SPRUJF2A March   2026  â€“ March 2026 AM13E23019

 

  1.   1
  2.   Read This First
    1.     About This Manual
    2.     Notational Conventions
    3.     Glossary
    4.     Related Documentation
    5.     Support Resources
    6.     Trademarks
  3. Introduction
    1. 1.1 Overview
    2. 1.2 AM13E230x Architecture Overview
      1. 1.2.1 Bus, Power, Clock Organization
      2. 1.2.2 Device Block Diagram
      3. 1.2.3 Module Allocation and Instances
    3. 1.3 Platform Memory Map
      1. 1.3.1 Code Region
      2. 1.3.2 SRAM Region
      3. 1.3.3 Peripheral Region
      4. 1.3.4 Subsystem Region
      5. 1.3.5 External Memory Region
      6. 1.3.6 System PPB Region
    4. 1.4 Boot Configuration
      1. 1.4.1 Configuration Memory
      2. 1.4.2 FLNONMAINECC Registers
    5. 1.5 Factory Constants
      1. 1.5.1 FLASH Registers
    6. 1.6 Memory Configuration
      1. 1.6.1 MEMCFG Registers
        1. 1.6.1.1 MEMCFG Base Address Table
        2. 1.6.1.2 MEM_CFG_REGS Registers
  4. Peripheral Registers Memory Map
  5. Power Management and Clock Unit (PMCU)
    1. 3.1 PMCU Overview
      1. 3.1.1 Power Domains
      2. 3.1.2 Operating Modes
        1. 3.1.2.1 RUN Mode
        2. 3.1.2.2 SLEEP Mode
        3. 3.1.2.3 STOP Mode
        4. 3.1.2.4 STANDBY Mode
        5. 3.1.2.5 SHUTDOWN Mode
        6. 3.1.2.6 Supported Functionality by Operating Mode
    2. 3.2 Quick Start Reference
      1. 3.2.1 Increasing MCLK Precision
      2. 3.2.2 Configuring MCLK for Maximum Speed
      3. 3.2.3 High Speed Clock (SYSPLL, HFCLK) Handling in Low-Power Modes
    3. 3.3 Power Management (PMU)
      1. 3.3.1 Power Supply
        1. 3.3.1.1 Main LDO
        2. 3.3.1.2 STOP LDO
        3. 3.3.1.3 VOSC LDO
        4. 3.3.1.4 HPLL LDO
      2. 3.3.2 Supply Supervisors
        1. 3.3.2.1 Power-on Reset (POR)
        2. 3.3.2.2 Brownout Reset (BOR)
        3. 3.3.2.3 POR and BOR Behavior During Supply Changes
      3. 3.3.3 Bandgap Reference
      4. 3.3.4 Analog Supplies
        1. 3.3.4.1 Analog Reference Circuits
      5. 3.3.5 Internal Temperature Sensor
      6. 3.3.6 Peripheral Enable
        1. 3.3.6.1 Automatic Peripheral Disable in Low Power Modes
    4. 3.4 Clock Module (CKM)
      1. 3.4.1 Clock Tree
      2. 3.4.2 Oscillators
        1. 3.4.2.1 Internal Low-Frequency Oscillator (LFOSC)
        2. 3.4.2.2 Internal System Oscillator (SYSOSC)
          1. 3.4.2.2.1 SYSOSC Frequency
          2. 3.4.2.2.2 SYSOSC Frequency Correction Loop
            1. 3.4.2.2.2.1 SYSOSC FCL in Internal Resistor Mode
          3. 3.4.2.2.3 Disabling SYSOSC
        3. 3.4.2.3 System Phase-Locked Loop (SYSPLL)
          1. 3.4.2.3.1 Configuring SYSPLL Output Frequencies
          2. 3.4.2.3.2 Loading SYSPLL Lookup Parameters
          3. 3.4.2.3.3 SYSPLL Startup Time
        4. 3.4.2.4 External Crystal Oscillator (XTAL)
        5. 3.4.2.5 HFCLK_IN (Digital clock)
      3. 3.4.3 Clocks
        1. 3.4.3.1 MCLK (Main Clock) Tree
        2. 3.4.3.2 CPUCLK (Processor Clock)
        3. 3.4.3.3 ULPCLK (Low-Power Clock)
        4. 3.4.3.4 LFCLK (Low-Frequency Clock)
        5. 3.4.3.5 HFCLK (High-Frequency External Clock)
        6. 3.4.3.6 HSCLK (High Speed Clock)
        7. 3.4.3.7 CANCLK (CAN-FD Functional Clock)
        8. 3.4.3.8 External Clock Output (CLK_OUT)
      4. 3.4.4 Clock Monitors
        1. 3.4.4.1 MCLK Monitor
        2. 3.4.4.2 Startup Monitors
          1. 3.4.4.2.1 LFOSC Startup Monitor
          2. 3.4.4.2.2 HFCLK Startup Monitor
          3. 3.4.4.2.3 SYSPLL Startup Monitor
          4. 3.4.4.2.4 HSCLK Status
      5. 3.4.5 Frequency Clock Counter (FCC)
        1. 3.4.5.1 Using the FCC
        2. 3.4.5.2 FCC Frequency Computation and Accuracy
    5. 3.5 System Controller (SYSCTL)
      1. 3.5.1  Resets and Device Initialization
        1. 3.5.1.1 Reset Levels
          1. 3.5.1.1.1 Power-on Reset (POR) Reset Level
          2. 3.5.1.1.2 Brownout Reset (BOR) Reset Level
          3. 3.5.1.1.3 Boot Reset (BOOTRST) Reset Level
          4. 3.5.1.1.4 System Reset (SYSRST) Reset Level
          5. 3.5.1.1.5 CPU-only Reset (CPURST) Reset Level
        2. 3.5.1.2 Initial Conditions After Power-Up
        3. 3.5.1.3 NRST Pin
        4. 3.5.1.4 SWD/JTAG Pins
        5. 3.5.1.5 Generating Resets in Software
        6. 3.5.1.6 Reset Cause
        7. 3.5.1.7 Peripheral Reset Control
        8. 3.5.1.8 Boot Fail Handling
      2. 3.5.2  Operating Mode Selection
      3. 3.5.3  Asynchronous Fast Clock Requests
      4. 3.5.4  SRAM Write Protection
      5. 3.5.5  Flash Wait States
      6. 3.5.6  Flash Bank Address Swap
      7. 3.5.7  Shutdown Mode Handling
      8. 3.5.8  Configuration Lockout
      9. 3.5.9  System Status
      10. 3.5.10 Error Handling
      11. 3.5.11 SYSCTL Events
        1. 3.5.11.1 CPU Interrupt Events (CPU_INT)
        2. 3.5.11.2 CPU Nonmaskable Interrupt (NMI) Events
    6. 3.6 SYSCTL Registers
      1. 3.6.1 SYSCTL Base Address Table
      2. 3.6.2 SYSCTL_REGS Registers
  6. Central Processing Unit (CPU)
    1. 4.1 Overview
    2. 4.2 CPU
      1. 4.2.1 Arm Cortex-M33 CPU
      2. 4.2.2 CPU Register File
      3. 4.2.3 Stack Behavior
      4. 4.2.4 Execution Modes and Privilege Levels
      5. 4.2.5 Address Space and Supported Data Sizes
    3. 4.3 Interrupts and Exceptions
      1. 4.3.1 Peripheral Interrupts (IRQs)
        1. 4.3.1.1 Nested Vectored Interrupt Controller (NVIC)
        2. 4.3.1.2 Wake Up Controller (WUC)
      2. 4.3.2 Interrupt and Exception Table
      3. 4.3.3 Processor Lockup Scenario
    4. 4.4 CPU Peripherals
      1. 4.4.1 System Control Block (SCB)
      2. 4.4.2 System Tick Timer (SysTick)
      3. 4.4.3 Memory Protection Unit (MPU)
      4. 4.4.4 Floating Point Unit (FPU)
      5. 4.4.5 Digital Signal Processing Extension
      6. 4.4.6 Custom Datapath Extension TMU
    5. 4.5 Read-Only Memory (ROM)
  7. Trigonometric Math Unit (TMU)
    1. 5.1 Introduction
    2. 5.2 Features
    3. 5.3 Functional Operation
