S32K知识库

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------------------------------------------------------------------------------ * Test HW: S32K3X4EVB-Q172 * MCU: S32K312 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE Micro * Target: internal_FLASH ******************************************************************************** S32K324 SPI Transmit & Receive, using Interrupt :-- https://community.nxp.com/t5/S32K-Knowledge-Base/Example-S32K324-I2C-Transmit-amp-Receive-Using-DMA-DS3-5-RTD300/ta-p/1818631 Example S32K324 Bootloader to Application Jump DS3.5 RTD300 :-- https://community.nxp.com/t5/S32K-Knowledge-Base/Example-S32K324-Bootloader-to-Application-Jump-DS3-5-RTD300/ta-p/1832649 Example S32K324 STANDBY wake up using GPIO Switch DS3.5 RTD300 :-- https://community.nxp.com/t5/S32K-Knowledge-Base/Example-S32K324-STANDBY-wake-up-using-GPIO-Switch-DS3-5-RTD300/ta-p/1892849 Example S32K324 STANDBY wake up using CAN-0-RX and GPIO Switch DS3.5 RTD300 :-- https://community.nxp.com/t5/S32K-Knowledge-Base/Example-S32K324-STANDBY-wake-up-using-CAN-0-RX-and-GPIO-Switch/ta-p/1911972

******************************************************************************* The purpose of this demo application is to present a usage of the POWER & WKUP IP Driver for the S32K3xx MCU. In current example :-- SW-5 = PTB-26 -----> PRESS to enter the STANDBY mode. SW-6 = PTB-19 = WKUP[38] --> PRESS to exit the STANDBY mode. CAN-0-RX = PTA-6 = WKUP[15] --> send CAN message to exit the STANDBY mode The example uses PIT-0 timer, to generate the periodic interrupt. The example uses FLEXCAN-0 for transmit & receive using following Message buffer :-- #define RX_MB_IDX_0 10U #define RX_MB_IDX 11U #define TX_MB_IDX 12U BAUDRATE : 500 KBPS ------------------------------------------------------------------------------ * Test HW: S32K3X4EVB-T172 * MCU: S32K324 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** CAN BUS :-- Push Buttons :--- Wake-up source, SW-6 GPIO:-- Wake-up source, CAN-0-RX :-- According to the IOMUX table in RM, for example, PTA6 can be used as WKPU15 and CAN0_RX. It means that the WKPU15 input doesn't require specific MSCR configuration. So if its input buffer is enabled and the corresponding WKPU input channel is enabled/configured in the WKPU, it should be able to act as wake-up input. Standby entry :-- STandby clock :-- Enter Standby mode :-- ********* If you use external BJT on your board to generate 1.5 volts ******************* I tested on Our T172 EVB, with NPN external Ballast transistor is selected to supply the V15_MCU domain. I am able to wake up from standby mode. If we select 2-3 in J31 then NPN external Ballast transistor is selected to supply the V15_MCU domain & wakeup is ok on T172 EVB You have to make following settings in code :--

******************************************************************************* The purpose of this demo application is to present a usage of the POWER & WKUP IP Driver for the S32K3xx MCU. In current example :-- SW-6 = PTB-19 -----> PRESS to enter the STANDBY mode. SW-5 = PTB-26 = WKUP[41] --> PRESS to exit the STANDBY mode. CAN-0-RX = PTA-6 = WKUP[15] --> send CAN message to exit the STANDBY mode. The example uses PIT-0 timer, to generate the periodic interrupt. The example uses FLEXCAN-0 for transmit & receive using following Message buffer :-- #define RX_MB_IDX_0 10U #define RX_MB_IDX 11U #define TX_MB_IDX 12U BAUDRATE : 500 KBPS ------------------------------------------------------------------------------ * Test HW: S32K3X2EVB-Q172 * MCU: S32K312 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Push button :-- Wake-up source, CAN-0-RX :-- According to the IOMUX table in RM, for example, PTA6 can be used as WKPU15 and CAN0_RX. It means that the WKPU15 input doesn't require specific MSCR configuration. So if its input buffer is enabled and the corresponding WKPU input channel is enabled/configured in the WKPU, it should be able to act as wake-up input. Wake-up source, SW-5 GPIO:-- Standby entry :-- STandby clock :-- Enter Standby mode :--

Question As we know, the TPPSDK supports S32K144 MCU and various Kinetis MCUs to initialize GD3000 in NXP MC solutions. Because of the release of S32K3 and related SW RTD, it’s necessary to expand the capability of TPPSDK to support S32K3 MC based RTD LLD driver or MCAL driver. Unfortunately, the AA team will not maintain the TPPSDK anymore. How could we configure the GD3000 chip for S32K3 platform? Answer I took some time to finish this work. Here I'd like to share you the The Expanded TPPSDK Based on S32K3 RTD that is suitable for S32K3 MC application. You can find the Application Note, the source code of new TPPSDK (GD3000 driver), two examples in the attachment. I hope these materials can help you get start with the expanded TPPSDK on S32K3.

