ST Nucleo F411RE

Overview

The Nucleo F411RE board features an ARM Cortex-M4 based STM32F411RE MCU with a wide range of connectivity support and configurations. Here are some highlights of the Nucleo F411RE board:

  • STM32 microcontroller in QFP64 package
  • Two types of extension resources:
    • Arduino Uno V3 connectivity
    • ST morpho extension pin headers for full access to all STM32 I/Os
  • On-board ST-LINK/V2-1 debugger/programmer with SWD connector
  • Flexible board power supply:
    • USB VBUS or external source(3.3V, 5V, 7 - 12V)
    • Power management access point
  • Three LEDs: USB communication (LD1), user LED (LD2), power LED (LD3)
  • Two push-buttons: USER and RESET
Nucleo F411RE

More information about the board can be found at the Nucleo F411RE website.

Hardware

Nucleo F411RE provides the following hardware components:

  • STM32F411RET6 in LQFP64 package
  • ARM® 32-bit Cortex®-M4 CPU with FPU
  • 100 MHz max CPU frequency
  • VDD from 1.7 V to 3.6 V
  • 512 KB Flash
  • 128 KB SRAM
  • GPIO with external interrupt capability
  • 12-bit ADC with 16 channels, with FIFO and burst support
  • RTC
  • 8 General purpose timers
  • 2 watchdog timers (independent and window)
  • SysTick timer
  • USART/UART (3)
  • I2C (3)
  • SPI (5)
  • SDIO
  • USB 2.0 OTG FS
  • DMA Controller
  • CRC calculation unit

More information about STM32F411RE can be found here:

Supported Features

The Zephyr nucleo_f411re board configuration supports the following hardware features:

Interface Controller Driver/Component
NVIC on-chip nested vector interrupt controller
UART on-chip serial port
PINMUX on-chip pinmux
GPIO on-chip gpio
PWM on-chip pwm
I2C on-chip i2c

Other hardware features are not yet supported on this Zephyr port.

The default configuration can be found in the defconfig file: boards/arm/nucleo_f411re/nucleo_f411re_defconfig

Connections and IOs

Nucleo F411RE Board has 8 GPIO controllers. These controllers are responsible for pin muxing, input/output, pull-up, etc.

Available pins:

Nucleo F411RE Arduino connectors Nucleo F411RE Morpho connectors

For mode details please refer to STM32 Nucleo-64 board User Manual.

Default Zephyr Peripheral Mapping:

  • UART_1_TX : PB6
  • UART_1_RX : PB7
  • UART_2_TX : PA2
  • UART_2_RX : PA3
  • PWM_2_CH1 : PA0
  • USER_PB : PC13
  • LD2 : PA5
  • I2C1_SDA : PB9
  • I2C1_SCL : PB8
  • I2C2_SDA : PB3
  • I2C2_SCL : PB10
  • I2C3_SDA : PB4
  • I2C3_SCL : PA8

System Clock

Nucleo F411RE 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 84MHz, driven by 8MHz high speed external clock.

Serial Port

Nucleo F411RE board has 3 UARTs. The Zephyr console output is assigned to UART2. Default settings are 115200 8N1.

Programming and Debugging

Applications for the nucleo_f411re board configuration can be built and flashed in the usual way (see Build an Application and Run an Application for more details).

Flashing

Nucleo F411RE board includes an ST-LINK/V2-1 embedded debug tool interface. This interface is supported by the openocd version included in Zephyr SDK.

Flashing an application to Nucleo F411RE

Here is an example for the Hello World application.

Run a serial host program to connect with your Nucleo board.

$ minicom -D /dev/ttyACM0

Build and flash the application:

# On Linux/macOS
cd $ZEPHYR_BASE/samples/hello_world
mkdir build && cd build

# On Windows
cd %ZEPHYR_BASE%\samples\hello_world
mkdir build & cd build

# Use cmake to configure a Ninja-based build system:
cmake -GNinja -DBOARD=nucleo_f411re ..

# Now run ninja on the generated build system:
ninja
ninja flash

You should see the following message on the console:

$ Hello World! arm

Debugging

You can debug an application in the usual way. Here is an example for the Hello World application.

# On Linux/macOS
cd $ZEPHYR_BASE/samples/hello_world
# If you already made a build directory (build) and ran cmake, just 'cd build' instead.
mkdir build && cd build

# On Windows
cd %ZEPHYR_BASE%\samples\hello_world
# If you already made a build directory (build) and ran cmake, just 'cd build' instead.
mkdir build & cd build

# Use cmake to configure a Ninja-based build system:
cmake -GNinja -DBOARD=nucleo_f411re ..

# Now run ninja on the generated build system:
ninja debug