We had a great morning today with the children and teachers of St. Brigid’s primary school. We had 22 participants who all left with working BBG’s. Pictures and some more details over at St. Brigid’s blog.
This year’s code was more or less the same as last year’s however support for additional screens was added. Source code is over on github.
The event took place in the recently refurbished and fantastic Kevin St. public library. Thanks to all concerned especially Gillian, Ciaran and Esmé, Sam, Oran, Shannon and Shane.
Author: fduignan
The STM32F030 driving an ST7789 display
The ST7789 display used in this example is a 1.3 inch 240×240 colour LCD display. It interfaces to the STM32F030 at the pretty fast speed of 24MHz. The display is connected as follows:
My intention with this circuit is to create a low cost conference badge (actually for Dublin Maker 2019). The target bill-of-materials cost is €5 – most of which is attributed to the display.
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Connecting the hardware is only part of the story however and a software library is also required. This was based on the Breadboard Games code from last August in Wexford. The main changes that had to be addressed were the new initialization code and the openAperture code. These were based on the Adafruit library code and the manufacturer’s datasheet. This library includes some graphic drawing primitives as well as other functions to support game play (e.g. timing and random number generation). Additional functions will be added as the badge develops.
Code is available on github
A video of the library in operation is available on YouTube.
The STM32F334 from the ground up
The STM32F334 MCU has an ARM Cortex M4F core along with ADC’s, DAC’s and motor control timers – all of which are useful to me for DSP and motor control. My final intention is to design a couple of PCB’s around this chip so rather than buy a ready made board like the STM32F334 Discovery I decided to work directly with the bare chip.
First task is to mount the chip on a breakout board so that I can use it with a breadboard.
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Some tips when doing this:
Have a good soldering iron that does not get too hot (I have an Antek 25W iron)
Have lots of liquid flux available and apply liberally
Have solder wick to hand to sort out the (inevitable for me) solder bridges
The circuit was wired as shown in the diagram above and is shown here:
I used an ST-Link clone from Aliexpress which costs 2 or 3 Euro.
In the past I have manually written header files for the various internal peripherals. ST Microelectronics provide a System Volume Description file which can be used with SVDConv to create a header file. This header file relies on other components from the ARM CMSIS libraries spread across various folders. I don’t like this so I added various dummy files (some with zero content) to the same directory as the generated header file. This allows me confine all header files to one directory and is completely standalone.
Having done all of this various examples were written and the code repository is over at github. This will grow over time but for now there are examples of blinky, systick interrupts, UART i/o and the ADC.
Using the TLS2561 to wake the STM32L031 from sleep
In some ways this example is a bit illogical. The TLS2561 consumes a few hundred micro amps while operating so using it to wake the STM32L031 from sleep doesn’t make a lot of sense. This example may be relevant to those who want to use an external I/O pin to wake the an STM32L031 generally or maybe as part of a larger circuit.
The TLS2561 can generate an interrupt signal when the light received on Channel 0 goes outside a user specified certain range. In this example, the range was arbitrarily set to go from 0 0x100. If the received light is equal to or greater than 0x100 then the interrupt signal is driven low which wakes the MCU. If the light is less than or equal to 0 an interrupt is also generated. This isn’t exactly what I wanted (I only wanted an interrupt if the light was bright) so if the circuit is plunged into complete darkness an interrupt will also be generated. This unintended waking could be dealt with by checking the value on Channel 0 and, if zero, going back to sleep again.
Code is available as usual over on github.
Using the TLS2561 with the STM32L031
The TLS2561 is a digital light sensor which senses light on two wavelengths and outputs two 16 bit results. These values are accessed over an I2C bus. This test program simply reads and displays the ADC results. The manufacturer provides a C source example that can then be used to convert this to LUX. For now I’m not particularly interested in this feature. What is possibly of more interest is the interrupt capability of the device which may allow it to wake a slumbering MCU when light levels fall between certain values. This may be of use in a power saving context. More to follow but for now, source code for my various STM32L031 examples can be found over here on github
STM32L031 controlling a PL9823 LED using SPI
The PL9823 is a smart LED much like the WS2812B. There are some slight timing differences and they can sometimes be found cheaper than an equivalent WS2812B. I got hold of a few from Aliexpress in a frosted 8mm package with 4 pins that allow them to be used in a breadboard.
In a previous post I outlined how SPI could be used with an STM32F042 to drive a WS2182b. Things were a little different in this case as the STM32L031 has fewer options with the SPI clock and the slightly different timing requirements of the PL9823. 