******************************************************************************** * Detailed Description: * The example updates th UART TX buffer for continuous transfer. * ---------------------------------------------------------------------- * Test HW: S32K344EVB-Q172 * MCU: S32K344, RTD 4.0.0 P24 * Debugger: S32DS_ARM_3.5 * Target: internal_FLASH ********************************************************************************

******************************************************************************* The purpose of this demo application is to present a usage of the MEM_InFls MCAL Driver for the S32K3x1 MCU. The example uses MEM_InFls driver to write 128 bytes to FLASH memory address 0x47_A000 starting of FLS_CODE_ARRAY_0_BLOCK_0_S61. ------------------------------------------------------------------------------ * MCU: S32K310 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Flash end address = 0x480000 Size of each block = 8192 = 0x2000 Start Address of 63 block = 0x480000 - 0x2000 = 0x47E000 = 4710400 Start Address of 62 block = 0x480000 - 0x4000 = 0x47C000 = 4702208 Start Address of 61 block = 0x480000 - 0x6000 = 0x47A000 = 4694016 Ram location where FLASH writing erase code is placed :-- I placed the code at 0x256 byte below the MAX address of the RAM size 16*1024 = 16384 = 0x4000 End of RAM = 0x20400000 + 0x4000 = 0x20404000 0x20404000 - 0x256 = 0x20403DAA 0x20403DAA = 541081002 Size of RAM need to save the flashing routine, as per the MAP & linker file :-- 0x00407b80 - 0x00407b54 = 0x2C = 44 byte S32K3 FLASH Memory Terminology :--

------------------------------------------------------------------------------ * Test HW: S32K31XEVB-Q100 * MCU: S32K311 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE Micro * Target: internal_FLASH ******************************************************************************** S32K31XEVB-Q100 :-- S32K31XEVB-Q100 Evaluation Board for Automotive General Purpose | NXP Semiconductors Example MCAL S32K311 MEM_InFls DS3.5 RTD300 :-- Example MCAL S32K311 MEM_InFls DS3.5 RTD300 - NXP Community

******************************************************************************* The purpose of this demo application is to present a usage of the MEM_InFls MCAL Driver for the S32K3x1 MCU. The example uses MEM_InFls driver to write 128 bytes to FLASH memory address 0x48_0000 . ------------------------------------------------------------------------------ * Test HW: S32K31XEVB-Q100 * MCU: S32K311 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Results :-- Ram location where FLASH writing erase code is placed :-- I placed the code at 256 byte below the MAX address of the RAM size 0x20407DAA = 541097386 Size of RAM need to save the flashing routine, as per the MAP & linker file :-- 0x00406ff0 - 0x00406f78 = 120 bytes S32K3 FLASH Memory Terminology :--

******************************************************************************* The purpose of this demo application is to present a usage of the MEM_InFls MCAL Driver for the S32K3xx MCU. The example uses MEM_InFls driver to write 128 bytes to FLASH memory address 0x50_0000 . ------------------------------------------------------------------------------ * Test HW: S32K3X2EVB-Q172 * MCU: S32K312 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Results :-- Ram location where FLASH writing erase code is placed :-- I placed the code at 256 byte below the MAX address of the RAM size 0x20417DAA = 541162922 Size of RAM need to save the flashing routine, as per the MAP & linker file :-- 0x00407e64 - 0x00407e38 = 44 bytes S32K3 FLASH Memory Terminology :--

******************************************************************************* The purpose of this demo application is to present a usage of the FEE MCAL Driver for the S32K3xx MCU. This example read & write 4 byte FEE BLock. I have renamed the FEE block using a MACRO as FOUR_BYTE_EEPROM_FEE_VARIABLE. The example uses MEM_InFls driver to write 128 bytes to FLASH memory address 0x52_0000 . ------------------------------------------------------------------------------ * Test HW: S32K3X2EVB-Q172 * MCU: S32K312 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ********************************************************************************

------------------------------------------------------------------------------ * Test HW: S32K3X4EVB-T172 * MCU: S32K344 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE Micro * Target: internal_FLASH ******************************************************************************** Example S32K344 UART Transmit & Receive Using DMA DS3.5 RTD300 :-- Example S32K344 UART Transmit & Receive Using DMA DS3.5 RTD300 - NXP Community Example S32K344 UART Transmit & Receive Using Interrupt DS3.5 RTD300 :-- Example S32K344 UART Transmit & Receive Using Interrupt DS3.5 RTD300 - NXP Community

******************************************************************************* The purpose of this demo application is to present a usage of the UART IP Driver for the S32K3xx MCU. The example uses LPUART6 for transmit & receive five bytes using the Interrupt. ------------------------------------------------------------------------------ * Test HW: S32K3X4EVB-T172 * MCU: S32K344 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Putty output :--

