RPiPico-Holonome2023/gyro_L3GD20H.c

100 lines
2.7 KiB
C

#include "gyro_L3GD20H.h"
#include "spi_nb.h"
#include <stdio.h>
#ifdef GYRO_L3GD20H
int gyro_read_register_blocking(uint8_t registrer, uint8_t *tampon, uint8_t nb_a_lire){
uint8_t reg = registrer | 0xC0 ;
int nb_recu;
cs_select();
spi_write_blocking(spi0, &reg, 1);
sleep_ms(10);
nb_recu = spi_read_blocking(spi0, 0, tampon, nb_a_lire);
cs_deselect();
}
int gyro_init_check(){
// Renvoi 0 si l'initialisation s'est bien passée
// Renvoi 1 si le gyroscope n'a pas répondu
uint8_t tampon[2]="";
gyro_read_register_blocking(0x0F, tampon, 1);
if(tampon[0] == 0xd7){
return 0;
}
return 1;
}
int gyro_config(){
// Registre CTRL1
// DR : 11
// BW : 10
// PD : 1
// Zen : 1
// Yen : 1
// Xen : 1
uint8_t config = 0b11101111;
uint16_t tampon[2] = {0x20, config};
uint8_t tampon2[10]="\0\0\0\0\0\0\0\0\0";
int statu, nb_read;
//while(spi_nb_busy(spi0) == SPI_BUSY);
cs_select();
int rep = spi_nb_write_data(spi0, tampon, 2);
if(rep == SPI_ERR_TRANSMIT_FIFO_FULL){
printf("Erreur: spi_read_register: SPI_ERR_TRANSMIT_FIFO_FULL\n");
//return statu;
}
while(spi_nb_busy(spi0));
cs_deselect();
int nb_lu = spi_read_register(spi0, 0x20, tampon2, 1);
printf("Nb lu: %d\n", nb_lu);
if(tampon2[1] == config){
//puts("gyro_config ok !");
return 0;
}else{
//printf("gyro_config FAILED ! :%#4x\n", tampon2[1]);
return 1;
}
// Registre
}
void gyro_get_vitesse_brute(struct t_angle_gyro* angle_gyro, struct t_angle_gyro* angle_gyro_moy){
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));
if(angle_gyro_moy == NULL){
angle_gyro->rot_x = (int32_t) rot_x * 32;
angle_gyro->rot_y = (int32_t) rot_y * 32;
angle_gyro->rot_z = (int32_t) rot_z * 32;
}else{
angle_gyro->rot_x = (int32_t) rot_x * 32 - angle_gyro_moy->rot_x;
angle_gyro->rot_y = (int32_t) rot_y * 32 - angle_gyro_moy->rot_y;
angle_gyro->rot_z = (int32_t) rot_z * 32 - angle_gyro_moy->rot_z;
}
}
void gyro_get_vitesse_normalisee(struct t_angle_gyro* _vitesse_angulaire,
struct t_angle_gyro_double * _vitesse_gyro){
_vitesse_gyro->rot_x = (double)_vitesse_angulaire->rot_x * 0.00875 / 32.0;
_vitesse_gyro->rot_y = (double)_vitesse_angulaire->rot_y * 0.00875 / 32.0;
_vitesse_gyro->rot_z = (double)_vitesse_angulaire->rot_z * 0.00875 / 32.0;
}
#endif