ardupilot/ArduCopter/navigation.pde

// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-

//****************************************************************
// Function that will calculate the desired direction to fly and distance
//****************************************************************
static byte navigate()
{
	// waypoint distance from plane in meters
	// ---------------------------------------
	wp_distance 	= get_distance(&current_loc, &next_WP);
	home_distance 	= get_distance(&current_loc, &home);

	if (wp_distance < 0){
		// something went very wrong
		return 0;
	}

	// target_bearing is where we should be heading
	// --------------------------------------------
	target_bearing 			= get_bearing(&current_loc, &next_WP);
	home_to_copter_bearing 	= get_bearing(&home, &current_loc);

	// nav_bearing will includes xtrac correction
	// ------------------------------------------
	nav_bearing = target_bearing;

	return 1;
}

static bool check_missed_wp()
{
	int32_t temp;
	temp = target_bearing - original_target_bearing;
	temp = wrap_180(temp);
	return (abs(temp) > 10000);	//we pased the waypoint by 10 °
}

// ------------------------------

static void calc_XY_velocity(){
	// offset calculation of GPS speed:
	// used for estimations below 1.5m/s
	// our GPS is about 1m per
	static int32_t last_longitude = 0;
	static int32_t last_latitude  = 0;

	static int16_t x_speed_old = 0;
	static int16_t y_speed_old = 0;

	// y_GPS_speed positve = Up
	// x_GPS_speed positve = Right

	// this speed is ~ in cm because we are using 10^7 numbers from GPS
	float tmp = 1.0/dTnav;

	// straightforward approach:
	///*
	x_actual_speed = x_speed_old + (float)(g_gps->longitude - last_longitude)  * scaleLongDown * tmp;
	y_actual_speed	= y_speed_old + (float)(g_gps->latitude  - last_latitude)  * tmp;

	x_actual_speed = x_actual_speed >> 1;
	y_actual_speed = y_actual_speed >> 1;

	x_speed_old 	= x_actual_speed;
	y_speed_old 	= y_actual_speed;

	/*
	// Ryan Beall's forward estimator:
	int16_t	x_speed_new = (float)(g_gps->longitude - last_longitude) * scaleLongDown* tmp;
	int16_t	y_speed_new = (float)(g_gps->latitude  - last_latitude)  * tmp;

	x_actual_speed 	= x_speed_new + (x_speed_new - x_speed_old);
	y_actual_speed 	= y_speed_new + (y_speed_new - y_speed_old);

	x_speed_old 	= x_speed_new;
	y_speed_old 	= y_speed_new;
	*/

	last_longitude 	= g_gps->longitude;
	last_latitude 	= g_gps->latitude;
}

static void calc_location_error(struct Location *next_loc)
{
	/*
	Becuase we are using lat and lon to do our distance errors here's a quick chart:
	100 	= 1m
	1000 	= 11m	 = 36 feet
	1800 	= 19.80m = 60 feet
	3000 	= 33m
	10000 	= 111m
	*/

	// X Error
	long_error	= (float)(next_loc->lng - current_loc.lng) * scaleLongDown;   // 500 - 0 = 500 Go East

	// Y Error
	lat_error	= next_loc->lat - current_loc.lat;							// 500 - 0 = 500 Go North
}

#define NAV_ERR_MAX 600
static void calc_loiter(int x_error, int y_error)
{
	#if LOITER_RATE == 1
	int16_t x_target_speed, y_target_speed;
	int16_t x_iterm, y_iterm;

	// East / West
	x_target_speed 	= g.pi_loiter_lon.get_p(x_error);			// not contstrained yet
	//x_target_speed	= constrain(x_target_speed, -250, 250);		// limit to 2.5m/s travel speed
	x_rate_error 	= x_target_speed - x_actual_speed;			// calc the speed error
	nav_lon			= g.pid_loiter_rate_lon.get_pid(x_rate_error, dTnav);
	nav_lon			= constrain(nav_lon, -3000, 3000); 			// 30°

	// North / South
	y_target_speed 	= g.pi_loiter_lat.get_p(y_error);
	//y_target_speed	= constrain(y_target_speed, -250, 250);
	y_rate_error 	= y_target_speed - y_actual_speed;
	nav_lat			= g.pid_loiter_rate_lat.get_pid(y_rate_error, dTnav);
	nav_lat			= constrain(nav_lat, -3000, 3000); // 30°

