Acquisition avec le gyroscope + début code servomoteur (commande fonctionnelle mais interface à refaire)

2022-10-15 21:13:52 +02:00 · 2022-10-15 21:13:52 +02:00 · bab11c7b45
commit bab11c7b45
parent 8831c3d8a9
20 changed files with 148342 additions and 47 deletions
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@ -9,11 +9,12 @@ test.c
 spi_nb.c
 gyro.c
 Temps.c
 Servomoteur.c
 )
 pico_enable_stdio_usb(test 1)
 pico_enable_stdio_uart(test 1)
 pico_add_extra_outputs(test)
-target_link_libraries(test pico_stdlib hardware_spi hardware_structs)
+target_link_libraries(test pico_stdlib hardware_spi hardware_pwm hardware_structs)
 add_custom_target(Flash
    DEPENDS test
--- a/Servomoteur.c
+++ b/Servomoteur.c
@ -0,0 +1,20 @@
 #include "pico/stdlib.h"
 #include "hardware/pwm.h"
 #include "Servomoteur.h"
 #define SERVO1 0
 void Servomoteur_Init(void){
    gpio_set_function(SERVO1, GPIO_FUNC_PWM);
    uint slice_num = pwm_gpio_to_slice_num(SERVO1);
    pwm_config pwm_servo = pwm_get_default_config();
    pwm_config_set_clkdiv_int(&pwm_servo, 254);
    pwm_config_set_phase_correct(&pwm_servo, false);
    pwm_config_set_wrap(&pwm_servo, 9842);
    pwm_init(slice_num, &pwm_servo, true);
    pwm_set_chan_level(slice_num, 0, 984 );
 }
--- a/Servomoteur.h
+++ b/Servomoteur.h
@ -0,0 +1 @@
 void Servomoteur_Init(void);
--- a/acq_5ms_env_50ms.csv
+++ b/acq_5ms_env_50ms.csv
--- a/acq_5ms_env_50ms_enr_01.csv
+++ b/acq_5ms_env_50ms_enr_01.csv
--- a/acq_5ms_env_50ms_enr_02.csv
+++ b/acq_5ms_env_50ms_enr_02.csv
--- a/graph.gp
+++ b/graph.gp
@ -0,0 +1,15 @@
 set title "Observation des 3 axes\nT_{acq} : 5 ms"
 set xlabel "Temps (s)"
 set ylabel "Vitesse (°/s)"
 plot "./acq_5ms_env_50ms.csv" using 2:5 w l title "Vitesse X"
 pause -1
 plot "./acq_5ms_env_50ms.csv" using 2:6 w l title "Vitesse Y"
 pause -1
 plot "./acq_5ms_env_50ms.csv" using 2:7 w l title "Vitesse Z"
 pause -1
--- a/graph/APDS9960_Vitesse_X_filtre.png
+++ b/graph/APDS9960_Vitesse_X_filtre.png
--- a/graph/APDS9960_Vitesse_Y_filtre.png
+++ b/graph/APDS9960_Vitesse_Y_filtre.png
--- a/graph/APDS9960_Vitesse_Z_filtre.png
+++ b/graph/APDS9960_Vitesse_Z_filtre.png
--- a/graph/APDS9960_Vitesse_debut_X_filtre.png
+++ b/graph/APDS9960_Vitesse_debut_X_filtre.png
--- a/graph/APDS9960_Vitesse_debut_Y_filtre.png
+++ b/graph/APDS9960_Vitesse_debut_Y_filtre.png
--- a/graph/APDS9960_Vitesse_debut_Z_filtre.png
+++ b/graph/APDS9960_Vitesse_debut_Z_filtre.png
--- a/graph_enr01.gp
+++ b/graph_enr01.gp
@ -0,0 +1,15 @@
 set title "Observation des 3 axes\nT_{acq} : 5 ms"
 set xlabel "Temps (s)"
 set ylabel "Vitesse (°/s)"
 plot "./acq_5ms_env_50ms_enr_01.csv" using 1:2 w l title "Vitesse X"
 pause -1
 plot "./acq_5ms_env_50ms_enr_01.csv" using 1:3 w l title "Vitesse Y"
 pause -1
