mirror of https://github.com/ArduPilot/ardupilot
369 lines
12 KiB
Plaintext
369 lines
12 KiB
Plaintext
// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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//****************************************************************
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// Function that will calculate the desired direction to fly and distance
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//****************************************************************
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static void navigate()
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{
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// do not navigate with corrupt data
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// ---------------------------------
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if (g_gps->fix == 0){
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g_gps->new_data = false;
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return;
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}
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if(next_WP.lat == 0){
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return;
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}
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// waypoint distance from plane
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// ----------------------------
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wp_distance = get_distance(¤t_loc, &next_WP);
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if (wp_distance < 0){
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//gcs.send_text_P(SEVERITY_HIGH,PSTR("<navigate> WP error - distance < 0"));
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//Serial.println(wp_distance,DEC);
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//print_current_waypoints();
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return;
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}
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// target_bearing is where we should be heading
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// --------------------------------------------
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target_bearing = get_bearing(¤t_loc, &next_WP);
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// nav_bearing will includes xtrac correction
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// ------------------------------------------
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nav_bearing = target_bearing;
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}
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static bool check_missed_wp()
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{
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long temp = target_bearing - saved_target_bearing;
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temp = wrap_180(temp);
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return (abs(temp) > 10000); //we pased the waypoint by 10 °
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}
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static int
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get_nav_throttle(long error)
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{
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int throttle;
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// limit error to prevent I term run up
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error = constrain(error, -600,600);
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throttle = g.pid_throttle.get_pid(error, delta_ms_medium_loop, 1.0);
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throttle = g.throttle_cruise + constrain(throttle, -80, 80);
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// failed experiment
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//int tem = alt_hold_velocity();
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//throttle -= tem;
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return throttle;
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}
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// ------------------------------
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// long_error, lat_error
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static void calc_loiter_nav2()
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{
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/*
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Becuase we are using lat and lon to do our distance errors here's a quick chart:
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100 = 1m
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1000 = 11m = 36 feet
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1800 = 19.80m = 60 feet
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3000 = 33m
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10000 = 111m
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pitch_max = 22° (2200)
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*/
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// X ROLL
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long_error = (float)(next_WP.lng - current_loc.lng) * scaleLongDown; // 500 - 0 = 500 roll EAST
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// Y PITCH
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lat_error = current_loc.lat - next_WP.lat; // 0 - 500 = -500 pitch NORTH
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// constrain input, not output to let I term ramp up and do it's job again wind
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long_error = constrain(long_error, -loiter_error_max, loiter_error_max); // +- 20m max error
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lat_error = constrain(lat_error, -loiter_error_max, loiter_error_max); // +- 20m max error
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}
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// sets nav_lon, nav_lat
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static void calc_rate_nav2(int target_x_speed, int target_y_speed)
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{
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// find the rates:
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// calc the cos of the error to tell how fast we are moving towards the target in cm
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int y_speed = (float)g_gps->ground_speed * cos(radians((float)g_gps->ground_course/100.0));
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int y_error = constrain(target_y_speed - y_speed, -1000, 1000);
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// calc the sin of the error to tell how fast we are moving laterally to the target in cm
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int x_speed = (float)g_gps->ground_speed * sin(radians((float)g_gps->ground_course/100.0));
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int x_error = constrain(target_x_speed - x_speed, -1000, 1000);
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// how fast should we be going?
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nav_lat += g.pid_nav_lat.get_pid(y_error, dTnav, 1.0);
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nav_lat >>= 1; // divide by two for smooting
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nav_lon += g.pid_nav_lon.get_pid(x_error, dTnav, 1.0);
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nav_lon >>= 1; // divide by two for smooting
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//Serial.printf("dTnav: %ld, gs: %d, err: %d, int: %d, pitch: %ld", dTnav, targetspeed, error, (int)g.pid_nav_wp.get_integrator(), (long)nav_lat);
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// limit our output
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nav_lat = constrain(nav_lat, -3500, 3500); // +- max error
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nav_lon = constrain(nav_lon, -3500, 3500); // +- max error
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}
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// ------------------------------
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//nav_lon, nav_lat
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static void calc_loiter_nav()
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{
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/*
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Becuase we are using lat and lon to do our distance errors here's a quick chart:
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100 = 1m
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1000 = 11m = 36 feet
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1800 = 19.80m = 60 feet
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3000 = 33m
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10000 = 111m
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pitch_max = 22° (2200)
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*/
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// X ROLL
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long_error = (float)(next_WP.lng - current_loc.lng) * scaleLongDown; // 500 - 0 = 500 roll EAST
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// Y PITCH
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lat_error = current_loc.lat - next_WP.lat; // 0 - 500 = -500 pitch NORTH
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// constrain input, not output to let I term ramp up and do it's job again wind
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long_error = constrain(long_error, -loiter_error_max, loiter_error_max); // +- 20m max error
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lat_error = constrain(lat_error, -loiter_error_max, loiter_error_max); // +- 20m max error
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nav_lon = g.pid_nav_lon.get_pid(long_error, dTnav, 1.0); // X 700 * 2.5 = 1750,
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nav_lat = g.pid_nav_lat.get_pid(lat_error, dTnav, 1.0); // Y invert lat (for pitch)
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}
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//nav_lat
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static void calc_simple_nav()
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{
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// no dampening here in SIMPLE mode
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nav_lat = constrain((wp_distance * 100), -4500, 4500); // +- 20m max error
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// Scale response by kP
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//nav_lat *= g.pid_nav_lat.kP(); // 1800 * 2 = 3600 or 36°
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}
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// sets nav_lon, nav_lat
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static void calc_rate_nav(int speed)
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{
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// which direction are we moving?