******************************************************************************* The purpose of this demo application is to present a usage of the UART IP Driver for the S32K3xx MCU. The example uses LPUART6 for transmit & receive five bytes using the DMA. ------------------------------------------------------------------------------ * Test HW: S32K3X4EVB-T172 * MCU: S32K344 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Putty output :--

S32K344 - Six-step commutation control These examples demonstrate a a 3-phase Brushless DC (BLDC) motor control drive using a Six-step commutation control with Hall position sensor and without any position sensor (sensorless). This design serves as an example of motor control design using NXP S32K3 automotive family. Examples were designed on S32K344 Brushless Direct Current and Permanent Magnet Synchronous Motor Control Development Kit. C-project based examples are part of MCSPTE1AK344 Development Kit Application Software. An innovative drivers set, Real-Time Drivers (RTD),are used to configure and control the MCU. It complies with Automotive-SPICE, ISO 26262, ISO 9001 and IATF 16949. Production-ready Automotive Math and Motor Control Library set provides essential building blocks for algorithm. FreeMASTER is used as useful run-time debugging tool. Application software contains: MCSPTE1AK344_BLDC_6Step_hall_ll-. Hall sensor-based example. Detailed description of the example can be found in attachment to this article MCSPTE1AK344 - 6-step hall.pdf. MCSPTE1AK344_BLDC_6Step_sensorless_ll – Sensorless based example. Detailed description of the example can be found in attachment to this article MCSPTE1AK344_- 6-step sensorless.pdf. MATLAB Simulink based project (Motor Control BLDC Example - s32k344_mc_bldc_ebt) is build using Model-Based Design Toolbox (MBDT) and can be downloaded from NXP Model-Based Design Toolbox for S32K3xx - version 1.4.0 or newer releases.

S32K344 - FOC with dual single current measurement These examples demonstrate a 3-phase Permanent Magnet Synchronous Motor (PMSM) vector control (Field Oriented Control - FOC) drive with 1- shunt current sensing with and without position sensor. This design serves as an example of motor control design using NXP S32K3 automotive family. Examples were designed on S32K344 Brushless Direct Current and Permanent Magnet Synchronous Motor Control Development Kit. C-project based examples are part of MCSPTE1AK344 Development Kit Application Software. An innovative drivers set, Real-Time Drivers (RTD),are used to configure and control the MCU. It complies with Automotive-SPICE, ISO 26262, ISO 9001 and IATF 16949. Production-ready Automotive Math and Motor Control Library set provides essential building blocks for algorithm. FreeMASTER is used as useful run-time debugging tool. Application software contains: MCSPTE1AK344_PMSM_FOC_1Sh_ll - Low-level drivers of RTD and S32 Design Studio Configuration Tools (S32CT) are used to demonstrate non-AUTOSAR approach. Since the structure of the example is similar to dual shunt example, detailed description of the example can be found in application note AN13767 and MCSPTE1AK344 - single shunt addendum.pdf (which highlights changes for single shunt) attached to this article . MCSPTE1AK344_PMSM_FOC_1Sh_as_tr - RTD, EB (Elektrobit) tresos Studio and S32 Design Studio are used to demonstrate AUTOSAR (AUTomotive Open System ARchitecture) approach. Since the structure of the example is similar to dual shunt example, detailed description of the example can be found in application note AN13884 and MCSPTE1AK344 - single shunt addendum.pdf (which highlights changes for single shunt) attached to this article . MATLAB Simulink based project (Motor Control PMSM Single Shunt Example - s32k344_mc_pmsm_1sh_ebt) is build using Model-Based Design Toolbox (MBDT) and can be downloaded from NXP Model-Based Design Toolbox for S32K3xx - version 1.4.0 or newer releases.

------------------------------------------------------------------------------ * Test HW: S32K31XEVB-Q100 * MCU: S32K311 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE Micro * Target: internal_FLASH ******************************************************************************** S32K31XEVB-Q100 :-- S32K31XEVB-Q100 Evaluation Board for Automotive General Purpose | NXP Semiconductors S32K312 UART Transmit & Receive Using DMA :-- S32K311 UART Transmit & Receive Using DMA - NXP Community S32K311 UART Idle state Interrupt :-- S32K311 UART Idle state Interrupt - NXP Community

