RobotHardware-UESTC/Hardware/银星机器人底盘/PiRobot-YH_Firmware v1.0/STM32/User/robot.cpp

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2024-01-20 13:19:09 +08:00
#include "robot.h"
#include "board.h"
#include "usart_transport.h"
#include "simple_dataframe_slave.h"
#include "data_holder.h"
#include "usart.h"
#if MOTOR_CONTROLLER == COMMON_CONTROLLER
#include "common_motor_controller.h"
#define MAX_PWM_VALUE 5000
#elif MOTOR_CONTROLLER == AF_SHIELD_CONTROLLER
#include "afs_motor_controller.h"
#define MAX_PWM_VALUE 255
#endif
#include "encoder_implement.h"
#include "pid.h"
#include "board_stm32.h"
#if IMU_ENABLE
#include "GY65.h"
#include "GY85.h"
#include "GY87.h"
#endif
#if JOYSTICK_ENABLE
#include "joystick.h"
#endif
#include "print.h"
#define min(a,b) ((a)<(b)?(a):(b))
#define max(a,b) ((a)>(b)?(a):(b))
Robot::Robot()
{
for (int i=0;i<MOTOR_COUNT;i++) {
motor[i] = NULL;
encoder[i] = NULL;
pid[i] = NULL;
input[i] = 0.0f;
feedback[i] = 0.0f;
}
trans = NULL;
frame = NULL;
model = NULL;
do_kinmatics_flag = false;
last_velocity_command_time = 0;
do_set_pwm_flag = false;
#if IMU_ENABLE
imu = NULL;
#endif
#if JOYSTICK_ENABLE
joystick = NULL;
#endif
}
void Robot::init()
{
// board初始化
Board::get()->init();
#if DEBUG_ENABLE
// 调试串口初始化
Board::get()->usart_debug_init();
#endif
// 加载参数, 该参数一般存储在flash或者eeprom
Data_holder::get()->load_parameter();
PB_USART_printf(USART1, (uint8_t *)"Init\n");
pb_printf("RobotParameters: %d %d %d %d %d %d %d %d %d %d %d %d %d",
Data_holder::get()->parameter.params.wheel_diameter, Data_holder::get()->parameter.params.wheel_track, Data_holder::get()->parameter.params.encoder_resolution, Data_holder::get()->parameter.params.motor_ratio,
Data_holder::get()->parameter.params.do_pid_interval, Data_holder::get()->parameter.params.kp, Data_holder::get()->parameter.params.ki, Data_holder::get()->parameter.params.kd, Data_holder::get()->parameter.params.ko,
Data_holder::get()->parameter.params.cmd_last_time, Data_holder::get()->parameter.params.max_v_liner_x, Data_holder::get()->parameter.params.max_v_liner_y, Data_holder::get()->parameter.params.max_v_angular_z);
#if IMU_ENABLE
// imu 初始化
init_imu();
#endif
pb_printf("init_motor");
// 电机相关初始化
init_motor();
pb_printf("init_trans");
// 通讯相关初始化
init_trans();
// joystick初始化
init_joystick();
pb_printf("pibot startup");
}
void Robot::init_imu()
{
#if IMU_ENABLE
if (Data_holder::get()->parameter.params.imu_type == IMU_TYPE_GY65) {
pb_printf("imu gy65");
static GY65 gy65;
imu = &gy65;
} else if (Data_holder::get()->parameter.params.imu_type == IMU_TYPE_GY85) {
pb_printf("imu gy85");
static GY85 gy85;
imu = &gy85;
} else if (Data_holder::get()->parameter.params.imu_type == IMU_TYPE_GY87) {
pb_printf("imu gy87");
static GY87 gy87;
imu = &gy87;
} else {
