RP Lidar A2M8
Diff: rplidar.cpp
- Revision:
- 0:9803ade33ac3
diff -r 000000000000 -r 9803ade33ac3 rplidar.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/rplidar.cpp Tue Dec 14 15:01:18 2021 +0000 @@ -0,0 +1,216 @@ +/****************************************************************************/ +/* LIDAR RPLidar A2M8 module library */ +/****************************************************************************/ +/* LEnsE / Julien VILLEMEJANE / Institut d'Optique Graduate School */ +/****************************************************************************/ +/* Library - rplidar.cpp file */ +/****************************************************************************/ +/* Tested on Nucleo-L476RG / 4th nov 2021 */ +/****************************************************************************/ + +#include "mbed.h" +#include "rplidar.h" +#include <cstdio> + +#define BLINKING_RATE_MS 500 +#define NB_DATA_MAX 20 +#define AFF_DATA 0 +// Lidar +Serial lidar(PA_0, PA_1); +PwmOut lidar_ct(PB_9); + + +char pc_debug_data[128]; +char received_data[64]; +int data_nb = 0; +int data_scan_nb = 0; +char mode = LIDAR_MODE_STOP; +char scan_ok = 0; +int distance_scan[360] = {0}; +int distance_scan_old[360] = {0}; +char tour_ok = 0; +char trame_ok = 0; + +struct lidar_data ld_current; + + + +// Fonction d'initialisation du Lidar +void initLidar(void){ + lidar.baud(115200); + wait_ms(2000); + lidar_ct.period(1/25000.0); + lidar_ct.write(0.4); + wait_ms(2000); + debug_pc.printf("\r\nLIDAR Testing\r\n"); + lidar.attach(&IT_lidar); + wait_ms(500); + debug_pc.printf("\r\nLIDAR OK\r\n"); + + getHealthLidar(); + getInfoLidar(); + getSampleRate(); +} + +// Fonction de test du Lidar +void testLidar(){ + if(tour_ok == 6){ + int maxDistance, maxAngle; + tour_ok = 0; + findMax(distance_scan_old, 0, 360, &maxDistance, &maxAngle); + print_int("A", maxAngle); + } +} + +void print_int(const char *name, int ki){ + debug_pc.printf("\t %s = %d\r\n", name, ki); +} + +void print_data(const char *name, char *datai, int sizedata){ + debug_pc.printf("\t %s = ", name); + for(int i = 0; i < sizedata; i++){ + debug_pc.printf("%x ", datai[i]); + } + debug_pc.printf("\r\n"); +} + +void wait_s(float sec){ + wait_us(sec*1000000); +} + +void findMax(int *int_data, int angle_min, int angle_max, int *value, int *indice){ + *value = 0; + *indice = 0; + for(int k = angle_min; k < angle_max; k++){ + if(int_data[k] > *value){ + *value = int_data[k]; + *indice = k; + } + } +} + +void IT_lidar(void){ + char data, startt, nostartt; + data = lidar.getc(); + + if(scan_ok){ + switch(data_scan_nb % 5){ + case 0 : + if (((data&0X03)==0X01) || ((data&0X03)==0X02)) { + trame_ok=1; + } else { + trame_ok=0; + } + ld_current.quality = data >> 2; + startt = data & 0x01; + nostartt = (data & 0x02) >> 1; + if((data & 0x01) == 0x01){ + for(int k = 0; k < 360; k++){ + distance_scan_old[k] = distance_scan[k]; + distance_scan[k] = 0; + } + tour_ok++; + } + if(startt == nostartt) data_scan_nb = 0; + break; + case 1 : + if((data&0x01) == 0){ + trame_ok = 0; + data_scan_nb = 0; + } + // angle_q6[6:0] / 64 and check (degre) + ld_current.angle = data >> (1 + 6); + // check ? + break; + case 2 : + // angle_q6[14:7] / 64 (degre) + ld_current.angle += data << 1; + break; + case 3 : + // distance_q2[7:0] / 4 (mm) + ld_current.distance = data >> 2; + break; + default : + // distance_q2[15:8] / 4 (mm) + ld_current.distance += data << 6; + if(trame_ok){ + distance_scan[ld_current.angle%360] = ld_current.distance; + } + } + data_scan_nb++; + } + else{ + received_data[data_nb] = data; + data_nb++; + } +} + + +void sendResetReq(void){ + mode = LIDAR_MODE_RESET; + char data[2] = {0xA5, 0x40}; + lidar.putc(data[0]); + lidar.putc(data[1]); + wait_us(10000); +} + +void getHealthLidar(void){ + stopScan(); + mode = LIDAR_MODE_HEALTH; + char data[2] = {0xA5, LIDAR_MODE_HEALTH}; + lidar.putc(data[0]); + lidar.putc(data[1]); + data_nb = 0; + while(data_nb != (NB_BYTE_HEALTH_REQ + NB_BYTE_HEALTH_RESP)){__nop();} + //print_data("Health", received_data, (NB_BYTE_HEALTH_REQ + NB_BYTE_HEALTH_RESP)); + if(received_data[7] == 0) debug_pc.printf("\r\nGOOD\r\n"); + else debug_pc.printf("\r\nBAD\r\n"); + +} + +void getInfoLidar(void){ + stopScan(); + mode = LIDAR_MODE_INFO; + char data[2] = {0xA5, LIDAR_MODE_INFO}; + lidar.putc(data[0]); + lidar.putc(data[1]); + data_nb = 0; + while(data_nb != (NB_BYTE_INFO_REQ + NB_BYTE_INFO_RESP)){__nop();} + print_data("Info", received_data, (NB_BYTE_INFO_REQ + NB_BYTE_INFO_RESP)); +} + +void getSampleRate(void){ + stopScan(); + mode = LIDAR_MODE_RATE; + char data[2] = {0xA5, LIDAR_MODE_RATE}; + lidar.putc(data[0]); + lidar.putc(data[1]); + data_nb = 0; + while(data_nb != (NB_BYTE_RATE_REQ + NB_BYTE_RATE_RESP)){__nop();} + print_data("Rate", received_data, (NB_BYTE_RATE_REQ + NB_BYTE_RATE_RESP)); + int usRate = (received_data[8] << 8) + received_data[7]; + print_int("Standard (uS) ", usRate); + usRate = (received_data[10] << 8) + received_data[9]; + print_int("Express (uS) ", usRate); +} + +void startScan(void){ + stopScan(); + mode = LIDAR_MODE_SCAN; + char data[2] = {0xA5, LIDAR_MODE_SCAN}; + lidar.putc(data[0]); + lidar.putc(data[1]); + data_nb = 0; + data_scan_nb = 0; + while(data_nb != (NB_BYTE_SCAN_REQ)){__nop();} + debug_pc.printf("over"); + scan_ok = 1; +} + +void stopScan(void){ + mode = LIDAR_MODE_STOP; + scan_ok = 0; + char data[2] = {0xA5, LIDAR_MODE_STOP}; + lidar.putc(data[0]); + lidar.putc(data[1]); +} \ No newline at end of file