 plot "./acq_5ms_env_50ms_enr_01.csv" using 1:4 w l title "Vitesse Z"
 pause -1
--- a/graph_enr02.gp
+++ b/graph_enr02.gp
@ -0,0 +1,10 @@
 set title "Observation des 3 axes\nT_{acq} : 5 ms"
 set xlabel "Temps (s)"
 set ylabel "Vitesse (°/s)"
 set grid ytics 
 set term png size 1200,600
 plot "./acq_5ms_env_50ms_enr_02.csv" using 1:2 w l title "Vitesse X"
--- a/gyro.c
+++ b/gyro.c
@ -7,10 +7,8 @@
 #include "Temps.h"
 #include "gyro.h"
 const uint PIN_CS = 1;
 struct t_angle_gyro{
-    int32_t rot_x, rot_y, rot_z;
+    int32_t rot_x, rot_y, rot_z, temp;
 };
 /// @brief structure d'échange des angles du gyrocope
@ -26,13 +24,15 @@ uint32_t rot_x_zero, rot_y_zero, rot_z_zero;
-struct t_angle_gyro_double angle_gyro;
+struct t_angle_gyro_double angle_gyro, vitesse_gyro;
 struct t_angle_gyro_double gyro_get_angle(void){
    return angle_gyro;
 }
-
+struct t_angle_gyro_double gyro_get_vitesse(void){
    return vitesse_gyro;
 }
 void Gyro_Init(void){
    // 
@ -45,9 +45,14 @@ void Gyro_Init(void){
    gpio_set_dir(PIN_CS, GPIO_OUT);
    cs_deselect();
    vitesse_calibration.rot_x = 0;
    vitesse_calibration.rot_y = 0;
    vitesse_calibration.rot_z = 0;
    vitesse_calibration.temp = 0;
    //spi_init(spi0, 100 * 1000); // SPI init @ 100 kHz
    uint speed = spi_init(spi0, 2 * 1000 * 1000); // SPI init @ 2 MHz
-    printf("vitesse SPI : %d ", speed);
+    printf("vitesse SPI : %d\n", speed);
    //Ça doit être les valeurs par défaut, mais ça marche !
    spi_set_format(spi0, 8, SPI_CPHA_1, SPI_CPOL_1, SPI_MSB_FIRST);
@ -59,7 +64,10 @@ void Gyro_Init(void){
        puts("Gyroscope trouve");
        gyro_config();        
    }
-    gyro_calibration();
+    sleep_ms(150); // Temps d'init du gyroscope
    /*while(1){
        gyro_calibration();
    }*/
 }
 int gyro_init_check(){
@ -86,22 +94,27 @@ void gyro_config(){
    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);
+
    //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) == SPI_BUSY);
+    while(spi_nb_busy(spi0));
    cs_deselect();
-    spi_read_register(spi0, 0x20, tampon2, 1);
+    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 !");
    }else{
-        puts("gyro_config FAILED !");
+        printf("gyro_config FAILED ! :%#4x\n", tampon2[1]);
    }
    // Registre 
@ -138,9 +151,13 @@ void Gyro_Read(uint16_t step_ms){
    //gyro_get_angles(&vitesse_angulaire, NULL);
    // Angle en degré
-    angle_gyro.rot_x = angle_gyro.rot_x + (double)vitesse_angulaire.rot_x * step_ms * 0.001 * 0.00875 * 0.125;
+    vitesse_gyro.rot_x = (double)vitesse_angulaire.rot_x * 0.00875 / 32.0;
-    angle_gyro.rot_y = angle_gyro.rot_y + (double)vitesse_angulaire.rot_y * step_ms * 0.001 * 0.00875 * 0.125;
+    vitesse_gyro.rot_y = (double)vitesse_angulaire.rot_y * 0.00875 / 32.0;
