SPRUIZ1 User guide

SPRUIZ1B July 2023 – August 2024 TMS320F28P650DH , TMS320F28P650DK , TMS320F28P650SH , TMS320F28P650SK , TMS320F28P659DH-Q1 , TMS320F28P659DK-Q1 , TMS320F28P659SH-Q1

1
Read This First
1. About This Manual
2. Notational Conventions
3. Glossary
4. Related Documentation From Texas Instruments
5. Support Resources
6. Trademarks
1 C2000™ Microcontrollers Software Support
1. 1.1 Introduction
2. 1.2 C2000Ware Structure
3. 1.3 Documentation
4. 1.4 Devices
5. 1.5 Libraries
6. 1.6 Code Composer Studio™ Integrated Development Environment (IDE)
7. 1.7 SysConfig and PinMUX Tool
2 C28x Processor
1. 2.1 Introduction
2. 2.2 C28X Related Collateral
3. 2.3 Features
4. 2.4 Floating-Point Unit (FPU)
5. 2.5 Trigonometric Math Unit (TMU)
6. 2.6 VCRC Unit
3 C28x System Control and Interrupts
1. 3.1 C28x System Control Introduction
  1. 3.1.1 SYSCTL Related Collateral
2. 3.2 System Control Functional Description
  1. 3.2.1 Device Identification
3. 3.3 Resets
4. 3.4 Peripheral Interrupts
5. 3.5 Exceptions and Non-Maskable Interrupts
6. 3.6 Safety Features
7. 3.7 Clocking
8. 3.8 Clock Configuration Semaphore
9. 3.9 32-Bit CPU Timers 0/1/2
10. 3.10 Watchdog Timers
11. 3.11 Low-Power Modes
12. 3.12 Memory Controller Module
13. 3.13 JTAG
  1. 3.13.1 JTAG Noise and TAP_STATUS
14. 3.14 Live Firmware Update (LFU)
15. 3.15 System Control Register Configuration Restrictions
16. 3.16 MCU Configuration (MCUCNFx)
17. 3.17 Software
18. 3.18 System Control Registers
4 ROM Code and Peripheral Booting
1. 4.1 Introduction
  1. 4.1.1 ROM Related Collateral
2. 4.2 Device Boot Sequence
3. 4.3 Device Boot Modes
  1. 4.3.1 Default Boot Modes
  2. 4.3.2 Custom Boot Modes
4. 4.4 Device Boot Configurations
5. 4.5 Device Boot Flow Diagrams
6. 4.6 Device Reset and Exception Handling
  1. 4.6.1 Reset Causes and Handling
  2. 4.6.2 Exceptions and Interrupts Handling
7. 4.7 Boot ROM Description
8. 4.8 Application Notes for Using the Bootloaders
  1. 4.8.1 Bootloader Data Stream Structure
    1. 4.8.1.1 Data Stream Structure 8-bit
  2. 4.8.2 The C2000 Hex Utility
    1. 4.8.2.1 HEX2000.exe Command Syntax
9. 4.9 Software
  1. 4.9.1 BOOT Examples
5 Dual Code Security Module (DCSM)
1. 5.1 Introduction
  1. 5.1.1 DCSM Related Collateral
2. 5.2 Functional Description
3. 5.3 Flash and OTP Erase/Program
4. 5.4 Secure Copy Code
5. 5.5 SecureCRC
6. 5.6 CSM Impact on Other On-Chip Resources
  1. 5.6.1 RAMOPEN
7. 5.7 Incorporating Code Security in User Applications
8. 5.8 Software
  1. 5.8.1 DCSM Examples
    1. 5.8.1.1 Empty DCSM Tool Example
    2. 5.8.1.2 DCSM Memory partitioning Example
9. 5.9 DCSM Registers
6 Background CRC-32 (BGCRC)
1. 6.1 Introduction
2. 6.2 Functional Description
3. 6.3 Application of the BGCRC
4. 6.4 Software
  1. 6.4.1 BGCRC Examples
5. 6.5 BGCRC Registers
7 Control Law Accelerator (CLA)
1. 7.1 Introduction
2. 7.2 CLA Interface
3. 7.3 CLA, DMA, and CPU Arbitration
4. 7.4 CLA Configuration and Debug
5. 7.5 Pipeline
6. 7.6 Software
  1. 7.6.1 CLA Examples
7. 7.7 Instruction Set
  1. 7.7.1 Instruction Descriptions
  2. 7.7.2 Addressing Modes and Encoding
  3. 7.7.3 Instructions
    1. MABSF32 MRa, MRb
    2. MADD32 MRa, MRb, MRc
    3. MADDF32 MRa, #16FHi, MRb
    4. MADDF32 MRa, MRb, #16FHi
    5. MADDF32 MRa, MRb, MRc
    6. MADDF32 MRd, MRe, MRf||MMOV32 mem32, MRa
    7. MADDF32 MRd, MRe, MRf ||MMOV32 MRa, mem32
    8. MAND32 MRa, MRb, MRc
    9. MASR32 MRa, #SHIFT
    10. MBCNDD 16BitDest [, CNDF]
    11. MCCNDD 16BitDest [, CNDF]
    12. MCLRC BGINTM
    13. MCMP32 MRa, MRb
    14. MCMPF32 MRa, MRb
    15. MCMPF32 MRa, #16FHi
    16. MDEBUGSTOP
    17. MDEBUGSTOP1
    18. MEALLOW
    19. MEDIS
    20. MEINVF32 MRa, MRb
    21. MEISQRTF32 MRa, MRb
    22. MF32TOI16 MRa, MRb
    23. MF32TOI16R MRa, MRb
    24. MF32TOI32 MRa, MRb
    25. MF32TOUI16 MRa, MRb
    26. MF32TOUI16R MRa, MRb
    27. MF32TOUI32 MRa, MRb
    28. MFRACF32 MRa, MRb
    29. MI16TOF32 MRa, MRb
    30. MI16TOF32 MRa, mem16
    31. MI32TOF32 MRa, mem32
    32. MI32TOF32 MRa, MRb
    33. MLSL32 MRa, #SHIFT
    34. MLSR32 MRa, #SHIFT
    35. MMACF32 MR3, MR2, MRd, MRe, MRf ||MMOV32 MRa, mem32
    36. MMAXF32 MRa, MRb
    37. MMAXF32 MRa, #16FHi
    38. MMINF32 MRa, MRb
    39. MMINF32 MRa, #16FHi
    40. MMOV16 MARx, MRa, #16I
    41. MMOV16 MARx, mem16
    42. MMOV16 mem16, MARx
    43. MMOV16 mem16, MRa
    44. MMOV32 mem32, MRa
    45. MMOV32 mem32, MSTF
    46. MMOV32 MRa, mem32 [, CNDF]
    47. MMOV32 MRa, MRb [, CNDF]
    48. MMOV32 MSTF, mem32
    49. MMOVD32 MRa, mem32
    50. MMOVF32 MRa, #32F
    51. MMOVI16 MARx, #16I
    52. MMOVI32 MRa, #32FHex
    53. MMOVIZ MRa, #16FHi
    54. MMOVZ16 MRa, mem16
    55. MMOVXI MRa, #16FLoHex
    56. MMPYF32 MRa, MRb, MRc
    57. MMPYF32 MRa, #16FHi, MRb
    58. MMPYF32 MRa, MRb, #16FHi
    59. MMPYF32 MRa, MRb, MRc||MADDF32 MRd, MRe, MRf
    60. MMPYF32 MRd, MRe, MRf ||MMOV32 MRa, mem32
    61. MMPYF32 MRd, MRe, MRf ||MMOV32 mem32, MRa
    62. MMPYF32 MRa, MRb, MRc ||MSUBF32 MRd, MRe, MRf
    63. MNEGF32 MRa, MRb[, CNDF]
    64. MNOP
    65. MOR32 MRa, MRb, MRc
    66. MRCNDD [CNDF]
    67. MSETC BGINTM
    68. MSETFLG FLAG, VALUE
    69. MSTOP
    70. MSUB32 MRa, MRb, MRc
    71. MSUBF32 MRa, MRb, MRc
    72. MSUBF32 MRa, #16FHi, MRb
    73. MSUBF32 MRd, MRe, MRf ||MMOV32 MRa, mem32
    74. MSUBF32 MRd, MRe, MRf ||MMOV32 mem32, MRa
    75. MSWAPF MRa, MRb [, CNDF]
    76. MTESTTF CNDF
    77. MUI16TOF32 MRa, mem16
    78. MUI16TOF32 MRa, MRb
    79. MUI32TOF32 MRa, mem32
    80. MUI32TOF32 MRa, MRb
    81. MXOR32 MRa, MRb, MRc
8. 7.8 CLA Registers
8 Configurable Logic Block (CLB)
1. 8.1 Introduction
  1. 8.1.1 CLB Related Collateral
2. 8.2 Description
  1. 8.2.1 CLB Clock
3. 8.3 CLB Input/Output Connection
4. 8.4 CLB Tile
5. 8.5 CPU Interface
  1. 8.5.1 Register Description
  2. 8.5.2 Non-Memory Mapped Registers
6. 8.6 DMA Access
7. 8.7 CLB Data Export Through SPI RX Buffer
8. 8.8 CLB Pipeline Mode
9. 8.9 Software
  1. 8.9.1 CLB Examples
10. 8.10 CLB Registers
9 Dual-Clock Comparator (DCC)
1. 9.1 Introduction
  1. 9.1.1 Features
  2. 9.1.2 Block Diagram
2. 9.2 Module Operation
3. 9.3 Interrupts
4. 9.4 Software
  1. 9.4.1 DCC Examples
5. 9.5 DCC Registers
10Direct Memory Access (DMA)
1. 10.1 Introduction
  1. 10.1.1 Features
  2. 10.1.2 Block Diagram
2. 10.2 Architecture
  1. 10.2.1 Peripheral Interrupt Event Trigger Sources
  2. 10.2.2 DMA Bus
3. 10.3 Address Pointer and Transfer Control
4. 10.4 Pipeline Timing and Throughput
5. 10.5 CPU and CLA Arbitration
6. 10.6 Channel Priority
  1. 10.6.1 Round-Robin Mode
  2. 10.6.2 Channel 1 High-Priority Mode
7. 10.7 Overrun Detection Feature
8. 10.8 Software
  1. 10.8.1 DMA Examples
9. 10.9 DMA Registers
11External Memory Interface (EMIF)
1. 11.1 Introduction
2. 11.2 EMIF Module Architecture
3. 11.3 Example Configuration
  1. 11.3.1 Hardware Interface
  2. 11.3.2 Software Configuration
    1. 11.3.2.1 Configuring the SDRAM Interface
    2. 11.3.2.2 Configuring the Flash Interface
      1. 11.3.2.2.1 Asynchronous 1 Configuration Register (ASYNC_CS2_CFG) Settings for EMIF to LH28F800BJE-PTTL90 Interface
4. 11.4 Software
  1. 11.4.1 EMIF Examples
5. 11.5 EMIF Registers
12Flash Module
1. 12.1 Introduction to Flash and OTP Memory
2. 12.2 Flash Bank, OTP, and Pump
3. 12.3 Flash Wrapper
4. 12.4 Flash and OTP Memory Performance
5. 12.5 Flash Read Interface
  1. 12.5.1 C28x-Flash Read Interface
6. 12.6 Flash Erase and Program
7. 12.7 Error Correction Code (ECC) Protection
8. 12.8 Reserved Locations Within Flash and OTP
9. 12.9 Migrating an Application from RAM to Flash
10. 12.10 Procedure to Change the Flash Control Registers
11. 12.11 Software
  1. 12.11.1 FLASH Examples
12. 12.12 Flash Registers
13Embedded Real-time Analysis and Diagnostic (ERAD)