      1. 5.3.1 Supported TMU Instructions
  8. TinyEngineâ„¢ NPU
    1. 6.1 Introduction
      1. 6.1.1 TinyEngineâ„¢ NPU Related Collateral
  9. Secure ROM
    1. 7.1 ROM Overview
    2. 7.2 Memory Map
    3. 7.3 Boot Configuration Routine (BCR)
      1. 7.3.1 SWD Mass Erase and Factory Reset Commands
      2. 7.3.2 Fast Boot
    4. 7.4 Bootstrap Loader (BSL)
      1. 7.4.1 Application Version
      2. 7.4.2 GPIO Invoke
      3. 7.4.3 BSL Triggered Mass Erase and Factory Reset
    5. 7.5 Lifecycle Management
      1. 7.5.1 Device Sub-Type
      2. 7.5.2 Lifecycle Transitions
    6. 7.6 Boot and Startup Sequence
      1. 7.6.1 Secure Boot
      2. 7.6.2 Customer Secure Code (CSC)
  10. Global Security Controller (GSC)
    1. 8.1 GSC Introduction
      1. 8.1.1 GSC Features
    2. 8.2 GSC Operation
      1. 8.2.1 Functional Block Diagram
      2. 8.2.2 Peripheral Protection Controller
        1. 8.2.2.1 DMA Security
        2. 8.2.2.2 TinyEngine NPU Security
      3. 8.2.3 SRAM Protection Controller
        1. 8.2.3.1 SRAM Page Use Model
      4. 8.2.4 Flash Protection Controller
        1. 8.2.4.1 Flash Bank Security Implementation
        2. 8.2.4.2 Flash Hide Protection
      5. 8.2.5 Strict Privilege Context Protection
      6. 8.2.6 GSC Configuration Lock
    3. 8.3 GSC Registers
      1. 8.3.1 GSC Base Address Table
      2. 8.3.2 GSC_LITE_REGS Registers
  11. Direct Memory Access (DMA)
    1. 9.1 DMA Overview
    2. 9.2 DMA Operation
      1. 9.2.1  Channel Types
      2. 9.2.2  Channel Priorities
      3. 9.2.3  Initiating DMA Transfers
        1. 9.2.3.1 DMA - DMA Trigger Source Options
        2. 9.2.3.2 Cascading DMA Channels
      4. 9.2.4  Transfer Modes
        1. 9.2.4.1 Single Transfer
        2. 9.2.4.2 Block Transfer
        3. 9.2.4.3 Repeated Single Transfer
        4. 9.2.4.4 Repeated Block Transfer
        5. 9.2.4.5 Burst Block Mode
      5. 9.2.5  Pausing DMA Transfers
      6. 9.2.6  DMA Auto-enable
      7. 9.2.7  Addressing Modes
        1. 9.2.7.1 Basic Addressing Modes
        2. 9.2.7.2 Stride Mode
        3. 9.2.7.3 Extended Modes
          1. 9.2.7.3.1 Fill Mode
          2. 9.2.7.3.2 Table Mode
          3. 9.2.7.3.3 Gather Mode
      8. 9.2.8  DMA Controller Interrupts
        1. 9.2.8.1 Using DMA with System Interrupts
      9. 9.2.9  DMA Trigger Event Status
      10. 9.2.10 DMA Operating Mode Support
        1. 9.2.10.1 Transfer in RUN Mode
        2. 9.2.10.2 Transfer in SLEEP Mode
        3. 9.2.10.3 Transfer in STOP Mode
        4. 9.2.10.4 Transfers in STANDBY Mode
      11. 9.2.11 DMA Address and Data Errors
    3. 9.3 DMA Registers
      1. 9.3.1 DMA Base Address Table
      2. 9.3.2 DMA_REGS Registers
  12. 10Flash Module
    1. 10.1 Flash (NVM)
      1. 10.1.1 Introduction to Flash and OTP Memory
        1. 10.1.1.1 Flash Features
        2. 10.1.1.2 System Components
        3. 10.1.1.3 Terminology
      2. 10.1.2 Flash Memory Bank Organization
        1. 10.1.2.1 Banks
        2. 10.1.2.2 Flash Memory Regions
        3. 10.1.2.3 Addressing
          1. 10.1.2.3.1 Flash Memory Map
        4. 10.1.2.4 Memory Organization Examples
      3. 10.1.3 Flash Controller
        1. 10.1.3.1 Overview of Flash Controller Commands
        2. 10.1.3.2 Command Diagnostics
          1. 10.1.3.2.1 Command Status
          2. 10.1.3.2.2 Address Translation
          3. 10.1.3.2.3 Pulse Counts
        3. 10.1.3.3 NOOP Command
        4. 10.1.3.4 PROGRAM Command
          1. 10.1.3.4.1 Program Bit Masking Behavior
          2. 10.1.3.4.2 Target Data Alignment
          3. 10.1.3.4.3 Executing a PROGRAM Operation
        5. 10.1.3.5 ERASE Command
          1. 10.1.3.5.1 Erase Sector Masking Behavior
          2. 10.1.3.5.2 Executing an ERASE Operation
        6. 10.1.3.6 READVERIFY Command
          1. 10.1.3.6.1 Executing a READVERIFY Operation
        7. 10.1.3.7 Overriding the System Address With a Bank ID, Region ID, and Bank Address
        8. 10.1.3.8 FLASHCTL Events
      4. 10.1.4 Write Protection
        1. 10.1.4.1 Write Protection Resolution
        2. 10.1.4.2 Static Write Protection
        3. 10.1.4.3 Dynamic Write Protection
          1. 10.1.4.3.1 Configuring Protection for the MAIN Region
          2. 10.1.4.3.2 Configuring Protection for the NONMAIN Region
      5. 10.1.5 Flash Read Interface
        1. 10.1.5.1 Bank Modes and Swapping
        2. 10.1.5.2 Flash Wait States
        3. 10.1.5.3 Buffer and Cache Mechanisms
        4. 10.1.5.4 Flash Read Arbitration
        5. 10.1.5.5 Error Correction Code (ECC) Protection
        6. 10.1.5.6 Procedure to Change Flash Read Interface Registers
      6. 10.1.6 Read Interface
        1. 10.1.6.1 Bank Address Swapping
        2. 10.1.6.2 ECC Error Handling
          1. 10.1.6.2.1 Single bit (correctable) errors
          2. 10.1.6.2.2 Dual bit (uncorrectable) errors
    2. 10.2 FLASH Registers
      1. 10.2.1 FLASH Base Address Table
      2. 10.2.2 FLASH_CTRL_REGS Registers
      3. 10.2.3 NVMNW_REGS Registers
  13. 11Error Aggregator Module (EAM)
    1. 11.1 EAM
      1. 11.1.1 EAM Introduction
      2. 11.1.2 EAM Operation
        1. 11.1.2.1 Security Error Aggregator
        2. 11.1.2.2 Safety Error Aggregator
        3. 11.1.2.3 SYSMEM Access Error
    2. 11.2 EAM Registers
      1. 11.2.1 EAM Base Address Table
      2. 11.2.2 EAM_REGS Registers
  14. 12Events
    1. 12.1 Events Overview
      1. 12.1.1 Event Publisher
        1. 12.1.1.1 Standard Event Registers
      2. 12.1.2 Event Subscriber
      3. 12.1.3 Event Routing Map
      4. 12.1.4 Event Fabric Routing
        1. 12.1.4.1 CPU Interrupt Event Route (CPU_INT)
        2. 12.1.4.2 DMA Trigger Event Route (DMA_TRIG)
        3. 12.1.4.3 ADC Start Of Conversion Event Route (ADC_SOC)
      5. 12.1.5 Event Propagation Latency
  15. 13IOMUX
    1. 13.1 IOMUX
      1. 13.1.1 IOMUX Overview
        1. 13.1.1.1 IO Types and Analog Sharing
      2. 13.1.2 IOMUX Operation
