basic_framework/application/gimbal/gimbal.c

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#include "gimbal.h"
#include "robot_def.h"
#include "dji_motor.h"
#include "ECmotor/ECA8210.h"
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#include "ins_task.h"
#include "message_center.h"
#include "general_def.h"
#include "bmi088.h"
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#include "vofa.h"
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static attitude_t *gimba_IMU_data; // 云台IMU数据
static DJIMotorInstance *yaw_motor, *pitch_motor;
static ECMotorInstance *big_yaw_motor;
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static Publisher_t *gimbal_pub; // 云台应用消息发布者(云台反馈给cmd)
static Subscriber_t *gimbal_sub; // cmd控制消息订阅者
static Gimbal_Upload_Data_s gimbal_feedback_data; // 回传给cmd的云台状态信息
static Gimbal_Ctrl_Cmd_s gimbal_cmd_recv; // 来自cmd的控制信息
sin_input_generate_t sinInputGenerate;
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void GimbalInit()
{
gimba_IMU_data = INS_Init(); // IMU先初始化,获取姿态数据指针赋给yaw电机的其他数据来源
// YAW
Motor_Init_Config_s yaw_config = {
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.can_init_config = {
.can_handle = &hcan1,
.tx_id = 1,
},
.controller_param_init_config = {
.angle_PID = {
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.Kp = 0.5, // 8
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.Ki = 0,
.Kd = 0,
.DeadBand = 0.1,
.Improve = PID_Trapezoid_Intergral | PID_Integral_Limit | PID_Derivative_On_Measurement,
.IntegralLimit = 100,
.MaxOut = 500,
},
.speed_PID = {
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.Kp = 12000, // 50
.Ki = 3000, // 200
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.Kd = 0,
.Improve = PID_Trapezoid_Intergral | PID_Integral_Limit | PID_Derivative_On_Measurement,
.IntegralLimit = 3000,
.MaxOut = 20000,
},
.other_angle_feedback_ptr = &gimba_IMU_data->YawTotalAngle,
// 还需要增加角速度额外反馈指针,注意方向,ins_task.md中有c板的bodyframe坐标系说明
.other_speed_feedback_ptr = &gimba_IMU_data->Gyro[2],
},
.controller_setting_init_config = {
.angle_feedback_source = OTHER_FEED,
.speed_feedback_source = OTHER_FEED,
.outer_loop_type = ANGLE_LOOP,
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.close_loop_type = SPEED_LOOP | ANGLE_LOOP,
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.motor_reverse_flag = MOTOR_DIRECTION_NORMAL,
},
.motor_type = GM6020,
.motor_control_type = CURRENT_CONTROL};
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// PITCH
Motor_Init_Config_s pitch_config = {
.can_init_config = {
.can_handle = &hcan2,
.tx_id = 2,
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},
.controller_param_init_config = {
// .angle_PID = {
// .Kp = 10, // 10
// .Ki = 0,
// .Kd = 0,
// .Improve = PID_Trapezoid_Intergral | PID_Integral_Limit | PID_Derivative_On_Measurement,
// .IntegralLimit = 100,
// .MaxOut = 500,
// },
.speed_PID = {
.Kp = 5.13, // 50
.Ki = 88.26, // 350
.Kd = 0, // 0
.Improve = PID_Trapezoid_Intergral | PID_Integral_Limit | PID_Derivative_On_Measurement,
.IntegralLimit = 2500,