1. 13.1 Introduction
  1. 13.1.1 ERAD Related Collateral
2. 13.2 Enhanced Bus Comparator Unit
  1. 13.2.1 Enhanced Bus Comparator Unit Operations
  2. 13.2.2 Event Masking and Exporting
3. 13.3 System Event Counter Unit
4. 13.4 ERAD Ownership, Initialization and Reset
5. 13.5 ERAD Programming Sequence
  1. 13.5.1 Hardware Breakpoint and Hardware Watch Point Programming Sequence
  2. 13.5.2 Timer and Counter Programming Sequence
6. 13.6 Cyclic Redundancy Check Unit
  1. 13.6.1 CRC Unit Qualifier
  2. 13.6.2 CRC Unit Programming Sequence
7. 13.7 Program Counter Trace
8. 13.8 Software
  1. 13.8.1 ERAD Examples
9. 13.9 ERAD Registers
14General-Purpose Input/Output (GPIO)
1. 14.1 Introduction
  1. 14.1.1 GPIO Related Collateral
2. 14.2 Configuration Overview
3. 14.3 Digital Inputs on ADC Pins (AIOs)
4. 14.4 Digital Inputs and Outputs on ADC Pins (AGPIOs)
5. 14.5 Digital General-Purpose I/O Control
6. 14.6 Input Qualification
7. 14.7 USB Signals
8. 14.8 GPIO and Peripheral Muxing
  1. 14.8.1 GPIO Muxing
  2. 14.8.2 Peripheral Muxing
9. 14.9 Internal Pullup Configuration Requirements
10. 14.10 Software
  1. 14.10.1 GPIO Examples
    1. 14.10.1.1 Device GPIO Toggle - SINGLE_CORE
    2. 14.10.1.2 XINT/XBAR example - SINGLE_CORE
  2. 14.10.2 LED Examples
11. 14.11 GPIO Registers
15Interprocessor Communication (IPC)
1. 15.1 Introduction
2. 15.2 Message RAMs
3. 15.3 IPC Flags and Interrupts
4. 15.4 IPC Command Registers
5. 15.5 Free-Running Counter
6. 15.6 IPC Communication Protocol
7. 15.7 Software
  1. 15.7.1 IPC Examples
8. 15.8 IPC Registers
16Crossbar (X-BAR)
1. 16.1 Input X-BAR, ICL XBAR, MINDB XBAR, and CLB Input X-BAR
  1. 16.1.1 CLB Input X-BAR
  2. 16.1.2 ICL and MINDB X-BAR
2. 16.2 ePWM , CLB, and GPIO Output X-BAR
3. 16.3 XBAR Registers
17Analog Subsystem
1. 17.1 Introduction
  1. 17.1.1 Features
  2. 17.1.2 Block Diagram
2. 17.2 Optimizing Power-Up Time
3. 17.3 Digital Inputs on ADC Pins (AIOs)
4. 17.4 Digital Inputs and Outputs on ADC Pins (AGPIOs)
5. 17.5 Analog Subsystem Registers
  1. 17.5.1 ASBSYS Base Address Table
  2. 17.5.2 ANALOG_SUBSYS_REGS Registers
18Analog-to-Digital Converter (ADC)
1. 18.1 Introduction
2. 18.2 ADC Configurability
3. 18.3 SOC Principle of Operation
4. 18.4 SOC Configuration Examples
5. 18.5 ADC Conversion Priority
6. 18.6 Burst Mode
  1. 18.6.1 Burst Mode Example
  2. 18.6.2 Burst Mode Priority Example
7. 18.7 EOC and Interrupt Operation
8. 18.8 Post-Processing Blocks
9. 18.9 Result Safety Checker
  1. 18.9.1 Result Safety Checker Operation
  2. 18.9.2 Result Safety Checker Interrupts and Events
10. 18.10 Opens/Shorts Detection Circuit (OSDETECT)
11. 18.11 Power-Up Sequence
12. 18.12 ADC Calibration
  1. 18.12.1 ADC Zero Offset Calibration
13. 18.13 ADC Timings
  1. 18.13.1 ADC Timing Diagrams
  2. 18.13.2 Post-Processing Block Timings
14. 18.14 Additional Information
15. 18.15 Software
  1. 18.15.1 ADC Examples
16. 18.16 ADC Registers
19Buffered Digital-to-Analog Converter (DAC)
1. 19.1 Introduction
2. 19.2 Using the DAC
3. 19.3 Lock Registers
4. 19.4 Software
  1. 19.4.1 DAC Examples
    1. 19.4.1.1 Buffered DAC Enable - SINGLE_CORE
    2. 19.4.1.2 Buffered DAC Random - SINGLE_CORE
5. 19.5 DAC Registers
20Comparator Subsystem (CMPSS)
1. 20.1 Introduction
2. 20.2 Comparator
3. 20.3 Reference DAC
4. 20.4 Ramp Generator
5. 20.5 Digital Filter
  1. 20.5.1 Filter Initialization Sequence
6. 20.6 Using the CMPSS
7. 20.7 Software
  1. 20.7.1 CMPSS Examples
    1. 20.7.1.1 CMPSS Asynchronous Trip - SINGLE_CORE
    2. 20.7.1.2 CMPSS Digital Filter Configuration - SINGLE_CORE
8. 20.8 CMPSS Registers
21Enhanced Capture (eCAP) and High Resolution Capture (HRCAP)
1. 21.1 Introduction
  1. 21.1.1 Features
  2. 21.1.2 ECAP Related Collateral
2. 21.2 Description
3. 21.3 Configuring Device Pins for the eCAP
4. 21.4 Capture and APWM Operating Mode
5. 21.5 Capture Mode Description
6. 21.6 Application of the eCAP Module
7. 21.7 Application of the APWM Mode
  1. 21.7.1 Example 1 - Simple PWM Generation (Independent Channels)
8. 21.8 High Resolution Capture (HRCAP) Module
9. 21.9 Software
  1. 21.9.1 ECAP Examples
  2. 21.9.2 HRCAP Examples
    1. 21.9.2.1 HRCAP Capture and Calibration Example - SINGLE_CORE
10. 21.10 eCAP Registers
11. 21.11 HRCAP Registers
22Enhanced Pulse Width Modulator (ePWM)
1. 22.1 Introduction
  1. 22.1.1 EPWM Related Collateral
  2. 22.1.2 Submodule Overview
2. 22.2 Configuring Device Pins
3. 22.3 ePWM Modules Overview
4. 22.4 Time-Base (TB) Submodule
  1. 22.4.1 Purpose of the Time-Base Submodule
  2. 22.4.2 Controlling and Monitoring the Time-Base Submodule
  3. 22.4.3 Calculating PWM Period and Frequency
  4. 22.4.4 Phase Locking the Time-Base Clocks of Multiple ePWM Modules
  5. 22.4.5 Simultaneous Writes to TBPRD and CMPx Registers Between ePWM Modules
  6. 22.4.6 Time-Base Counter Modes and Timing Waveforms
  7. 22.4.7 Global Load
5. 22.5 Counter-Compare (CC) Submodule
  1. 22.5.1 Purpose of the Counter-Compare Submodule
  2. 22.5.2 Controlling and Monitoring the Counter-Compare Submodule
  3. 22.5.3 Operational Highlights for the Counter-Compare Submodule
  4. 22.5.4 Count Mode Timing Waveforms
6. 22.6 Action-Qualifier (AQ) Submodule
  1. 22.6.1 Purpose of the Action-Qualifier Submodule
  2. 22.6.2 Action-Qualifier Submodule Control and Status Register Definitions
  3. 22.6.3 Action-Qualifier Event Priority
  4. 22.6.4 AQCTLA and AQCTLB Shadow Mode Operations
  5. 22.6.5 Configuration Requirements for Common Waveforms
7. 22.7 XCMP Complex Waveform Generator Mode
  1. 22.7.1 XCMP Allocation to CMPA and CMPB
  2. 22.7.2 XCMP Shadow Buffers
  3. 22.7.3 XCMP Operation
8. 22.8 Dead-Band Generator (DB) Submodule
  1. 22.8.1 Purpose of the Dead-Band Submodule
  2. 22.8.2 Dead-band Submodule Additional Operating Modes
  3. 22.8.3 Operational Highlights for the Dead-Band Submodule
9. 22.9 PWM Chopper (PC) Submodule
  1. 22.9.1 Purpose of the PWM Chopper Submodule
  2. 22.9.2 Operational Highlights for the PWM Chopper Submodule
  3. 22.9.3 Waveforms
    1. 22.9.3.1 One-Shot Pulse
    2. 22.9.3.2 Duty Cycle Control
10. 22.10 Trip-Zone (TZ) Submodule
  1. 22.10.1 Purpose of the Trip-Zone Submodule
  2. 22.10.2 Operational Highlights for the Trip-Zone Submodule
    1. 22.10.2.1 Trip-Zone Configurations
  3. 22.10.3 Generating Trip Event Interrupts
11. 22.11 Diode Emulation (DE) Submodule
  1. 22.11.1 DEACTIVE Mode
  2. 22.11.2 Exiting DE Mode
  3. 22.11.3 Re-Entering DE Mode
  4. 22.11.4 DE Monitor
12. 22.12 Minimum Dead-Band (MINDB) + Illegal Combination Logic (ICL) Submodules
  1. 22.12.1 Minimum Dead-Band (MINDB)
  2. 22.12.2 Illegal Combo Logic (ICL)
13. 22.13 Event-Trigger (ET) Submodule
  1. 22.13.1 Operational Overview of the ePWM Event-Trigger Submodule
14. 22.14 Digital Compare (DC) Submodule
  1. 22.14.1 Purpose of the Digital Compare Submodule
  2. 22.14.2 Enhanced Trip Action Using CMPSS
  3. 22.14.3 Using CMPSS to Trip the ePWM on a Cycle-by-Cycle Basis
  4. 22.14.4 Operation Highlights of the Digital Compare Submodule
15. 22.15 ePWM Crossbar (X-BAR)
16. 22.16 Applications to Power Topologies
  1. 22.16.1 Overview of Multiple Modules
  2. 22.16.2 Key Configuration Capabilities
  3. 22.16.3 Controlling Multiple Buck Converters With Independent Frequencies
  4. 22.16.4 Controlling Multiple Buck Converters With Same Frequencies
  5. 22.16.5 Controlling Multiple Half H-Bridge (HHB) Converters
  6. 22.16.6 Controlling Dual 3-Phase Inverters for Motors (ACI and PMSM)
  7. 22.16.7 Practical Applications Using Phase Control Between PWM Modules
  8. 22.16.8 Controlling a 3-Phase Interleaved DC/DC Converter
  9. 22.16.9 Controlling Zero Voltage Switched Full Bridge (ZVSFB) Converter
  10. 22.16.10 Controlling a Peak Current Mode Controlled Buck Module
