Keuronde/RPiPico-Holonome2023
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Structuration du code pour le gyroscope - calcul de l'angle

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This commit is contained in:
Samuel 2022-09-26 19:28:45 +02:00
parent d7e885244d
commit e98c500801
3 changed files with 67 additions and 24 deletions
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1
CMakeLists.txt
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@ -8,6 +8,7 @@ add_executable(test
test.c test.c
spi_nb.c spi_nb.c
gyro.c gyro.c
Temps.c
) )
pico_enable_stdio_usb(test 1) pico_enable_stdio_usb(test 1)
pico_enable_stdio_uart(test 1) pico_enable_stdio_uart(test 1)

78
gyro.c
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@ -4,12 +4,25 @@
#include "hardware/spi.h" #include "hardware/spi.h"
#include "hardware/structs/spi.h" #include "hardware/structs/spi.h"
#include "spi_nb.h" #include "spi_nb.h"
#include "Temps.h"
const uint PIN_CS = 1; const uint PIN_CS = 1;
/// @brief structure d'échange des angles du gyrocope
struct t_angle_gyro{
int32_t rot_x, rot_y, rot_z;
} angle_gyro, angle_gyro_moy;
int gyro_init_check(); int gyro_init_check();
void gyro_config(); void gyro_config();
int gyro_read_register_blocking(uint8_t registrer, uint8_t *tampon, uint8_t nb_a_lire); int gyro_read_register_blocking(uint8_t registrer, uint8_t *tampon, uint8_t nb_a_lire);
void gyro_get_angles(struct t_angle_gyro* angle_gyro);
void gyro_calibration(void);
uint32_t rot_x_zero, rot_y_zero, rot_z_zero;
void Gyro_Init(void){ void Gyro_Init(void){
@ -32,11 +45,11 @@ void Gyro_Init(void){
// Test de la présence du gyroscope : // Test de la présence du gyroscope :
if(gyro_init_check()){ if(gyro_init_check()){
puts("Gyroscope non trouve"); puts("Gyroscope non trouve");
gyro_config();
}else{ }else{
puts("Gyroscope trouve"); puts("Gyroscope trouve");
gyro_config(); gyro_config();
} }
//gyro_calibration();
} }
int gyro_init_check(){ int gyro_init_check(){
@ -110,35 +123,64 @@ void Gyro_Read(uint16_t step_ms){
int nb_recu; int nb_recu;
spi_read_register(spi0, 0x20, tampon, 1); spi_read_register(spi0, 0x20, tampon, 1);
//printf ("Gyro CTRL1 (bis) : %#4x\n", tampon[1] ); //printf ("Gyro CTRL1 (bis) : %#4x\n", tampon[1] );
//printf ("RPI SSPCPSR : %#4x\n", spi_get_hw(spi0)->cpsr ); //printf ("RPI SSPCPSR : %#4x\n", spi_get_hw(spi0)->cpsr );
//printf ("RPI SSPCR0 : %#4x\n", spi_get_hw(spi0)->cr0 ); //printf ("RPI SSPCR0 : %#4x\n", spi_get_hw(spi0)->cr0 );
gyro_get_angles(&angle_gyro);
//gyro_read_register_blocking(0x28, tampon, 6); angle_x = angle_x + (double)angle_gyro.rot_x * step_ms * 0.001 * 0.00875 * 0.125;
spi_read_register(spi0, 0x28, tampon, 6); angle_y = angle_y + (double)angle_gyro.rot_y * step_ms * 0.001 * 0.00875 * 0.125;
angle_z = angle_z + (double)angle_gyro.rot_z * step_ms * 0.001 * 0.00875 * 0.125;
for(int i=0; i<10; i++){
printf("%#4x ", tampon[i]);
}
rot_x = -(tampon[1] + (tampon[2] << 8));
rot_y = -(tampon[3] + (tampon[4] << 8));
rot_z = -(tampon[5] + (tampon[6] << 8));
angle_x = angle_x + (double)rot_x * step_ms * 0.001 * 0.00875;
angle_y = angle_y + (double)rot_y * step_ms * 0.001 * 0.00875;
angle_z = angle_z + (double)rot_z * step_ms * 0.001 * 0.00875;
printf("rx : %f, ry : %f, rz: %f\n", angle_x, angle_y, angle_z); printf("rx : %f, ry : %f, rz: %f\n", angle_x, angle_y, angle_z);
//while(spi_nb_busy(spi0)); //while(spi_nb_busy(spi0));
//spi_nb_read_data_8bits(spi0,tampon); //spi_nb_read_data_8bits(spi0,tampon);
//printf("tampon : %s\n", tampon); //printf("tampon : %s\n", tampon);
}
void gyro_get_angles(struct t_angle_gyro* angle_gyro){
uint8_t tampon[10]="\0\0\0\0\0\0\0\0\0";
int16_t rot_x, rot_y, rot_z;
spi_read_register(spi0, 0x28, tampon, 6);
rot_x = -(tampon[1] + (tampon[2] << 8));
rot_y = -(tampon[3] + (tampon[4] << 8));
rot_z = -(tampon[5] + (tampon[6] << 8));
} angle_gyro->rot_x = (int32_t) rot_x * 8;
angle_gyro->rot_y = (int32_t) rot_y * 8;
angle_gyro->rot_z = (int32_t) rot_z * 8;
}
void gyro_calibration(void){
uint16_t nb_ech = 3000;
uint32_t m_temps_ms = Temps_get_temps_ms();
printf("Calibration...\n");
angle_gyro_moy.rot_x = 0;
angle_gyro_moy.rot_y = 0;
angle_gyro_moy.rot_z = 0;
for(uint16_t i=0; i<nb_ech; i++){
while(m_temps_ms == Temps_get_temps_ms());
gyro_get_angles(&angle_gyro);
angle_gyro_moy.rot_x += angle_gyro.rot_x;
angle_gyro_moy.rot_y += angle_gyro.rot_y;
angle_gyro_moy.rot_z += angle_gyro.rot_z;
}
angle_gyro_moy.rot_x = angle_gyro_moy.rot_x / nb_ech;
angle_gyro_moy.rot_y = angle_gyro_moy.rot_y / nb_ech;
angle_gyro_moy.rot_z = angle_gyro_moy.rot_z / nb_ech;
printf("Calibration : rx : %f, ry : %f, rz: %f\n", angle_gyro_moy.rot_x,
angle_gyro_moy.rot_y, angle_gyro_moy.rot_z);
}