        1. 13.1.2.1 Peripheral Function (PF) Assignment
        2. 13.1.2.2 Logic High to Hi-Z Conversion
        3. 13.1.2.3 Logic Inversion
        4. 13.1.2.4 SHUTDOWN Mode Wakeup Logic
        5. 13.1.2.5 Pullup/Pulldown Resistors
        6. 13.1.2.6 Drive Strength Control
    2. 13.2 IOMUX Registers
      1. 13.2.1 IOMUX Base Address Table
      2. 13.2.2 IOMUX_REGS Registers
  16. 14General Purpose Input/Output (GPIO)
    1. 14.1 General-Purpose Input/Output (GPIO)
      1. 14.1.1 GPIO Overview
      2. 14.1.2 GPIO Operation
        1. 14.1.2.1 GPIO Ports
        2. 14.1.2.2 GPIO Read/Write Interface
        3. 14.1.2.3 GPIO Input Glitch Filtering and Synchronization
        4. 14.1.2.4 GPIO Fast Wake
        5. 14.1.2.5 GPIO DMA Interface
        6. 14.1.2.6 Event Publishers
    2. 14.2 GPIO Registers
      1. 14.2.1 GPIO Base Address Table
      2. 14.2.2 GPIO_REGS Registers
  17. 15Analog-to-Digital Converter (ADC)
    1. 15.1  Introduction
      1. 15.1.1 Features
      2. 15.1.2 ADC Related Collateral
      3. 15.1.3 Block Diagram
    2. 15.2  ADC Configurability
      1. 15.2.1 ADC Clock Configuration
      2. 15.2.2 Resolution
      3. 15.2.3 Voltage Reference
        1. 15.2.3.1 External Reference Mode
        2. 15.2.3.2 Internal Reference Mode
        3. 15.2.3.3 Selecting Reference Mode
      4. 15.2.4 Signal Mode
        1. 15.2.4.1 Expected Conversion Results
        2. 15.2.4.2 Interpreting Conversion Results
    3. 15.3  SOC Principle of Operation
      1. 15.3.1 ADC Sequencer
      2. 15.3.2 SOC Configuration
      3. 15.3.3 Trigger Operation
        1. 15.3.3.1 Global Software Trigger
      4. 15.3.4 ADC Acquisition (Sample and Hold) Window
      5. 15.3.5 Sample Capacitor Reset
      6. 15.3.6 ADC Input Models
      7. 15.3.7 Channel Selection
    4. 15.4  SOC Configuration Examples
      1. 15.4.1 Single Conversion fromMCPWM Trigger
      2. 15.4.2 Oversampled Conversion from MCPWM Trigger
      3. 15.4.3 Software Triggering of SOCs
    5. 15.5  EOC and Interrupt Operation
      1. 15.5.1 Interrupt Overflow
      2. 15.5.2 Continue to Interrupt Mode
      3. 15.5.3 Early Interrupt Configuration Mode
    6. 15.6  Post-Processing Blocks
      1. 15.6.1 PPB Offset Correction
      2. 15.6.2 PPB Error Calculation
      3. 15.6.3 PPB Limit Detection and Zero-Crossing Detection
      4. 15.6.4 PPB Sample Delay Capture
      5. 15.6.5 PPB Oversampling
        1. 15.6.5.1 Accumulation and Average Functions
        2. 15.6.5.2 Outlier Rejection
    7. 15.7  Opens/Shorts Detection Circuit (OSDETECT)
      1. 15.7.1 Open Short Detection Implementation
      2. 15.7.2 Detecting an Open Input Pin
      3. 15.7.3 Detecting a Shorted Input Pin
    8. 15.8  Power-Up Sequence
    9. 15.9  ADC Calibration
    10. 15.10 ADC Timings
      1. 15.10.1 ADC Timing Diagrams
      2. 15.10.2 Post-Processing Block Timings
    11. 15.11 Additional Information
      1. 15.11.1  Ensuring Synchronous Operation
        1. 15.11.1.1 Basic Synchronous Operation
        2. 15.11.1.2 Synchronous Operation with Multiple Trigger Sources
        3. 15.11.1.3 Synchronous Operation with Uneven SOC Numbers
        4. 15.11.1.4 Non-overlapping Conversions
      2. 15.11.2  Choosing an Acquisition Window Duration
      3. 15.11.3  Achieving Simultaneous Sampling
      4. 15.11.4  Result Register Mapping
      5. 15.11.5  Internal Temperature Sensor
      6. 15.11.6  Designing an External Reference Circuit
      7. 15.11.7  ADC-DAC Loopback Testing
      8. 15.11.8  Internal Test Mode
      9. 15.11.9  ADC Gain and Offset Calibration
      10. 15.11.10 ADC Zero Offset Calibration
    12. 15.12 ADC Registers
      1. 15.12.1 ADC Base Address Table
      2. 15.12.2 ADC_LITE_REGS Registers
      3. 15.12.3 ADC_LITE_RESULT_REGS Registers
  18. 16Comparator Subsystem (CMPSS)
    1. 16.1 Introduction
      1. 16.1.1 Features
      2. 16.1.2 CMPSS Related Collateral
      3. 16.1.3 Block Diagram
    2. 16.2 Comparator
    3. 16.3 Reference DAC
    4. 16.4 Digital Filter
      1. 16.4.1 Filter Initialization Sequence
    5. 16.5 Using the CMPSS
      1. 16.5.1 LATCHCLR, and MCPWMSYNCPER Signals
      2. 16.5.2 Synchronizer, Digital Filter, and Latch Delays
      3. 16.5.3 Calibrating the CMPSS
      4. 16.5.4 Enabling and Disabling the CMPSS Clock
    6. 16.6 CMPSS DAC Output
    7. 16.7 CMPSS Registers
      1. 16.7.1 CMPSS Base Address Table
      2. 16.7.2 CMPSS_LITE_REGS Registers
  19. 17Programmable Gain Amplifier (PGA)
    1. 17.1  Programmable Gain Amplifier (PGA) Overview
      1. 17.1.1 Features
      2. 17.1.2 Block Diagram
        1. 17.1.2.1 PGA Mux Selection Options
    2. 17.2  Linear Output Range
    3. 17.3  Gain Values
    4. 17.4  Modes of Operation
      1. 17.4.1 Buffer Mode
      2. 17.4.2 Standalone Mode
      3. 17.4.3 Non-inverting Mode
      4. 17.4.4 Subtractor Mode
    5. 17.5  External Filtering
      1. 17.5.1 Low-Pass Filter Using Internal Filter Resistor and External Capacitor
      2. 17.5.2 Single Pole Low-Pass Filter Using Internal Gain Resistor and External Capacitor
    6. 17.6  Error Calibration
      1. 17.6.1 Offset Error
      2. 17.6.2 Gain Error
    7. 17.7  Chopping Feature
    8. 17.8  Enabling and Disabling the PGA Clock
    9. 17.9  Lock Register
    10. 17.10 Analog Front-End Integration
      1. 17.10.1 Buffered DAC
      2. 17.10.2 Analog-to-Digital Converter (ADC)
        1. 17.10.2.1 Unfiltered Acquisition Window
        2. 17.10.2.2 Filtered Acquisition Window
      3. 17.10.3 Comparator Subsystem (CMPSS)
      4. 17.10.4 PGA_NEG_SHARED Feature
      5. 17.10.5 Alternate Functions
    11. 17.11 Examples
      1. 17.11.1 Non-Inverting Amplifier Using Non-Inverting Mode
      2. 17.11.2 Buffer Mode
      3. 17.11.3 Low-Side Current Sensing
      4. 17.11.4 Bidirectional Current Sensing
    12. 17.12 PGA Registers
      1. 17.12.1 PGA Base Address Table
      2. 17.12.2 PGA_REGS Registers
  20. 18Multi-Channel Pulse Width Modulator (MCPWM)