  11. 22.16.11 Controlling H-Bridge LLC Resonant Converter
17. 22.17 Register Lock Protection
18. 22.18 High-Resolution Pulse Width Modulator (HRPWM)
  1. 22.18.1 Operational Description of HRPWM
  2. 22.18.2 SFO Library Software - SFO_TI_Build_V8.lib
    1. 22.18.2.1 Scale Factor Optimizer Function - int SFO()
    2. 22.18.2.2 Software Usage
      1. 22.18.2.2.1 A Sample of How to Add "Include" Files
      2. 1198
      3. 22.18.2.2.2 Declaring an Element
      4. 1200
      5. 22.18.2.2.3 Initializing With a Scale Factor Value
      6. 1202
      7. 22.18.2.2.4 SFO Function Calls
19. 22.19 Software
  1. 22.19.1 EPWM Examples
  2. 22.19.2 HRPWM Examples
20. 22.20 ePWM Registers
  1. 22.20.1 EPWM Base Address Table
  2. 22.20.2 EPWM_REGS Registers
  3. 22.20.3 EPWM_XCMP_REGS Registers
  4. 22.20.4 DE_REGS Registers
  5. 22.20.5 MINDB_LUT_REGS Registers
  6. 22.20.6 HRPWMCAL_REGS Registers
  7. 22.20.7 Register to Driverlib Function Mapping
23Enhanced Quadrature Encoder Pulse (eQEP)
1. 23.1 Introduction
  1. 23.1.1 EQEP Related Collateral
2. 23.2 Configuring Device Pins
3. 23.3 Description
4. 23.4 Quadrature Decoder Unit (QDU)
5. 23.5 Position Counter and Control Unit (PCCU)
6. 23.6 eQEP Edge Capture Unit
7. 23.7 eQEP Watchdog
8. 23.8 eQEP Unit Timer Base
9. 23.9 QMA Module
  1. 23.9.1 Modes of Operation
    1. 23.9.1.1 QMA Mode-1 (QMACTRL[MODE] = 1)
    2. 23.9.1.2 QMA Mode-2 (QMACTRL[MODE] = 2)
  2. 23.9.2 Interrupt and Error Generation
10. 23.10 eQEP Interrupt Structure
11. 23.11 Software
  1. 23.11.1 EQEP Examples
    1. 23.11.1.1 Frequency Measurement Using eQEP via unit timeout interrupt - SINGLE_CORE
    2. 23.11.1.2 Motor speed and direction measurement using eQEP via unit timeout interrupt - SINGLE_CORE
12. 23.12 eQEP Registers
24Sigma Delta Filter Module (SDFM)
1. 24.1 Introduction
2. 24.2 Configuring Device Pins
3. 24.3 Input Qualification
4. 24.4 Input Control Unit
5. 24.5 SDFM Clock Control
6. 24.6 Sinc Filter
  1. 24.6.1 Data Rate and Latency of the Sinc Filter
7. 24.7 Data (Primary) Filter Unit
8. 24.8 Comparator (Secondary) Filter Unit
9. 24.9 Theoretical SDFM Filter Output
10. 24.10 Interrupt Unit
  1. 24.10.1 SDFM (SDyERR) Interrupt Sources
  2. 24.10.2 Data Ready (DRINT) Interrupt Sources
11. 24.11 Software
  1. 24.11.1 SDFM Examples
12. 24.12 SDFM Registers
25Controller Area Network (CAN)
1. 25.1 Introduction
2. 25.2 Functional Description
  1. 25.2.1 Configuring Device Pins
  2. 25.2.2 Address/Data Bus Bridge
3. 25.3 Operating Modes
4. 25.4 Multiple Clock Source
5. 25.5 Interrupt Functionality
6. 25.6 DMA Functionality
7. 25.7 Parity Check Mechanism
  1. 25.7.1 Behavior on Parity Error
8. 25.8 Debug Mode
9. 25.9 Module Initialization
10. 25.10 Configuration of Message Objects
11. 25.11 Message Handling
12. 25.12 CAN Bit Timing
  1. 25.12.1 Bit Time and Bit Rate
  2. 25.12.2 Configuration of the CAN Bit Timing
13. 25.13 Message Interface Register Sets
  1. 25.13.1 Message Interface Register Sets 1 and 2 (IF1 and IF2)
  2. 25.13.2 Message Interface Register Set 3 (IF3)
14. 25.14 Message RAM
15. 25.15 Software
  1. 25.15.1 CAN Examples
16. 25.16 CAN Registers
26EtherCAT® SubordinateDevice Controller (ESC)
1. 26.1 Introduction
2. 26.2 ESC and ESCSS Description
3. 26.3 Software Initialization Sequence and Allocating Ownership
4. 26.4 ESC Configuration Constants
5. 26.5 EtherCAT IP Registers
27Fast Serial Interface (FSI)
1. 27.1 Introduction
  1. 27.1.1 FSI Related Collateral
  2. 27.1.2 FSI Features
2. 27.2 System-level Integration
3. 27.3 FSI Functional Description
4. 27.4 FSI Programing Guide
5. 27.5 Software
  1. 27.5.1 FSI Examples
    1. 27.5.1.1 FSI Loopback:CPU Control - SINGLE_CORE
    2. 27.5.1.2 FSI data transfers upon CPU Timer event - SINGLE_CORE
6. 27.6 FSI Registers
28Inter-Integrated Circuit Module (I2C)
1. 28.1 Introduction
2. 28.2 Configuring Device Pins
3. 28.3 I2C Module Operational Details
4. 28.4 Interrupt Requests Generated by the I2C Module
  1. 28.4.1 Basic I2C Interrupt Requests
  2. 28.4.2 I2C FIFO Interrupts
5. 28.5 Resetting or Disabling the I2C Module
6. 28.6 Software
  1. 28.6.1 I2C Examples
7. 28.7 I2C Registers
29Power Management Bus Module (PMBus)
1. 29.1 Introduction
2. 29.2 Configuring Device Pins
3. 29.3 Target Mode Operation
  1. 29.3.1 Configuration
  2. 29.3.2 Message Handling
4. 29.4 Controller Mode Operation
  1. 29.4.1 Configuration
  2. 29.4.2 Message Handling
5. 29.5 PMBUS Registers
30Serial Communications Interface (SCI)
1. 30.1 Introduction
2. 30.2 Architecture
3. 30.3 SCI Module Signal Summary
4. 30.4 Configuring Device Pins
5. 30.5 Multiprocessor and Asynchronous Communication Modes
6. 30.6 SCI Programmable Data Format
7. 30.7 SCI Multiprocessor Communication
8. 30.8 Idle-Line Multiprocessor Mode
9. 30.9 Address-Bit Multiprocessor Mode
  1. 30.9.1 Sending an Address
10. 30.10 SCI Communication Format
  1. 30.10.1 Receiver Signals in Communication Modes
  2. 30.10.2 Transmitter Signals in Communication Modes
11. 30.11 SCI Port Interrupts
  1. 30.11.1 Break Detect
12. 30.12 SCI Baud Rate Calculations
13. 30.13 SCI Enhanced Features
14. 30.14 Software
  1. 30.14.1 SCI Examples
15. 30.15 SCI Registers
31Serial Peripheral Interface (SPI)
1. 31.1 Introduction
2. 31.2 System-Level Integration
3. 31.3 SPI Operation
4. 31.4 Programming Procedure
5. 31.5 Software
  1. 31.5.1 SPI Examples
6. 31.6 SPI Registers
32Universal Serial Bus (USB) Controller
1. 32.1 Introduction
2. 32.2 Functional Description
3. 32.3 Initialization and Configuration
  1. 32.3.1 Pin Configuration
  2. 32.3.2 Endpoint Configuration
4. 32.4 USB Global Interrupts
5. 32.5 Software
  1. 32.5.1 USB Examples
6. 32.6 USB Registers
33Advanced Encryption Standard (AES) Accelerator
1. 33.1 Introduction
  1. 33.1.1 AES Block Diagram
  2. 33.1.2 AES Algorithm
2. 33.2 AES Operating Modes
3. 33.3 Extended and Combined Modes of Operations
4. 33.4 AES Module Programming Guide
  1. 33.4.1 AES Low-Level Programming Models
5. 33.5 Software
  1. 33.5.1 AES Examples
6. 33.6 AES Registers
34Embedded Pattern Generator (EPG)
1. 34.1 Introduction
2. 34.2 Clock Generator Modules
  1. 34.2.1 DCLK (50% duty cycle clock)
  2. 34.2.2 Clock Stop
3. 34.3 Signal Generator Module
4. 34.4 EPG Peripheral Signal Mux Selection
5. 34.5 Application Software Notes
6. 34.6 EPG Example Use Cases
7. 34.7 EPG Interrupt
8. 34.8 Software
  1. 34.8.1 EPG Examples
9. 34.9 EPG Registers
35Modular Controller Area Network (MCAN)
1. 35.1 MCAN Introduction
  1. 35.1.1 MCAN Related Collateral
  2. 35.1.2 MCAN Features
2. 35.2 MCAN Environment
3. 35.3 CAN Network Basics
4. 35.4 MCAN Integration
5. 35.5 MCAN Functional Description
6. 35.6 Software
  1. 35.6.1 MCAN Examples
    1. 35.6.1.1 MCAN Loopback with Interrupts Example Using SYSCONFIG Tool - SINGLE_CORE
    2. 35.6.1.2 MCAN Loopback with Polling Example Using SYSCONFIG Tool - SINGLE_CORE
7. 35.7 MCAN Registers
36Universal Asynchronous Receiver/Transmitter (UART)
1. 36.1 Introduction
  1. 36.1.1 Features
  2. 36.1.2 Block Diagram
2. 36.2 Functional Description
3. 36.3 Initialization and Configuration
4. 36.4 Software
  1. 36.4.1 UART Examples
5. 36.5 UART Registers
37Local Interconnect Network (LIN)
1. 37.1 LIN Overview
2. 37.2 Serial Communications Interface Module
3. 37.3 Local Interconnect Network Module
4. 37.4 Low-Power Mode
5. 37.5 Emulation Mode
6. 37.6 Software
  1. 37.6.1 LIN Examples
7. 37.7 SCI/LIN Registers
38Lockstep Compare Module (LCM)
1. 38.1 Introduction
  1. 38.1.1 Features
  2. 38.1.2 Block Diagram
2. 38.2 Enabling LCM Comparators
3. 38.3 Disabling LCM Redundant Module
4. 38.4 LCM Error Handling
5. 38.5 LCM Error Flags
6. 38.6 Debug Mode with LCM
7. 38.7 Register Parity Error Protection
8. 38.8 Functional Logic
9. 38.9 LCM Registers
39Revision History