.MaxOut = 30000,
},
// .other_angle_feedback_ptr = &gimba_IMU_data->Pitch,
// // 还需要增加角速度额外反馈指针,注意方向,ins_task.md中有c板的bodyframe坐标系说明
// .other_speed_feedback_ptr = (&gimba_IMU_data->Gyro[0]),
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},
.controller_setting_init_config = {
.outer_loop_type = SPEED_LOOP,
.close_loop_type = SPEED_LOOP|CURRENT_LOOP,
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.motor_reverse_flag = MOTOR_DIRECTION_NORMAL,
},
.motor_type = GM6020,
.motor_control_type = CURRENT_CONTROL
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};
Motor_Init_Config_s big_yaw_config = {
.can_init_config = {
.can_handle = &hcan1,
.tx_id = 1,
},
.controller_setting_init_config = {
.outer_loop_type = OPEN_LOOP,
.close_loop_type = OPEN_LOOP,
.motor_reverse_flag = MOTOR_DIRECTION_NORMAL,
},
.motor_type = ECA8210
};
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// 电机对total_angle闭环,上电时为零,会保持静止,收到遥控器数据再动
// yaw_motor = DJIMotorInit(&yaw_config);
// pitch_motor = DJIMotorInit(&pitch_config);
big_yaw_motor = ECMotorInit(&big_yaw_config);
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gimbal_pub = PubRegister("gimbal_feed", sizeof(Gimbal_Upload_Data_s));
gimbal_sub = SubRegister("gimbal_cmd", sizeof(Gimbal_Ctrl_Cmd_s));
sin_input_frequency_init(&sinInputGenerate);
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}
/* 机器人云台控制核心任务,后续考虑只保留IMU控制,不再需要电机的反馈 */
void GimbalTask()
{
// 获取云台控制数据
// 后续增加未收到数据的处理
SubGetMessage(gimbal_sub, &gimbal_cmd_recv);
// @todo:现在已不再需要电机反馈,实际上可以始终使用IMU的姿态数据来作为云台的反馈,yaw电机的offset只是用来跟随底盘
// 根据控制模式进行电机反馈切换和过渡,视觉模式在robot_cmd模块就已经设置好,gimbal只看yaw_ref和pitch_ref
// switch (gimbal_cmd_recv.gimbal_mode)
// {
// // 停止
// case GIMBAL_ZERO_FORCE:
// DJIMotorStop(yaw_motor);
// DJIMotorStop(pitch_motor);
// break;
// // 使用陀螺仪的反馈,底盘根据yaw电机的offset跟随云台或视觉模式采用
// case GIMBAL_GYRO_MODE: // 后续只保留此模式
// DJIMotorEnable(yaw_motor);
// DJIMotorEnable(pitch_motor);
// DJIMotorChangeFeed(yaw_motor, ANGLE_LOOP, OTHER_FEED);
// DJIMotorChangeFeed(yaw_motor, SPEED_LOOP, OTHER_FEED);
// DJIMotorChangeFeed(pitch_motor, ANGLE_LOOP, OTHER_FEED);
// DJIMotorChangeFeed(pitch_motor, SPEED_LOOP, OTHER_FEED);
// DJIMotorSetRef(yaw_motor, gimbal_cmd_recv.yaw); // yaw和pitch会在robot_cmd中处理好多圈和单圈
//// DJIMotorSetRef(pitch_motor, gimbal_cmd_recv.pitch);
// break;
// // 云台自由模式,使用编码器反馈,底盘和云台分离,仅云台旋转,一般用于调整云台姿态(英雄吊射等)/能量机关
// case GIMBAL_FREE_MODE: // 后续删除,或加入云台追地盘的跟随模式(响应速度更快)
// DJIMotorEnable(yaw_motor);
// DJIMotorEnable(pitch_motor);
// DJIMotorChangeFeed(yaw_motor, ANGLE_LOOP, OTHER_FEED);
// DJIMotorChangeFeed(yaw_motor, SPEED_LOOP, OTHER_FEED);
// DJIMotorChangeFeed(pitch_motor, ANGLE_LOOP, OTHER_FEED);
// DJIMotorChangeFeed(pitch_motor, SPEED_LOOP, OTHER_FEED);
// DJIMotorSetRef(yaw_motor, gimbal_cmd_recv.yaw); // yaw和pitch会在robot_cmd中处理好多圈和单圈
//// DJIMotorSetRef(pitch_motor, gimbal_cmd_recv.pitch);
// break;
// default:
// break;
// }
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// 在合适的地方添加pitch重力补偿前馈力矩
// 根据IMU姿态/pitch电机角度反馈计算出当前配重下的重力矩
// ...
