mirror of https://github.com/ArduPilot/ardupilot
253 lines
8.5 KiB
C++
253 lines
8.5 KiB
C++
#include "Rover.h"
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#include <AP_RangeFinder/RangeFinder_Backend.h>
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#include <AP_VisualOdom/AP_VisualOdom.h>
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// initialise compass
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void Rover::init_compass()
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{
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if (!g.compass_enabled) {
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return;
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}
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compass.init();
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if (!compass.read()) {
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hal.console->printf("Compass initialisation failed!\n");
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g.compass_enabled = false;
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} else {
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ahrs.set_compass(&compass);
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}
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}
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/*
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initialise compass's location used for declination
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*/
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void Rover::init_compass_location(void)
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{
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// update initial location used for declination
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if (!compass_init_location) {
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Location loc;
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if (ahrs.get_position(loc)) {
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compass.set_initial_location(loc.lat, loc.lng);
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compass_init_location = true;
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}
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}
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}
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// check for new compass data - 10Hz
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void Rover::update_compass(void)
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{
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if (g.compass_enabled && compass.read()) {
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ahrs.set_compass(&compass);
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// update offsets
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if (should_log(MASK_LOG_COMPASS)) {
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logger.Write_Compass();
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}
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}
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}
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// Calibrate compass
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void Rover::compass_cal_update() {
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if (!hal.util->get_soft_armed()) {
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compass.compass_cal_update();
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}
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}
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// Save compass offsets
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void Rover::compass_save() {
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if (g.compass_enabled &&
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compass.get_learn_type() >= Compass::LEARN_INTERNAL &&
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!arming.is_armed()) {
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compass.save_offsets();
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}
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}
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// init beacons used for non-gps position estimates
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void Rover::init_beacon()
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{
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g2.beacon.init();
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}
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// init visual odometry sensor
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void Rover::init_visual_odom()
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{
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g2.visual_odom.init();
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}
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// update wheel encoders
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void Rover::update_wheel_encoder()
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{
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// exit immediately if not enabled
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if (g2.wheel_encoder.num_sensors() == 0) {
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return;
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}
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// update encoders
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g2.wheel_encoder.update();
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// initialise on first iteration
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const uint32_t now = AP_HAL::millis();
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if (wheel_encoder_last_ekf_update_ms == 0) {
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wheel_encoder_last_ekf_update_ms = now;
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for (uint8_t i = 0; i < g2.wheel_encoder.num_sensors(); i++) {
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wheel_encoder_last_angle_rad[i] = g2.wheel_encoder.get_delta_angle(i);
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wheel_encoder_last_update_ms[i] = g2.wheel_encoder.get_last_reading_ms(i);
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}
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return;
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}
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// calculate delta angle and delta time and send to EKF
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// use time of last ping from wheel encoder
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// send delta time (time between this wheel encoder time and previous wheel encoder time)
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// in case where wheel hasn't moved, count = 0 (cap the delta time at 50ms - or system time)
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// use system clock of last update instead of time of last ping
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const float system_dt = (now - wheel_encoder_last_ekf_update_ms) / 1000.0f;
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for (uint8_t i = 0; i < g2.wheel_encoder.num_sensors(); i++) {
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// calculate angular change (in radians)
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const float curr_angle_rad = g2.wheel_encoder.get_delta_angle(i);
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const float delta_angle = curr_angle_rad - wheel_encoder_last_angle_rad[i];
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wheel_encoder_last_angle_rad[i] = curr_angle_rad;
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// save cumulative distances at current time (in meters)
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wheel_encoder_last_distance_m[i] = g2.wheel_encoder.get_distance(i);
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// calculate delta time
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float delta_time;
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const uint32_t latest_sensor_update_ms = g2.wheel_encoder.get_last_reading_ms(i);
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const uint32_t sensor_diff_ms = latest_sensor_update_ms - wheel_encoder_last_update_ms[i];
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// if we have not received any sensor updates, or time difference is too high then use time since last update to the ekf
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// check for old or insane sensor update times
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if (sensor_diff_ms == 0 || sensor_diff_ms > 100) {
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delta_time = system_dt;
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wheel_encoder_last_update_ms[i] = wheel_encoder_last_ekf_update_ms;
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} else {
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delta_time = sensor_diff_ms / 1000.0f;
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wheel_encoder_last_update_ms[i] = latest_sensor_update_ms;
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}
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/* delAng is the measured change in angular position from the previous measurement where a positive rotation is produced by forward motion of the vehicle (rad)