******************************************************************************* The purpose of this demo application is to present a usage of the UART IP Driver for the S32K3xx MCU. The example uses LPUART0 for transmit 20 packets with each packet of 21 bytes using the Interrupt in cyclic order. Also when receiving UART packet generate Idle interrupt when variable length of data is received. I used coolterm tool to send the string of data. If Data send by cool term is less than 20 bytes which is set by API call Lpuart_Uart_Ip_AsyncReceive(), then Ideal interrupt is received RTD driver modified in RTD --> Lpuart_Uart_Ip.c. Baudrate : 921600 ------------------------------------------------------------------------------ * Test HW: S32K31XEVB-Q100 * MCU: S32K311 * Compiler: S32DS3.5 * SDK release: RTD 3.0.0 * Debugger: PE micro * Target: internal_FLASH ******************************************************************************** Idle Interrupt received :--

特色文章

The S32K3 family of 32-bit AEC-Q100 qualified MCUs combines a scalable family of Arm® Cortex-M7-based microcontrollers built on long-lasting features with a comprehensive suite of production-grade tools. S32K3 MCUs are included in NXP’s Product Longevity Program, guaranteeing a minimum of 15 years of assured supply. The S32K3 offers dedicated peripherals set for rapid motor control loop implementation: enhanced Modular IO Subsystem(eMIOS), Logic Control Unit (LCU), TRGMUX, BodyCross-triggering Unit (BCTU), Analog to Digital Converter(ADC), and Analog Comparator (CMP). The comprehensive motor control ecosystem based on Automotive Math and Motor Control Library(AMMCLib) set, FreeMASTER with Motor Control ApplicationTuning (MCAT) tool and Model-Based Design Toolbox (MBDT) helps to enable S32K3 MCU in wide range of motor control use cases. The table below points to the articles with more detailed description each of S32K3 motor control use cases, hardware description, links to appropriate application notes and their addendums, and software repositories. Device HW Article S32K344 MCSPTE1AK344 12 V development kit engineered for 3-phase PMSM and BLDC motor control applications FOC with dual shunt current measurement Article focuses on solution based Field Oriented Control (FOC) technique (typically used for 3-phase PMSM motors) with dual shunt current measurement and without any position sensor (sensorless). The Encoder sensor is supported by SW option, but missing on HW kit. The available example codes covers both ANSI-C and Matlab Simulink approaches and uses RTD drivers with high-level Autosar compliant API or low-level non-Autosar API. FOC with single shunt current measurement Article focuses on solution based Field Oriented Control (FOC) technique (typically used for 3-phase PMSM motors) with single shunt current measurement and without any position sensor (sensorless). The Encoder sensor is supported by SW option, but missing on HW kit. The single shunt current measurement is advanced technique that allows decrese the cost of Bill of Material (BOM). The available example codes covers both ANSI-C and Matlab Simulink approaches and uses RTD drivers with high-level Autosar compliant API or low-level non-Autosar API. FOC integrated with FreeRTOS Article focuses on integration of motor control software (based on FOC with dual shunt current measurement) and Real Time Operating System (FreeRTOS). The available example code is based ANSI-C code and uses RTD drivers with low-level non-Autosar API. Six-step commutation control. Article focuses on solution based Six-step commutation (6-step) technique (typically used for 3-phase BLDC motors) with Hall position sensor and without any position sensor (sensorless). The available example codes covers both ANSI-C and Matlab Simulink approaches and uses RTD drivers with low-level non-Autosar API. Note: the list of use cases cannot cover all combinations of MCU, current measurement scenario, control technique and sensor inputs, but should work as a base reference for most common configurations. This list is not final, please follow this acticle to be notified about updates with new use cases.

S32K知识库

S32K Knowledge Base

讨论

Example S32K312 STANDBY wake up using RTC DS3.5 RTD300

All Example S32K324 DS3.5 RTD-3.0.0

Example S32K324 STANDBY wake up using CAN-0-RX and GPIO Switch DS3.5 RTD300

Example S32K312 STANDBY wake up using CAN-0-RX and GPIO Switch DS3.5 RTD300

The new TPPSDK (GD3000 driver) based on RTD for S32K3

Lpuart_Ip_Set_Tx_Buffer_Example_S32K344_S32DS35_RTD400_P24

Example S32K324 STANDBY wake up using GPIO Switch DS3.5 RTD300

Example MCAL S32K310 MEM_InFls DS3.5 RTD300

All Example MCAL S32K310 DS3.5 RTD-3.0.0

All Example MCAL S32K311 DS3.5 RTD-3.0.0

Example MCAL S32K311 MEM_InFls DS3.5 RTD300

Example MCAL S32K312 MEM_InFls DS3.5 RTD300

Example MCAL S32K312 FEE and MEM_InFls DS3.5 RTD300

All Example S32K344 DS3.5 RTD-3.0.0

Example S32K344 UART Transmit & Receive Using Interrupt DS3.5 RTD300

Example S32K344 UART Transmit & Receive Using DMA DS3.5 RTD300

S32K344 - Six-step commutation control

S32K344 - FOC with single shunt current measurement

All Example S32K311 DS3.5 RTD-3.0.0

S32K311 UART Idle state Interrupt

S32K3 Motor control SW examples