    1. 18.1  Introduction
      1. 18.1.1 PWM Related Collateral
      2. 18.1.2 MCPWM Overview
    2. 18.2  Configuring Device Pins
    3. 18.3  MCPWM Modules Overview
    4. 18.4  Time-Base (TB) Submodule
      1. 18.4.1 Purpose of the Time-Base Submodule
      2. 18.4.2 Controlling and Monitoring the Time-Base Submodule
      3. 18.4.3 Calculating PWM Period and Frequency
        1. 18.4.3.1 Time-Base Period Shadow Register
        2. 18.4.3.2 Time-Base Clock Synchronization
        3. 18.4.3.3 Time-Base Counter Synchronization
        4. 18.4.3.4 MCPWM SYNC Selection
      4. 18.4.4 Phase Locking the Time-Base Clocks of Multiple MCPWM Modules
      5. 18.4.5 Time-Base Counter Modes and Timing Waveforms
      6. 18.4.6 Global Load
        1. 18.4.6.1 One-Shot Load Mode
    5. 18.5  Counter-Compare (CC) Submodule
      1. 18.5.1 Purpose of the Counter-Compare Submodule
      2. 18.5.2 Controlling and Monitoring the Counter-Compare Submodule
      3. 18.5.3 Operational Highlights for the Counter-Compare Submodule
      4. 18.5.4 Count Mode Timing Waveforms
    6. 18.6  Action-Qualifier (AQ) Submodule
      1. 18.6.1 Purpose of the Action-Qualifier Submodule
      2. 18.6.2 Action-Qualifier Submodule Control and Status Register Definitions
      3. 18.6.3 Action-Qualifier Event Priority
      4. 18.6.4 AQCTLA and AQCTLB Shadow Mode Operations
      5. 18.6.5 Configuration Requirements for Common Waveforms
    7. 18.7  Dead-Band Generator (DB) Submodule
      1. 18.7.1 Purpose of the Dead-Band Submodule
      2. 18.7.2 Dead-Band Submodule Additional Operating Modes
      3. 18.7.3 Operational Highlights for the Dead-Band Submodule
    8. 18.8  Trip-Zone (TZ) Submodule
      1. 18.8.1 Purpose of the Trip-Zone Submodule
      2. 18.8.2 Operational Highlights for the Trip-Zone Submodule
        1. 18.8.2.1 Trip-Zone Configurations
      3. 18.8.3 Generating Trip Event Interrupts
    9. 18.9  Event-Trigger (ET) Submodule
      1. 18.9.1 Operational Overview of the MCPWM Event-Trigger Submodule
    10. 18.10 PWM Crossbar (X-BAR)
    11. 18.11 MCPWM Registers
      1. 18.11.1 MCPWM Base Address Table
      2. 18.11.2 MCPWM_6CH_REGS Registers
  21. 19Enhanced Capture (eCAP)
    1. 19.1 Introduction
      1. 19.1.1 Features
      2. 19.1.2 ECAP Related Collateral
    2. 19.2 Description
    3. 19.3 Configuring Device Pins for the eCAP
    4. 19.4 Capture and APWM Operating Mode
    5. 19.5 Capture Mode Description
      1. 19.5.1 Event Prescaler
      2. 19.5.2 Edge Polarity Select and Qualifier
      3. 19.5.3 Continuous/One-Shot Control
      4. 19.5.4 32-Bit Counter and Phase Control
      5. 19.5.5 CAP1-CAP4 Registers
      6. 19.5.6 eCAP Synchronization
        1. 19.5.6.1 Example 1 - Using SWSYNC with ECAP Module
      7. 19.5.7 Interrupt Control
      8. 19.5.8 Shadow Load and Lockout Control
      9. 19.5.9 APWM Mode Operation
    6. 19.6 Application of the eCAP Module
      1. 19.6.1 Example 1 - Absolute Time-Stamp Operation Rising-Edge Trigger
      2. 19.6.2 Example 2 - Absolute Time-Stamp Operation Rising- and Falling-Edge Trigger
      3. 19.6.3 Example 3 - Time Difference (Delta) Operation Rising-Edge Trigger
      4. 19.6.4 Example 4 - Time Difference (Delta) Operation Rising- and Falling-Edge Trigger
    7. 19.7 Application of the APWM Mode
      1. 19.7.1 Example 1 - Simple PWM Generation (Independent Channels)
    8. 19.8 ECAP Registers
      1. 19.8.1 ECAP Base Address Table
      2. 19.8.2 ECAP_REGS Registers
  22. 20Enhanced Quadrature Encoder Pulse (eQEP)
    1. 20.1  Introduction
      1. 20.1.1 EQEP Related Collateral
    2. 20.2  Configuring Device Pins
    3. 20.3  Description
      1. 20.3.1 EQEP Inputs
      2. 20.3.2 Functional Description
      3. 20.3.3 eQEP Memory Map
    4. 20.4  Quadrature Decoder Unit (QDU)
      1. 20.4.1 Position Counter Input Modes
        1. 20.4.1.1 Quadrature Count Mode
        2. 20.4.1.2 Direction-Count Mode
        3. 20.4.1.3 Up-Count Mode
        4. 20.4.1.4 Down-Count Mode
      2. 20.4.2 eQEP Input Polarity Selection
      3. 20.4.3 Position-Compare Sync Output
    5. 20.5  Position Counter and Control Unit (PCCU)
      1. 20.5.1 Position Counter Operating Modes
        1. 20.5.1.1 Position Counter Reset on Index Event (QEPCTL[PCRM] = 00)
        2. 20.5.1.2 Position Counter Reset on Maximum Position (QEPCTL[PCRM] = 01)
        3. 20.5.1.3 Position Counter Reset on the First Index Event (QEPCTL[PCRM] = 10)
        4. 20.5.1.4 Position Counter Reset on Unit Time-out Event (QEPCTL[PCRM] = 11)
      2. 20.5.2 Position Counter Latch
        1. 20.5.2.1 Index Event Latch
        2. 20.5.2.2 Strobe Event Latch
      3. 20.5.3 Position Counter Initialization
      4. 20.5.4 eQEP Position-compare Unit
    6. 20.6  eQEP Edge Capture Unit
    7. 20.7  eQEP Watchdog
    8. 20.8  eQEP Unit Timer Base
    9. 20.9  QMA Module
      1. 20.9.1 Modes of Operation
        1. 20.9.1.1 QMA Mode-1 (QMACTRL[MODE] = 1)
        2. 20.9.1.2 QMA Mode-2 (QMACTRL[MODE] = 2)
      2. 20.9.2 Interrupt and Error Generation
    10. 20.10 eQEP Interrupt Structure
    11. 20.11 Software
      1. 20.11.1 EQEP Examples
        1. 20.11.1.1 Frequency Measurement Using eQEP
        2. 20.11.1.2 Position and Speed Measurement Using eQEP
        3. 20.11.1.3 PWM Frequency Measurement using EQEP via XBAR connection
        4. 20.11.1.4 Frequency Measurement Using eQEP via unit timeout interrupt
        5. 20.11.1.5 Motor speed and direction measurement using eQEP via unit timeout interrupt
    12. 20.12 EQEP Registers
      1. 20.12.1 EQEP Base Address Table
      2. 20.12.2 EQEP_REGS Registers
  23. 21Crossbar (X-BAR)
    1. 21.1 INPUTXBAR
    2. 21.2 MCPWM and GPIO Output X-BAR
      1. 21.2.1 MCPWM X-BAR
        1. 21.2.1.1 MCPWM X-BAR Architecture
      2. 21.2.2 GPIO Output X-BAR
        1. 21.2.2.1 GPIO Output X-BAR Architecture
      3. 21.2.3 X-BAR Flags
    3. 21.3 XBAR Registers
      1. 21.3.1 XBAR Base Address Table
