米6体育平台手机版

SLAU846A June 2023 – October 2023 MSPM0G1105 , MSPM0G1106 , MSPM0G1107 , MSPM0G1505 , MSPM0G1506 , MSPM0G1507 , MSPM0G3105 , MSPM0G3105-Q1 , MSPM0G3106 , MSPM0G3106-Q1 , MSPM0G3107 , MSPM0G3107-Q1 , MSPM0G3505 , MSPM0G3505-Q1 , MSPM0G3506 , MSPM0G3506-Q1 , MSPM0G3507 , MSPM0G3507-Q1

1
Read This First
1. About This Manual
2. Notational Conventions
3. Glossary
4. Support Resources
5. Trademarks
1 Architecture
1. 1.1 Architecture Overview
2. 1.2 Bus Organization
3. 1.3 Platform Memory Map
4. 1.4 Boot Configuration
5. 1.5 NONMAIN Registers
6. 1.6 Factory Constants
  1. 1.6.1 FACTORYREGION Registers
2 PMCU
1. 2.1 PMCU Overview
  1. 2.1.1 Power Domains
  2. 2.1.2 Operating Modes
2. 2.2 Power Management (PMU)
3. 2.3 Clock Module (CKM)
4. 2.4 System Controller (SYSCTL)
5. 2.5 Quick Start Reference
6. 2.6 SYSCTL Registers
3 CPU
1. 3.1 Overview
2. 3.2 Arm Cortex-M0+ CPU
3. 3.3 Interrupts and Exceptions
4. 3.4 CPU Peripherals
5. 3.5 Read-Only Memory (ROM)
6. 3.6 CPUSS Registers
7. 3.7 WUC Registers
4 DMA
1. 4.1 DMA Overview
2. 4.2 DMA Operation
3. 4.3 DMA Registers
5 MATHACL
1. 5.1 Overview
2. 5.2 Data Format
3. 5.3 Basic Operation
4. 5.4 Configuration Details with Examples
5. 5.5 MATHACL Registers
6 NVM (Flash)
1. 6.1 NVM Overview
2. 6.2 Flash Memory Bank Organization
3. 6.3 Flash Controller
4. 6.4 Write Protection
5. 6.5 Read Interface
  1. 6.5.1 Bank Address Swapping
  2. 6.5.2 ECC Error Handling
    1. 6.5.2.1 Single bit (correctable) errors
    2. 6.5.2.2 Dual bit (uncorrectable) errors
6. 6.6 FLASHCTL Registers
7 Events
1. 7.1 Events Overview
2. 7.2 Events Operation
8 IOMUX
1. 8.1 IOMUX Overview
  1. 8.1.1 IO Types and Analog Sharing
2. 8.2 IOMUX Operation
3. 8.3 IOMUX (PINCMx) Register Format
4. 8.4 IOMUX Registers
9 GPIO
1. 9.1 GPIO Overview
2. 9.2 GPIO Operation
3. 9.3 GPIO Registers
10ADC
1. 10.1 ADC Overview
2. 10.2 ADC Operation
3. 10.3 ADC12 Registers
11COMP
1. 11.1 Comparator Overview
2. 11.2 Comparator Operation
3. 11.3 COMP Registers
12OPA
1. 12.1 OPA Overview
2. 12.2 OPA Operation
3. 12.3 OA Registers
13GPAMP
1. 13.1 GPAMP Overview
2. 13.2 GPAMP Operation
3. 13.3 GPAMP Registers
14DAC
1. 14.1 DAC Introduction
2. 14.2 DAC Operation
3. 14.3 DAC12 Registers
15VREF
1. 15.1 VREF Overview
2. 15.2 VREF Operation
3. 15.3 VREF Registers
16UART
1. 16.1 UART Overview
2. 16.2 UART Operation
3. 16.3 UART Registers
17SPI
1. 17.1 SPI Overview
2. 17.2 SPI Operation
3. 17.3 SPI Registers
18I2C
1. 18.1 I2C Overview
2. 18.2 I2C Operation
19I2C Registers
20CAN-FD
1. 20.1 MCAN Overview
  1. 20.1.1 MCAN Features
2. 20.2 MCAN Environment
3. 20.3 CAN Network Basics
4. 20.4 MCAN Functional Description
5. 20.5 MCAN Integration
6. 20.6 Interrupt and Event Support
  1. 20.6.1 CPU Interrupt Event Publisher (CPU_INT)
7. 20.7 MCAN Registers
21MCAN Registers
22CRC
1. 22.1 CRC Overview
  1. 22.1.1 CRC16-CCITT
  2. 22.1.2 CRC32-ISO3309
2. 22.2 CRC Operation
  1. 22.2.1 CRC Generator Implementation
  2. 22.2.2 Configuration
3. 22.3 CRC Registers
23AES
1. 23.1 AES Overview
  1. 23.1.1 AES Performance
2. 23.2 AES Operation
3. 23.3 AES Registers
24TRNG
1. 24.1 TRNG Overview
2. 24.2 TRNG Operation
3. 24.3 TRNG Registers
25Timers (TIMx)
1. 25.1 TIMx Overview
2. 25.2 TIMx Operation
3. 25.3 Timers (TIMx) Registers
26RTC
1. 26.1 Overview
2. 26.2 Basic Operation
3. 26.3 Configuration
4. 26.4 RTC Registers
27WWDT
1. 27.1 WWDT Overview
  1. 27.1.1 Watchdog Mode
  2. 27.1.2 Interval Timer Mode
2. 27.2 WWDT Operation
3. 27.3 WWDT Registers
28Debug
1. 28.1 Overview
2. 28.2 Debug Features
3. 28.3 Behavior in Low Power Modes
4. 28.4 Restricting Debug Access
5. 28.5 Mailbox (DSSM)
  1. 28.5.1 DSSM Events
    1. 28.5.1.1 CPU Interrupt Event (CPU_INT)
  2. 28.5.2 DEBUGSS Registers
29Revision History

