重力补偿、功率限制
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ef5c502f81
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@ -84,6 +84,7 @@ void ChassisInit() {
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.speed_feedback_source = MOTOR_FEED,
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.speed_feedback_source = MOTOR_FEED,
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.outer_loop_type = SPEED_LOOP,
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.outer_loop_type = SPEED_LOOP,
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.close_loop_type = SPEED_LOOP, //| CURRENT_LOOP,
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.close_loop_type = SPEED_LOOP, //| CURRENT_LOOP,
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.power_limit_flag = POWER_LIMIT_ON,
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},
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},
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.motor_type = M3508,
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.motor_type = M3508,
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};
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};
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@ -114,6 +115,8 @@ void ChassisInit() {
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}};
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}};
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cap = SuperCapInit(&cap_conf); // 超级电容初始化
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cap = SuperCapInit(&cap_conf); // 超级电容初始化
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// PowerMeter_Init_Config_s
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// 发布订阅初始化,如果为双板,则需要can comm来传递消息
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// 发布订阅初始化,如果为双板,则需要can comm来传递消息
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#ifdef CHASSIS_BOARD
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#ifdef CHASSIS_BOARD
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Chassis_IMU_data = INS_Init(); // 底盘IMU初始化
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Chassis_IMU_data = INS_Init(); // 底盘IMU初始化
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@ -165,20 +168,47 @@ static void OmniCalculate() {
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vt_lf /= (WHEEL_BASE * 1.414f);
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vt_lf /= (WHEEL_BASE * 1.414f);
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}
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}
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static const float motor_power_K[3] = {1.6301e-6f,5.7501e-7f,2.5863e-7f};
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///依据3508电机功率模型,预测电机输出功率
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static float EstimatePower(DJIMotorInstance* chassis_motor)
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{
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float I_cmd = chassis_motor->motor_controller.current_PID.Output;
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float w = chassis_motor->measure.speed_aps /6 ;//aps to rpm
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float power = motor_power_K[0] * I_cmd * w + motor_power_K[1]*w*w + motor_power_K[2]*I_cmd*I_cmd;
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return power;
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}
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float vofa_send_data[6];
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/**
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/**
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* @brief 根据裁判系统和电容剩余容量对输出进行限制并设置电机参考值
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* @brief 根据裁判系统和电容剩余容量对输出进行限制并设置电机参考值
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*
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*
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*/
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*/
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static void LimitChassisOutput() {
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static void LimitChassisOutput()
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// 功率限制待添加
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{
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// referee_data->PowerHeatData.chassis_power;
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float P_cmd = motor_rf->motor_controller.motor_power_predict +
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// referee_data->PowerHeatData.chassis_power_buffer;
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motor_rb->motor_controller.motor_power_predict +
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motor_lb->motor_controller.motor_power_predict +
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motor_lf->motor_controller.motor_power_predict + 3.6f;
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float P_max = 60 - 10;
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float K = P_max/P_cmd;
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vofa_send_data[2] = P_cmd;
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// 完成功率限制后进行电机参考输入设定
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motor_rf->motor_controller.motor_power_scale = K;
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motor_rb->motor_controller.motor_power_scale = K;
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motor_lf->motor_controller.motor_power_scale = K;
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motor_lb->motor_controller.motor_power_scale = K;
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{
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DJIMotorSetRef(motor_lf, vt_lf);
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DJIMotorSetRef(motor_lf, vt_lf);
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DJIMotorSetRef(motor_rf, vt_rf);
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DJIMotorSetRef(motor_rf, vt_rf);
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DJIMotorSetRef(motor_lb, vt_lb);
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DJIMotorSetRef(motor_lb, vt_lb);
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DJIMotorSetRef(motor_rb, vt_rb);
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DJIMotorSetRef(motor_rb, vt_rb);
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}
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}
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}
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/**
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/**
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@ -235,8 +265,7 @@ void ChassisTask() {
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static float sin_theta, cos_theta;
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static float sin_theta, cos_theta;
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cos_theta = arm_cos_f32(chassis_cmd_recv.offset_angle * DEGREE_2_RAD);
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cos_theta = arm_cos_f32(chassis_cmd_recv.offset_angle * DEGREE_2_RAD);
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sin_theta = arm_sin_f32(chassis_cmd_recv.offset_angle * DEGREE_2_RAD);
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sin_theta = arm_sin_f32(chassis_cmd_recv.offset_angle * DEGREE_2_RAD);
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// sin_theta = 0;
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// cos_theta = 1;
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chassis_vx = chassis_cmd_recv.vx * cos_theta - chassis_cmd_recv.vy * sin_theta;
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chassis_vx = chassis_cmd_recv.vx * cos_theta - chassis_cmd_recv.vy * sin_theta;
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chassis_vy = chassis_cmd_recv.vx * sin_theta + chassis_cmd_recv.vy * cos_theta;
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chassis_vy = chassis_cmd_recv.vx * sin_theta + chassis_cmd_recv.vy * cos_theta;
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@ -118,12 +118,12 @@ static void RemoteControlSet() {
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// 控制底盘和云台运行模式,云台待添加,云台是否始终使用IMU数据?
