Nucleo H563ZI
Overview
The Nucleo H563ZI board is designed as an affordable development platform for STMicroelectronics ARM® Cortex®-M33 core-based STM32H563ZIT6 microcontroller with TrustZone®. Here are some highlights of the Nucleo H563ZI board:
STM32H563ZI microcontroller featuring 2 Mbytes of Flash memory and 640Kbyte of SRAM in LQFP144 package
Board connectors:
USB Type-C™ Sink device FS
Ethernet RJ45 connector compliant with IEEE-802.3-2002 (depending on STM32 support)
ST Zio expansion connector including Arduino Uno V3 connectivity (CN7, CN8, CN9, CN10)
ST morpho extension connector (CN11, CN12)
Flexible board power supply:
5V_USB_STLK from ST-Link USB connector
VIN (7 - 12V, 0.8A) supplied via pin header CN8 pin 15 or CN11 pin 24
5V_EXT on the ST morpho connector CN11 Pin 6 (5V, 1.3)
CHGR from a USB charger via the ST-LINK USB connector
USB_USER from the USB user connector (5V, 3A)
3V3_EXT supplied via a pin header CN8 pin 7 or CN11 pin 16 (3.3V, 1.3A)
On-board ST-LINK/V3EC debugger/programmer
mass storage
Virtual COM port
debug port
Three users LEDs
Two push-buttons: USER and RESET
32.789 kHz crystal oscillator
More information about the board can be found at the NUCLEO_H563ZI website.
Hardware
The STM32H563xx devices are high-performance microcontrollers from the STM32H5 Series based on the high-performance Arm® Cortex®-M33 32-bit RISC core. They operate at a frequency of up to 250 MHz.
Core: ARM® 32-bit Cortex® -M33 CPU with TrustZone® and FPU.
Performance benchmark:
375 DMPIS/MHz (Dhrystone 2.1)
Security
Arm® TrustZone® with ARMv8-M mainline security extension
Up to 8 configurable SAU regions
TrustZone® aware and securable peripherals
Flexible lifecycle scheme with secure debug authentication
SFI (secure firmware installation)
Secure firmware upgrade support with TF-M
HASH hardware accelerator
True random number generator, NIST SP800-90B compliant
96-bit unique ID
Active tampers
Clock management:
25 MHz crystal oscillator (HSE)
32 kHz crystal oscillator for RTC (LSE)
Internal 64 MHz (HSI) trimmable by software
Internal low-power 32 kHz RC (LSI)( ±5%)
Internal 4 MHz oscillator (CSI), trimmable by software
Internal 48 MHz (HSI48) with recovery system
3 PLLs for system clock, USB, audio, ADC
Power management
Embedded regulator (LDO) with three configurable range output to supply the digital circuitry
Embedded SMPS step-down converter
RTC with HW calendar, alarms and calibration
Up to 139 fast I/Os, most 5 V-tolerant, up to 10 I/Os with independent supply down to 1.08 V
Up to 16 timers and 2 watchdogs
12x 16-bit
2x 32-bit timers with up to 4 IC/OC/PWM or pulse counter and quadrature (incremental) encoder input
6x 16-bit low-power 16-bit timers (available in Stop mode)
2x watchdogs
2x SysTick timer
Memories
Up to 2 MB Flash, 2 banks read-while-write
1 Kbyte OTP (one-time programmable)
640 KB of SRAM including 64 KB with hardware parity check and 320 Kbytes with flexible ECC
4 Kbytes of backup SRAM available in the lowest power modes
Flexible external memory controller with up to 16-bit data bus: SRAM, PSRAM, FRAM, SDRAM/LPSDR SDRAM, NOR/NAND memories
1x OCTOSPI memory interface with on-the-fly decryption and support for serial PSRAM/NAND/NOR, Hyper RAM/Flash frame formats
2x SD/SDIO/MMC interfaces
Rich analog peripherals (independent supply)
2x 12-bit ADC with up to 5 MSPS in 12-bit
1x 12-bit D/A with 2 channels
1x Digital temperature sensor
34x communication interfaces
1x USB Type-C / USB power-delivery controller
1x USB 2.0 full-speed host and device
4x I2C FM+ interfaces (SMBus/PMBus)
1x I3C interface
12x U(S)ARTS (ISO7816 interface, LIN, IrDA, modem control)
1x LP UART
6x SPIs including 3 muxed with full-duplex I2S
5x additional SPI from 5x USART when configured in Synchronous mode
2x SAI
2x FDCAN
1x SDMMC interface
2x 16 channel DMA controllers
1x 8- to 14- bit camera interface
1x HDMI-CEC
1x Ethernel MAC interface with DMA controller
1x 16-bit parallel slave synchronous-interface
CORDIC for trigonometric functions acceleration
FMAC (filter mathematical accelerator)
CRC calculation unit
Development support: serial wire debug (SWD), JTAG, Embedded Trace Macrocell™
More information about STM32H563ZI can be found here:
Supported Features
The Zephyr nucleo_h563zi board configuration supports the following hardware features:
Interface |
Controller |
Driver/Component |
---|---|---|
ADC |
on-chip |
ADC Controller |
BKP SRAM |
on-chip |
Backup SRAM |
CAN/CANFD |
on-chip |
CAN |
CLOCK |
on-chip |
reset and clock control |
DAC |
on-chip |
DAC Controller |
GPIO |
on-chip |
gpio |
NVIC |
on-chip |
nested vector interrupt controller |
PINMUX |
on-chip |
pinmux |
PWM |
on-chip |
PWM |
RNG |
on-chip |
True Random number generator |
RTC |
on-chip |
Real Time Clock |
SPI |
on-chip |
spi bus |
I2C |
on-chip |
i2c bus |
I3C |
on-chip |
i3c bus |
UART |
on-chip |
serial port-polling; serial port-interrupt |
WATCHDOG |
on-chip |
independent watchdog |
USB |
on-chip |
USB full-speed host/device bus |
ETHERNET |
on-chip |
ethernet |
Other hardware features are not yet supported on this Zephyr port.