      2. 21.3.2 INPUT_XBAR_REGS Registers
      3. 21.3.3 EPWM_XBAR_REGS Registers
      4. 21.3.4 OUTPUTXBAR_REGS Registers
      5. 21.3.5 SYNC_SOC_REGS Registers
      6. 21.3.6 OUTPUTXBAR_FLAG_REGS Registers
      7. 21.3.7 INPUT_FLAG_XBAR_REGS Registers
  24. 22Unified Communication Peripheral (UNICOMM)
    1. 22.1 Overview
      1. 22.1.1 Block Diagram
    2. 22.2 Unicomm Architecture
      1. 22.2.1 Scalable Peripheral Group (SPG) Configurations
        1. 22.2.1.1 Loopback Operation
        2. 22.2.1.2 I2C Pairings
      2. 22.2.2 FIFO Operation
        1. 22.2.2.1 Receive FIFO Levels
        2. 22.2.2.2 Transmitter FIFO Levels
        3. 22.2.2.3 Clearing FIFO Contents
        4. 22.2.2.4 FIFO Status Flags
      3. 22.2.3 Interrupts
        1. 22.2.3.1 Receive Interrupt Sequence
        2. 22.2.3.2 Transmit Interrupt Sequence
      4. 22.2.4 DMA Operation
    3. 22.3 High-Level Initialization
    4. 22.4 Enables & Resets
    5. 22.5 Suspending Communication
    6. 22.6 UNICOMM Registers
      1. 22.6.1 UNICOMM Base Address Table
      2. 22.6.2 UNICOMM_REGS Registers
    7. 22.7 SPG Registers
      1. 22.7.1 SPG Base Address Table
      2. 22.7.2 SPGSS_REGS Registers
  25. 23Universal Asychronous Receiver/Transmitter (UART)
    1. 23.1 Overview
      1. 23.1.1 Purpose of the Peripheral
      2. 23.1.2 Features
      3. 23.1.3 Functional Block Diagram
    2. 23.2 Peripheral Functional Description
      1. 23.2.1 Clock Control
      2. 23.2.2 General Architecture and Protocol
        1. 23.2.2.1 Signal Descriptions
        2. 23.2.2.2 Transmit and Receive Logic
        3. 23.2.2.3 Bit Sampling
        4. 23.2.2.4 Baud Rate Generation
        5. 23.2.2.5 Data Transmission
        6. 23.2.2.6 Error and Status
        7. 23.2.2.7 DMA Operation
        8. 23.2.2.8 Internal Loopback Operation
      3. 23.2.3 Additional Protocol and Feature Support
        1. 23.2.3.1 Local Interconnect Network (LIN) Support
          1. 23.2.3.1.1 LIN Commander Transmit
          2. 23.2.3.1.2 LIN Responder Receive
          3. 23.2.3.1.3 LIN Wakeup
        2. 23.2.3.2 Flow Control
        3. 23.2.3.3 RS485 Support
        4. 23.2.3.4 Idle-Line Multiprocessor
        5. 23.2.3.5 9-Bit UART Mode
        6. 23.2.3.6 ISO7816 Smart Card Support
        7. 23.2.3.7 Address Detection
      4. 23.2.4 Initialization
      5. 23.2.5 Interrupt and Events Support
        1. 23.2.5.1 CPU Interrupt Event Publisher (CPU_INT)
        2. 23.2.5.2 DMA Trigger Publisher (DMA_TRIG_RX, DMA_TRIG_TX)
      6. 23.2.6 Emulation Modes
    3. 23.3 UNICOMM-UART Registers
      1. 23.3.1 UNICOMM-UART Base Address Table
      2. 23.3.2 UNICOMMUART_REGS Registers
  26. 24Inter-Integrated Circuit (I2C)
    1. 24.1 Overview
      1. 24.1.1 Purpose of the Peripheral
      2. 24.1.2 Features
      3. 24.1.3 Functional Block Diagram
    2. 24.2 Peripheral Functional Description
      1. 24.2.1 Clock Control
        1. 24.2.1.1 Clock Select and I2C Speed
        2. 24.2.1.2 Clock Startup
      2. 24.2.2 Signal Descriptions
      3. 24.2.3 General Architecture
        1. 24.2.3.1  I2C Bus Functional Overview
        2. 24.2.3.2  START and STOP Conditions
        3. 24.2.3.3  7-Bit Address Format
        4. 24.2.3.4  10-Bit Address Format
        5. 24.2.3.5  General Call
        6. 24.2.3.6  Dual Address
        7. 24.2.3.7  Acknowledge
        8. 24.2.3.8  Repeated Start
        9. 24.2.3.9  Clock Low Timeout
        10. 24.2.3.10 Clock Stretching
        11. 24.2.3.11 Arbitration
        12. 24.2.3.12 Multiple Controller Mode
        13. 24.2.3.13 Glitch Suppression
        14. 24.2.3.14 Burst Mode
        15. 24.2.3.15 DMA Operation
        16. 24.2.3.16 SMBus 3.0 Support
          1. 24.2.3.16.1 Quick Command
          2. 24.2.3.16.2 Acknowledge Control
          3. 24.2.3.16.3 Clock Low Timeout Detection
          4. 24.2.3.16.4 Clock High Timeout Detection
          5. 24.2.3.16.5 Cumulative clock low extended timeout for controller and target
          6. 24.2.3.16.6 Packet Error Checking (PEC)
          7. 24.2.3.16.7 Host Notify Protocol
          8. 24.2.3.16.8 Alert Response Protocol
          9. 24.2.3.16.9 Address Resolution Protocol
      4. 24.2.4 Protocol Descriptions
        1. 24.2.4.1 I2C Controller Mode
          1. 24.2.4.1.1 I2C Controller Initialization
          2. 24.2.4.1.2 I2C Controller Status
          3. 24.2.4.1.3 I2C Controller Receive Mode
          4. 24.2.4.1.4 I2C Controller Transmitter Mode
          5. 24.2.4.1.5 Controller Configuration
        2. 24.2.4.2 I2C Target Mode
          1. 24.2.4.2.1 I2C Target Initialization
          2. 24.2.4.2.2 I2C Target Status
          3. 24.2.4.2.3 I2C Target Receiver Mode
          4. 24.2.4.2.4 I2C Target Transmitter Mode
      5. 24.2.5 Reset Considerations
      6. 24.2.6 Interrupt and Events Support
        1. 24.2.6.1 CPU Interrupt Event Publisher (CPU_INT)
        2. 24.2.6.2 DMA Trigger Publisher (DMA_TRIG_RX, DMA_TRIG_TX)
      7. 24.2.7 Emulation Modes
    3. 24.3 UNICOMM-I2C Registers
      1. 24.3.1 UNICOMM-I2C Base Address Table
      2. 24.3.2 UNICOMMI2CC_REGS Registers
      3. 24.3.3 UNICOMMI2CT_REGS Registers
  27. 25Serial Peripheral Interface (SPI)
    1. 25.1 Overview
      1. 25.1.1 Purpose of the Peripheral
      2. 25.1.2 Features
      3. 25.1.3 Functional Block Diagram
    2. 25.2 Peripheral Functional Description
      1. 25.2.1 Clock Control
      2. 25.2.2 General Architecture
        1. 25.2.2.1 Chip Select Control
        2. 25.2.2.2 Data Format
        3. 25.2.2.3 Delayed Data Sampling
        4. 25.2.2.4 Clock Generation
        5. 25.2.2.5 SPI FIFO Operation
        6. 25.2.2.6 DMA Operation
      3. 25.2.3 Internal Loopback Operation
      4. 25.2.4 Protocol Descriptions
        1. 25.2.4.1 Motorola SPI Frame Format
        2. 25.2.4.2 Texas Instruments Synchronous Serial Frame Format
      5. 25.2.5 Status Flags
      6. 25.2.6 Initialization
      7. 25.2.7 Interrupt and Events Support