-    angle_gyro.rot_z = angle_gyro.rot_z + (double)vitesse_angulaire.rot_z * step_ms * 0.001 * 0.00875 * 0.125;
+    vitesse_gyro.rot_z = (double)vitesse_angulaire.rot_z * 0.00875 / 32.0;
    angle_gyro.rot_x = angle_gyro.rot_x + vitesse_gyro.rot_x * step_ms * 0.001;
    angle_gyro.rot_y = angle_gyro.rot_y + vitesse_gyro.rot_y * step_ms * 0.001;
    angle_gyro.rot_z = angle_gyro.rot_z + vitesse_gyro.rot_z * step_ms * 0.001;
    //printf("%d, %#4x, %#4x, %#4x\n", step_ms, vitesse_angulaire.rot_x, vitesse_angulaire.rot_y, vitesse_angulaire.rot_z);
@ -151,6 +168,15 @@ void Gyro_Read(uint16_t step_ms){
    //printf("tampon : %s\n", tampon);
 }
 int16_t gyro_get_temp(void){
    int8_t tampon[3]="\0\0";
    int16_t temperature;
    spi_read_register(spi0, 0x26, tampon, 6);
    temperature = -tampon[1];
    printf("temperature %d\n",temperature);
 }
 void gyro_get_angles(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;
@ -161,32 +187,31 @@ void gyro_get_angles(struct t_angle_gyro* angle_gyro, struct t_angle_gyro* angle
    rot_z = -(tampon[5] + (tampon[6] << 8));
    if(angle_gyro_moy == NULL){
-        angle_gyro->rot_x = (int32_t) rot_x * 8;
+        angle_gyro->rot_x = (int32_t) rot_x * 32;
-        angle_gyro->rot_y = (int32_t) rot_y * 8;
+        angle_gyro->rot_y = (int32_t) rot_y * 32;
-        angle_gyro->rot_z = (int32_t) rot_z * 8;
+        angle_gyro->rot_z = (int32_t) rot_z * 32;
    }else{
-        angle_gyro->rot_x = (int32_t) rot_x * 8 - angle_gyro_moy->rot_x;
+        angle_gyro->rot_x = (int32_t) rot_x * 32 - angle_gyro_moy->rot_x;
-        angle_gyro->rot_y = (int32_t) rot_y * 8 - angle_gyro_moy->rot_y;
+        angle_gyro->rot_y = (int32_t) rot_y * 32 - angle_gyro_moy->rot_y;
-        angle_gyro->rot_z = (int32_t) rot_z * 8 - angle_gyro_moy->rot_z;
+        angle_gyro->rot_z = (int32_t) rot_z * 32 - angle_gyro_moy->rot_z;
    }
 }
 void gyro_affiche(struct t_angle_gyro_double angle_gyro, char * titre){
    if(titre != NULL){
        printf("%s ",titre);
    }
-    printf("rx : %f, ry : %f, rz: %f\n", angle_gyro.rot_x, 
+    printf("angle, %f, %f, %f\n", angle_gyro.rot_x, angle_gyro.rot_y, angle_gyro.rot_z);
    angle_gyro.rot_y, angle_gyro.rot_z);
 }
 void gyro_calibration(void){
-    uint32_t nb_ech = 100;
+    uint32_t t_calibration_ms = 40000;
    uint32_t nb_ech = t_calibration_ms/5;
    uint32_t m_temps_ms = Temps_get_temps_ms();
    uint32_t temps_500ms = m_temps_ms;
    int16_t temperature;
    printf("Calibration...\n");
@ -194,7 +219,7 @@ void gyro_calibration(void){
    vitesse_calibration.rot_y = 0;
    vitesse_calibration.rot_z = 0;
-    // Acquisition des échantillons, 1 par milliseconde
+    // Acquisition des échantillons, 1 par milliseconde (1 ms, c'est trop court on dirait !)