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// 控制底盘和云台运行模式,云台待添加,云台是否始终使用IMU数据?
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if (switch_is_down(rc_data[TEMP].rc.switch_right)) // 右侧开关状态[下],小陀螺
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if (switch_is_down(rc_data[TEMP].rc.switch_right)) // 右侧开关状态[下],小陀螺
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{
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{
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// chassis_cmd_send.chassis_mode = CHASSIS_ROTATE;
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chassis_cmd_send.chassis_mode = CHASSIS_ROTATE;
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// gimbal_cmd_send.gimbal_mode = GIMBAL_GYRO_MODE;
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chassis_cmd_send.chassis_mode = CHASSIS_FOLLOW_GIMBAL_YAW;
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gimbal_cmd_send.gimbal_mode = GIMBAL_GYRO_MODE;
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gimbal_cmd_send.gimbal_mode = GIMBAL_GYRO_MODE;
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} else if (switch_is_mid(rc_data[TEMP].rc.switch_right)) // 右侧开关状态[中],,底盘跟随云台
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} else if (switch_is_mid(rc_data[TEMP].rc.switch_right)) // 右侧开关状态[中],,底盘跟随云台
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{
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{
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chassis_cmd_send.chassis_mode = CHASSIS_FOLLOW_GIMBAL_YAW;
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chassis_cmd_send.chassis_mode = CHASSIS_FOLLOW_GIMBAL_YAW;
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gimbal_cmd_send.gimbal_mode = GIMBAL_GYRO_MODE;
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gimbal_cmd_send.gimbal_mode = GIMBAL_GYRO_MODE;
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}
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}
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@ -15,7 +15,7 @@ static Subscriber_t *gimbal_sub; // cmd控制消息订阅者
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static Gimbal_Upload_Data_s gimbal_feedback_data; // 回传给cmd的云台状态信息
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static Gimbal_Upload_Data_s gimbal_feedback_data; // 回传给cmd的云台状态信息
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static Gimbal_Ctrl_Cmd_s gimbal_cmd_recv; // 来自cmd的控制信息
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static Gimbal_Ctrl_Cmd_s gimbal_cmd_recv; // 来自cmd的控制信息
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static float gravity_current = 0;
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static void LimitPitchAngleAuto() {
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static void LimitPitchAngleAuto() {
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/** 注意电机角度与陀螺仪角度方向是否相同
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/** 注意电机角度与陀螺仪角度方向是否相同
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* 目前 add > 0, 向下转动
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* 目前 add > 0, 向下转动
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@ -97,7 +97,7 @@ void GimbalInit() {
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.MaxOut = 500,
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.MaxOut = 500,
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},
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},
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.speed_PID = {
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.speed_PID = {
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.Kp = -800, // 50
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.Kp = 0,//-800, // 50
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.Ki = 0, // 350
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.Ki = 0, // 350
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.Kd = 0, // 0
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.Kd = 0, // 0
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.Improve = PID_Trapezoid_Intergral | PID_Integral_Limit | PID_Derivative_On_Measurement,
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.Improve = PID_Trapezoid_Intergral | PID_Integral_Limit | PID_Derivative_On_Measurement,
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@ -107,6 +107,7 @@ void GimbalInit() {
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.other_angle_feedback_ptr = &gimba_IMU_data->Pitch,
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.other_angle_feedback_ptr = &gimba_IMU_data->Pitch,
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// 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
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// 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
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.other_speed_feedback_ptr = &gimba_IMU_data->Gyro[0],