        1. 25.2.7.1 CPU Interrupt Event Publisher (CPU_INT)
        2. 25.2.7.2 DMA Trigger Publisher (DMA_TRIG_RX, DMA_TRIG_TX)
      8. 25.2.8 Emulation Modes
    3. 25.3 UNICOMM-SPI Registers
      1. 25.3.1 UNICOMM-SPI Base Address Table
      2. 25.3.2 UNICOMMSPI_REGS Registers
  28. 26Modular Controller Area Network (MCAN)
    1. 26.1 CAN-FD
      1. 26.1.1 MCAN Overview
        1. 26.1.1.1 MCAN Features
      2. 26.1.2 MCAN Environment
      3. 26.1.3 CAN Network Basics
      4. 26.1.4 MCAN Functional Description
        1. 26.1.4.1  Clock Setup
        2. 26.1.4.2  Module Clocking Requirements
        3. 26.1.4.3  Interrupt Requests
        4. 26.1.4.4  Operating Modes
          1. 26.1.4.4.1 Normal Operation
          2. 26.1.4.4.2 CAN Classic
          3. 26.1.4.4.3 CAN FD Operation
        5. 26.1.4.5  Software Initialization
        6. 26.1.4.6  Transmitter Delay Compensation
          1. 26.1.4.6.1 Description
          2. 26.1.4.6.2 Transmitter Delay Compensation Measurement
        7. 26.1.4.7  Restricted Operation Mode
        8. 26.1.4.8  Bus Monitoring Mode
        9. 26.1.4.9  Disabled Automatic Retransmission (DAR) Mode
          1. 26.1.4.9.1 Frame Transmission in DAR Mode
        10. 26.1.4.10 Clock Stop Mode
          1. 26.1.4.10.1 Suspend Mode
          2. 26.1.4.10.2 Wakeup Request
        11. 26.1.4.11 Test Modes
          1. 26.1.4.11.1 External Loop Back Mode
          2. 26.1.4.11.2 Internal Loop Back Mode
        12. 26.1.4.12 Timestamp Generation
          1. 26.1.4.12.1 External Timestamp Counter
        13. 26.1.4.13 Timeout Counter
        14. 26.1.4.14 Safety
          1. 26.1.4.14.1 MCAN ECC Wrapper
          2. 26.1.4.14.2 MCAN ECC Aggregator
            1. 26.1.4.14.2.1 MCAN ECC Aggregator Overview
            2. 26.1.4.14.2.2 MCAN ECC Aggregator Registers
          3. 26.1.4.14.3 Reads to ECC Control and Status Registers
          4. 26.1.4.14.4 ECC Interrupts
        15. 26.1.4.15 Tx Handling
          1. 26.1.4.15.1 Transmit Pause
          2. 26.1.4.15.2 Dedicated Tx Buffers
          3. 26.1.4.15.3 Tx FIFO
          4. 26.1.4.15.4 Tx Queue
          5. 26.1.4.15.5 Mixed Dedicated Tx Buffers/Tx FIFO
          6. 26.1.4.15.6 Mixed Dedicated Tx Buffers/Tx Queue
          7. 26.1.4.15.7 Transmit Cancellation
          8. 26.1.4.15.8 Tx Event Handling
          9. 26.1.4.15.9 FIFO Acknowledge Handling
        16. 26.1.4.16 Rx Handling
          1. 26.1.4.16.1 Acceptance Filtering
            1. 26.1.4.16.1.1 Range Filter
            2. 26.1.4.16.1.2 Filter for Specific IDs
            3. 26.1.4.16.1.3 Classic Bit Mask Filter
            4. 26.1.4.16.1.4 Standard Message ID Filtering
            5. 26.1.4.16.1.5 Extended Message ID Filtering
        17. 26.1.4.17 Rx FIFOs
          1. 26.1.4.17.1 Rx FIFO Blocking Mode
          2. 26.1.4.17.2 Rx FIFO Overwrite Mode
        18. 26.1.4.18 Dedicated Rx Buffers
          1. 26.1.4.18.1 Rx Buffer Handling
        19. 26.1.4.19 Message RAM
          1. 26.1.4.19.1 Message RAM Configuration
          2. 26.1.4.19.2 Rx Buffer and FIFO Element
          3. 26.1.4.19.3 Tx Buffer Element
          4. 26.1.4.19.4 Tx Event FIFO Element
          5. 26.1.4.19.5 Standard Message ID Filter Element
          6. 26.1.4.19.6 Extended Message ID Filter Element
      5. 26.1.5 MCAN Integration
      6. 26.1.6 Interrupt and Event Support
        1. 26.1.6.1 CPU Interrupt Event Publisher (CPU_INT)
    2. 26.2 MCAN Registers
      1. 26.2.1 MCAN Base Address Table
      2. 26.2.2 MCAN_REGS Registers
  29. 27External Peripheral Interface (EPI)
    1. 27.1 External Peripheral Interface (EPI)
      1. 27.1.1 Introduction
      2. 27.1.2 EPI Block Diagram
      3. 27.1.3 Functional Description
        1. 27.1.3.1 Controller Access to EPI
        2. 27.1.3.2 Nonblocking Reads
        3. 27.1.3.3 DMA Operation
      4. 27.1.4 Initialization and Configuration
        1. 27.1.4.1 EPI Interface Options
        2. 27.1.4.2 SDRAM Mode
          1. 27.1.4.2.1 External Signal Connections
          2. 27.1.4.2.2 Refresh Configuration
          3. 27.1.4.2.3 Bus Interface Speed
          4. 27.1.4.2.4 Nonblocking Read Cycle
          5. 27.1.4.2.5 Normal Read Cycle
          6. 27.1.4.2.6 Write Cycle
        3. 27.1.4.3 Host Bus Mode
          1. 27.1.4.3.1 Control Pins
          2. 27.1.4.3.2 PSRAM Support
          3. 27.1.4.3.3 Host Bus 16-Bit Muxed Interface
          4. 27.1.4.3.4 Speed of Transactions
          5. 27.1.4.3.5 Sub-Modes of Host Bus 8 and 16
          6. 27.1.4.3.6 Bus Operation
        4. 27.1.4.4 General-Purpose Mode
          1. 27.1.4.4.1 Bus Operation
            1. 27.1.4.4.1.1 FRAME Signal Operation
            2. 27.1.4.4.1.2 EPI Clock Operation
    2. 27.2 EPI Registers
      1. 27.2.1 EPI Base Address Table
      2. 27.2.2 EPI_REGS_GPCFG Registers
      3. 27.2.3 EPI_REGS_SDRAMCFG Registers
      4. 27.2.4 EPI_REGS_HB8CFG Registers
      5. 27.2.5 EPI_REGS_HB16CFG Registers
  30. 28Cyclic Redundancy Check (CRC)
    1. 28.1 CRC
      1. 28.1.1 CRC Overview
        1. 28.1.1.1 CRC16-CCITT
        2. 28.1.1.2 CRC32-ISO3309
      2. 28.1.2 CRC Operation
        1. 28.1.2.1 CRC Generator Implementation
        2. 28.1.2.2 Configuration
          1. 28.1.2.2.1 Polynomial Selection
          2. 28.1.2.2.2 Bit Order
          3. 28.1.2.2.3 Byte Swap
          4. 28.1.2.2.4 Byte Order
          5. 28.1.2.2.5 CRC C Library Compatibility
    2. 28.2 CRC Registers
      1. 28.2.1 CRC Base Address Table
      2. 28.2.2 CRCP_REGS Registers
  31. 29Advanced Encryption Standard (AES) Accelerator
    1. 29.1 AESADV
      1. 29.1.1 AES Overview
        1. 29.1.1.1 AESADV Performance
      2. 29.1.2 AESADV Operation
        1. 29.1.2.1 Loading the Key
        2. 29.1.2.2 Writing Input Data
        3. 29.1.2.3 Reading Output Data
        4. 29.1.2.4 Operation Descriptions
          1. 29.1.2.4.1 Single Block Operation
          2. 29.1.2.4.2 Electronic Codebook (ECB) Mode