    for(uint32_t i=0; i<nb_ech; i++){
        while(m_temps_ms == Temps_get_temps_ms());
        m_temps_ms = Temps_get_temps_ms();
@ -202,13 +227,19 @@ void gyro_calibration(void){
        vitesse_calibration.rot_x += vitesse_angulaire.rot_x;
        vitesse_calibration.rot_y += vitesse_angulaire.rot_y;
        vitesse_calibration.rot_z += vitesse_angulaire.rot_z;
-
+        if(m_temps_ms > temps_500ms){
            printf(".");
            gyro_get_temp();
            temps_500ms += 500;
        }
        sleep_ms(5);
    }
-    vitesse_calibration.rot_x = vitesse_calibration.rot_x / nb_ech;
+    vitesse_calibration.rot_x = vitesse_calibration.rot_x / (int32_t)nb_ech;
-    vitesse_calibration.rot_y = vitesse_calibration.rot_y / nb_ech;
+    vitesse_calibration.rot_y = vitesse_calibration.rot_y / (int32_t)nb_ech;
-    vitesse_calibration.rot_z = vitesse_calibration.rot_z / nb_ech;
+    vitesse_calibration.rot_z = vitesse_calibration.rot_z / (int32_t)nb_ech;
    temperature = gyro_get_temp();
-    printf("fin calibration\n");
+    printf("fin calibration, %d, %d, %d, %d\n", vitesse_calibration.rot_x, vitesse_calibration.rot_y ,vitesse_calibration.rot_z, temperature);
 }
--- a/gyro.h
+++ b/gyro.h
@ -6,3 +6,5 @@ void Gyro_Init(void);
 void Gyro_Read(u_int16_t);
 void gyro_affiche(struct t_angle_gyro_double angle_gyro, char * titre);
 struct t_angle_gyro_double gyro_get_angle(void);
 struct t_angle_gyro_double gyro_get_vitesse(void);
 int16_t gyro_get_temp(void);
--- a/spi_nb.c
+++ b/spi_nb.c
@ -14,7 +14,7 @@ uint16_t spi0_slave_register;
 uint8_t* spi0_buffer;
 uint8_t  spi0_nb_data_to_read;
-#define PIN_CS 1
+
 void cs_select(void) {
    asm volatile("nop \n nop \n nop");
@ -158,7 +158,7 @@ uint8_t spi_nb_read_data_8bits(spi_inst_t * spi, uint8_t * buffer){
 /// @param size size of the data to transmit
 /// @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){
-    int status_spi = SPI_OK;
+    int status_spi;
    uint8_t index=0;
    do
    {
@ -168,7 +168,7 @@ inline int spi_nb_write_data(spi_inst_t * spi, uint16_t * buffer, uint8_t size){
        }else{
            status_spi = SPI_ERR_TRANSMIT_FIFO_FULL;
        }
-        while (spi_nb_busy(spi));
+        //while (spi_nb_busy(spi));// <== ça, c'est bizarre !
        //statu_spi = spi_nb_write_byte(spi, buffer[index]);
        //printf("envoi : %x\n", buffer[index]);
        //sleep_ms(1);
@ -209,5 +209,65 @@ int spi_read_register(spi_inst_t * spi, uint16_t spi_slave_register, uint8_t *bu
    if(nb_read != nb_to_read+1){
        printf("Erreur: spi_read_register, nb de valeurs lues incoherentes");
    }
    return nb_read;
 }
 void spi_test(){
    // Gyro_Init
    uint16_t tampon_ecriture[] = {'a','b','c','d','e','f','g','h','i','j',0};
    uint8_t tampon_lecture[10] = {0,0,0,0,0,0,0,0,0,0};
    uint8_t nb_lu, statu;
    uint8_t config = 0b11101111;
    uint16_t config_gyro[2] = {0x20, config};
    gpio_set_function(16, GPIO_FUNC_SPI); // SDI
    gpio_set_function(18, GPIO_FUNC_SPI); // SCK
    gpio_set_function(19, GPIO_FUNC_SPI); // SDO
    gpio_set_function(PIN_CS, GPIO_OUT); // CSn
    gpio_init(PIN_CS);
    gpio_set_dir(PIN_CS, GPIO_OUT);
    cs_deselect();
    //spi_init(spi0, 100 * 1000); // SPI init @ 100 kHz
    uint speed = spi_init(spi0, 2 * 1000 * 1000); // SPI init @ 2 MHz
    printf("vitesse SPI : %d\n", speed);
    //Ça doit être les valeurs par défaut, mais ça marche !