pb_printf("imu default null driver");
imu = NULL;
}
if (imu != NULL) {
imu->init();
}
#endif
}
void Robot::init_joystick()
{
#if JOYSTICK_ENABLE
static Joystick joy;
joystick = &joy;
if (joystick)
joystick->init();
#endif
}
void Robot::init_motor()
{
//MOTOR_COUNT为电机数量 该宏定义在相应的机器人模型文件中, KinematicModels/differential.h
#if MOTOR_COUNT>0 //电机1
// MOTOR_CONTROLLER在params.mk中定义 表示电机控制器类型
// 当前使用的COMMON_CONTROLLER为2个io控制方向一个PWD控制速度类型的控制器
#if MOTOR_CONTROLLER == COMMON_CONTROLLER
static CommonMotorController motor1(MOTOR_1, MAX_PWM_VALUE, (Data_holder::get()->parameter.params.motor_nonexchange_flag & MOTOR_ENCODER_1_FLAG)==0); // MOTOR1_REVERS标识电机方向反向,等同于电机线交换
#elif MOTOR_CONTROLLER == AF_SHIELD_CONTROLLER
static AFSMotorController motor1(MOTOR_1_PORT_NUM, MAX_PWM_VALUE);
#endif
// 定义使用的编码器 传入参数为编码器的AB GPIO引脚 定义在params.mk中
static EncoderImp encoder1(MOTOR_1, (Data_holder::get()->parameter.params.encoder_nonexchange_flag & MOTOR_ENCODER_1_FLAG)==0);
// 定义PID控制对象 传入参数为输入和输出的地址及kp ki kd 这里ko为比例
static PID pid1(&input[0], &feedback[0], float(Data_holder::get()->parameter.params.kp)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.ki)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.kd)/Data_holder::get()->parameter.params.ko , MAX_PWM_VALUE);
#endif
#if MOTOR_COUNT>1 //电机2
#if MOTOR_CONTROLLER == COMMON_CONTROLLER
static CommonMotorController motor2(MOTOR_2, MAX_PWM_VALUE, (Data_holder::get()->parameter.params.motor_nonexchange_flag & MOTOR_ENCODER_2_FLAG)==0); // MOTOR1_REVERS标识电机方向反向,等同于电机线交换
#elif MOTOR_CONTROLLER == AF_SHIELD_CONTROLLER
static AFSMotorController motor2(MOTOR_2_PORT_NUM, MAX_PWM_VALUE);
#endif
static EncoderImp encoder2(MOTOR_2, (Data_holder::get()->parameter.params.encoder_nonexchange_flag & MOTOR_ENCODER_2_FLAG)==0);
static PID pid2(&input[1], &feedback[1], float(Data_holder::get()->parameter.params.kp)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.ki)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.kd)/Data_holder::get()->parameter.params.ko , MAX_PWM_VALUE);
#endif
#if MOTOR_COUNT>2 //电机3
#if MOTOR_CONTROLLER == COMMON_CONTROLLER
static CommonMotorController motor3(MOTOR_3, MAX_PWM_VALUE, (Data_holder::get()->parameter.params.motor_nonexchange_flag & MOTOR_ENCODER_3_FLAG)==0); // MOTOR1_REVERS标识电机方向反向,等同于电机线交换
#elif MOTOR_CONTROLLER == AF_SHIELD_CONTROLLER
static AFSMotorController motor3(MOTOR_3);
#endif
static EncoderImp encoder3(MOTOR_3, (Data_holder::get()->parameter.params.encoder_nonexchange_flag & MOTOR_ENCODER_3_FLAG)==0);
static PID pid3(&input[2], &feedback[2], float(Data_holder::get()->parameter.params.kp)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.ki)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.kd)/Data_holder::get()->parameter.params.ko , MAX_PWM_VALUE);
#endif