The image above shows the control from the MOSI signal for a nearly white colour on the LED. The signal is shows a 12 byte sequence which is interpreted as a 3 byte RGB sequence by the PL9823. A PL9823 logic ‘1’ is sent by sending 3 SPI ‘1’s followed by a zero. This takes 2 microseconds. A logic ‘0’ is sent by sending a single SPI ‘1’ and 3 SPI ‘0’s. The sequence is generated using the following function
void writePL9823(uint32_t Colour)
{
// each colour bit should map to 4 SPI bits.
// Format of Colour (bytes) 00RRGGBB
uint8_t SPI_Output[12];
int SrcIndex = 0;
int DestIndex = 0;
for (DestIndex = 0; DestIndex < 12; DestIndex++)
{
if (Colour & (1 << 23))
{
SPI_Output[DestIndex] = 0xe0;
}
else
{
SPI_Output[DestIndex] = 0x80;
}
Colour = Colour << 1;
if (Colour & (1 << 23))
{
SPI_Output[DestIndex] |= 0xe;
}
else
{
SPI_Output[DestIndex] |= 0x8;
}
Colour = Colour << 1;
}
for (int i=0;i<12;i++)
{
transferSPI(SPI_Output[i]);
}
}
The code expands a 3 byte colour sequence into a 12 byte one and sends it over an SPI link running at 2MHz. This is sufficient to match the timing requirements of the PL9823.
A demo program which cycles through various colours can be found over on github.
Using an SPI Flash chip with the STM32L031 Nucleo and mbed
The W25Q32 is a 4 MByte SPI Flash ROM device which costs about 30 cents. It comes in an 8 pin surface mount package and so must be mounted on a breakout board if you want to use it with a breadboard. I designed a breakout board with KiCad and you can see it in the above image.
A test program was written along with a C++ class to encapsulate the device’s functions. The test program begins by powering up the device, it then does a bulk erase followed by a write of the string “Hello World”. The main loop then continuously reads this string back from the chip. Be careful how often you erase the device – you only get so many write/erase cycles.
This sort of device could be useful for event logging in an embedded system or it could be used to store an large program that is pulled in to RAM by a bootloader.
file: main.cpp
// Developed on the NUCLEO-L031K6 board from ST Micro and
// the W25Q32BV SPI Flash rom
#include "mbed.h"
#include "spiflash.h"
DigitalOut myled(LED1);
SPI spi(PB_5, PB_4, PB_3);
Serial pc(USBTX, USBRX);
DigitalOut nSS(PA_11);
spiflash Myflash(spi,nSS);
int main() {
spi.format(8,3);
pc.printf("Powering up\r\n");
Myflash.powerUp();
wait(0.1);
pc.printf("Erasing\r\n");
Myflash.eraseAll();
pc.printf("Writing\r\n");
Myflash.writeDataBytes(0,(uint8_t *)"Hello World",11);
while(1) {
uint8_t Contents[16];
// Write guard bytes to the end of the buffer to test operation
// of read function.
Contents[13]=13;
Contents[14]=14;
Contents[15]=15;
Myflash.readDataBytes(0,Contents,14);
pc.printf("\r\n++++++++++++++++++++++++++++++++++\r\n");
for (int i=0;i < 16; i++)
{
pc.printf("%02x ", Contents[i]);
}
myled = 1; // LED is ON
wait(0.2); // 200 ms
myled = 0; // LED is OFF
wait(1.0); // 1 sec
pc.printf("\r\nID = %X\r\n",Myflash.readDeviceIdentifier());
}
}
The listings for the spiflash class are listed further down this post. I used PulseView and a cheap 8 channel USB logic analyzer to capture the following waveforms for the function readDeviceIdentifier()
file: spiflash.h
#ifndef __spiflash_h
#define __spiflash_h
#include "mbed.h"
class spiflash {
public:
spiflash(SPI &Spi, DigitalOut & NSS);
void powerUp();
void eraseAll();
void eraseSector(uint32_t Address);
void enableWrite();
void disableWrite();
void readDataBytes(uint32_t Address, uint8_t *ByteArray, uint32_t Length);
void writeDataBytes(uint32_t Address, uint8_t *ByteArray, uint32_t Length);
uint32_t readDeviceIdentifier();
private:
static const uint32_t FlashMemorySize=4194304; // Capacity of W25Q32BV
static const uint32_t SectorSize=4096; // Erase sector size
static const uint32_t PageSize=256; // Number of bytes that can be programmed at one time
SPI & spi;
DigitalOut &nSS;
uint32_t readStatusRegister1();
};
#endif
file: spiflash.cpp
#include "spiflash.h"
spiflash::spiflash(SPI &Spi, DigitalOut & NSS) : spi(Spi), nSS(NSS)
{
}
void spiflash::powerUp()
{
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0xAB; // Command 0xAB = "Release from power down"
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,1,RxBuffer,1); // Write 1 byte and read 1 byte
nSS = 1; // Drive nCS high to disconnect slave from the bus
}
void spiflash::eraseAll()
{
enableWrite();
// Use sparingly!!! Limited number of cycles available
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0xc7; // Command 0xc7 = "Bulk Erase"
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,1,RxBuffer,1); // Write 1 byte and read 1 byte
nSS = 1; // Drive nCS high to disconnect slave from the bus
while (readStatusRegister1() & 1)
{ // Wait for device erase to complete
}
}
void spiflash::eraseSector(uint32_t Address)
{
enableWrite();
// Mask off the lower bits of the Sector Address (redundant?)