	// copy over I term to Nav_Rate
	g.pid_nav_lon.set_integrator(g.pid_loiter_rate_lon.get_integrator());
	g.pid_nav_lat.set_integrator(g.pid_loiter_rate_lat.get_integrator());

	#else

	// no rate control on Loiter
	nav_lon			= g.pid_loiter_rate_lon.get_pid(x_error, dTnav);
	nav_lat			= g.pid_loiter_rate_lat.get_pid(y_error, dTnav);

	nav_lon			= constrain(nav_lon, -3000, 3000); 			// 30°
	nav_lat			= constrain(nav_lat, -3000, 3000); // 30°

	#endif


	// Wind I term based on location error,
	// limit windup
	/*
	x_error 		= constrain(x_error, -NAV_ERR_MAX, NAV_ERR_MAX);
	y_error 		= constrain(y_error, -NAV_ERR_MAX, NAV_ERR_MAX);
	x_iterm 		= g.pi_loiter_lon.get_i(x_error, dTnav);
	y_iterm 		= g.pi_loiter_lat.get_i(y_error, dTnav);
	nav_lat			= nav_lat + y_iterm;
	nav_lon			= nav_lon + x_iterm;
	*/

	/*
	int8_t ttt = 1.0/dTnav;
	int16_t t2 = g.pi_nav_lat.get_integrator();

				// 1   2   3      4   5   6   7   8   9   10
	Serial.printf("%d, %d, %d,    %d, %d, %d, %d, %d, %d, %d\n",
					wp_distance, 	//1
					y_error,		//2
					y_GPS_speed,	//3

					y_actual_speed,	//4  ;
					y_target_speed,	//5
					y_rate_error,	//6
					nav_lat_p,		//7
					nav_lat,		//8
					y_iterm,		//9
					t2);			//10
	//*/

	/*
	int16_t t1 = g.pid_nav_lon.get_integrator(); // X
	Serial.printf("%d, %1.4f, %d, %d, %d, %d, %d, %d, %d, %d\n",
					wp_distance, 	//1
					dTnav,			//2
					x_error,		//3
					x_GPS_speed,	//4
					x_actual_speed,	//5
					x_target_speed,	//6
					x_rate_error,	//7
					nav_lat,		//8
					x_iterm,		//9
					t1);			//10
	//*/
}

static void calc_nav_rate(int max_speed)
{
	// push us towards the original track
	update_crosstrack();

	// nav_bearing includes crosstrack
	float temp 		= (9000l - nav_bearing) * RADX100;

	// East / West
	x_rate_error 	= (cos(temp) * max_speed) - x_actual_speed; // 413
	x_rate_error 	= constrain(x_rate_error, -1000, 1000);
	nav_lon			= g.pid_nav_lon.get_pid(x_rate_error, dTnav);
	nav_lon			= constrain(nav_lon, -3000, 3000);

	// North / South
	y_rate_error 	= (sin(temp) * max_speed) - y_actual_speed; // 413
	y_rate_error 	= constrain(y_rate_error, -1000, 1000);	// added a rate error limit to keep pitching down to a minimum
	nav_lat			= g.pid_nav_lat.get_pid(y_rate_error, dTnav);
	nav_lat			= constrain(nav_lat, -3000, 3000);

	// copy over I term to Loiter_Rate
	g.pid_loiter_rate_lon.set_integrator(g.pid_nav_lon.get_integrator());
	g.pid_loiter_rate_lat.set_integrator(g.pid_nav_lat.get_integrator());

	//int16_t x_iterm 	= g.pi_loiter_lon.get_i(x_rate_error, dTnav);
	//int16_t y_iterm 	= g.pi_loiter_lat.get_i(y_rate_error, dTnav);

	//nav_lon				= nav_lon + x_iterm;
	//nav_lat				= nav_lat + y_iterm;



	/*
	Serial.printf("max_sp %d,\t x_sp %d, y_sp %d,\t x_re: %d, y_re: %d, \tnav_lon: %d, nav_lat: %d, Xi:%d, Yi:%d, \t XE %d \n",
					max_speed,
					x_actual_speed,
					y_actual_speed,
					x_rate_error,
					y_rate_error,
					nav_lon,
					nav_lat,
					x_iterm,
					y_iterm,
					crosstrack_error);
	//*/