// 分别把地址保存在统一的数组内, 方便处理
#if MOTOR_COUNT>0
motor[0] = &motor1;
encoder[0] = &encoder1;
pid[0] = &pid1;
#endif
#if MOTOR_COUNT>1
motor[1] = &motor2;
encoder[1] = &encoder2;
pid[1] = &pid2;
#endif
#if MOTOR_COUNT>2
motor[2] = &motor3;
encoder[2] = &encoder3;
pid[2] = &pid3;
#endif
// 根据定义的模型参数ROBOT_MODEL 创建模型对象及保存地址
#if ROBOT_MODEL == MODEL_TYPE_2WD_DIFF //2轮差分
static Differential diff(Data_holder::get()->parameter.params.wheel_diameter*0.0005, Data_holder::get()->parameter.params.wheel_track*0.0005);
model = &diff;
#endif
#if ROBOT_MODEL == MODEL_TYPE_3WD_OMNI //三轮全向
static Omni3 omni3(Data_holder::get()->parameter.params.wheel_diameter*0.0005, Data_holder::get()->parameter.params.wheel_track*0.0005);
model = &omni3;
#endif
// 分别初始化各个控制器
for (int i=0;i<MOTOR_COUNT;i++) {
encoder[i]->init();
motor[i]->init();
}
// 初始化各个变量
do_kinmatics_flag = false;
memset(&odom, 0 , sizeof(odom));
memset(&input, 0 , sizeof(input));
memset(&feedback, 0 , sizeof(feedback));
last_velocity_command_time = 0;
}
void Robot::init_trans()
{
//定义一个串口通讯对象 注意这里USART_transport继承实现Transport接口
// 实现了一个通讯对象这么做的原因是如果我换为其他通讯方式例如USB只需要创建一个USB_Transport继承实现实现Transport接口就可以实现
static USART_transport _trans(MASTER_USART, 115200);
// 定义一个通讯协议处理对象, 同上, 我们需要更换协议只需要继承实现Dataframe的接口就可以实现
static Simple_dataframe _frame(&_trans);
// 保存对象指针
trans = &_trans;
frame = &_frame;
// 初始化
trans->init();
frame->init();
// 注册消息处理对象 这里把各个消息id的处理注册了一个观察者 即再收到相应的消息后会回调update函数
// Robot(this)继承实现了notify
frame->register_notify(ID_SET_ROBOT_PARAMTER, this);
frame->register_notify(ID_CLEAR_ODOM, this);
frame->register_notify(ID_SET_VELOCITY, this);
frame->register_notify(ID_GET_ENCODER_COUNT, this);
frame->register_notify(ID_SET_MOTOR_PWM, this);
}
void Robot::check_command()
{
static unsigned long lastMillis = 0;
if (Board::get()->getTickCount() - lastMillis >= 50){
lastMillis = Board::get()->getTickCount();
Board::get()->setDOState(_RUN_LED, 2);
}
unsigned char ch = 0;
// 从通讯设备(trans)读取数据交给协议处理模块(frame)处理
if (trans->read(ch)) {
if (frame->dataRecv(ch)) {
// 这里检测到正确的一帧命令,做解析
frame->dataParse();
}
}
}
// 实现Notify接口 上面注册的命令id接收到时候会回调执行响应的动作
void Robot::update(const MESSAGE_ID id, void* data)
{
switch (id) {
case ID_SET_ROBOT_PARAMTER: //设置参数的回调, 这里会更新pid的参数 model的参数 最终保存到flash
pb_printf("RobotParameters: %d %d %d %d %d %d %d %d %d %d %d %d %d",
Data_holder::get()->parameter.params.wheel_diameter, Data_holder::get()->parameter.params.wheel_track, Data_holder::get()->parameter.params.encoder_resolution, Data_holder::get()->parameter.params.motor_ratio,
Data_holder::get()->parameter.params.do_pid_interval, Data_holder::get()->parameter.params.kp, Data_holder::get()->parameter.params.ki, Data_holder::get()->parameter.params.kd, Data_holder::get()->parameter.params.ko,