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long heading_error = nav_bearing - g_gps->ground_course;
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heading_error = wrap_180(heading_error);
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// calc the cos of the error to tell how fast we are moving towards the target in cm
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int targetspeed = (float)g_gps->ground_speed * cos(radians((float)heading_error/100));
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// calc the sin of the error to tell how fast we are moving laterally to the target in cm
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int lateralspeed = (float)g_gps->ground_speed * sin(radians((float)heading_error/100));
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//targetspeed = max(targetspeed, 0);
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// Reduce speed on RTL
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if(control_mode == RTL){
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int tmp = min(wp_distance, 80) * 50;
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waypoint_speed = min(tmp, speed);
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//waypoint_speed = max(waypoint_speed, 50);
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}else{
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int tmp = min(wp_distance, 200) * 90;
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waypoint_speed = min(tmp, speed);
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waypoint_speed = max(waypoint_speed, 50);
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//waypoint_speed = g.waypoint_speed_max.get();
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}
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int error = constrain(waypoint_speed - targetspeed, -1000, 1000);
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nav_lat += g.pid_nav_wp.get_pid(error, dTnav, 1.0);
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nav_lat >>= 1; // divide by two for smooting
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nav_lon += lateralspeed * 2; // 2 is our fake PID gain
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nav_lon >>= 1; // divide by two for smooting
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//Serial.printf("dTnav: %ld, gs: %d, err: %d, int: %d, pitch: %ld", dTnav, targetspeed, error, (int)g.pid_nav_wp.get_integrator(), (long)nav_lat);
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// limit our output
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nav_lat = constrain(nav_lat, -3500, 3500); // +- max error
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}
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// output pitch and roll
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// ------------------------------
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// nav_roll, nav_pitch
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static void calc_loiter_output()
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{
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// rotate the vector
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nav_roll = (float)nav_lon * sin_yaw_y - (float)nav_lat * -cos_yaw_x;
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// BAD
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//NORTH -1000 * 1 - 1000 * 0 = -1000 // roll left
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//WEST -1000 * 0 - 1000 * -1 = 1000 // roll right - Backwards
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//EAST -1000 * 0 - 1000 * 1 = -1000 // roll left - Backwards
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//SOUTH -1000 * -1 - 1000 * 0 = 1000 // roll right
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// GOOD
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//NORTH -1000 * 1 - 1000 * 0 = -1000 // roll left
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//WEST -1000 * 0 - 1000 * 1 = -1000 // roll right
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//EAST -1000 * 0 - 1000 * -1 = 1000 // roll left
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//SOUTH -1000 * -1 - 1000 * 0 = 1000 // roll right
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nav_pitch = ((float)nav_lon * -cos_yaw_x + (float)nav_lat * sin_yaw_y);
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// BAD
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//NORTH -1000 * 0 + 1000 * 1 = 1000 // pitch back
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//WEST -1000 * -1 + 1000 * 0 = 1000 // pitch back - Backwards
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//EAST -1000 * 1 + 1000 * 0 = -1000 // pitch forward - Backwards
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//SOUTH -1000 * 0 + 1000 * -1 = -1000 // pitch forward
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// GOOD
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//NORTH -1000 * 0 + 1000 * 1 = 1000 // pitch back
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//WEST -1000 * 1 + 1000 * 0 = -1000 // pitch forward
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//EAST -1000 * -1 + 1000 * 0 = 1000 // pitch back
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//SOUTH -1000 * 0 + 1000 * -1 = -1000 // pitch forward
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}
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// nav_roll, nav_pitch
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static void calc_nav_output()
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{
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// get the sin and cos of the bearing error - rotated 90°
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float sin_nav_y = sin(radians((float)(9000 - bearing_error) / 100));
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float cos_nav_x = cos(radians((float)(bearing_error - 9000) / 100));
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// rotate the vector
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//nav_roll = (float)nav_lat * cos_nav_x;
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//nav_pitch = -(float)nav_lat * sin_nav_y;
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nav_roll = (float)nav_lon * sin_nav_y - (float)nav_lat * -cos_nav_x;
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nav_pitch = (float)nav_lon * cos_nav_x - (float)nav_lat * sin_nav_y;
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}
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// ------------------------------
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static void calc_bearing_error()
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{
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// 83 99 Yaw = -16
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bearing_error = nav_bearing - dcm.yaw_sensor;
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bearing_error = wrap_180(bearing_error);
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}
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static void calc_altitude_error()
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{
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altitude_error = next_WP.alt - current_loc.alt;
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}
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static void calc_altitude_smoothing_error()
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{
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// limit climb rates - we draw a straight line between first location and edge of waypoint_radius
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target_altitude = next_WP.alt - ((float)(wp_distance * (next_WP.alt - prev_WP.alt)) / (float)(wp_totalDistance - g.waypoint_radius));