12
spi_nb.c
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@ -158,23 +158,23 @@ uint8_t spi_nb_read_data_8bits(spi_inst_t * spi, uint8_t * buffer){
/// @param size size of the data to transmit /// @param size size of the data to transmit
/// @return SPI_OK or SPI_ERR_TRANSMIT_FIFO_FULL /// @return SPI_OK or SPI_ERR_TRANSMIT_FIFO_FULL
inline int spi_nb_write_data(spi_inst_t * spi, uint16_t * buffer, uint8_t size){ inline int spi_nb_write_data(spi_inst_t * spi, uint16_t * buffer, uint8_t size){
int statu_spi = SPI_OK; int status_spi = SPI_OK;
uint8_t index=0; uint8_t index=0;
do do
{ {
if(spi_get_hw(spi)->sr & SPI_SSPSR_TNF_BITS){ if(spi_get_hw(spi)->sr & SPI_SSPSR_TNF_BITS){
spi_get_hw(spi)->dr = buffer[index]; spi_get_hw(spi)->dr = buffer[index];
statu_spi = SPI_OK; status_spi = SPI_OK;
}else{ }else{
statu_spi = SPI_ERR_TRANSMIT_FIFO_FULL; status_spi = SPI_ERR_TRANSMIT_FIFO_FULL;
} }
while (spi_is_busy(spi)); while (spi_nb_busy(spi));
//statu_spi = spi_nb_write_byte(spi, buffer[index]); //statu_spi = spi_nb_write_byte(spi, buffer[index]);
//printf("envoi : %x\n", buffer[index]); //printf("envoi : %x\n", buffer[index]);
//sleep_ms(1); //sleep_ms(1);
index++; index++;
} while ( (statu_spi == SPI_OK) && (index < size)); } while ( (status_spi == SPI_OK) && (index < size));
return statu_spi; return status_spi;
} }
/// @brief Write one "byte", 4 to 16 bits to the SPI Transmit FIFO. /// @brief Write one "byte", 4 to 16 bits to the SPI Transmit FIFO.