clock polarity = 0)
14
tw(SPCH)S
Pulse duration, SPICLK high (clock polarity = 1)
14
td(SPCH-SOMI)S
Delay time, SPISOMI valid after SPICLK high (clock
polarity = 0)
trf(SOMI) + 20
td(SPCL-SOMI)S
Delay time, SPISOMI valid after SPICLK low (clock polarity
= 1)
trf(SOMI) + 20
th(SPCH-SOMI)S
Hold time, SPISOMI data valid after SPICLK high (clock
polarity =0)
2
th(SPCL-SOMI)S
Hold time, SPISOMI data valid after SPICLK low (clock
polarity =1)
2
tsu(SIMO-SPCL)S
Setup time, SPISIMO before SPICLK low (clock polarity =
0)
4
tsu(SIMO-SPCH)S
Setup time, SPISIMO before SPICLK high (clock polarity =
1)
4
th(SPCL-SIMO)S
Hold time, SPISIMO data valid after SPICLK low (clock
polarity = 0)
2
th(SPCH-SIMO)S
Hold time, SPISIMO data valid after S PICLK high (clock
polarity = 1)
2
td(SPCL-SENAH)S
Delay time, SPIENAn high after last SPICLK low (clock
polarity = 0)
1.5tc(VCLK)
2.5tc(VCLK)+tr(ENAn)+
22
td(SPCH-SENAH)S
Delay time, SPIENAn high after last SPICLK high (clock
polarity = 1)
1.5tc(VCLK)
2.5tc(VCLK)+ tr(ENAn) +
22
td(SCSL-SENAL)S
Delay time, SPIENAn low after SPICSn low (if new data
has been written to the SPI buffer)
tf(ENAn)
tc(VCLK)+tf(ENAn)+27
ns
ns
ns
ns
ns
ns
ns
The MASTER bit (SPIGCR1.0) is cleared and the CLOCK PHASE bit (SPIFMTx.16) is cleared.
If the SPI is in slave mode, the following must be true: tc(SPC)S ≥ (PS + 1) tc(VCLK), where PS = prescale value set in SPIFMTx.[15:8].
For rise and fall timings, see Table 5-8.
tc(VCLK) = interface clock cycle time = 1 /f(VCLK)
When the SPI is in Slave mode, the following must be true:
For PS values from 1 to 255: tc(SPC)S ≥ (PS +1)tc(VCLK) ≥ 40ns, where PS is the prescale value set in the SPIFMTx.[15:8] register bits.
For PS values of 0: tc(SPC)S = 2tc(VCLK) ≥ 40ns.
The active edge of the SPICLK signal referenced is controlled by the CLOCK POLARITY bit (SPIFMTx.17).
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1
SPICLK
(clock polarity = 0)
2
3
SPICLK
(clock polarity = 1)
5
4
SPISOMI Data Is Valid
SPISOMI
6
7
SPISIMO Data
Must Be Valid
SPISIMO
Figure 7-19. SPI Slave Mode External Timing (CLOCK PHASE = 0)
SPICLK
(clock polarity=0)
SPICLK
(clock polarity=1)
8
SPIENAn
9
SPICSn
Figure 7-20. SPI Slave Mode Enable Timing (CLOCK PHASE = 0)
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Table 7-38. SPI Slave Mode External Timing Parameters (CLOCK PHASE = 1, SPICLK = input, SPISIMO =
input, and SPISOMI = output) (1) (2) (3) (4)
NO.
Parameter
MIN
MAX
Unit
1
tc(SPC)S
Cycle time, SPICLK (5)
40
ns
(6)
tw(SPCH)S
Pulse duration, SPICLK high (clock polarity = 0)
14
ns
tw(SPCL)S
Pulse duration, SPICLK low (clock polarity = 1)
14
tw(SPCL)S
Pulse duration, SPICLK low (clock polarity = 0)
14
tw(SPCH)S
Pulse duration, SPICLK high (clock polarity = 1)
14
td(SOMI-SPCL)S
Delay time, SPISOMI data valid after SPICLK low
(clock polarity = 0)
trf(SOMI) + 20
td(SOMI-SPCH)S
Delay time, SPISOMI data valid after SPICLK high
(clock polarity = 1)
trf(SOMI) + 20
th(SPCL-SOMI)S
Hold time, SPISOMI data valid after SPICLK high
(clock polarity =0)
2
th(SPCH-SOMI)S
Hold time, SPISOMI data valid after SPICLK low (clock
polarity =1)
2
tsu(SIMO-SPCH)S
Setup time, SPISIMO before SPICLK high (clock
polarity = 0)
4
tsu(SIMO-SPCL)S
Setup time, SPISIMO before SPICLK low (clock polarity
= 1)
4
tv(SPCH-SIMO)S
High time, SPISIMO data valid after SPICLK high
(clock polarity = 0)
2
tv(SPCL-SIMO)S
High time, SPISIMO data valid after SPICLK low (clock
polarity = 1)
2
2
3 (6)
4 (6)
5 (6)
6 (6)
7 (6)
8
ns
ns
ns
ns
ns
td(SPCH-SENAH)S Delay time, SPIENAn high after last SPICLK high
(clock polarity = 0)
1.5tc(VCLK)
2.5tc(VCLK)+tr(ENAn) + 22
td(SPCL-SENAH)S
Delay time, SPIENAn high after last SPICLK low (clock
polarity = 1)
1.5tc(VCLK)
2.5tc(VCLK)+tr(ENAn) + 22
9
td(SCSL-SENAL)S
Delay time, SPIENAn low after SPICSn low (if new data
has been written to the SPI buffer)
tf(ENAn)
tc(VCLK)+tf(ENAn)+ 27
ns
10
td(SCSL-SOMI)S
Delay time, SOMI valid after SPICSn low (if new data
has been written to the SPI buffer)
tc(VCLK)
2tc(VCLK)+trf(SOMI)+ 28
ns
(1)
(2)
(3)
(4)
(5)
(6)
156
ns
The MASTER bit (SPIGCR1.0) is cleared and the CLOCK PHASE bit (SPIFMTx.16) is set.