//DJIMotorEnable(pitch_motor);
ECMotorEnable(big_yaw_motor);
float input = step_input_generate(&sinInputGenerate);
//DJIMotorSetRef(pitch_motor,input);
ECMotorSetRef(big_yaw_motor,30);
//ANODT_SendF1(input*1000,pitch_motor->measure.speed_aps*1000,0,0);
float theta = pitch_motor->measure.angle_single_round - 6200 * ECD_ANGLE_COEF_DJI;
float gravity_feed = 3800*arm_cos_f32(theta/180*PI);
//DJIMotorSetRef(pitch_motor,gravity_feed);
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float vofa_send_data[4];
vofa_send_data[0]=big_yaw_motor->measure.speed_rads;
vofa_send_data[1]=big_yaw_motor->measure.angle_single_round;
vofa_send_data[2]=big_yaw_motor->measure.real_current;
vofa_send_data[3]=big_yaw_motor->measure.temperature;
// vofa_send_data[3]=yaw_motor->motor_controller.angle_PID.Measure;
vofa_justfloat_output(vofa_send_data,16,&huart1);
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vofa_send_data[0] = pitch_motor->motor_controller.pid_ref;
vofa_send_data[1] = pitch_motor->measure.real_current;
vofa_send_data[2] = theta;
vofa_send_data[3] = gravity_feed;
vofa_justfloat_output(vofa_send_data,16,&huart1);
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// 设置反馈数据,主要是imu和yaw的ecd
gimbal_feedback_data.gimbal_imu_data = *gimba_IMU_data;
gimbal_feedback_data.yaw_motor_single_round_angle = yaw_motor->measure.angle_single_round;
// 推送消息
PubPushMessage(gimbal_pub, (void *)&gimbal_feedback_data);
}
//void sin_input_generate(float frequency, int count)
//{
// static uint32_t cnt;
// static float time;
// while(time>=count*(1/frequency))
// {
// float deltaT=DWT_GetDeltaT(&cnt);
// time += deltaT;
//
// float input = arm_sin_f32(2*PI*frequency*time);
// DJIMotorSetRef(yaw_motor,input);
// }
//}
void sin_input_frequency_init(sin_input_generate_t* InputGenerate)
{
for(int i=0;i<43;i++)
{
InputGenerate->frequency[i] = 1.0 + 0.5*i;
}
for(int i=0;i<9;i++)
{
InputGenerate->frequency[i+43] = 24.0 + 2.0*i;
}
for(int i=0;i<8;i++)
{
InputGenerate->frequency[i+43+9] = 50 + 10*i;
}
InputGenerate->frequency[60] = 200;
InputGenerate->frequency[61] = 250;
InputGenerate->frequency[62] = 333;
InputGenerate->frequency[63] = 500;
}
float sin_input_generate(sin_input_generate_t* InputGenerate)
{
InputGenerate->DeltaT = DWT_GetDeltaT(&InputGenerate->cnt);
InputGenerate->time += InputGenerate->DeltaT;
if(InputGenerate->time >= 20*(1/InputGenerate->frequency[InputGenerate->frequency_index]))
{
InputGenerate->time = 0;
InputGenerate->frequency_index += 1;
}
if(InputGenerate->frequency_index >= 64)
{
InputGenerate->input = 0;
}
else
InputGenerate->input = arm_sin_f32(2*PI*InputGenerate->frequency[InputGenerate->frequency_index]*InputGenerate->time);
//float input = arm_sin_f32(2*PI*frequency*time);
return InputGenerate->input;
}
float step_input_generate(sin_input_generate_t* InputGenerate)
{
static int8_t forward_flag = 1;
InputGenerate->DeltaT = DWT_GetDeltaT(&InputGenerate->cnt);
InputGenerate->time += InputGenerate->DeltaT;
if(InputGenerate->time >= 3)
{
if(forward_flag ==1) forward_flag = -1;
else if (forward_flag == -1) forward_flag = 1;
InputGenerate->time = 0;
}
return 60*forward_flag;
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}