	// nav_lat and nav_lon will be rotated to the angle of the quad in calc_nav_pitch_roll()

	/*Serial.printf("max_speed: %d, xspeed: %d, yspeed: %d, x_re: %d, y_re: %d, nav_lon: %ld, nav_lat: %ld  ",
					max_speed,
					x_actual_speed,
					y_actual_speed,
					x_rate_error,
					y_rate_error,
					nav_lon,
					nav_lat);*/
}


/*static void calc_nav_lon(int rate)
{
	nav_lon		= g.pid_nav_lon.get_pid(rate, dTnav);
	nav_lon		= constrain(nav_lon, -3000, 3000);
}

static void calc_nav_lat(int rate)
{
	nav_lat		= g.pid_nav_lat.get_pid(rate, dTnav);
	nav_lat		= constrain(nav_lat, -3000, 3000);
}
*/

//static int16_t get_corrected_angle(int16_t desired_rate, int16_t rate_out)
/*{
	int16_t tt = desired_rate;
	// scale down the desired rate and square it
	desired_rate = desired_rate / 20;
	desired_rate = desired_rate * desired_rate;
	int16_t tmp = 0;

	if (tt > 0){
		tmp = rate_out + (rate_out - desired_rate);
		tmp = max(tmp, rate_out);
	}else if (tt < 0){
		tmp = rate_out + (rate_out + desired_rate);
		tmp = min(tmp, rate_out);
	}
	//Serial.printf("rate:%d, norm:%d, out:%d \n", tt, rate_out, tmp);
	return tmp;
}*/

//wp_distance,ttt, y_error, y_GPS_speed, y_actual_speed, y_target_speed, y_rate_error, nav_lat, y_iterm, t2



// this calculation rotates our World frame of reference to the copter's frame of reference
// We use the DCM's matrix to precalculate these trig values at 50hz
static void calc_loiter_pitch_roll()
{
	//Serial.printf("ys %ld, cx %1.4f, _cx %1.4f | sy %1.4f, _sy %1.4f\n", dcm.yaw_sensor, cos_yaw_x, _cos_yaw_x, sin_yaw_y, _sin_yaw_y);
	// rotate the vector
	auto_roll 	= (float)nav_lon * sin_yaw_y - (float)nav_lat * cos_yaw_x;
	auto_pitch 	= (float)nav_lon * cos_yaw_x + (float)nav_lat * sin_yaw_y;

	// flip pitch because forward is negative
	auto_pitch = -auto_pitch;
}

static int16_t calc_desired_speed(int16_t max_speed, bool _slow)
{
	/*
	|< WP Radius
	0  1   2   3   4   5   6   7   8m
	...|...|...|...|...|...|...|...|
		  100  |  200	  300	  400cm/s
	           |  		 		            +|+
	           |< we should slow to 1.5 m/s as we hit the target
	*/

	// max_speed is default 600 or 6m/s
	if(_slow){
		max_speed 		= min(max_speed, wp_distance / 2);
		max_speed 		= max(max_speed, 0);
	}else{
		max_speed 		= min(max_speed, wp_distance);
		max_speed 		= max(max_speed, WAYPOINT_SPEED_MIN);	// go at least 100cm/s
	}

	// limit the ramp up of the speed
	// waypoint_speed_gov is reset to 0 at each new WP command
	if(max_speed > waypoint_speed_gov){
		waypoint_speed_gov += (int)(100.0 * dTnav); // increase at .5/ms
		max_speed = waypoint_speed_gov;
	}

	return max_speed;
}


static void update_crosstrack(void)
{
	// Crosstrack Error
	// ----------------
	if (abs(wrap_180(target_bearing - original_target_bearing)) < 4500) {	 // If we are too far off or too close we don't do track following
		float temp = (target_bearing - original_target_bearing) * RADX100;
		crosstrack_error = sin(temp) * (wp_distance * g.crosstrack_gain);	 // Meters we are off track line
		nav_bearing = target_bearing + constrain(crosstrack_error, -3000, 3000);
		nav_bearing = wrap_360(nav_bearing);
	}else{
		nav_bearing = target_bearing;
	}
}

static int32_t get_altitude_error()
{
	// Next_WP alt is our target alt
	// It changes based on climb rate
	// until it reaches the target_altitude
	return next_WP.alt - current_loc.alt;
}

static void clear_new_altitude()
{
	alt_change_flag = REACHED_ALT;
}

static void set_new_altitude(int32_t _new_alt)
{
	if(_new_alt == current_loc.alt){
		next_WP.alt 	= _new_alt;
		target_altitude = _new_alt;
		alt_change_flag = REACHED_ALT;
		return;
	}