Data_holder::get()->parameter.params.cmd_last_time, Data_holder::get()->parameter.params.max_v_liner_x, Data_holder::get()->parameter.params.max_v_liner_y, Data_holder::get()->parameter.params.max_v_angular_z);
// 更新pid参数 这样可以保证设置参数实时生效
for (int i=0;i<MOTOR_COUNT;i++) {
pid[i]->update(float(Data_holder::get()->parameter.params.kp)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.ki)/Data_holder::get()->parameter.params.ko,
float(Data_holder::get()->parameter.params.kd)/Data_holder::get()->parameter.params.ko , MAX_PWM_VALUE);
}
// 更新模型参数, 这样可以保证设置参数实时生效
model->set(Data_holder::get()->parameter.params.wheel_diameter*0.0005, Data_holder::get()->parameter.params.wheel_track*0.0005);
// 保存参数到flash
Data_holder::get()->save_parameter();
break;
case ID_CLEAR_ODOM: // 清除里程计信息
clear_odom();
break;
case ID_SET_VELOCITY: // 设置机器人的速度
update_velocity(); //更新机器人的期望速度
break;
case ID_GET_ENCODER_COUNT:
update_encoder_count(); // 更新encoder count
break;
case ID_SET_MOTOR_PWM:
update_pwm_value(); // 设置pwm值
break;
default:
break;
}
}
// 清除里程计数据及相关变量
void Robot::clear_odom()
{
for (int i=0;i<MOTOR_COUNT;i++) {
encoder[i]->clear();
}
memset(&odom, 0, sizeof(odom));
memset(&Data_holder::get()->odom, 0, sizeof(Data_holder::get()->odom));
}
#define __PI 3.1415926535897932384626433832795
//根据下发的速度更新期望速度, 并转为pid时间间隔内的期望编码器的变化值
void Robot::update_velocity()
{
// 下发速度检测 保证限制在设置的最大最小值内
short vx = min(max(Data_holder::get()->velocity.v_liner_x, -(short(Data_holder::get()->parameter.params.max_v_liner_x))), short(Data_holder::get()->parameter.params.max_v_liner_x));
short vy = min(max(Data_holder::get()->velocity.v_liner_y, -(short(Data_holder::get()->parameter.params.max_v_liner_y))), short(Data_holder::get()->parameter.params.max_v_liner_y));
short vz = min(max(Data_holder::get()->velocity.v_angular_z, -(short(Data_holder::get()->parameter.params.max_v_angular_z))), short(Data_holder::get()->parameter.params.max_v_angular_z));
float vel[3]={vx/100.0, vy/100.0, vz/100.0}; // 保存速度转换单位 传入的速度值为cm/s 0.01rad/s 转为m/s 和rad/s
float motor_speed[MOTOR_COUNT]={0};
model->motion_solver(vel, motor_speed); // 期望的机器人的速度转换为各个电机的速度(通过设置的机器人模型接口)
// 把得到的期望电机速度 (m/s)转换为期望pid时间间隔内编码器反馈的输入
// 该值即为PID的输入
for(int i=0;i<MOTOR_COUNT;i++) {
input[i] = motor_speed[i]*short(Data_holder::get()->parameter.params.encoder_resolution)*short(Data_holder::get()->parameter.params.motor_ratio)/(2*__PI)*short(Data_holder::get()->parameter.params.do_pid_interval)*0.001;
}
//pb_printf("vx=%d %d motor_speed=%ld %ld", vx, vz, long(motor_speed[0]*1000), long(motor_speed[1]*1000));
//保存时间戳
last_velocity_command_time = Board::get()->getTickCount();
// 更新变量, 激活pid运算和控制电机
do_kinmatics_flag = true;
}
void Robot::update_encoder_count()
{
for (int i=0; i<MOTOR_COUNT; i++) {
