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STM32F411CEU6: A beginner Guide [+Step by Steps Tutorial]

Are you interested in learning the basics of embedded systems and microcontrollers and want to start with a device as strong and adaptable as the STM32F411CEU6? You’re in the right location! This thorough guide is intended to assist you in unlocking the STM32F411CEU6’s creative potential and helping you grasp all of its details, from applications to specifications.

To assist you with getting started with the STM32F411CEU6, we have included extensive descriptions and step-by-step tutorials in this beginner-friendly guide. Whether you’re a professional, hobbyist, or enthusiast in electronics, this tutorial will provide you the know-how to get the most out of this amazing microcontroller.

Understanding the STM32F411CEU6

What is the STM32F411CEU6?

An STM32F411CEU6 microcontroller is one of STMicroelectronics’ STM32F4 series microcontrollers. It has a floating-point unit (FPU), an ARM Cortex-M4 processor that can run at up to 100 MHz, and a robust peripheral suite. Because of its remarkable capabilities and small size, the ‘Black Pill’ variation of this microcontroller has become increasingly popular.

Key Specifications and Features

  • Core: ARM Cortex-M4
  • Clock Speed: Up to 100 MHz
  • Flash Memory: 512 KB
  • SRAM: 128 KB
  • Peripherals: Multiple timers, ADCs, DACs, USARTs, SPIs, I2Cs, and more
  • Operating Voltage: 1.7V to 3.6V
  • Package: LQFP64
  • Operating Temperature: -40°C to 85°C

Applications of the STM32F411CEU6

The STM32F411CEU6 is used in many different fields, such as but not restricted to:

  • IoT Devices: It is perfect for IoT applications due to its comprehensive feature set and low power consumption.
  • Industrial Automation: The STM32F411CEU6 is a good choice for industrial automation systems due to its real-time capabilities and sturdy architecture.
  • Consumer Electronics: The STM32F411CEU6 is the chip that powers a range of consumer electronics items, including smartwatches and audio devices.
  • Embedded Systems: It is a well-liked option for embedded systems development due to its performance and versatility.

Exploring the STM32F411CEU6 in Depth

Reviewing the Datasheet in detail

The STM32F411CEU6 datasheet is an extensive document that offers full details regarding the electrical properties, pinout, memory structure, and additional features of the microcontroller. It is an essential tool for anyone utilizing the STM32F411CEU6.

Understanding the Pinout

The pin layout and associated functionalities of the STM32F411CEU6 microcontroller are specified by its pinout. When constructing circuits or integrating with external components, pinout comprehension is crucial.

Referencing the Reference Manual

Comprehensive details regarding the memory map, peripheral functions, and architecture of the microcontroller are available in the STM32F411CEU6 reference manual. For developers hoping to take full use of the STM32F411CEU6, this is an essential tool.

STM32F401CCU6 and STM32F411CEU6 comparison

Despite belonging to the same STM32F4 family, the STM32F401CCU6 and STM32F411CEU6 differ significantly in a few important ways. In comparison to the STM32F401CCU6, the STM32F411CEU6 has more peripherals and higher performance, making it a better option for demanding applications.

FeatureSTM32F401CCU6STM32F411CEU6
CoreARM Cortex-M4 @ 84 MHzARM Cortex-M4 @ up to 100 MHz
Flash Memory256 KB512 KB
SRAM64 KB128 KB
Operating Voltage1.7V to 3.6V1.7V to 3.6V
PackageLQFP48LQFP64
PeripheralsMultiple timers, ADCs, DACs, USARTs, SPIs, I2CsMultiple timers, ADCs, DACs, USARTs, SPIs, I2Cs
Temperature Range-40°C to 85°C-40°C to 85°C
STM32F401CCU6 vs STM32F411CEU6

Getting Started with the STM32F411CEU6 Using Arduino IDE

The STM32 Arduino core allows the STM32F411CEU6 to be programmed via the Arduino IDE. This makes it simple for developers who are already familiar with Arduino to work with and utilize the features of the STM32F411CEU6.

Prerequisites

Before you begin, make sure you have the following:

  • STM32F411CEU6 development board (such as the WeAct STM32F411CEU6)
  • USB cable
  • Arduino IDE installed on your computer
  • STM32 Arduino Core installed in the Arduino IDE

Step 1: Install the STM32 Arduino Core

  1. Open the Arduino IDE.
  2. Go to File > Preferences.
  3. In the “Additional Boards Manager URLs” field, add the following URL: https://github.com/stm32duino/BoardManagerFiles/raw/master/STM32/package_stm_index.json
  4. Click OK to save the preferences.
  5. Go to Tools > Board > Boards Manager.
  6. Search for “STM32” and install the “STM32 Cores” package.

Step 2: Select the Board and Port

  1. Connect your STM32F411CEU6 development board to your computer using the USB cable.
  2. Go to Tools > Board and select “WeAct STM32F411CEU6”.
  3. Go to Tools > Port and select the appropriate COM port for your board.