//Address = Address & 0xfffc00; //0b1111 1111 1111 1100 0000 0000
// Use sparingly!!! Limited number of cycles available
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0x20; // Command 0x20 = "Sector Erase"
TxBuffer[1] = (Address >> 16) & 0xff;
TxBuffer[2] = (Address >> 8) & 0xff;
TxBuffer[3] = (Address & 0xff);
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,4,RxBuffer,1); // Write 1 byte and read 1 byte
nSS = 1; // Drive nCS high to disconnect slave from the bus
while (readStatusRegister1() & 1)
{
// Wait for sector erase to complete
}
}
void spiflash::enableWrite()
{
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0x06; // Command 0x06 = "Enable writes"
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,1,RxBuffer,1); // Write 1 byte and read 1 byte
nSS = 1; // Drive nSS high to disconnect slave from the bus
}
void spiflash::disableWrite()
{
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0x06; // Command 0x06 = "Disable writes"
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,1,RxBuffer,1); // Write 1 byte and read 1 byte
nSS = 1; // Drive nSS high to disconnect slave from the bus
}
void spiflash::readDataBytes(uint32_t Address, uint8_t *ByteArray, uint32_t Length)
{
// Read Length bytes starting at Address and return in ByteArray
char TxBuffer[4]; // Transmit buffer
TxBuffer[0]=0x03; // Command 0x03 = "Read bytes"
nSS = 0;
TxBuffer[1] = (Address >> 16) & 0xff;
TxBuffer[2] = (Address >> 8) & 0xff;
TxBuffer[3] = (Address) & 0xff;
spi.write(TxBuffer,4,0,0); // Send command and Address of interest
spi.write(0,0,(char *)ByteArray,Length); // Send command and Address of interest
nSS = 1;
}
void spiflash::writeDataBytes(uint32_t Address, uint8_t *ByteArray, uint32_t Length)
{
enableWrite();
char TxBuffer[4]; // Transmit buffer
TxBuffer[0]=0x02; // Command 0x02 = "Write bytes"
TxBuffer[1] = (Address >> 16) & 0xff;
TxBuffer[2] = (Address >> 8) & 0xff;
TxBuffer[3] = (Address) & 0xff;
nSS = 0;
spi.write(TxBuffer,4,0,0); // Send command and Address of interest
spi.write((char *)ByteArray, Length, 0,0); // Send command and Address of interest
nSS = 1;
while (readStatusRegister1() & 1)
{
// Wait for write data to complete
}
}
uint32_t spiflash::readDeviceIdentifier()
{
// If the chip conforms with JEDEC norms, the last byte of the ID should
// indicate the capacity. The last byte is the size of the chip express
// in powers of 2. For example if you read 0x16 (22 decimal) then the
// chip should have a capacity of 2^22 = 4MiB.
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0x9f; // Command 0x9f = "Read status Device ID"
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,1,RxBuffer,4); // Write 1 byte and read 4 bytes
nSS = 1; // Drive nCS high to disconnect slave from the bus
uint32_t ID=RxBuffer[1];
ID = ID << 8;
ID += RxBuffer[2];
ID = ID << 8;
ID += RxBuffer[3];
return ID; // return the status register contents
}
uint32_t spiflash::readStatusRegister1()
{
char TxBuffer[4]; // Transmit buffer
char RxBuffer[4]; // Receive buffer
TxBuffer[0]=0x05; // Command 0x9f = "Read Status register 1"
nSS = 0; // Drive nCS low to connect slave to the bus
spi.write(TxBuffer,1,RxBuffer,2); // Write 1 byte and read 1 byte
nSS = 1; // Drive nCS high to disconnect slave from the bus
return RxBuffer[1]; // return the status register contents
}