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// stay within a certain range
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if(prev_WP.alt > next_WP.alt){
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target_altitude = constrain(target_altitude, next_WP.alt, prev_WP.alt);
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}else{
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target_altitude = constrain(target_altitude, prev_WP.alt, next_WP.alt);
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}
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altitude_error = target_altitude - current_loc.alt;
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}
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static void update_loiter()
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{
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float power;
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if(wp_distance <= g.loiter_radius){
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power = float(wp_distance) / float(g.loiter_radius);
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power = constrain(power, 0.5, 1);
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nav_bearing += (int)(9000.0 * (2.0 + power));
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}else if(wp_distance < (g.loiter_radius + LOITER_RANGE)){
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power = -((float)(wp_distance - g.loiter_radius - LOITER_RANGE) / LOITER_RANGE);
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power = constrain(power, 0.5, 1); //power = constrain(power, 0, 1);
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nav_bearing -= power * 9000;
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}else{
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update_crosstrack();
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loiter_time = millis(); // keep start time for loiter updating till we get within LOITER_RANGE of orbit
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}
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nav_bearing = wrap_360(nav_bearing);
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}
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static long wrap_360(long error)
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{
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if (error > 36000) error -= 36000;
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if (error < 0) error += 36000;
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return error;
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}
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static long wrap_180(long error)
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{
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if (error > 18000) error -= 36000;
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if (error < -18000) error += 36000;
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return error;
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}
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static void update_crosstrack(void)
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{
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// Crosstrack Error
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// ----------------
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if (cross_track_test() < 9000) { // If we are too far off or too close we don't do track following
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// Meters we are off track line
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crosstrack_error = sin(radians((target_bearing - crosstrack_bearing) / (float)100)) * (float)wp_distance;
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// take meters * 100 to get adjustment to nav_bearing
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long xtrack = g.pid_crosstrack.get_pid(crosstrack_error, dTnav, 1.0) * 100;
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nav_bearing += constrain(xtrack, -g.crosstrack_entry_angle.get(), g.crosstrack_entry_angle.get());
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nav_bearing = wrap_360(nav_bearing);
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}
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}
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static long cross_track_test()
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{
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long temp = target_bearing - crosstrack_bearing;
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temp = wrap_180(temp);
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return abs(temp);
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}
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static void reset_crosstrack()
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{
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crosstrack_bearing = get_bearing(¤t_loc, &next_WP); // Used for track following
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}
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static long get_altitude_above_home(void)
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{
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// This is the altitude above the home location
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// The GPS gives us altitude at Sea Level
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// if you slope soar, you should see a negative number sometimes
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// -------------------------------------------------------------
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return current_loc.alt - home.alt;
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}
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// distance is returned in meters
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static long get_distance(struct Location *loc1, struct Location *loc2)
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{
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//if(loc1->lat == 0 || loc1->lng == 0)
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// return -1;
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//if(loc2->lat == 0 || loc2->lng == 0)
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// return -1;
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float dlat = (float)(loc2->lat - loc1->lat);
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float dlong = ((float)(loc2->lng - loc1->lng)) * scaleLongDown;
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return sqrt(sq(dlat) + sq(dlong)) * .01113195;
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}
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static long get_alt_distance(struct Location *loc1, struct Location *loc2)
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{
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return abs(loc1->alt - loc2->alt);
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}
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static long get_bearing(struct Location *loc1, struct Location *loc2)
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{
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long off_x = loc2->lng - loc1->lng;
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long off_y = (loc2->lat - loc1->lat) * scaleLongUp;
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long bearing = 9000 + atan2(-off_y, off_x) * 5729.57795;
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if (bearing < 0) bearing += 36000;
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return bearing;
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}
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