            1. 29.1.2.4.2.1 ECB Encryption
            2. 29.1.2.4.2.2 ECB Decryption
          3. 29.1.2.4.3 Cipher Block Chaining (CBC) Mode
            1. 29.1.2.4.3.1 CBC Encryption
            2. 29.1.2.4.3.2 CBC Decryption
          4. 29.1.2.4.4 Output Feedback (OFB) Mode
            1. 29.1.2.4.4.1 OFB Encryption
            2. 29.1.2.4.4.2 OFB Decryption
          5. 29.1.2.4.5 Cipher Feedback (CFB) Mode
            1. 29.1.2.4.5.1 CFB Encryption
            2. 29.1.2.4.5.2 CFB Decryption
          6. 29.1.2.4.6 Counter (CTR) Mode
            1. 29.1.2.4.6.1 CTR Encryption
            2. 29.1.2.4.6.2 CTR Decryption
          7. 29.1.2.4.7 Galois Counter (GCM) Mode
            1. 29.1.2.4.7.1 GHASH Operation
            2. 29.1.2.4.7.2 GCM Operating Modes
              1. 29.1.2.4.7.2.1 Autonomous GCM Operation
                1. 29.1.2.4.7.2.1.1 GMAC
              2. 29.1.2.4.7.2.2 GCM With Pre-Calculations
              3. 29.1.2.4.7.2.3 GCM Operation With Precalculated H- and Y0-Encrypted Forced to Zero
          8. 29.1.2.4.8 Counter With Cipher Block Chaining Message Authentication Code (CCM)
            1. 29.1.2.4.8.1 CCM Operation
        5. 29.1.2.5 AES Events
          1. 29.1.2.5.1 CPU Interrupt Event Publisher (CPU_EVENT)
          2. 29.1.2.5.2 DMA Trigger Event Publisher (DMA_TRIG_DATAIN)
          3. 29.1.2.5.3 DMA Trigger Event Publisher (DMA_TRIG_DATAOUT)
    2. 29.2 AES Registers
      1. 29.2.1 AES Base Address Table
      2. 29.2.2 AES_REGS Registers
  32. 30Keystore
    1. 30.1 Keystore
      1. 30.1.1 Overview
      2. 30.1.2 Detailed Description
    2. 30.2 KEYSTORE Registers
      1. 30.2.1 KEYSTORE Base Address Table
      2. 30.2.2 KEYSTORE_REGS Registers
  33. 31Timers
    1. 31.1 Timers (TIMx)
      1. 31.1.1 TIMx Overview
        1. 31.1.1.1 TIMx Instance Configuration
        2. 31.1.1.2 TIMG Features
        3. 31.1.1.3 Functional Block Diagram
      2. 31.1.2 TIMx Operation
        1. 31.1.2.1 Timer Counter
          1. 31.1.2.1.1 Clock Source Select and Prescaler
            1. 31.1.2.1.1.1 Internal Clock and Prescaler
            2. 31.1.2.1.1.2 External Signal Trigger
        2. 31.1.2.2 Counting Mode Control
          1. 31.1.2.2.1 One-shot and Periodic Modes
          2. 31.1.2.2.2 Down Counting Mode
          3. 31.1.2.2.3 Up/Down Counting Mode
          4. 31.1.2.2.4 Up Counting Mode
        3. 31.1.2.3 Capture/Compare Module
          1. 31.1.2.3.1 Capture Mode
            1. 31.1.2.3.1.1 Input Selection, Counter Conditions, and Inversion
              1. 31.1.2.3.1.1.1 CCP Input Edge Synchronization
              2. 31.1.2.3.1.1.2 Input Selection
              3. 31.1.2.3.1.1.3 CCP Input Filtering
              4. 31.1.2.3.1.1.4 CCP Input Pulse Conditions
              5. 31.1.2.3.1.1.5 Counter Control Operation
            2. 31.1.2.3.1.2 Capture Mode Use Cases
              1. 31.1.2.3.1.2.1 Edge Time Capture
              2. 31.1.2.3.1.2.2 Period Capture
              3. 31.1.2.3.1.2.3 Pulse Width Capture
              4. 31.1.2.3.1.2.4 Combined Pulse Width and Period Time
          2. 31.1.2.3.2 Compare Mode
            1. 31.1.2.3.2.1 Edge Count
        4. 31.1.2.4 Shadow Load and Shadow Compare
          1. 31.1.2.4.1 Shadow Load (TIMG4-7)
          2. 31.1.2.4.2 Shadow Compare (TIMG4-7, TIMG12-13)
        5. 31.1.2.5 Output Generator
          1. 31.1.2.5.1 Configuration
          2. 31.1.2.5.2 Use Cases
            1. 31.1.2.5.2.1 Edge-Aligned PWM
            2. 31.1.2.5.2.2 Center-Aligned PWM
          3. 31.1.2.5.3 Forced Output
        6. 31.1.2.6 Synchronization With Cross Trigger
          1. 31.1.2.6.1 Main Timer Cross Trigger Configuration
          2. 31.1.2.6.2 Secondary Timer Cross Trigger Configuration
        7. 31.1.2.7 Low Power Operation
        8. 31.1.2.8 Interrupt and Event Support
          1. 31.1.2.8.1 CPU Interrupt Event Publisher (CPU_INT)
          2. 31.1.2.8.2 GEN_EVENT0 and GEN_EVENT1
        9. 31.1.2.9 944
    2. 31.2 TIMERS Registers
      1. 31.2.1 TIMERS Base Address Table
      2. 31.2.2 TIMG4_REGS Registers
      3. 31.2.3 TIMG12_REGS Registers
  34. 32Windowed Watchdog Timer (WWDT)
    1. 32.1 Window Watchdog Timer (WWDT)
      1. 32.1.1 WWDT Overview
        1. 32.1.1.1 Watchdog Mode
        2. 32.1.1.2 Interval Timer Mode
      2. 32.1.2 WWDT Operation
        1. 32.1.2.1 Mode Selection
        2. 32.1.2.2 Clock Configuration
        3. 32.1.2.3 Low-Power Mode Behavior
        4. 32.1.2.4 Debug Behavior
        5. 32.1.2.5 WWDT Events
          1. 32.1.2.5.1 CPU Interrupt Event (CPU_INT)
    2. 32.2 WWDT Registers
      1. 32.2.1 WWDT Base Address Table
      2. 32.2.2 WWDT_REGS Registers
  35. 33Debug Subsystem (DEBUGSS)
    1. 33.1 Debug Subsystem
      1. 33.1.1 DEBUGSS Overview
        1. 33.1.1.1 Debug Interconnect
        2. 33.1.1.2 Physical Interfaces
          1. 33.1.1.2.1 JTAG Debug Port (JTAG-DP)
          2. 33.1.1.2.2 Serial Wire Debug (SWD) Debug Port (SW-DP)
          3. 33.1.1.2.3 Serial Wire Debug and JTAG Debug Port (SWJ-DP)
          4. 33.1.1.2.4 Debug Wake Up and Interrupts
        3. 33.1.1.3 Debug Access Ports
      2. 33.1.2 DEBUGSS Operation
        1. 33.1.2.1 Debug Features
          1. 33.1.2.1.1 Processor Debug
            1. 33.1.2.1.1.1 Breakpoint Unit (BPU)
            2. 33.1.2.1.1.2 Data Watchpoint and Trace Unit (DWT)
            3. 33.1.2.1.1.3 Processor Trace (MTB)
            4. 33.1.2.1.1.4 External Trace (ETM)
          2. 33.1.2.1.2 Peripheral Debug
          3. 33.1.2.1.3 EnergyTrace Technology
        2. 33.1.2.2 Behavior in Low Power Modes
        3. 33.1.2.3 Restricting Debug Access
        4. 33.1.2.4 Mailbox (DSSM)
          1. 33.1.2.4.1 DSSM Events
            1. 33.1.2.4.1.1 CPU Interrupt Event (CPU_INT)
          2. 33.1.2.4.2 DSSM Commands
    2. 33.2 DEBUGSS Registers
      1. 33.2.1 DEBUGSS Base Address Table
      2. 33.2.2 DEBUGSS_REGS Registers
  36. 34Revision History