Data_holder::get()->encoder_count[i] = encoder[i]->get_total_count();//输出累计编码器值 用于调试
}
}
void Robot::update_pwm_value()
{
do_set_pwm_flag = true;
}
// pid运算 控制电机
void Robot::do_kinmatics()
{
if (do_set_pwm_flag) {
do_set_pwm_flag = false;
for (int i=0; i<MOTOR_COUNT; i++) {
motor[i]->control(Data_holder::get()->pwm.value[i]);
}
}
if (!do_kinmatics_flag) { // 停止后
for(int i=0;i<MOTOR_COUNT;i++) {
pid[i]->clear(); // 清除pid
encoder[i]->get_increment_count_for_dopid();// 实时更新用于pid的encoder值
}
return; //do_kinmatics_flag false表示电机停止 不需要做pid 故返回
}
static unsigned long last_millis=0;
// 判断时间间隔做pid运算
if (Board::get()->getTickCount()-last_millis>=Data_holder::get()->parameter.params.do_pid_interval) {
last_millis = Board::get()->getTickCount();
//得到编码器的反馈差值, 即在do_pid_interval这段间隔时间内编码器的差值 该值作为pid的反馈
for (int i=0;i<MOTOR_COUNT;i++) {
feedback[i] = encoder[i]->get_increment_count_for_dopid();
}
#if PID_DEBUG_OUTPUT
#if MOTOR_COUNT==2
pb_printf("input=%ld %ld feedback=%ld %ld", long(input[0]*1000), long(input[1]*1000),
long(feedback[0]), long(feedback[1]));
#endif
#if MOTOR_COUNT==3
pb_printf("input=%ld %ld %ld feedback=%ld %ld %ld", long(input[0]*1000), long(input[1]*1000), long(input[2]*1000),
long(feedback[0]), long(feedback[1]), long(feedback[2]));
#endif
#if MOTOR_COUNT==4
pb_printf("input=%ld %ld %ld %ld feedback=%ld %ld %ld %ld", long(input[0]*1000), long(input[1]*1000), long(input[2]*1000), long(input[3]*1000),
long(feedback[0]), long(feedback[1]), long(feedback[2]), long(feedback[3]));
#endif
#endif
bool stoped=true;
//当期望和反馈都为0 置位stoped标志
for (int i=0;i<MOTOR_COUNT;i++) {
if (input[i] != 0 || feedback[i] != 0) {
stoped = false;
break;
}
}
short output[MOTOR_COUNT]={0};
if (stoped) {
do_kinmatics_flag = false;
} else {
// 没有需要停止则做pid运算得到out值该值作为电机模块控制器输入
for(int i=0;i<MOTOR_COUNT;i++) {
output[i] = pid[i]->compute(Data_holder::get()->parameter.params.do_pid_interval*0.001);
}
}
//当次计算完成 重置变量
for (int i=0;i<MOTOR_COUNT;i++) {
Data_holder::get()->pid_data.input[i] = int(input[i]);
Data_holder::get()->pid_data.output[i] = int(feedback[i]);
}
#if PID_DEBUG_OUTPUT
#if MOTOR_COUNT==2
pb_printf("output=%ld %ld", output[0], output[1]);
#endif
#if MOTOR_COUNT==3
pb_printf("output=%ld %ld %ld", output[0], output[1], output[2]);
#endif
#if MOTOR_COUNT==4
pb_printf("output=%ld %ld %ld %ld", output[0], output[1], output[2], output[3]);
#endif
#endif
long elapsed_ms = Board::get()->getTickCount()-last_velocity_command_time;
//判断上次下发的时间戳如果超时把各个电机期望的输入置零pid下次会根据改期望计算pid输出转速慢慢停止点击
if (elapsed_ms > Data_holder::get()->parameter.params.cmd_last_time) {
memset(input, 0, sizeof(input));
if (elapsed_ms > Data_holder::get()->parameter.params.cmd_last_time*2) {
memset(output, 0, sizeof(output));
}
}
// 把pid得到的值交给电机控制器该值有符号表示正反转
for (int i=0;i<MOTOR_COUNT;i++) {