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* delTime is the time interval for the measurement of delAng (sec)
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* timeStamp_ms is the time when the rotation was last measured (msec)
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* posOffset is the XYZ body frame position of the wheel hub (m)
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*/
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EKF3.writeWheelOdom(delta_angle, delta_time, wheel_encoder_last_update_ms[i], g2.wheel_encoder.get_pos_offset(i), g2.wheel_encoder.get_wheel_radius(i));
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}
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// record system time update for next iteration
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wheel_encoder_last_ekf_update_ms = now;
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}
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// Accel calibration
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void Rover::accel_cal_update() {
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if (hal.util->get_soft_armed()) {
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return;
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}
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ins.acal_update();
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// check if new trim values, and set them float trim_roll, trim_pitch;
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float trim_roll, trim_pitch;
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if (ins.get_new_trim(trim_roll, trim_pitch)) {
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ahrs.set_trim(Vector3f(trim_roll, trim_pitch, 0));
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}
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}
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// read the rangefinders
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void Rover::read_rangefinders(void)
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{
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rangefinder.update();
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AP_RangeFinder_Backend *s0 = rangefinder.get_backend(0);
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AP_RangeFinder_Backend *s1 = rangefinder.get_backend(1);
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if (s0 == nullptr || s0->status() == RangeFinder::RangeFinder_NotConnected) {
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// this makes it possible to disable rangefinder at runtime
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return;
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}
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if (s1 != nullptr && s1->has_data()) {
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// we have two rangefinders
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obstacle.rangefinder1_distance_cm = s0->distance_cm();
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obstacle.rangefinder2_distance_cm = s1->distance_cm();
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if (obstacle.rangefinder1_distance_cm < static_cast<uint16_t>(g.rangefinder_trigger_cm) &&
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obstacle.rangefinder1_distance_cm < static_cast<uint16_t>(obstacle.rangefinder2_distance_cm)) {
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// we have an object on the left
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if (obstacle.detected_count < 127) {
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obstacle.detected_count++;
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}
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if (obstacle.detected_count == g.rangefinder_debounce) {
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gcs().send_text(MAV_SEVERITY_INFO, "Rangefinder1 obstacle %u cm",
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static_cast<uint32_t>(obstacle.rangefinder1_distance_cm));
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}
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obstacle.detected_time_ms = AP_HAL::millis();
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obstacle.turn_angle = g.rangefinder_turn_angle;
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} else if (obstacle.rangefinder2_distance_cm < static_cast<uint16_t>(g.rangefinder_trigger_cm)) {
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// we have an object on the right
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if (obstacle.detected_count < 127) {
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obstacle.detected_count++;
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}
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if (obstacle.detected_count == g.rangefinder_debounce) {
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gcs().send_text(MAV_SEVERITY_INFO, "Rangefinder2 obstacle %u cm",
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static_cast<uint32_t>(obstacle.rangefinder2_distance_cm));
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}
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obstacle.detected_time_ms = AP_HAL::millis();
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obstacle.turn_angle = -g.rangefinder_turn_angle;
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}
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} else {
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// we have a single rangefinder
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obstacle.rangefinder1_distance_cm = s0->distance_cm();
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obstacle.rangefinder2_distance_cm = 0;
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if (obstacle.rangefinder1_distance_cm < static_cast<uint16_t>(g.rangefinder_trigger_cm)) {
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// obstacle detected in front
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if (obstacle.detected_count < 127) {
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obstacle.detected_count++;
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}
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if (obstacle.detected_count == g.rangefinder_debounce) {
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gcs().send_text(MAV_SEVERITY_INFO, "Rangefinder obstacle %u cm",
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static_cast<uint32_t>(obstacle.rangefinder1_distance_cm));
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}
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obstacle.detected_time_ms = AP_HAL::millis();
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obstacle.turn_angle = g.rangefinder_turn_angle;
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}
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}
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Log_Write_Rangefinder();
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Log_Write_Depth();
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// no object detected - reset after the turn time
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if (obstacle.detected_count >= g.rangefinder_debounce &&
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AP_HAL::millis() > obstacle.detected_time_ms + g.rangefinder_turn_time*1000) {
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gcs().send_text(MAV_SEVERITY_INFO, "Obstacle passed");
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obstacle.detected_count = 0;
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obstacle.turn_angle = 0;
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}
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}
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// initialise proximity sensor
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void Rover::init_proximity(void)
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{
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g2.proximity.init();
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g2.proximity.set_rangefinder(&rangefinder);
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}
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/*
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ask airspeed sensor for a new value, duplicated from plane
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*/
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void Rover::read_airspeed(void)
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{
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g2.airspeed.update(should_log(MASK_LOG_IMU));
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}
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/*
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update RPM sensors
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*/
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void Rover::rpm_update(void)
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{
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rpm_sensor.update();
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if (rpm_sensor.enabled(0) || rpm_sensor.enabled(1)) {
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if (should_log(MASK_LOG_RC)) {
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logger.Write_RPM(rpm_sensor);
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}
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}
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}
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