Step 3: Upload a Sample Sketch

  1. Open the Arduino IDE.
  2. Go to File > Examples > 01.Basics > Blink to open the Blink example sketch.
  3. Modify the sketch if necessary (e.g., change the LED pin number).
  4. Click the Upload button to compile and upload the sketch to your STM32F411CEU6 board.

Step 4: Verify the Upload

  1. Once the upload is complete, the LED on your STM32F411CEU6 board should start blinking.
  2. If the LED blinks as expected, congratulations! You have successfully programmed your STM32F411CEU6 board.

Step 5: Explore Further

You are able to explore the STM32F411CEU6 board’s additional features and capabilities after uploading a sketch to it successfully. To learn more about its capabilities, try experimenting with various designs and sensors.

Example 1: Blinking an LED

const int ledPin = PC13;

void setup() {
  pinMode(ledPin, OUTPUT);
}

void loop() {
  digitalWrite(ledPin, HIGH);
  delay(1000);
  digitalWrite(ledPin, LOW);
  delay(1000);
}

Example 2: Reading Analog Inputs

const int analogPin = PA0;

void setup() {
  Serial.begin(9600);
}

void loop() {
  int sensorValue = analogRead(analogPin);
  Serial.print("Analog Value: ");
  Serial.println(sensorValue);
  delay(1000);
}

Example 3: Serial Communication

void setup() {
  Serial.begin(9600);
}

void loop() {
  if (Serial.available() > 0) {
    char incomingByte = Serial.read();
    Serial.print("Received: ");
    Serial.println(incomingByte);
  }
}

Getting Started with the STM32F411CEU6 Using STM32CubeIDE

An integrated development environment for STM32 microcontrollers is called STM32CubeIDE. We will walk you through the process of configuring STM32CubeIDE for the STM32F411CEU6 microcontroller and writing an example of a basic LED flashing in this tutorial.

Prerequisites

Before you begin, make sure you have the following:

  • STM32F411CEU6 development board
  • STM32CubeIDE installed on your computer
  • USB cable

Step 1: Create a New STM32CubeIDE Project

  1. Open STM32CubeIDE.
  2. Go to File > New > STM32 Project.
  3. Select your board or microcontroller. For the STM32F411CEU6, select “STM32F4” > “STM32F411xE” > “STM32F411CE”.
  4. Click Next.
  5. Enter a project name and select a location to save the project.
  6. Click Finish.

Step 2: Configure the Project

  1. In the “Project Explorer” view, expand your project folder.
  2. Right-click on “Core” and select Properties.
  3. Under “C/C++ Build”, select Settings.
  4. Under “Tool Settings”, select Target Processor and choose “Cortex-M4”.
  5. Click OK to save the settings.

Step 3: Write the Code

  1. In the “Project Explorer” view, expand your project folder and double-click on “Src” to open the source files.
  2. Open the “main.c” file.
  3. Replace the existing code(int main(void)) with the following:
#include "stm32f4xx_hal.h"

int main(void)
{
  HAL_Init();

  __HAL_RCC_GPIOC_CLK_ENABLE();

  GPIO_InitTypeDef GPIO_InitStruct;
  GPIO_InitStruct.Pin = GPIO_PIN_13;
  GPIO_InitStruct.Mode = GPIO_MODE_OUTPUT_PP;
  GPIO_InitStruct.Pull = GPIO_NOPULL;
  GPIO_InitStruct.Speed = GPIO_SPEED_FREQ_LOW;
  HAL_GPIO_Init(GPIOC, &GPIO_InitStruct);

  while (1)
  {
    HAL_GPIO_TogglePin(GPIOC, GPIO_PIN_13);
    HAL_Delay(1000);
  }
}

Step 4: Build the Project

  1. Go to Project > Build Project (or press Ctrl+B) to build the project.
  2. Check the “Console” view for build errors. If there are no errors, proceed to the next step.

Step 5: Configure the Debug Settings

  1. Go to Run > Debug Configurations.
  2. Right-click on “STM32 Cortex-M C/C++ Application” and select New Configuration.
  3. In the “Main” tab, select your project and set the “GDB Command” to “arm-none-eabi-gdb”.
  4. In the “Debugger” tab, select your debug probe (e.g., ST-Link) and configure the settings.
  5. Click Apply and then Debug.

Step 6: Debug and Program the Microcontroller

  1. Connect your STM32F411CEU6 development board to your computer using the USB cable.
  2. Click Resume (or press F8) in the debug perspective to start debugging.
  3. If everything is set up correctly, you should see the LED on your board blinking at 1-second intervals.

Congratulations! You have successfully set up STM32CubeIDE for the STM32F411CEU6 microcontroller and programmed a simple LED blinking example. You can now explore more features and capabilities of STM32CubeIDE to develop your own projects.

Conclusion

Using the Arduino IDE and the STM32 Arduino Core, you learnt how to configure and program the STM32F411CEU6 microcontroller in this lesson. Now that you have this knowledge, you may begin creating your own projects and discovering all of the STM32F411CEU6’s limitless potential.

2 Comments

  1. Bolehkah saya bertanya kak, apakah untuk uploading program tidak memerlukan st link atau modul ftdi? apakah cukup pakai usb kabel?

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