2020-07-24 05:29:43 -03:00
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#include <AP_Winch/AP_Winch_Daiwa.h>
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#include <GCS_MAVLink/GCS.h>
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extern const AP_HAL::HAL& hal;
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// true if winch is healthy
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bool AP_Winch_Daiwa::healthy() const
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{
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// healthy if we have received data within 3 seconds
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return (AP_HAL::millis() - data_update_ms < 3000);
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}
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void AP_Winch_Daiwa::init()
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{
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2020-08-06 22:24:36 -03:00
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// call superclass init
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AP_Winch_Backend::init();
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2020-07-24 05:29:43 -03:00
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// initialise serial connection to winch
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const AP_SerialManager &serial_manager = AP::serialmanager();
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uart = serial_manager.find_serial(AP_SerialManager::SerialProtocol_Winch, 0);
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if (uart != nullptr) {
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// always use baudrate of 115200
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uart->begin(115200);
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}
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}
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void AP_Winch_Daiwa::update()
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{
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// return immediately if no servo is assigned to control the winch
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if (!SRV_Channels::function_assigned(SRV_Channel::k_winch)) {
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return;
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}
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// read latest data from winch
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read_data_from_winch();
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// read pilot input
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read_pilot_desired_rate();
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// send outputs to winch
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control_winch();
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}
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//send generator status
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void AP_Winch_Daiwa::send_status(const GCS_MAVLINK &channel)
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{
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// prepare status bitmask
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uint32_t status_bitmask = 0;
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if (healthy()) {
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status_bitmask |= MAV_WINCH_STATUS_HEALTHY;
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}
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if (latest.thread_end) {
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status_bitmask |= MAV_WINCH_STATUS_FULLY_RETRACTED;
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}
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if (latest.moving > 0) {
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status_bitmask |= MAV_WINCH_STATUS_MOVING;
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}
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if (latest.clutch > 0) {
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status_bitmask |= MAV_WINCH_STATUS_CLUTCH_ENGAGED;
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}
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// convert speed percentage to absolute speed
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2020-09-07 04:23:44 -03:00
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const float speed_ms = fabsf(config.rate_max) * (float)latest.speed_pct * 0.01f;
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2020-07-24 05:29:43 -03:00
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// send status
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mavlink_msg_winch_status_send(
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channel.get_chan(),
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AP_HAL::micros64(),
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latest.line_length,
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speed_ms,
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(float)latest.tension_corrected * 0.01f,
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latest.voltage,
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latest.current,
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latest.motor_temp,
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status_bitmask);
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}
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// write log
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void AP_Winch_Daiwa::write_log()
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{
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AP::logger().Write_Winch(
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healthy(),
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latest.thread_end,
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latest.moving,
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latest.clutch,
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(uint8_t)config.control_mode,
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config.length_desired,
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get_current_length(),
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config.rate_desired,
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latest.tension_corrected,
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latest.voltage,
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constrain_int16(latest.motor_temp, INT8_MIN, INT8_MAX));
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}
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// read incoming data from winch and update intermediate and latest structures
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void AP_Winch_Daiwa::read_data_from_winch()
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{
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// return immediately if serial port is not configured
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if (uart == nullptr) {
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return;
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}
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// read any available characters from serial port and send to GCS
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int16_t nbytes = uart->available();
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while (nbytes-- > 0) {
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int16_t b = uart->read();
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if ((b >= '0' && b <= '9') || (b >= 'A' && b <= 'F') || (b >= 'a' && b <= 'f')) {
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// add digits to buffer
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buff[buff_len] = b;
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buff_len++;
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2020-08-06 22:24:36 -03:00
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if (buff_len >= ARRAY_SIZE(buff)) {
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2020-07-24 05:29:43 -03:00
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buff_len = 0;
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parse_state = ParseState::WAITING_FOR_TIME;
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}
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} else if (b == ',' || b == '\r') {
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// comma or carriage return signals end of current value
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2020-08-06 22:24:36 -03:00
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// parse number received and empty buffer
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2020-07-24 05:29:43 -03:00
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buff[buff_len] = '\0';
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2020-08-06 22:24:36 -03:00
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long int value = (int32_t)strtol(buff, nullptr, 16);