If the SPI is in slave mode, the following must be true: tc(SPC)S ≤ (PS + 1) tc(VCLK), where PS = prescale value set in SPIFMTx.[15:8].
For rise and fall timings, see Table 5-8.
tc(VCLK) = interface clock cycle time = 1 /f(VCLK)
When the SPI is in Slave mode, the following must be true:
For PS values from 1 to 255: tc(SPC)S ≥ (PS +1)tc(VCLK) ≥ 40ns, where PS is the prescale value set in the SPIFMTx.[15:8] register bits.
For PS values of 0: tc(SPC)S = 2tc(VCLK) ≥ 40ns.
The active edge of the SPICLK signal referenced is controlled by the CLOCK POLARITY bit (SPIFMTx.17).
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1
SPICLK
(clock polarity = 0)
2
3
SPICLK
(clock polarity = 1)
5
4
SPISOMI
SPISOMI Data Is Valid
6
7
SPISIMO Data
Must Be Valid
SPISIMO
Figure 7-21. SPI Slave Mode External Timing (CLOCK PHASE = 1)
SPICLK
(clock polarity=0)
SPICLK
(clock polarity=1)
8
SPIENAn
9
SPICSn
10
SPISOMI
Slave Out Data Is Valid
Figure 7-22. SPI Slave Mode Enable Timing (CLOCK PHASE = 1)
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8 Device and Documentation Support
8.1
Device and Development-Support Tool Nomenclature
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of
all devices and support tools. Each commercial family member has one of three prefixes: TMX, TMP,
or TMS (for example,TMS570LS1115). Texas Instruments recommends two of three possible prefix
designators for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages of
product development from engineering prototypes (TMX/TMDX) through fully qualified production
devices/tools (TMS/TMDS).
Device development evolutionary flow:
TMX
Experimental device that is not necessarily representative of the final device's electrical
specifications.
TMP
Final silicon die that conforms to the device's electrical specifications but has not completed
quality and reliability verification.
TMS
Fully-qualified production device.
TMX and TMP devices are shipped against the following disclaimer:
"Developmental product is intended for internal evaluation purposes."
TMS devices have been characterized fully, and the quality and reliability of the device have been
demonstrated fully. TI's standard warranty applies.
Predictions show that prototype devices (TMX or TMP) have a greater failure rate than the standard
production devices. Texas Instruments recommends that these devices not be used in any production
system because their expected end-use failure rate still is undefined. Only qualified production devices
are to be used.
The figure below illustrates the numbering and symbol nomenclature for the TMS570LS1115 .
158
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SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Full Part #
TMS
570
Orderable Part #
TMX
570
LS
11
1
5
B
ZWT
Q
Q1
R
11
1
5
B
ZWT
Q
Q1
R
Prefix: TM
TMS = Fully Qualified
TMP = Prototype
TMX = Samples
Core Technology:
570 = Cortex R4F
Architecture:
LS = Dual CPUs in Lockstep
(not included in orderable part #)
Flash Memory Size:
11 = 1MB
RAM MemorySize:
1 = 128kB
Peripheral Set:
5 = FlexRay
Die Revision:
A = Die Revision A
B = Die Revision B
Package Type:
ZWT = 337-Pin Plastic BGA with pb-free solder ball
PGE = 144 Pin Plastic Quad Flatpack
Temperature Range:
Q = -40...+125oC
Quality Designator:
Q1 = Automotive
Shipping Options:
R = Tape and Reel
Figure 8-1. TMS570LS1115 Device Numbering Conventions
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8.2
8.2.1
www.ti.com
Documentation Support
Related Documentation from Texas Instruments
The following documents describe the TMS570LS11x/12x microcontroller..
8.2.2
SPNU515
TMS570LS12x/11x 16/32-Bit RISC Flash Microcontroller Technical Reference Manual details the
integration, the environment, the functional description, and the programming models for each
peripheral and subsystem in the device.