	// just to be clear
	next_WP.alt = current_loc.alt;

	// for calculating the delta time
	alt_change_timer = millis();

	// save the target altitude
	target_altitude = _new_alt;

	// reset our altitude integrator
	alt_change = 0;

	// save the original altitude
	original_altitude = current_loc.alt;

	// to decide if we have reached the target altitude
	if(target_altitude > original_altitude){
		// we are below, going up
		alt_change_flag = ASCENDING;
		//Serial.printf("go up\n");
	}else if(target_altitude < original_altitude){
		// we are above, going down
		alt_change_flag = DESCENDING;
		//Serial.printf("go down\n");
	}else{
		// No Change
		alt_change_flag = REACHED_ALT;
		//Serial.printf("reached alt\n");
	}
	//Serial.printf("new alt: %d Org alt: %d\n", target_altitude, original_altitude);
}

static int32_t get_new_altitude()
{
	// returns a new next_WP.alt

	if(alt_change_flag == ASCENDING){
		// we are below, going up
		if(current_loc.alt >=  target_altitude){
			alt_change_flag = REACHED_ALT;
		}

		// we shouldn't command past our target
		if(next_WP.alt >=  target_altitude){
			return target_altitude;
		}
	}else if (alt_change_flag == DESCENDING){
		// we are above, going down
		if(current_loc.alt <=  target_altitude)
			alt_change_flag = REACHED_ALT;

		// we shouldn't command past our target
		if(next_WP.alt <=  target_altitude){
			return target_altitude;
		}
	}

	// if we have reached our target altitude, return the target alt
	if(alt_change_flag == REACHED_ALT){
		return target_altitude;
	}

	int32_t diff 	= abs(next_WP.alt - target_altitude);
	int8_t			_scale 	= 4;

	if (next_WP.alt < target_altitude){
		// we are below the target alt
		if(diff < 200){
			_scale = 5;
		} else {
			_scale = 4;
		}
	}else {
		// we are above the target, going down
		if(diff < 400){
			_scale = 5;
		}
		if(diff < 100){
			_scale = 6;
		}
	}

	// we use the elapsed time as our altitude offset
	// 1000 = 1 sec
	// 1000 >> 4 = 64cm/s descent by default
	int32_t change = (millis() - alt_change_timer) >> _scale;

	if(alt_change_flag == ASCENDING){
		alt_change += change;
	}else{
		alt_change -= change;
	}
	// for generating delta time
	alt_change_timer = millis();

	return original_altitude + alt_change;
}


static int32_t wrap_360(int32_t error)
{
	if (error > 36000)	error -= 36000;
	if (error < 0)		error += 36000;
	return error;
}

static int32_t wrap_180(int32_t error)
{
	if (error > 18000)	error -= 36000;
	if (error < -18000)	error += 36000;
	return error;
}

/*
//static int32_t get_altitude_above_home(void)
{
	// This is the altitude above the home location
	// The GPS gives us altitude at Sea Level
	// if you slope soar, you should see a negative number sometimes
	// -------------------------------------------------------------
	return current_loc.alt - home.alt;
}
*/

// distance is returned in meters
static int32_t get_distance(struct Location *loc1, struct Location *loc2)
{
	float dlat 		= (float)(loc2->lat - loc1->lat);
	float dlong		= ((float)(loc2->lng - loc1->lng)) * scaleLongDown;
	dlong			= sqrt(sq(dlat) + sq(dlong)) * 1.113195;
	return			dlong;
}
/*
//static int32_t get_alt_distance(struct Location *loc1, struct Location *loc2)
{
	return abs(loc1->alt - loc2->alt);
}
*/
static int32_t get_bearing(struct Location *loc1, struct Location *loc2)
{
	int32_t off_x = loc2->lng - loc1->lng;
	int32_t off_y = (loc2->lat - loc1->lat) * scaleLongUp;
	int32_t bearing =	9000 + atan2(-off_y, off_x) * 5729.57795;
	if (bearing < 0) bearing += 36000;
	return bearing;
}