23.12.2 EQEP_REGS Registers

Table 23-5 lists the memory-mapped registers for the EQEP_REGS registers. All register offset addresses not listed in Table 23-5 should be considered as reserved locations and the register contents should not be modified.

Table 23-5 EQEP_REGS Registers

Offset	Acronym	Register Name	Section
0h	QPOSCNT	Position Counter	Go
2h	QPOSINIT	Position Counter Init	Go
4h	QPOSMAX	Maximum Position Count	Go
6h	QPOSCMP	Position Compare	Go
8h	QPOSILAT	Index Position Latch	Go
Ah	QPOSSLAT	Strobe Position Latch	Go
Ch	QPOSLAT	Position Latch	Go
Eh	QUTMR	QEP Unit Timer	Go
10h	QUPRD	QEP Unit Period	Go
12h	QWDTMR	QEP Watchdog Timer	Go
13h	QWDPRD	QEP Watchdog Period	Go
14h	QDECCTL	Quadrature Decoder Control	Go
15h	QEPCTL	QEP Control	Go
16h	QCAPCTL	Qaudrature Capture Control	Go
17h	QPOSCTL	Position Compare Control	Go
18h	QEINT	QEP Interrupt Control	Go
19h	QFLG	QEP Interrupt Flag	Go
1Ah	QCLR	QEP Interrupt Clear	Go
1Bh	QFRC	QEP Interrupt Force	Go
1Ch	QEPSTS	QEP Status	Go
1Dh	QCTMR	QEP Capture Timer	Go
1Eh	QCPRD	QEP Capture Period	Go
1Fh	QCTMRLAT	QEP Capture Latch	Go
20h	QCPRDLAT	QEP Capture Period Latch	Go
30h	REV	QEP Revision Number	Go
32h	QEPSTROBESEL	QEP Strobe select register	Go
34h	QMACTRL	QMA Control register	Go
36h	QEPSRCSEL	QEP Source Select Register	Go

Complex bit access types are encoded to fit into small table cells. Table 23-6 shows the codes that are used for access types in this section.

Table 23-6 EQEP_REGS Access Type Codes

Access Type	Code	Description
Read Type
R	R	Read
R-0	R -0	Read Returns 0s
Write Type
W	W	Write
W1C	W 1C	Write 1 to clear
W1S	W 1S	Write 1 to set
Reset or Default Value
-n		Value after reset or the default value
Register Array Variables
i,j,k,l,m,n		When these variables are used in a register name, an offset, or an address, they refer to the value of a register array where the register is part of a group of repeating registers. The register groups form a hierarchical structure and the array is represented with a formula.
y		When this variable is used in a register name, an offset, or an address it refers to the value of a register array.

23.12.2.1 QPOSCNT Register (Offset = 0h) [Reset = 00000000h]

QPOSCNT is shown in Figure 23-26 and described in Table 23-7.

Return to the Summary Table.