The default configuration can be found in the defconfig and dts files:
Zephyr board options
The STM32H563 is an SoC with Cortex-M33 architecture. Zephyr provides support for building for Secure firmware.
The BOARD options are summarized below:
BOARD |
Description |
---|---|
nucleo_h563zi |
For building Secure firmware |
Connections and IOs
Nucleo H563ZI Board has 9 GPIO controllers. These controllers are responsible for pin muxing, input/output, pull-up, etc.
For more details please refer to STM32H5 Nucleo-144 board User Manual.
Default Zephyr Peripheral Mapping:
ADC1 channel 3 input: PA6
ADC1 channel 15 input: PA3
DAC1 channel 2 output: PA5
CAN/CANFD TX/RX: PD1/PD0
LD1 (green): PB0
LD2 (yellow): PF4
LD3 (red): PG4
LPUART1 TX/RX : PB6/PB7 (Arduino LPUART1)
SPI1 SCK/MISO/MOSI/CS: PA5/PG9/PB5/PD14
UART3 TX/RX : PD8/PD9 (VCP)
USER_PB : PC13
I3C1: PD12(SCL) & PD13(SDA)
System Clock
Nucleo H563ZI System Clock could be driven by internal or external oscillator, as well as main PLL clock. By default System clock is driven by PLL clock at 240MHz, driven by 8MHz external clock provided from the STLINK-V3EC.
Serial Port
Nucleo H563ZI board has up to 12 U(S)ARTs. The Zephyr console output is assigned to USART3. Default settings are 115200 8N1.
Backup SRAM
In order to test backup SRAM, you may want to disconnect VBAT from VDD_MCU.
You can do it by removing SB55
jumper on the back side of the board.
VBAT can be provided via the left ST Morpho connector’s pin 33.
Programming and Debugging
Nucleo H563ZI board includes an ST-LINK/V3EC embedded debug tool interface. This probe allows to flash the board using various tools.
Applications for the nucleo_h563zi
board can be built and
flashed in the usual way (see Building an Application and
Run an Application for more details).
OpenOCD Support
For now, openocd support for stm32h5 is not available on upstream OpenOCD. You can check OpenOCD official Github mirror. In order to use it though, you should clone from the cutomized STMicroelectronics OpenOCD Github and compile it following usual README guidelines. Once it is done, you can set the OPENOCD and OPENOCD_DEFAULT_PATH variables in boards/st/nucleo_h563zi/board.cmake to point the build to the paths of the OpenOCD binary and its scripts, before including the common openocd.board.cmake file:
set(OPENOCD "<path_to_openocd_repo>/src/openocd" CACHE FILEPATH "" FORCE) set(OPENOCD_DEFAULT_PATH <path_to_opneocd_repo>/tcl) include(${ZEPHYR_BASE}/boards/common/openocd.board.cmake)
Flashing
The board is configured to be flashed using west STM32CubeProgrammer runner, so its installation is required.
Alternatively, OpenOCD, JLink, or pyOCD can also be used to flash the board using
the --runner
(or -r
) option:
$ west flash --runner openocd
$ west flash --runner pyocd
$ west flash --runner jlink
For pyOCD, additional target information needs to be installed. This can be done by executing the following commands.
$ pyocd pack --update
$ pyocd pack --install stm32h5
Flashing an application to Nucleo H563ZI
Connect the Nucleo H563ZI to your host computer using the USB port. Then build and flash an application. Here is an example for the Hello World application.
Run a serial host program to connect with your Nucleo board:
$ minicom -D /dev/ttyACM0
Then build and flash the application.
# From the root of the zephyr repository
west build -b nucleo_h563zi samples/hello_world
west flash
You should see the following message on the console:
Hello World! nucleo_h563zi
Debugging
You can debug an application in the usual way. Here is an example for the Blinky application.
# From the root of the zephyr repository
west build -b nucleo_h563zi samples/basic/blinky
west debug