25.2.4.1 Motorola SPI Frame Format

The Motorola SPI interface is a 4-wire interface where the CS signal behaves as a peripheral select. In the 3-wire mode, the CS signal is not required and the module behaves as if always selected. The main feature of the Motorola SPI format is that the inactive state and phase of the SCLK signal can be programmed through the SPO and SPH bits in the CTL0 control register.

SPO Clock Polarity Bit

If the CTL0.SPO clock polarity control bit is clear, the bit produces a steady-state low value on the SCLK pin when data is not being transferred. If the CTL0.SPO bit is set, the bit places a steady-state high value on the SCLK pin when data is not being transferred.

SPH Phase-Control Bit

The CTL0.SPH phase-control bit selects the clock edge that captures data, and allows it to change state. The state of this bit has the most impact on the first bit transmitted, by either allowing or not allowing a clock transition before the first data capture edge. If the CTL0.SPH phase-control bit is clear, data is captured on the first clock edge transition. If the SPH bit is set, data is captured on the second clock edge transition.

The serial clock (SCLK) is held inactive while the SPI is IDLE. SCLK transitions at the programmed frequency only during active transmission or reception of data. The IDLE state of SCLK provides a receive timeout indication that occurs when the RX FIFO still contains data after a timeout period.

Motorola SPI Frame Format with SPO = 0 and SPH = 0

Figure 25-3 shows signal sequences for Motorola SPI format with SPO = 0 and SPH = 0.

AM13E23x Motorola SPI Format With SPO = 0 and SPH = 0 Figure 25-3 Motorola SPI Format With SPO = 0 and SPH = 0

In this configuration, the following occurs during idle periods:

  • SCLK is forced low
  • CS is forced high
  • The transmit data line PICO is forced low
  • The UNICOMM-SPI enables the SCLK pin when configured as a controller
  • The UNICOMM-SPI disables the SCLK pin when configured as a peripheral

If the SPI is enabled and the TX FIFO contains valid data, the CS controller signal is driven low at the start of transmission, enabling peripheral data onto the POCI input line of the controller. The controller PICO output pin is enabled.

One-half SCLK period later, valid controller data is transferred to the PICO pin. Once both the controller and peripheral data are set, the SCLK controller clock pin goes high after an additional one-half SCLK period. The data is now captured on the rising edges and propagated on the falling edges of the SCLK signal.

For a single-word transmission, after all bits of the data word are transferred, the CS line is returned to the IDLE high state one SCLK period after the last bit is captured. For continuous back-to-back transmissions, the CS signal must pulse high between each data-word transfer because the peripheral-select pin freezes the data in the serial peripheral register and prevents altering the data if the SPH bit is clear. The controller device must raise the CS pin of the peripheral device between each data transfer to enable the serial peripheral data write. When the continuous transfer completes, the CS pin is returned to the IDLE state one SCLK period after the last bit is captured.

Motorola SPI Frame Format with SPO = 0 and SPH = 1

Figure 25-4 shows the signal sequence for Motorola SPI format with SPO = 0 and SPH = 1.

AM13E23x Motorola SPI Frame Format With SPO = 0 and SPH = 1 Figure 25-4 Motorola SPI Frame Format With SPO = 0 and SPH = 1
In this configuration, the following occurs during idle periods:
  • SCLK is forced low
  • CS is forced high
  • The transmit data line PICO is forced low
  • The UNICOMM-SPI enables the SCLK pin when configured as a controller
  • The UNICOMM-SPI disables the SCLK pin when configured as a peripheral

If the SPI is enabled and valid data is present in the TX FIFO, CS controller signal goes low at the start of transmission.The controller PICO output is enabled. After an additional one-half SCLK period, both controller and peripheral valid data are enabled onto the respective transmission lines. At the same time, SCLK is enabled with a rising-edge transition. Data is then captured on the falling edges and propagated on the rising edges of the SCLK signal.

Fora single-word transfer, after all bits are transferred, the CS line is returned to the IDLE high state one SCLK period after the last bit is captured. For continuous back-to-back transfers, the CS pin is held low between successive data words and terminates like a single-word transfer.

Motorola SPI Frame Format with SPO = 1 and SPH = 0

Figure 25-5 shows signal sequences for Motorola SPI format with SPO = 1 and SPH = 0.

AM13E23x Motorola SPI Frame Format With SPO = 1 and SPH = 0 Figure 25-5 Motorola SPI Frame Format With SPO = 1 and SPH = 0

In this configuration, the following occurs during idle periods:

  • SCLK is forced high
  • CS is forced high
  • The transmit data line PICO is arbitrarily forced low
  • The UNICOMM-SPI enables the SCLK pin when configured as a controller
  • The UNICOMM-SPI disables the SCLK pin when configured as a peripheral
If the SPI is enabled and valid data is in the TX FIFO, the SPI CS controller signal goes low at the start of transmission and transfers the peripheral data to the controller's POCI line immediately. The controller PICO output pin is enabled.

One-half SCLK period later, valid controller data is transferred to the PICO line. When both the controller and peripheral data have been set, the SCLK controller clock pin becomes low after one additional half SCLK period. Data is captured on the falling edges and propagated on the rising edges of the SCLK signal.

For a single-word transmission after all bits of the data word are transferred, the CS line is returned to the IDLE high state one SCLK period after the last bit is captured. For continuous back-to-back transmissions, the CS signal must pulse high between each data-word transfer, as the peripheral-select pin freezes the data in the serial peripheral register and prevents the data from being altered when the SPH bit is clear. The controller device must raise the CS pin of the peripheral device between each data transfer to enable the serial peripheral data write. When the continuous transfer completes, the CS pin returns to the IDLE state one SCLK period after the last bit is captured.

Motorola SPI Frame Format with SPO = 1 and SPH = 1

Figure 25-6 shows the signal sequence for Motorola SPI format with SPO = 1 and SPH = 1.

AM13E23x Motorola SPI Frame Format With SPO = 1 and SPH = 1

In this configuration, the following occurs during idle periods:

  • SCLK is forced high
  • CS is forced high
  • The transmit data line PICO is arbitrarily forced low
  • The UNICOMM-SPI enables the SCLK pin when configured as a controller
  • The UNICOMM-SPI disables the SCLK pin when configured as a peripheral

If the SPI is enabled and valid data is in the TX FIFO, the start of transmission is signified by the CS controller signal going low. The controller PICO output pin is enabled. After an additional one-half SCLK period, both controller and peripheral data is transmitted onto their respective transmission lines. At the same time, SCLK is enabled with a falling-edge transition. Data is then captured on the rising edges and propagated on the falling edges of the SCLK signal.

For a single word transmission, after all bits are transferred, the CS line returns to its IDLE high state one SCLK period after the last bit is captured. For continuous back-to-back transmissions, the CS pin remains in its active low state until the final bit of the last word is captured and then returns to its IDLE state. For continuous back-to-back transfers, the CS pin is held low between successive data words and terminates like a single-word transfer.

Figure 25-6 Motorola SPI Frame Format With SPO = 1 and SPH = 1