Position Counter

Figure 23-26 QPOSCNT Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSCNT
R/W-0h

Table 23-7 QPOSCNT Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSCNT	R/W	0h	Position Counter This 32-bit position counter register counts up/down on every eQEP pulse based on direction input. This counter acts as a position integrator whose count value is proportional to position from a give reference point. This Register acts as a Read ONLY register while counter is counting up/down. Note: It is recommended to only write to the position counter register (QPOSCNT) during initialization, i.e. when the eQEP position counter is disabled (QPEN bit of QEPCTL is zero). Once the position counter is enabled (QPEN bit is one), writing to the eQEP position counter register (QPOSCNT) may cause unexpected results. Reset type: SYSRSn

23.12.2.2 QPOSINIT Register (Offset = 2h) [Reset = 00000000h]

QPOSINIT is shown in Figure 23-27 and described in Table 23-8.

Return to the Summary Table.

Position Counter Init

Figure 23-27 QPOSINIT Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSINIT
R/W-0h

Table 23-8 QPOSINIT Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSINIT	R/W	0h	Position Counter Init This register contains the position value that is used to initialize the position counter based on external strobe or index event. The position counter can be initialized through software. Writes to this register should always be full 32-bit writes. Reset type: SYSRSn

23.12.2.3 QPOSMAX Register (Offset = 4h) [Reset = 00000000h]

QPOSMAX is shown in Figure 23-28 and described in Table 23-9.

Return to the Summary Table.

Maximum Position Count

Figure 23-28 QPOSMAX Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSMAX
R/W-0h

Table 23-9 QPOSMAX Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSMAX	R/W	0h	Maximum Position Count This register contains the maximum position counter value. Writes to this register should always be full 32-bit writes. Reset type: SYSRSn

23.12.2.4 QPOSCMP Register (Offset = 6h) [Reset = 00000000h]

QPOSCMP is shown in Figure 23-29 and described in Table 23-10.

Return to the Summary Table.

Position Compare

Figure 23-29 QPOSCMP Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSCMP
R/W-0h

Table 23-10 QPOSCMP Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSCMP	R/W	0h	Position Compare The position-compare value in this register is compared with the position counter (QPOSCNT) to generate sync output and/or interrupt on compare match. Writes to this register should always be full 32-bit writes. Reset type: SYSRSn

23.12.2.5 QPOSILAT Register (Offset = 8h) [Reset = 00000000h]

QPOSILAT is shown in Figure 23-30 and described in Table 23-11.

Return to the Summary Table.

Index Position Latch

Figure 23-30 QPOSILAT Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSILAT
R-0h

Table 23-11 QPOSILAT Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSILAT	R	0h	Index Position Latch The position-counter value is latched into this register on an index event as defined by the QEPCTL[IEL] bits. Reset type: SYSRSn

23.12.2.6 QPOSSLAT Register (Offset = Ah) [Reset = 00000000h]

QPOSSLAT is shown in Figure 23-31 and described in Table 23-12.

Return to the Summary Table.

Strobe Position Latch

Figure 23-31 QPOSSLAT Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSSLAT
R-0h

Table 23-12 QPOSSLAT Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSSLAT	R	0h	Strobe Position Latch The position-counter value is latched into this register on a strobe event as defined by the QEPCTL[SEL] bits. Reset type: SYSRSn

23.12.2.7 QPOSLAT Register (Offset = Ch) [Reset = 00000000h]

QPOSLAT is shown in Figure 23-32 and described in Table 23-13.

Return to the Summary Table.

Position Latch

Figure 23-32 QPOSLAT Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QPOSLAT
R-0h

Table 23-13 QPOSLAT Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QPOSLAT	R	0h	Position Latch The position-counter value is latched into this register on a unit time out event. Reset type: SYSRSn

23.12.2.8 QUTMR Register (Offset = Eh) [Reset = 00000000h]

QUTMR is shown in Figure 23-33 and described in Table 23-14.

Return to the Summary Table.

QEP Unit Timer

Figure 23-33 QUTMR Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QUTMR
R/W-0h

Table 23-14 QUTMR Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QUTMR	R/W	0h	QEP Unit Timer This register acts as time base for unit time event generation. When this timer value matches the unit time period value a unit time event is generated. Writes to this register should always be full 32-bit writes. Reset type: SYSRSn

23.12.2.9 QUPRD Register (Offset = 10h) [Reset = 00000000h]

QUPRD is shown in Figure 23-34 and described in Table 23-15.

Return to the Summary Table.

QEP Unit Period

Figure 23-34 QUPRD Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QUPRD
R/W-0h

Table 23-15 QUPRD Register Field Descriptions

Bit	Field	Type	Reset	Description
31-0	QUPRD	R/W	0h	QEP Unit Period This register contains the period count for the unit timer to generate periodic unit time events. These events latch the eQEP position information at periodic intervals and optionally generate an interrupt. Writes to this register should always be full 32-bit writes. Reset type: SYSRSn

23.12.2.10 QWDTMR Register (Offset = 12h) [Reset = 0000h]

QWDTMR is shown in Figure 23-35 and described in Table 23-16.

Return to the Summary Table.

QEP Watchdog Timer

Figure 23-35 QWDTMR Register

15	14	13	12	11	10	9	8
QWDTMR
R/W-0h

7	6	5	4	3	2	1	0
QWDTMR
R/W-0h

Table 23-16 QWDTMR Register Field Descriptions

Bit	Field	Type	Reset	Description
15-0	QWDTMR	R/W	0h	QEP Watchdog Timer This register acts as time base for the watchdog to detect motor stalls. When this timer value matches with the watchdog's period value a watchdog timeout interrupt is generated. This register is reset upon edge transition in quadrature-clock indicating the motion. Reset type: SYSRSn

23.12.2.11 QWDPRD Register (Offset = 13h) [Reset = 0000h]

QWDPRD is shown in Figure 23-36 and described in Table 23-17.

Return to the Summary Table.

QEP Watchdog Period

Figure 23-36 QWDPRD Register

15	14	13	12	11	10	9	8
QWDPRD
R/W-0h

7	6	5	4	3	2	1	0
QWDPRD
R/W-0h

Table 23-17 QWDPRD Register Field Descriptions

Bit	Field	Type	Reset	Description
15-0	QWDPRD	R/W	0h	QEP Watchdog Period This register contains the time-out count for the eQEP peripheral watch dog timer. When the watchdog timer value matches the watchdog period value, a watchdog timeout interrupt is generated. Reset type: SYSRSn

23.12.2.12 QDECCTL Register (Offset = 14h) [Reset = 0000h]

QDECCTL is shown in Figure 23-37 and described in Table 23-18.

Return to the Summary Table.

Quadrature Decoder Control

Figure 23-37 QDECCTL Register

15	14	13	12	11	10	9	8
QSRC		SOEN	SPSEL	XCR	SWAP	IGATE	QAP
R/W-0h		R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h

7	6	5	4	3	2	1	0
QBP	QIP	QSP	RESERVED				QIDIRE
R/W-0h	R/W-0h	R/W-0h	R-0h				R/W-0h

Table 23-18 QDECCTL Register Field Descriptions

Bit	Field	Type	Reset	Description
15-14	QSRC	R/W	0h	Position-counter source selection Reset type: SYSRSn 0h (R/W) = Quadrature count mode (QCLK = iCLK, QDIR = iDIR) 1h (R/W) = Direction-count mode (QCLK = xCLK, QDIR = xDIR) 2h (R/W) = UP count mode for frequency measurement (QCLK = xCLK, QDIR = 1) 3h (R/W) = DOWN count mode for frequency measurement (QCLK = xCLK, QDIR = 0)
13	SOEN	R/W	0h	Sync output-enable Reset type: SYSRSn 0h (R/W) = Disable position-compare sync output 1h (R/W) = Enable position-compare sync output
12	SPSEL	R/W	0h	Sync output pin selection Reset type: SYSRSn 0h (R/W) = Index pin is used for sync output 1h (R/W) = Strobe pin is used for sync output
11	XCR	R/W	0h	External Clock Rate Reset type: SYSRSn 0h (R/W) = 2x resolution: Count the rising/falling edge 1h (R/W) = 1x resolution: Count the rising edge only
10	SWAP	R/W	0h	CLK/DIR Signal Source for Position Counter Reset type: SYSRSn 0h (R/W) = Quadrature-clock inputs are not swapped 1h (R/W) = Quadrature-clock inputs are swapped
9	IGATE	R/W	0h	Index pulse gating option Reset type: SYSRSn 0h (R/W) = Disable gating of Index pulse 1h (R/W) = Gate the index pin with strobe
8	QAP	R/W	0h	QEPA input polarity Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Negates QEPA input
7	QBP	R/W	0h	QEPB input polarity Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Negates QEPB input
6	QIP	R/W	0h	QEPI input polarity Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Negates QEPI input
5	QSP	R/W	0h	QEPS input polarity Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Negates QEPS input
4-1	RESERVED	R	0h	Reserved
0	QIDIRE	R/W	0h	0 - Compatible mode, Behavior same as existing devices 1 - Enhancement for Direction change during Index will be enabled: On QEPI direction change, the incoming posedge of QA can erroneously update/reset the position counter of the eQEP. This bit only needs to be enabled if the application requires a direction change occurring at the same time as an incoming QEPI signal, or when erroneous PC resets are observed. Reset type: SYSRSn

23.12.2.13 QEPCTL Register (Offset = 15h) [Reset = 0000h]

QEPCTL is shown in Figure 23-38 and described in Table 23-19.

