This repo contains notes and programming assignments for the Udemy's "Mastering Microcontroller: STM32-LTDC, LCD-TFT, LVGL (MCU3)" course by FastBit Embedded Brain Academy.
Date: August, 2023.
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The course is instructed by Engineer Kiran Nayak.
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The Certificate is available.
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The Output Results are available.
In this course, we will learn the embedded graphics systems and programming part of it along with using LVGL for creating UI applications, writing all the code completely from scratch (using register-level programming), as well as creating an embedded graphics application for different boards simultaneously (any STM32 board with external TFT LCD interfaced via the SPI interface).
First part of the course covers:
- Basics of embedded graphics systems.
- How to interface an LCD-TFT display to the microcontroller board.
- How to use the LTDC peripheral of the STM32 microcontroller.
- How to communicate between the microcontroller and the TFT display using MIPI DPI and MIPI DBI.
- Bare metal programming.
Second part of the course covers:
- Introduction to LVGL (an open-source graphics library for microcontrollers).
- Using LVGL in STM32 projects.
- LVGL widgets and their usage, APIs.
- Create UI application using LVGL.
- Testing LVGL application on PC simulator and different STM32 development boards.
- Final project.
STM32 32F429IDISCOVERY Discovery Board with STM32F429ZI Microcontroller - Board used in this course but any board with Arm Cortex-M4/7 core interfaced with External ILI9341 TFT-LCD via SPI will work, just modifying the target board and configuring with the respective datasheet.
Eclipse-based STM32CubeIDE - C/C++ development platform with peripheral configuration, code generation, code compilation, and debug features for STM32 microcontrollers and microprocessors. Works on Windows/Linux/Mac and is free.
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Right click on the project -> properties -> expand C/C++ build -> Settings -> Tool settings -> MCU settings
Floating-point unit: None
Floating-point ABI: Software implementation ( -mfloat-abi=soft )
Open syscalls.c file and paste following code bellow Includes
/////////////////////////////////////////////////////////////////////////////////////////////////////////
// Implementation of printf like feature using ARM Cortex M3/M4/ ITM functionality
// This function will not work for ARM Cortex M0/M0+
// If you are using Cortex M0, then you can use semihosting feature of openOCD
/////////////////////////////////////////////////////////////////////////////////////////////////////////
//Debug Exception and Monitor Control Register base address
#define DEMCR *((volatile uint32_t*) 0xE000EDFCU )
/* ITM register addresses */
#define ITM_STIMULUS_PORT0 *((volatile uint32_t*) 0xE0000000 )
#define ITM_TRACE_EN *((volatile uint32_t*) 0xE0000E00 )
void ITM_SendChar(uint8_t ch)
{
//Enable TRCENA
DEMCR |= ( 1 << 24);
//enable stimulus port 0
ITM_TRACE_EN |= ( 1 << 0);
// read FIFO status in bit [0]:
while(!(ITM_STIMULUS_PORT0 & 1));
//Write to ITM stimulus port0
ITM_STIMULUS_PORT0 = ch;
}
After that find function _write and replace __io_putchar(*ptr++)
with ITM_SendChar(*ptr++)
like in code snippet below
__attribute__((weak)) int _write(int file, char *ptr, int len)
{
int DataIdx;
for (DataIdx = 0; DataIdx < len; DataIdx++)
{
//__io_putchar(*ptr++);
ITM_SendChar(*ptr++);
}
return len;
}
After these steps navigate to Debug configuration and check Serial Wire Viewer (SWV)
check box like on snapshot below
Once you enter Debug mode, go to Window -> Show View -> SWV -> Select SWV ITM Data Console
. On this way ITM Data Console
will be shown in Debug session.
In SWV ITM Data Console Settings
in section ITM Stimulus Ports
enable port 0, so that you can see printf
data.