2.5.7 High Speed Clock (SYSPLL, HFCLK) Handling in Low-Power Modes

The SYSPLL and HFCLK (HFXT, HFCLK_IN) high speed clock sources are not supported in the STOP and STANDBY operating modes. When a high-speed clock source (SYSPLL, HFCLK) is enabled, entering either the STOP mode or STANDBY mode will cause SYSCTL to automatically disable the SYSPLL and/or HFCLK before entering STOP or STANDBY mode. Upon exit from STOP or STANDBY mode to RUN mode, SYSCTL will automatically re-enable the SYSPLL and/or HFCLK if they were previously enabled before entering the low-power mode.

Before entering STOP or STANDBY for the first time after enabling the SYSPLL or HFCLK, and after waking up from STOP or STANDBY mode, application software must wait to enter STOP or STANDBY mode until any previously enabled high speed clock sources have completed startup.

Application software must check the following before entering STOP or STANDBY mode:

If the SYSPLL was enabled, then application software must wait for the SYSPLL to complete startup. When the SYSPLL startup is complete, the SYSPLLGOOD bit will be set in the CLKSTATUS register in SYSCTL. If the SYSPLL fails to start, the SYSPLLOFF bit will be set instead. The SYSPLLOFF bit indicates that the SYSPLL was dead at startup or was not previously enabled. Ensure that either SYSPLLGOOD or SYSPLLOFF is set before attempting to enter STOP or STANDBY.
If the HFCLK was enabled, then application software must wait for the HFCLK to complete startup. When the HFCLK startup is complete, the HFCLKGOOD bit will be set in the CLKSTATUS register in SYSCTL. If the HFCLK fails to start, the HFCLKOFF bit will be set instead. The HFCLKOFF bit indicates that the HFCLK was dead at startup or was not previously enabled. Ensure that either HFCLKGOOD or HFCLKOFF is set before attempting to enter STOP or STANDBY.

In the event that the MCLK was configured to be sourced from HSCLK before entry to STOP or STANDBY, upon exit from STOP or STANDBY the MCLK will be sourced from SYSOSC initially and the CPU will be released to begin executing code at the SYSOSC frequency. SYSCTL will automatically restore the MCLK configuration to the previously selected high-speed clock when the high-speed clock has started and is ready for use. When MCLK switches back to the high-speed clock, SYSCTL will generate an HSCLK GOOD interrupt to alert the application that MCLK is again running from the high-speed clock.