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.other_speed_feedback_ptr = &gimba_IMU_data->Gyro[0],
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.current_feedforward_ptr = &gravity_current,
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},
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},
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.controller_setting_init_config = {
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.controller_setting_init_config = {
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.angle_feedback_source = OTHER_FEED,
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.angle_feedback_source = OTHER_FEED,
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@ -114,6 +115,7 @@ void GimbalInit() {
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.outer_loop_type = ANGLE_LOOP,
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.outer_loop_type = ANGLE_LOOP,
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.close_loop_type = SPEED_LOOP | ANGLE_LOOP,
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.close_loop_type = SPEED_LOOP | ANGLE_LOOP,
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.motor_reverse_flag = MOTOR_DIRECTION_NORMAL,
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.motor_reverse_flag = MOTOR_DIRECTION_NORMAL,
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.feedforward_flag = CURRENT_FEEDFORWARD,
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},
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},
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.motor_type = GM6020,
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.motor_type = GM6020,
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.motor_control_type = CURRENT_CONTROL
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.motor_control_type = CURRENT_CONTROL
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@ -170,6 +172,8 @@ void GimbalTask() {
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// 在合适的地方添加pitch重力补偿前馈力矩
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// 在合适的地方添加pitch重力补偿前馈力矩
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// 根据IMU姿态/pitch电机角度反馈计算出当前配重下的重力矩
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// 根据IMU姿态/pitch电机角度反馈计算出当前配重下的重力矩
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// ...
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// ...
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float theta = - gimba_IMU_data->Pitch/180*PI;
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gravity_current = (5000)*arm_cos_f32(theta);
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// float vofa_send_data[4];
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// float vofa_send_data[4];
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// vofa_send_data[0] = pitch_motor->motor_controller.speed_PID.Ref;
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// vofa_send_data[0] = pitch_motor->motor_controller.speed_PID.Ref;
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@ -32,7 +32,7 @@ void RobotInit()
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#if defined(ONE_BOARD) || defined(GIMBAL_BOARD)
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#if defined(ONE_BOARD) || defined(GIMBAL_BOARD)
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RobotCMDInit();
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RobotCMDInit();
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GimbalInit();
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GimbalInit();
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ShootInit();
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//ShootInit();
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#endif
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#endif
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#if defined(ONE_BOARD) || defined(CHASSIS_BOARD)
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#if defined(ONE_BOARD) || defined(CHASSIS_BOARD)
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@ -50,7 +50,7 @@ void RobotTask()
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#if defined(ONE_BOARD) || defined(GIMBAL_BOARD)
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#if defined(ONE_BOARD) || defined(GIMBAL_BOARD)
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RobotCMDTask();
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RobotCMDTask();
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GimbalTask();
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GimbalTask();
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ShootTask();
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//ShootTask();
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#endif