Return to the Summary Table.

QEP Control

Figure 23-38 QEPCTL Register

15	14	13	12	11	10	9	8
FREE_SOFT		PCRM		SEI		IEI
R/W-0h		R/W-0h		R/W-0h		R/W-0h

7	6	5	4	3	2	1	0
SWI	SEL	IEL		QPEN	QCLM	UTE	WDE
R/W-0h	R/W-0h	R/W-0h		R/W-0h	R/W-0h	R/W-0h	R/W-0h

Table 23-19 QEPCTL Register Field Descriptions

Bit	Field	Type	Reset	Description
15-14	FREE_SOFT	R/W	0h	Emulation mode Reset type: SYSRSn 0h (R/W) = QPOSCNT behavior Position counter stops immediately on emulation suspend 0h (R/W) = QWDTMR behavior Watchdog counter stops immediately 0h (R/W) = QUTMR behavior Unit timer stops immediately 0h (R/W) = QCTMR behavior Capture Timer stops immediately 1h (R/W) = QPOSCNT behavior Position counter continues to count until the rollover 1h (R/W) = QWDTMR behavior Watchdog counter counts until WD period match roll over 1h (R/W) = QUTMR behavior Unit timer counts until period rollover 1h (R/W) = QCTMR behavior Capture Timer counts until next unit period event 2h (R/W) = QPOSCNT behavior Position counter is unaffected by emulation suspend 2h (R/W) = QWDTMR behavior Watchdog counter is unaffected by emulation suspend 2h (R/W) = QUTMR behavior Unit timer is unaffected by emulation suspend 2h (R/W) = QCTMR behavior Capture Timer is unaffected by emulation suspend 3h (R/W) = Same as FREE_SOFT_2
13-12	PCRM	R/W	0h	Postion counter reset Reset type: SYSRSn 0h (R/W) = Position counter reset on an index event 1h (R/W) = Position counter reset on the maximum position 2h (R/W) = Position counter reset on the first index event 3h (R/W) = Position counter reset on a unit time event
11-10	SEI	R/W	0h	Strobe event initialization of position counter Reset type: SYSRSn 0h (R/W) = Does nothing (action disabled) 1h (R/W) = Does nothing (action disabled) 2h (R/W) = Initializes the position counter on rising edge of the QEPS signal 3h (R/W) = Clockwise Direction: Initializes the position counter on the rising edge of QEPS strobe Counter Clockwise Direction: Initializes the position counter on the falling edge of QEPS strobe
9-8	IEI	R/W	0h	Index event init of position count Reset type: SYSRSn 0h (R/W) = Do nothing (action disabled) 1h (R/W) = Do nothing (action disabled) 2h (R/W) = Initializes the position counter on the rising edge of the QEPI signal (QPOSCNT = QPOSINIT) 3h (R/W) = Initializes the position counter on the falling edge of QEPI signal (QPOSCNT = QPOSINIT)
7	SWI	R/W	0h	Software init position counter Reset type: SYSRSn 0h (R/W) = Do nothing (action disabled) 1h (R/W) = Initialize position counter (QPOSCNT=QPOSINIT). This bit is not cleared automatically
6	SEL	R/W	0h	Strobe event latch of position counter Reset type: SYSRSn 0h (R/W) = The position counter is latched on the rising edge of QEPS strobe (QPOSSLAT = POSCCNT). Latching on the falling edge can be done by inverting the strobe input using the QSP bit in the QDECCTL register 1h (R/W) = Clockwise Direction: Position counter is latched on rising edge of QEPS strobe Counter Clockwise Direction: Position counter is latched on falling edge of QEPS strobe
5-4	IEL	R/W	0h	Index event latch of position counter (software index marker) Reset type: SYSRSn 0h (R/W) = Reserved 1h (R/W) = Latches position counter on rising edge of the index signal 2h (R/W) = Latches position counter on falling edge of the index signal 3h (R/W) = Software index marker. Latches the position counter and quadrature direction flag on index event marker. The position counter is latched to the QPOSILAT register and the direction flag is latched in the QEPSTS[QDLF] bit. This mode is useful for software index marking.
3	QPEN	R/W	0h	Quadrature position counter enable/software reset Reset type: SYSRSn 0h (R/W) = Reset the eQEP peripheral internal operating flags/read-only registers. Control/configuration registers are not disturbed by a software reset. When QPEN is disabled, some flags in the QFLG register do not get reset or cleared and show the actual state of that flag. 1h (R/W) = eQEP position counter is enabled
2	QCLM	R/W	0h	QEP capture latch mode Reset type: SYSRSn 0h (R/W) = Latch on position counter read by CPU. Capture timer and capture period values are latched into QCTMRLAT and QCPRDLAT registers when CPU reads the QPOSCNT register. 1h (R/W) = Latch on unit time out. Position counter, capture timer and capture period values are latched into QPOSLAT, QCTMRLAT and QCPRDLAT registers on unit time out.
1	UTE	R/W	0h	QEP unit timer enable Reset type: SYSRSn 0h (R/W) = Disable eQEP unit timer 1h (R/W) = Enable unit timer
0	WDE	R/W	0h	QEP watchdog enable Reset type: SYSRSn 0h (R/W) = Disable the eQEP watchdog timer 1h (R/W) = Enable the eQEP watchdog timer

23.12.2.14 QCAPCTL Register (Offset = 16h) [Reset = 0000h]

QCAPCTL is shown in Figure 23-39 and described in Table 23-20.

Return to the Summary Table.

Qaudrature Capture Control

Figure 23-39 QCAPCTL Register

15	14	13	12	11	10	9	8
CEN	RESERVED
R/W-0h	R-0h

7	6	5	4	3	2	1	0
RESERVED	CCPS			UPPS
R-0h	R/W-0h			R/W-0h

Table 23-20 QCAPCTL Register Field Descriptions

Bit	Field	Type	Reset	Description
15	CEN	R/W	0h	Enable eQEP capture Reset type: SYSRSn 0h (R/W) = eQEP capture unit is disabled 1h (R/W) = eQEP capture unit is enabled
14-7	RESERVED	R	0h	Reserved
6-4	CCPS	R/W	0h	eQEP capture timer clock prescaler Reset type: SYSRSn 0h (R/W) = CAPCLK = SYSCLKOUT/1 1h (R/W) = CAPCLK = SYSCLKOUT/2 2h (R/W) = CAPCLK = SYSCLKOUT/4 3h (R/W) = CAPCLK = SYSCLKOUT/8 4h (R/W) = CAPCLK = SYSCLKOUT/16 5h (R/W) = CAPCLK = SYSCLKOUT/32 6h (R/W) = CAPCLK = SYSCLKOUT/64 7h (R/W) = CAPCLK = SYSCLKOUT/128
3-0	UPPS	R/W	0h	Unit position event prescaler Reset type: SYSRSn 0h (R/W) = UPEVNT = QCLK/1 1h (R/W) = UPEVNT = QCLK/2 2h (R/W) = UPEVNT = QCLK/4 3h (R/W) = UPEVNT = QCLK/8 4h (R/W) = UPEVNT = QCLK/16 5h (R/W) = UPEVNT = QCLK/32 6h (R/W) = UPEVNT = QCLK/64 7h (R/W) = UPEVNT = QCLK/128 8h (R/W) = UPEVNT = QCLK/256 9h (R/W) = UPEVNT = QCLK/512 Ah (R/W) = UPEVNT = QCLK/1024 Bh (R/W) = UPEVNT = QCLK/2048 Ch (R/W) = Reserved Dh (R/W) = Reserved Eh (R/W) = Reserved Fh (R/W) = Reserved

23.12.2.15 QPOSCTL Register (Offset = 17h) [Reset = 0000h]

QPOSCTL is shown in Figure 23-40 and described in Table 23-21.

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Position Compare Control

Figure 23-40 QPOSCTL Register

15	14	13	12	11	10	9	8
PCSHDW	PCLOAD	PCPOL	PCE	PCSPW
R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h

7	6	5	4	3	2	1	0
PCSPW
R/W-0h

Table 23-21 QPOSCTL Register Field Descriptions

Bit	Field	Type	Reset	Description
15	PCSHDW	R/W	0h	Position compare of shadow enable Reset type: SYSRSn 0h (R/W) = Shadow disabled, load Immediate 1h (R/W) = Shadow enabled
14	PCLOAD	R/W	0h	Position compare of shadow load Reset type: SYSRSn 0h (R/W) = Load on QPOSCNT = 0 1h (R/W) = Load when QPOSCNT = QPOSCMP
13	PCPOL	R/W	0h	Polarity of sync output Reset type: SYSRSn 0h (R/W) = Active HIGH pulse output 1h (R/W) = Active LOW pulse output
12	PCE	R/W	0h	Position compare enable/disable Reset type: SYSRSn 0h (R/W) = Disable position compare unit 1h (R/W) = Enable position compare unit
11-0	PCSPW	R/W	0h	Select-position-compare sync output pulse width Reset type: SYSRSn 0h (R/W) = 1 * 4 * SYSCLKOUT cycles 1h (R/W) = 2 * 4 * SYSCLKOUT cycles FFFh (R/W) = 4096 * 4 * SYSCLKOUT cycles

23.12.2.16 QEINT Register (Offset = 18h) [Reset = 0000h]

QEINT is shown in Figure 23-41 and described in Table 23-22.