    spi_set_format(spi0, 8, SPI_CPHA_1, SPI_CPOL_1, SPI_MSB_FIRST);
    // Gyro_Init
    // gyro_config
    cs_select();
    statu = spi_nb_write_data(spi0, config_gyro, 2);
    if(statu == SPI_ERR_TRANSMIT_FIFO_FULL){
        printf("Erreur: spi_read_register: SPI_ERR_TRANSMIT_FIFO_FULL\n");
    }
    while(spi_nb_busy(spi0));
    cs_deselect();
    nb_lu = spi_read_register(spi0, 0x20, tampon_lecture, 1);
    printf("Nb lu: %d\n", nb_lu);
    //puts(tampon_lecture);
    if(tampon_lecture[1] == config){
        puts("gyro_config ok !");
    }else{
        puts("gyro_config FAILED !");
        printf("gyro_config FAILED ! :%#4x\n", tampon_lecture[1]);
    }
 }
--- a/spi_nb.h
+++ b/spi_nb.h
@ -7,9 +7,11 @@
 #define SPI_IN_PROGRESS 1
 #define SPI_FAILED 2
-#define SPI_ERR_TRANSMIT_FIFO_FULL 1
+#define SPI_ERR_TRANSMIT_FIFO_FULL -1
 #define SPI_OK 0
 #define PIN_CS 1
 int spi_nb_busy(spi_inst_t * spi);
 void spi_nb_flush_recieve_fifo(spi_inst_t * spi);
 int spi_nb_write_byte(spi_inst_t * spi, uint16_t data);
@ -20,3 +22,4 @@ int spi_read_register(spi_inst_t * spi, uint16_t spi_slave_register, uint8_t *bu
 void cs_select(void);
 void cs_deselect(void);
 void spi_test();
--- a/test.c
+++ b/test.c
@ -5,14 +5,20 @@
 #include "gyro.h"
 #include "Temps.h"
 #include "spi_nb.h"
 #include "Servomoteur.h"
 const uint LED_PIN = 25;
 #define V_INIT -999.0
 int main() {
    bi_decl(bi_program_description("This is a test binary."));
    bi_decl(bi_1pin_with_name(LED_PIN, "On-board LED"));
    double vitesse_filtre_x=V_INIT, vitesse_filtre_y=V_INIT, vitesse_filtre_z=V_INIT;
    struct t_angle_gyro_double angle_gyro;
-    uint32_t temps_ms = 0;
+    uint32_t temps_ms = 0, temps_ms_old;
    stdio_init_all();
@ -21,24 +27,54 @@ int main() {
    gpio_put(LED_PIN, 1);
    sleep_ms(3000);
    Servomoteur_Init();
    //puts("Debut");
    //spi_test();
-
+    //while(1);
    Temps_init();
    Gyro_Init();
    temps_ms = Temps_get_temps_ms();
    temps_ms_old = temps_ms;
    while (1) { 
        u_int16_t step_ms = 5;
        float coef_filtre = 0.001;
        while(temps_ms_old == Temps_get_temps_ms());
        temps_ms_old = Temps_get_temps_ms();
        // Tous les pas de step_ms
-        if(temps_ms == Temps_get_temps_ms()){
+        if(Temps_get_temps_ms() % step_ms){
            temps_ms += step_ms;
            Gyro_Read(step_ms);
            //gyro_affiche(gyro_get_vitesse(), "Angle :");
            // Filtre 
            angle_gyro = gyro_get_vitesse();
            if(vitesse_filtre_x == V_INIT){
                vitesse_filtre_x = angle_gyro.rot_x;
                vitesse_filtre_y = angle_gyro.rot_y;
                vitesse_filtre_z = angle_gyro.rot_z;
            }else{
                vitesse_filtre_x = vitesse_filtre_x * (1-coef_filtre) + angle_gyro.rot_x * coef_filtre;
                vitesse_filtre_y = vitesse_filtre_y * (1-coef_filtre) + angle_gyro.rot_y * coef_filtre;
                vitesse_filtre_z = vitesse_filtre_z * (1-coef_filtre) + angle_gyro.rot_z * coef_filtre;
            }
            printf("%f, %f, %f, %f\n", (double)temps_ms_old / 1000, vitesse_filtre_x, vitesse_filtre_y, vitesse_filtre_z);
            //gyro_affiche(angle_gyro, "Vitesse (°/s),");
        }
        // Toutes les 50 ms
        if((Temps_get_temps_ms() % 50) == 0){
        }
        // Toutes les 500 ms
        if((Temps_get_temps_ms() % 500) == 0){
-            gyro_affiche(gyro_get_angle(), "Angle :");
+            //gyro_affiche(gyro_get_angle(), "Angle :");
        }
        // Toutes les secondes
        if((Temps_get_temps_ms() % 500) == 0){
            //gyro_get_temp();
        }
    }
 }