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#endif
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#if defined(ONE_BOARD) || defined(CHASSIS_BOARD)
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#if defined(ONE_BOARD) || defined(CHASSIS_BOARD)
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@ -26,7 +26,7 @@
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/* 机器人重要参数定义,注意根据不同机器人进行修改,浮点数需要以.0或f结尾,无符号以u结尾 */
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/* 机器人重要参数定义,注意根据不同机器人进行修改,浮点数需要以.0或f结尾,无符号以u结尾 */
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// 云台参数
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// 云台参数
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#define YAW_CHASSIS_ALIGN_ECD 3055 // 云台和底盘对齐指向相同方向时的电机编码器值,若对云台有机械改动需要修改
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#define YAW_CHASSIS_ALIGN_ECD 7856 // 云台和底盘对齐指向相同方向时的电机编码器值,若对云台有机械改动需要修改
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#define YAW_ECD_GREATER_THAN_4096 0 // ALIGN_ECD值是否大于4096,是为1,否为0;用于计算云台偏转角度
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#define YAW_ECD_GREATER_THAN_4096 0 // ALIGN_ECD值是否大于4096,是为1,否为0;用于计算云台偏转角度
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#define PITCH_HORIZON_ECD 1670 // 云台处于水平位置时编码器值,若对云台有机械改动需要修改
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#define PITCH_HORIZON_ECD 1670 // 云台处于水平位置时编码器值,若对云台有机械改动需要修改
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#define PITCH_MAX_ANGLE 25 // 云台竖直方向最大角度 (注意反馈如果是陀螺仪,则填写陀螺仪的角度)
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#define PITCH_MAX_ANGLE 25 // 云台竖直方向最大角度 (注意反馈如果是陀螺仪,则填写陀螺仪的角度)
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@ -201,7 +201,7 @@ typedef struct
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typedef struct
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typedef struct
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{
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{
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attitude_t gimbal_imu_data;
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attitude_t gimbal_imu_data;
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uint16_t yaw_motor_single_round_angle;
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float yaw_motor_single_round_angle;
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} Gimbal_Upload_Data_s;
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} Gimbal_Upload_Data_s;
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typedef struct
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typedef struct
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#include "general_def.h"
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#include "general_def.h"
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#include "bsp_dwt.h"
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#include "bsp_dwt.h"
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#include "bsp_log.h"
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#include "bsp_log.h"
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#include "user_lib.h"
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static uint8_t idx = 0; // register idx,是该文件的全局电机索引,在注册时使用
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static uint8_t idx = 0; // register idx,是该文件的全局电机索引,在注册时使用
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/* DJI电机的实例,此处仅保存指针,内存的分配将通过电机实例初始化时通过malloc()进行 */
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/* DJI电机的实例,此处仅保存指针,内存的分配将通过电机实例初始化时通过malloc()进行 */
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@ -246,6 +247,18 @@ void DJIMotorSetRef(DJIMotorInstance *motor, float ref) {
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motor->motor_controller.pid_ref = ref;
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motor->motor_controller.pid_ref = ref;
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}
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}
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static const float motor_power_K[3] = {1.6301e-6f,5.7501e-7f,2.5863e-7f};
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//依据3508电机功率模型,预测电机输出功率
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static float EstimatePower(DJIMotorInstance* chassis_motor,float output)
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{
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float I_cmd = chassis_motor->motor_controller.current_PID.Output;
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float w = chassis_motor->measure.speed_aps /6 ;//aps to rpm
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float power = motor_power_K[0] * I_cmd * w + motor_power_K[1]*w*w + motor_power_K[2]*I_cmd*I_cmd;
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return power;
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}