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QEP Interrupt Control

Figure 23-41 QEINT Register

15	14	13	12	11	10	9	8
RESERVED			QMAE	UTO	IEL	SEL	PCM
R-0h			R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h

7	6	5	4	3	2	1	0
PCR	PCO	PCU	WTO	QDC	QPE	PCE	RESERVED
R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R-0h

Table 23-22 QEINT Register Field Descriptions

Bit	Field	Type	Reset	Description
15-13	RESERVED	R	0h	Reserved
12	QMAE	R/W	0h	QMA Error Interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
11	UTO	R/W	0h	Unit time out interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
10	IEL	R/W	0h	Index event latch interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
9	SEL	R/W	0h	Strobe event latch interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
8	PCM	R/W	0h	Position-compare match interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
7	PCR	R/W	0h	Position-compare ready interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
6	PCO	R/W	0h	Position counter overflow interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
5	PCU	R/W	0h	Position counter underflow interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
4	WTO	R/W	0h	Watchdog time out interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
3	QDC	R/W	0h	Quadrature direction change interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
2	QPE	R/W	0h	Quadrature phase error interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
1	PCE	R/W	0h	Position counter error interrupt enable Reset type: SYSRSn 0h (R/W) = Interrupt is disabled 1h (R/W) = Interrupt is enabled
0	RESERVED	R	0h	Reserved

23.12.2.17 QFLG Register (Offset = 19h) [Reset = 0000h]

QFLG is shown in Figure 23-42 and described in Table 23-23.

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QEP Interrupt Flag

Figure 23-42 QFLG Register

15	14	13	12	11	10	9	8
RESERVED			QMAE	UTO	IEL	SEL	PCM
R-0h			R-0h	R-0h	R-0h	R-0h	R-0h

7	6	5	4	3	2	1	0
PCR	PCO	PCU	WTO	QDC	PHE	PCE	INT
R-0h	R-0h	R-0h	R-0h	R-0h	R-0h	R-0h	R-0h

Table 23-23 QFLG Register Field Descriptions

Bit	Field	Type	Reset	Description
15-13	RESERVED	R	0h	Reserved
12	QMAE	R	0h	QMA Error interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Interrupt was generated
11	UTO	R	0h	Unit time out interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Set by eQEP unit timer period match
10	IEL	R	0h	Index event latch interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = This bit is set after latching the QPOSCNT to QPOSILAT
9	SEL	R	0h	Strobe event latch interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = This bit is set after latching the QPOSCNT to QPOSSLAT
8	PCM	R	0h	eQEP compare match event interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = This bit is set on position-compare match
7	PCR	R	0h	Position-compare ready interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = This bit is set after transferring the shadow register value to the active position compare register
6	PCO	R	0h	Position counter overflow interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = This bit is set on position counter overflow.
5	PCU	R	0h	Position counter underflow interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = This bit is set on position counter underflow.
4	WTO	R	0h	Watchdog timeout interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Set by watchdog timeout
3	QDC	R	0h	Quadrature direction change interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Interrupt was generated
2	PHE	R	0h	Quadrature phase error interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Set on simultaneous transition of QEPA and QEPB
1	PCE	R	0h	Position counter error interrupt flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Position counter error
0	INT	R	0h	Global interrupt status flag Reset type: SYSRSn 0h (R/W) = No interrupt generated 1h (R/W) = Interrupt was generated

23.12.2.18 QCLR Register (Offset = 1Ah) [Reset = 0000h]

QCLR is shown in Figure 23-43 and described in Table 23-24.

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QEP Interrupt Clear

Figure 23-43 QCLR Register

15	14	13	12	11	10	9	8
RESERVED			QMAE	UTO	IEL	SEL	PCM
R-0h			R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h

7	6	5	4	3	2	1	0
PCR	PCO	PCU	WTO	QDC	PHE	PCE	INT
R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h	R-0/W1S-0h

Table 23-24 QCLR Register Field Descriptions

Bit	Field	Type	Reset	Description
15-13	RESERVED	R	0h	Reserved
12	QMAE	R-0/W1S	0h	Clear QMA Error interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
11	UTO	R-0/W1S	0h	Clear unit time out interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
10	IEL	R-0/W1S	0h	Clear index event latch interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
9	SEL	R-0/W1S	0h	Clear strobe event latch interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
8	PCM	R-0/W1S	0h	Clear eQEP compare match event interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
7	PCR	R-0/W1S	0h	Clear position-compare ready interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
6	PCO	R-0/W1S	0h	Clear position counter overflow interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
5	PCU	R-0/W1S	0h	Clear position counter underflow interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
4	WTO	R-0/W1S	0h	Clear watchdog timeout interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
3	QDC	R-0/W1S	0h	Clear quadrature direction change interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
2	PHE	R-0/W1S	0h	Clear quadrature phase error interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
1	PCE	R-0/W1S	0h	Clear position counter error interrupt flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag
0	INT	R-0/W1S	0h	Global interrupt clear flag Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Clears the interrupt flag

23.12.2.19 QFRC Register (Offset = 1Bh) [Reset = 0000h]

QFRC is shown in Figure 23-44 and described in Table 23-25.

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QEP Interrupt Force

Figure 23-44 QFRC Register

15	14	13	12	11	10	9	8
RESERVED			QMAE	UTO	IEL	SEL	PCM
R-0h			R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h

7	6	5	4	3	2	1	0
PCR	PCO	PCU	WTO	QDC	PHE	PCE	RESERVED
R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R/W-0h	R-0h

Table 23-25 QFRC Register Field Descriptions

Bit	Field	Type	Reset	Description
15-13	RESERVED	R	0h	Reserved
12	QMAE	R/W	0h	Force QMA error interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
11	UTO	R/W	0h	Force unit time out interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
10	IEL	R/W	0h	Force index event latch interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
9	SEL	R/W	0h	Force strobe event latch interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
8	PCM	R/W	0h	Force position-compare match interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
7	PCR	R/W	0h	Force position-compare ready interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
6	PCO	R/W	0h	Force position counter overflow interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
5	PCU	R/W	0h	Force position counter underflow interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
4	WTO	R/W	0h	Force watchdog time out interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
3	QDC	R/W	0h	Force quadrature direction change interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
2	PHE	R/W	0h	Force quadrature phase error interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
1	PCE	R/W	0h	Force position counter error interrupt Reset type: SYSRSn 0h (R/W) = No effect 1h (R/W) = Force the interrupt
0	RESERVED	R	0h	Reserved

23.12.2.20 QEPSTS Register (Offset = 1Ch) [Reset = 0000h]

QEPSTS is shown in Figure 23-45 and described in Table 23-26.

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QEP Status

Figure 23-45 QEPSTS Register

15	14	13	12	11	10	9	8
RESERVED
R-0h

7	6	5	4	3	2	1	0
UPEVNT	FIDF	QDF	QDLF	COEF	CDEF	FIMF	PCEF
R/W1C-0h	R-0h	R-0h	R-0h	R/W1C-0h	R/W1C-0h	R/W1C-0h	R-0h

Table 23-26 QEPSTS Register Field Descriptions

Bit	Field	Type	Reset	Description
15-8	RESERVED	R	0h	Reserved
7	UPEVNT	R/W1C	0h	Unit position event flag Reset type: SYSRSn 0h (R/W) = No unit position event detected 1h (R/W) = Unit position event detected. Write 1 to clear
6	FIDF	R	0h	Direction on the first index marker Status of the direction is latched on the first index event marker. Reset type: SYSRSn 0h (R/W) = Counter-clockwise rotation (or reverse movement) on the first index event 1h (R/W) = Clockwise rotation (or forward movement) on the first index event
5	QDF	R	0h	Quadrature direction flag Reset type: SYSRSn 0h (R/W) = Counter-clockwise rotation (or reverse movement) 1h (R/W) = Clockwise rotation (or forward movement)
4	QDLF	R	0h	eQEP direction latch flag Reset type: SYSRSn 0h (R/W) = Counter-clockwise rotation (or reverse movement) on index event marker 1h (R/W) = Clockwise rotation (or forward movement) on index event marker
3	COEF	R/W1C	0h	Capture overflow error flag Reset type: SYSRSn 0h (R/W) = Overflow has not occurred. 1h (R/W) = Overflow occurred in eQEP Capture timer (QEPCTMR). This bit is cleared by writing a '1'.
2	CDEF	R/W1C	0h	Capture direction error flag Reset type: SYSRSn 0h (R/W) = Capture direction error has not occurred. 1h (R/W) = Direction change occurred between the capture position event. This bit is cleared by writing a '1'.
1	FIMF	R/W1C	0h	First index marker flag Reset type: SYSRSn 0h (R/W) = First index pulse has not occurred. 1h (R/W) = Set by first occurrence of index pulse. This bit is cleared by writing a '1'.
0	PCEF	R	0h	Position counter error flag. This bit is not sticky and it is updated for every index event. Reset type: SYSRSn 0h (R/W) = No error occurred during the last index transition 1h (R/W) = Position counter error

23.12.2.21 QCTMR Register (Offset = 1Dh) [Reset = 0000h]

QCTMR is shown in Figure 23-46 and described in Table 23-27.