motor[i]->control(output[i]);
}
}
}
//计算里程计
void Robot::calc_odom()
{
static unsigned long last_millis=0;
//根据实际间隔计算轮子里程
if (Board::get()->getTickCount()-last_millis>=CALC_ODOM_INTERVAL) {
last_millis = Board::get()->getTickCount();
#if ODOM_DEBUG_OUTPUT
long total_count[MOTOR_COUNT]={0};
for (int i=0;i<MOTOR_COUNT;i++) {
total_count[i] = encoder[i]->get_total_count(); //输出累计编码器值 用于调试
}
#if MOTOR_COUNT==2
pb_printf("total_count=[%ld %ld]", total_count[0], total_count[1]);
#endif
#if MOTOR_COUNT==3
pb_printf("total_count=[%ld %ld %ld]", total_count[0], total_count[1], total_count[2]);
#endif
#if MOTOR_COUNT==4
pb_printf("total_count=[%ld %ld %ld %ld]", total_count[0], total_count[1], total_count[2], total_count[3]);
#endif
#endif
float dis[MOTOR_COUNT] = {0};
for (int i=0;i<MOTOR_COUNT;i++) {
//根据CALC_ODOM_INTERVAL的间隔内的各个电机的编码器变化值转换各个电机实际的里程
dis[i] = encoder[i]->get_increment_count_for_odom()*__PI*Data_holder::get()->parameter.params.wheel_diameter*0.001/Data_holder::get()->parameter.params.encoder_resolution/Data_holder::get()->parameter.params.motor_ratio;
#if ODOM_DEBUG_OUTPUT
pb_printf(" %ld ", long(dis[i]*1000000));
#endif
}
// long total_count[MOTOR_COUNT]={0};
// for (int i=0;i<MOTOR_COUNT;i++) {
// total_count[i] = encoder[i]->get_total_count(); //输出累计编码器值 用于调试
// }
// 把计算得到的各个电机的里程转为为机器人里程(通过机器人运动模型对象)
model->get_odom(&odom, dis, CALC_ODOM_INTERVAL);
#if ODOM_DEBUG_OUTPUT
// 输出机器人的里程
pb_printf(" x=%ld y=%ld yaw=%ld", long(odom.x*1000), long(odom.y*1000), long(odom.z*1000));//mm
pb_printf("");
#endif
// 转换单位保存到Data_holder
Data_holder::get()->odom.v_liner_x = odom.vel_x*100; //转为cm/s
Data_holder::get()->odom.v_liner_y = odom.vel_y*100;
Data_holder::get()->odom.v_angular_z = odom.vel_z*100;
Data_holder::get()->odom.x = odom.x*100; //转为cm
Data_holder::get()->odom.y = odom.y*100;
Data_holder::get()->odom.yaw = long(odom.z*100)%628;//转为0.01rad 628为2pi*100
}
}
//获取imu数据
void Robot::get_imu_data()
{
#if IMU_ENABLE
if (imu == NULL) {
return;
}
static unsigned long last_millis=0;
//按照设置的时间间隔获取imu数据
if (Board::get()->get_tick_count()-last_millis>=CALC_IMU_INTERVAL) {
last_millis = Board::get()->get_tick_count();
imu->get_data(Data_holder::get()->imu_data);
}
#endif
}
//检测joystick
void Robot::check_joystick()
{
#if JOYSTICK_ENABLE
if (joystick == NULL) {
return;
}
static unsigned long last_millis=0;
short liner_x=0, liner_y=0, angular_z=0;
if (Board::get()->get_tick_count()-last_millis>=CHECK_JOYSTICK_INTERVAL){
last_millis = Board::get()->get_tick_count();
// 按照设置的间隔间隔 更新期望速度
if (joystick->check(liner_x, liner_y, angular_z)) {
Data_holder::get()->velocity.v_liner_x = liner_x;
Data_holder::get()->velocity.v_liner_y = liner_y;
Data_holder::get()->velocity.v_angular_z = angular_z;
update_velocity();
}
joystick->test();
}
#endif
}