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// 为所有电机实例计算三环PID,发送控制报文
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// 为所有电机实例计算三环PID,发送控制报文
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void DJIMotorControl() {
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void DJIMotorControl() {
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// 直接保存一次指针引用从而减小访存的开销,同样可以提高可读性
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// 直接保存一次指针引用从而减小访存的开销,同样可以提高可读性
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@ -303,6 +316,38 @@ void DJIMotorControl() {
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if (motor_setting->feedback_reverse_flag == FEEDBACK_DIRECTION_REVERSE)
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if (motor_setting->feedback_reverse_flag == FEEDBACK_DIRECTION_REVERSE)
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pid_ref *= -1;
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pid_ref *= -1;
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//功率限制
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if(motor_setting->power_limit_flag == POWER_LIMIT_ON)
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{
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float I_cmd = pid_ref;
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float w = measure->speed_aps /6 ;//aps to rpm
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motor_controller->motor_power_predict = motor_power_K[0] * I_cmd * w + motor_power_K[1]*w*w + motor_power_K[2]*I_cmd*I_cmd;
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//这里K应该使用所有底盘电机一起计算 (在底盘任务中)
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//float K = motor_controller->motor_power_max / motor_controller->motor_power_predict;
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float K = motor_controller->motor_power_scale;
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if(K>=1 || motor_controller->motor_power_predict < 0)//未超过最大功率 或做负功的电机 不做限制
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{
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}
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else if(K<1)
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{
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float P_cmd = K * motor_controller->motor_power_predict; //对输出功率进行缩放
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float a = motor_power_K[2] ;
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float b = motor_power_K[0] * w;
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float c = motor_power_K[1] * w * w - P_cmd;
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if(pid_ref < 0)
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pid_ref = (-b - sqrtf(b*b-4*a*c))/(2*a);
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else
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pid_ref = (-b + sqrtf(b*b-4*a*c))/(2*a);
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}
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//if( motor_controller->motor_power_predict < )
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}
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// 获取最终输出 此处注意set不要超过int16_t能表达的最大数 +-32767
|
||||||
|
|
||||||
|
pid_ref = float_constrain(pid_ref,-30000,30000);
|
||||||
// 获取最终输出
|
// 获取最终输出
|
||||||
set = (int16_t) pid_ref;
|
set = (int16_t) pid_ref;
|
||||||
|
|
||||||
|
|
|
@ -68,6 +68,12 @@ typedef enum
|
||||||
MOTOR_ENALBED = 1,
|
MOTOR_ENALBED = 1,
|
||||||
} Motor_Working_Type_e;
|
} Motor_Working_Type_e;
|
||||||
|
|
||||||
|
typedef enum
|
||||||
|
{
|
||||||
|
NO_POWER_LIMIT = 0,
|
||||||
|
POWER_LIMIT_ON = 1,
|
||||||
|
} Power_Limit_Type_e;
|
||||||
|
|
||||||
/* 电机控制设置,包括闭环类型,反转标志和反馈来源 */
|
/* 电机控制设置,包括闭环类型,反转标志和反馈来源 */
|
||||||
typedef struct
|
typedef struct
|
||||||
{
|
{
|
||||||
|
@ -78,6 +84,7 @@ typedef struct
|
||||||
Feedback_Source_e angle_feedback_source; // 角度反馈类型
|
Feedback_Source_e angle_feedback_source; // 角度反馈类型
|
||||||
Feedback_Source_e speed_feedback_source; // 速度反馈类型
|
Feedback_Source_e speed_feedback_source; // 速度反馈类型
|
||||||
Feedfoward_Type_e feedforward_flag; // 前馈标志
|
Feedfoward_Type_e feedforward_flag; // 前馈标志
|
||||||
|
Power_Limit_Type_e power_limit_flag; //功率限制标志
|
||||||
|
|
||||||
} Motor_Control_Setting_s;
|
} Motor_Control_Setting_s;
|
||||||
|
|
||||||
|
@ -104,6 +111,10 @@ typedef struct
|
||||||
PIDInstance angle_PID;
|
PIDInstance angle_PID;
|
||||||
|
|
||||||
float pid_ref; // 将会作为每个环的输入和输出顺次通过串级闭环
|
float pid_ref; // 将会作为每个环的输入和输出顺次通过串级闭环
|
||||||
|
|
||||||
|
float motor_power_max; //每个电机分配的功率上限
|
||||||
|
float motor_power_predict; //根据模型预测的电机功率
|
||||||
|
float motor_power_scale; //电机功率缩放比例
|
||||||
} Motor_Controller_s;
|
} Motor_Controller_s;
|
||||||
|
|
||||||
/* 电机类型枚举 */
|
/* 电机类型枚举 */
|
||||||
|
|
Loading…
Reference in New Issue