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buff_len = 0;
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switch (parse_state) {
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case ParseState::WAITING_FOR_TIME:
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intermediate.time_ms = (uint32_t)value;
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parse_state = ParseState::WAITING_FOR_SPOOL;
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break;
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case ParseState::WAITING_FOR_SPOOL:
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intermediate.line_length = (int32_t)value * line_length_correction_factor;
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parse_state = ParseState::WAITING_FOR_TENSION1;
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break;
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case ParseState::WAITING_FOR_TENSION1:
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intermediate.tension_uncorrected = (uint16_t)value;
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parse_state = ParseState::WAITING_FOR_TENSION2;
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break;
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case ParseState::WAITING_FOR_TENSION2:
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intermediate.tension_corrected = (uint16_t)value;
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parse_state = ParseState::WAITING_FOR_THREAD_END;
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break;
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case ParseState::WAITING_FOR_THREAD_END:
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intermediate.thread_end = (value > 0);
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parse_state = ParseState::WAITING_FOR_MOVING;
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break;
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case ParseState::WAITING_FOR_MOVING:
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intermediate.moving = constrain_int32(value, 0, UINT8_MAX);
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parse_state = ParseState::WAITING_FOR_CLUTCH;
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break;
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case ParseState::WAITING_FOR_CLUTCH:
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intermediate.clutch = constrain_int32(value, 0, UINT8_MAX);
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parse_state = ParseState::WAITING_FOR_SPEED;
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break;
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case ParseState::WAITING_FOR_SPEED:
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intermediate.speed_pct = constrain_int32(value, 0, UINT8_MAX);
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parse_state = ParseState::WAITING_FOR_VOLTAGE;
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break;
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case ParseState::WAITING_FOR_VOLTAGE:
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intermediate.voltage = (float)value * 0.1f;
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parse_state = ParseState::WAITING_FOR_CURRENT;
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break;
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case ParseState::WAITING_FOR_CURRENT:
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intermediate.current = (float)value * 0.1f;
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parse_state = ParseState::WAITING_FOR_PCB_TEMP;
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break;
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case ParseState::WAITING_FOR_PCB_TEMP:
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intermediate.pcb_temp = (float)value * 0.1f;
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parse_state = ParseState::WAITING_FOR_MOTOR_TEMP;
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break;
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case ParseState::WAITING_FOR_MOTOR_TEMP:
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intermediate.motor_temp = (float)value * 0.1f;
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// successfully parsed a complete message
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latest = intermediate;
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data_update_ms = AP_HAL::millis();
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2020-07-24 05:29:43 -03:00
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parse_state = ParseState::WAITING_FOR_TIME;
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2020-08-06 22:24:36 -03:00
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break;
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2020-07-24 05:29:43 -03:00
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}
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} else {
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2020-08-06 22:24:36 -03:00
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// line feed or unexpected characters
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2020-07-24 05:29:43 -03:00
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buff_len = 0;
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parse_state = ParseState::WAITING_FOR_TIME;
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}
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}
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}
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// update pwm outputs to control winch
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void AP_Winch_Daiwa::control_winch()
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{
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2020-08-06 22:24:36 -03:00
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const uint32_t now_ms = AP_HAL::millis();
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2020-07-24 05:29:43 -03:00
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float dt = (now_ms - control_update_ms) / 1000.0f;
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if (dt > 1.0f) {
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dt = 0.0f;
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}
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control_update_ms = now_ms;
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// if real doing any control output trim value
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if (config.control_mode == AP_Winch::ControlMode::RELAXED) {
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// if not doing any control output release clutch and move winch to trim
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SRV_Channels::set_output_limit(SRV_Channel::k_winch_clutch, SRV_Channel::Limit::MAX);
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SRV_Channels::set_output_scaled(SRV_Channel::k_winch, 0);
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// rate used for acceleration limiting reset to zero
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set_previous_rate(0.0f);
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return;
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}
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// release clutch
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SRV_Channels::set_output_limit(SRV_Channel::k_winch_clutch, SRV_Channel::Limit::MIN);
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// if doing position control, calculate position error to desired rate
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if ((config.control_mode == AP_Winch::ControlMode::POSITION) && healthy()) {
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float position_error = config.length_desired - latest.line_length;
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config.rate_desired = constrain_float(position_error * config.pos_p, -config.rate_max, config.rate_max);
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}
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// apply acceleration limited to rate
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const float rate_limited = get_rate_limited_by_accel(config.rate_desired, dt);
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// use linear interpolation to calculate output to move winch at desired rate
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int16_t scaled_output = 0;
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if (!is_zero(rate_limited)) {
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scaled_output = linear_interpolate(output_dz, 1000, fabsf(rate_limited), 0, config.rate_max) * (is_positive(rate_limited) ? 1.0f : -1.0f);
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}
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SRV_Channels::set_output_scaled(SRV_Channel::k_winch, scaled_output);
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}
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