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QEP Capture Timer

Figure 23-46 QCTMR Register

15	14	13	12	11	10	9	8
QCTMR
R/W-0h

7	6	5	4	3	2	1	0
QCTMR
R/W-0h

Table 23-27 QCTMR Register Field Descriptions

Bit	Field	Type	Reset	Description
15-0	QCTMR	R/W	0h	This register provides time base for edge capture unit. Reset type: SYSRSn

23.12.2.22 QCPRD Register (Offset = 1Eh) [Reset = 0000h]

QCPRD is shown in Figure 23-47 and described in Table 23-28.

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QEP Capture Period

Figure 23-47 QCPRD Register

15	14	13	12	11	10	9	8
QCPRD
R/W-0h

7	6	5	4	3	2	1	0
QCPRD
R/W-0h

Table 23-28 QCPRD Register Field Descriptions

Bit	Field	Type	Reset	Description
15-0	QCPRD	R/W	0h	This register holds the period count value between the last successive eQEP position events Reset type: SYSRSn

23.12.2.23 QCTMRLAT Register (Offset = 1Fh) [Reset = 0000h]

QCTMRLAT is shown in Figure 23-48 and described in Table 23-29.

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QEP Capture Latch

Figure 23-48 QCTMRLAT Register

15	14	13	12	11	10	9	8
QCTMRLAT
R-0h

7	6	5	4	3	2	1	0
QCTMRLAT
R-0h

Table 23-29 QCTMRLAT Register Field Descriptions

Bit	Field	Type	Reset	Description
15-0	QCTMRLAT	R	0h	The eQEP capture timer value can be latched into this register on two events viz., unit timeout event, reading the eQEP position counter. Reset type: SYSRSn

23.12.2.24 QCPRDLAT Register (Offset = 20h) [Reset = 0000h]

QCPRDLAT is shown in Figure 23-49 and described in Table 23-30.

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QEP Capture Period Latch

Figure 23-49 QCPRDLAT Register

15	14	13	12	11	10	9	8
QCPRDLAT
R-0h

7	6	5	4	3	2	1	0
QCPRDLAT
R-0h

Table 23-30 QCPRDLAT Register Field Descriptions

Bit	Field	Type	Reset	Description
15-0	QCPRDLAT	R	0h	eQEP capture period value can be latched into this register on two events viz., unit timeout event, reading the eQEP position counter. Reset type: SYSRSn

23.12.2.25 REV Register (Offset = 30h) [Reset = 00000009h]

REV is shown in Figure 23-50 and described in Table 23-31.

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QEP Revision Number

Figure 23-50 REV Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16
RESERVED
R-0-0h

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
RESERVED										MINOR			MAJOR
R-0-0h										R-1h			R-1h

Table 23-31 REV Register Field Descriptions

Bit	Field	Type	Reset	Description
31-6	RESERVED	R-0	0h	Reserved
5-3	MINOR	R	1h	This field specifies the Minor Revision number for the eQEP IP. Reset type: N/A
2-0	MAJOR	R	1h	This field specifies the Major Revision number for the eQEP IP. Reset type: N/A

23.12.2.26 QEPSTROBESEL Register (Offset = 32h) [Reset = 00000000h]

QEPSTROBESEL is shown in Figure 23-51 and described in Table 23-32.

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QEP Strobe select register

Figure 23-51 QEPSTROBESEL Register

31	30	29	28	27	26	25	24
RESERVED
R-0-0h

23	22	21	20	19	18	17	16
RESERVED
R-0-0h

15	14	13	12	11	10	9	8
RESERVED
R-0-0h

7	6	5	4	3	2	1	0
RESERVED						STROBESEL
R-0-0h						R/W-0h

Table 23-32 QEPSTROBESEL Register Field Descriptions

Bit	Field	Type	Reset	Description
31-2	RESERVED	R-0	0h	Reserved
1-0	STROBESEL	R/W	0h	Strobe source select: Reset type: SYSRSn 0h (R/W) = QEP Strobe after polarity mux 1h (R/W) = QEP Strobe after polarity mux 2h (R/W) = QEP Strobe after polarity mux ORed with ADCSOCA 3h (R/W) = QEP Strobe after polarity mux ORed with ADCSOCB

23.12.2.27 QMACTRL Register (Offset = 34h) [Reset = 00000000h]

QMACTRL is shown in Figure 23-52 and described in Table 23-33.

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QMA Control register

Figure 23-52 QMACTRL Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16
RESERVED
R-0-0h

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
RESERVED													MODE
R-0-0h													R/W-0h

Table 23-33 QMACTRL Register Field Descriptions

Bit	Field	Type	Reset	Description
31-3	RESERVED	R-0	0h	Reserved
2-0	MODE	R/W	0h	Select Mode for QMA mode: 000 : QMA Module is bypassed. 001 : QMA Mode-1 operation selected 010 : QMA Mode-2 operation selected 011 : QMA Module is bypassed (reserved) 1xx : QMA Module is bypassed (reserved) Reset type: SYSRSn

23.12.2.28 QEPSRCSEL Register (Offset = 36h) [Reset = 00000000h]

QEPSRCSEL is shown in Figure 23-53 and described in Table 23-34.

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QEP Source Select Register

Figure 23-53 QEPSRCSEL Register

31	30	29	28	27	26	25	24	23	22	21	20	19	18	17	16
RESERVED
R-0-0h

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
QEPSSEL				QEPISEL				QEPBSEL				QEPASEL
R/W-0h				R/W-0h				R/W-0h				R/W-0h

Table 23-34 QEPSRCSEL Register Field Descriptions

Bit	Field	Type	Reset	Description
31-16	RESERVED	R-0	0h	Reserved
15-12	QEPSSEL	R/W	0h	QEP Strobe source select: 0x0: From device Pins (Default). Others: Tied to zero. Reset type: SYSRSn
11-8	QEPISEL	R/W	0h	QEP Index source select: 0x0: Device Pin (Default) 0x1: CMPSS1.CTRIPH 0x2: CMPSS2.CTRIPH 0x3: CMPSS3.CTRIPH 0x4: CMPSS4.CTRIPH 0x5: CMPSS5.CTRIPH 0x6: CMPSS6.CTRIPH 0x7: CMPSS7.CTRIPH 0x8: CMPSS8.CTRIPH 0x9: PWMXBAR.1 0xA:PWMXBAR.2 0xB:PWMXBAR.3 0xC:PWMXBAR.4 0xD:PWMXBAR.5 0xE:PWMXBAR.6 0xF:PWMXBAR.7 Note: eQEP needs to be disabled before configuring these bits as it can lead to unexpected behavior if eQEP is running. Reset type: SYSRSn
7-4	QEPBSEL	R/W	0h	QEPB source select: 0x0: Device Pin (Default) 0x1: CMPSS1.CTRIPH 0x2: CMPSS2.CTRIPH 0x3: CMPSS3.CTRIPH 0x4: CMPSS4.CTRIPH 0x5: CMPSS5.CTRIPH 0x6: CMPSS6.CTRIPH 0x7: CMPSS7.CTRIPH 0x8: CMPSS8.CTRIPH 0x9: PWMXBAR.1 0xA:PWMXBAR.2 0xB:PWMXBAR.3 0xC:PWMXBAR.4 0xD:PWMXBAR.5 0xE:PWMXBAR.6 0xF:PWMXBAR.7 Note: eQEP needs to be disabled before configuring these bits as it can lead to unexpected behavior if eQEP is running. Reset type: SYSRSn
3-0	QEPASEL	R/W	0h	QEPA source select: 0x0: Device Pin (Default) 0x1: CMPSS1.CTRIPH 0x2: CMPSS2.CTRIPH 0x3: CMPSS3.CTRIPH 0x4: CMPSS4.CTRIPH 0x5: CMPSS5.CTRIPH 0x6: CMPSS6.CTRIPH 0x7: CMPSS7.CTRIPH 0x8: CMPSS8.CTRIPH 0x9: PWMXBAR.1 0xA:PWMXBAR.2 0xB:PWMXBAR.3 0xC:PWMXBAR.4 0xD:PWMXBAR.5 0xE:PWMXBAR.6 0xF:PWMXBAR.7 Note: eQEP needs to be disabled before configuring these bits as it can lead to unexpected behavior if eQEP is running. Reset type: SYSRSn