SPNZ199
TMS570LS12x/11x Microcontroller, Silicon Revision B, Silicon Errata describes the usage notes
and known exceptions to the functional specifications for the device silicon revision B.
SPNZ218
TMS570LS12x/11x Microcontroller, Silicon Revision C, Silicon Errata describes the usage notes
and known exceptions to the functional specifications for the device silicon revision C.
Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the
respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views;
see TI's Terms of Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration among
engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help solve
problems with fellow engineers.
TI Embedded Processors Wiki Texas Instruments Embedded Processors Wiki. Established to help developers
get started with Embedded Processors from Texas Instruments and to foster innovation and growth of
general knowledge about the hardware and software surrounding these devices.
8.3
Trademarks
E2E is a trademark of Texas Instruments.
CoreSight is a trademark of ARM Limited.
ARM, Cortex are registered trademarks of ARM Limited (or its subsidiaries) in the EU and/or elsewhere.
All rights reserved.
All other trademarks are the property of their respective owners.
8.4
Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
8.5
Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
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8.6
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Device Identification
8.6.1
Device Identification Code Register
The device identification code register identifies several aspects of the device including the silicon version.
The details of the device identification code register are shown in Table 8-1. The device identification code
register value for this device is:
• Rev A = 0x8046AD05
• Rev B = 0x8046AD15
• Rev C = 0x8046AD1D
Figure 8-2. Device ID Bit Allocation Register
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
CP-15
UNIQUE ID
TECH
R-1
R-00000000100011
R-0
15
12
11
2
1
0
TECH
14
13
I/O
VOLT
AGE
PERIPH
PARITY
FLASH ECC
10
9
RAM
ECC
8
7
6
VERSION
5
4
3
1
0
1
R-101
R-0
R-1
R-10
R-1
R-00011
R-1
R-0
R-1
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 8-1. Device ID Bit Allocation Register Field Descriptions
Bit
Field
31
CP15
Value
Indicates the presence of coprocessor 15
1
30-17
UNIQUE ID
16-13
TECH
100011
11
10-9
I/O VOLTAGE
Unique device identification number
This bitfield holds a unique number for a dedicated device configuration (die).
PERIPHERAL
PARITY
F021
I/O voltage of the device.
0
I/O are 3.3v
1
Peripheral Parity
Parity on peripheral memories
FLASH ECC
Flash ECC
10
8
CP15 present
Process technology on which the device is manufactured.
0101
12
Description
RAM ECC
Program memory with ECC
Indicates if RAM memory ECC is present.
1
ECC implemented
7-3
REVISION
Revision of the Device.
2-0
101
The platform family ID is always 0b101
8.6.2
Die Identification Registers
The two die ID registers at addresses 0xFFFFFF7C and 0xFFFFFF80 form a 64-bit dieid with the
information as shown in Table 8-2.
Table 8-2. Die-ID Registers
Item
# of Bits
Bit Location
X Coordinate on Wafer
12
0xFFFFFF7C[11:0]
Y Coordinate on Wafer
12
0xFFFFFF7C[23:12]
Wafer #
8
0xFFFFFF7C[31:24]
Lot #
24
0xFFFFFF80[23:0]
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Table 8-2. Die-ID Registers (continued)
162
Item
# of Bits
Bit Location
Reserved
8
0xFFFFFF80[31:24]
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8.7
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
Module Certifications
The following communications modules have received certification of adherence to a standard.
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8.7.1
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FlexRay™ Certifications
Figure 8-3. Flexray Certification for ZWT Package
164
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Figure 8-4. Flexray Certification for PGE Package
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DCAN Certification
Figure 8-5. DCAN Certification
166
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8.7.3
8.7.3.1
SPNS189B – OCTOBER 2012 – REVISED FEBRUARY 2015
LIN Certification
LIN Master Mode
Figure 8-6. LIN Certification - Master Mode
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LIN Slave Mode - Fixed Baud Rate
Figure 8-7. LIN Certification - Slave Mode - Fixed Baud Rate
168
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LIN Slave Mode - Adaptive Baud Rate
Figure 8-8. LIN Certification - Slave Mode - Adaptive Baud Rate
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9 Mechanical Packaging and Orderable Information
9.1
Packaging Information
The following pages include mechanical packaging and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and
without revision of this document. For browser-based versions of this data sheet, refer to the left-hand
navigation.
170
Mechanical Packaging and Orderable Information
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PACKAGE OPTION ADDENDUM
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10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
(3)
Device Marking
(4/5)
(6)
TMS5701115CPGEQQ1
ACTIVE
LQFP
PGE
144
60
RoHS & Green
NIPDAU
Level-3-260C-168 HR
-40 to 125
TMS570LS
1115CPGEQQ1
TMS5701115CZWTQQ1
ACTIVE
NFBGA
ZWT
337
90
RoHS & Green
SNAGCU
Level-3-260C-168 HR
-40 to 125
TMS570LS
1115CZWTQQ1
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of