#pragma once /* Gain and phase determination algorithm */ #include class AC_AutoTune_FreqResp { public: // Constructor AC_AutoTune_FreqResp() { } // Enumeration of input type enum InputType { DWELL = 0, SWEEP = 1, }; // Enumeration of type enum ResponseType { RATE = 0, ANGLE = 1, }; // Initialize the Frequency Response Object. // Must be called before running dwell or frequency sweep tests void init(InputType input_type, ResponseType response_type, uint8_t cycles); // Determines the gain and phase based on angle response for a dwell or sweep void update(float command, float tgt_resp, float meas_resp, float tgt_freq); // Enable external query if cycle is complete and freq response data are available bool is_cycle_complete() { return cycle_complete;} // Reset cycle_complete flag void reset_cycle_complete() { cycle_complete = false; } // Frequency response data accessors float get_freq() { return curr_test_freq; } float get_gain() { return curr_test_gain; } float get_phase() { return curr_test_phase; } float get_accel_max() { return max_accel; } private: // time of the start of a new target value search. keeps noise from prematurely starting the search of a new target value. uint32_t new_tgt_time_ms; // flag for searching for a new target peak bool new_target = false; // maximum target value float max_target; // time of maximum target value in current cycle uint32_t max_tgt_time; // counter for target value maximums uint16_t max_target_cnt; // holds previously determined maximum target value while current cycle is running float temp_max_target; // holds previously determined time of maximum target value while current cycle is running uint32_t temp_max_tgt_time; // minimum target value float min_target; // counter for target value minimums uint16_t min_target_cnt; // holds previously determined minimum target value while current cycle is running float temp_min_target; // maximum target value from previous cycle float prev_target; // maximum target response from previous cycle float prev_tgt_resp; // holds target amplitude for gain calculation float temp_tgt_ampl; // time of the start of a new measured value search. keeps noise from prematurely starting the search of a new measured value. uint32_t new_meas_time_ms; // flag for searching for a new measured peak bool new_meas = false; // maximum measured value float max_meas; // time of maximum measured value in current cycle uint32_t max_meas_time; // counter for measured value maximums uint16_t max_meas_cnt; // holds previously determined maximum measured value while current cycle is running float temp_max_meas; // holds previously determined time of maximum measured value while current cycle is running uint32_t temp_max_meas_time; // minimum measured value float min_meas; // counter for measured value minimums uint16_t min_meas_cnt; // holds previously determined minimum measured value while current cycle is running float temp_min_meas; // maximum measured value from previous cycle float prev_meas; // maximum measured response from previous cycle float prev_meas_resp; // holds measured amplitude for gain calculation float temp_meas_ampl; // calculated target rate from angle data float target_rate; // calculated measured rate from angle data float measured_rate; // holds start time of input to track length of time that input in running uint32_t input_start_time_ms; // flag indicating when one oscillation cycle is complete bool cycle_complete = false; // number of dwell cycles to complete for dwell excitation uint8_t dwell_cycles; // current test frequency, gain, and phase float curr_test_freq; float curr_test_gain; float curr_test_phase; // maximum measured rate throughout excitation used for max accel calculation float max_meas_rate; // maximum command associated with maximum rate used for max accel calculation float max_command; // maximum acceleration in cdss determined during test float max_accel; // Input type for frequency response object InputType excitation; // Response type for frequency response object ResponseType response; // sweep_peak_finding_data tracks the peak data struct sweep_peak_finding_data { uint16_t count_m1; float amplitude_m1; float max_time_m1; }; // Measured data for sweep peak sweep_peak_finding_data sweep_meas; // Target data for sweep peak sweep_peak_finding_data sweep_tgt; //store gain data in ring buffer struct peak_info { uint16_t curr_count; float amplitude; uint32_t time_ms; }; // Buffer object for measured peak data ObjectBuffer meas_peak_info_buffer{12}; // Buffer object for target peak data ObjectBuffer tgt_peak_info_buffer{12}; // Push data into measured peak data buffer object void push_to_meas_buffer(uint16_t count, float amplitude, uint32_t time_ms); // Pull data from measured peak data buffer object void pull_from_meas_buffer(uint16_t &count, float &litude, uint32_t &time_ms); // Push data into target peak data buffer object void push_to_tgt_buffer(uint16_t count, float amplitude, uint32_t time_ms); // Pull data from target peak data buffer object void pull_from_tgt_buffer(uint16_t &count, float &litude, uint32_t &time_ms); };