# Calculate bearing between two locations (lat, long)

I'm trying to develop my own augmented reality engine.

Searching on internet, I've found this useful tutorial. Reading it I see that the important thing is bearing between user location, point location and north.

The following picture is from that tutorial.

Following it, I wrote an Objective-C method to obtain beta:

+ (float) calculateBetaFrom:(CLLocationCoordinate2D)user to:(CLLocationCoordinate2D)destination
{
double beta = 0;
double a, b = 0;

a = destination.latitude - user.latitude;
b = destination.longitude - user.longitude;

beta = atan2(a, b) * 180.0 / M_PI;
if (beta < 0.0)
beta += 360.0;
else if (beta > 360.0)
beta -= 360;

return beta;
}

But, when I try it, it doesn't work very well.

So, I checked iPhone AR Toolkit, to see how it works (I've been working with this toolkit, but it is so big for me).

And, in ARGeoCoordinate.m there is another implementation of how to obtain beta:

- (float)angleFromCoordinate:(CLLocationCoordinate2D)first toCoordinate:(CLLocationCoordinate2D)second {

float longitudinalDifference    = second.longitude - first.longitude;
float latitudinalDifference     = second.latitude  - first.latitude;
float possibleAzimuth           = (M_PI * .5f) - atan(latitudinalDifference / longitudinalDifference);

if (longitudinalDifference > 0)
return possibleAzimuth;
else if (longitudinalDifference < 0)
return possibleAzimuth + M_PI;
else if (latitudinalDifference < 0)
return M_PI;

return 0.0f;
}

It uses this formula:

float possibleAzimuth = (M_PI * .5f) - atan(latitudinalDifference / longitudinalDifference);

Why is (M_PI * .5f) in this formula? I don't understand it.

And continue searching, I've found another page talking about how to calculate distance and bearing of 2 locations. In this page there is another implementation:

/**
* Returns the (initial) bearing from this point to the supplied point, in degrees
*   see http://williams.best.vwh.net/avform.htm#Crs
*
* @param   {LatLon} point: Latitude/longitude of destination point
* @returns {Number} Initial bearing in degrees from North
*/
LatLon.prototype.bearingTo = function(point) {

var y = Math.sin(dLon) * Math.cos(lat2);
var x = Math.cos(lat1)*Math.sin(lat2) -
Math.sin(lat1)*Math.cos(lat2)*Math.cos(dLon);
var brng = Math.atan2(y, x);

return (brng.toDeg()+360) % 360;
}

Which one is the right one?

• Did you ever resolve this issue? I am interested in which solution you went with – Craigy Dec 1 '11 at 14:21
• Yes, I have to add my own answer shortly. – VansFannel Dec 1 '11 at 19:55

Calculate bearing

//Source
JSONObject source = step.getJSONObject("start_location");
double lat1 = Double.parseDouble(source.getString("lat"));
double lng1 = Double.parseDouble(source.getString("lng"));

// destination
JSONObject destination = step.getJSONObject("end_location");
double lat2 = Double.parseDouble(destination.getString("lat"));
double lng2 = Double.parseDouble(destination.getString("lng"));

double dLon = (lng2-lng1);
double y = Math.sin(dLon) * Math.cos(lat2);
double x = Math.cos(lat1)*Math.sin(lat2) - Math.sin(lat1)*Math.cos(lat2)*Math.cos(dLon);
double brng = Math.toDegrees((Math.atan2(y, x)));
brng = (360 - ((brng + 360) % 360));

Radians = Degrees * PI / 180

Degrees = Radians * 180 / PI
• You convert the value to degrees, but isn't Latitude and Longitude in degrees? Shouldn't you convert them to radians first? – ravemir May 5 '13 at 16:14
• I dont convert the latitude and Longitude in radius. I don't think that it make any difference – Kirit Vaghela May 6 '13 at 4:52
• Do you tried online bearing match for testing? for ex. test on by this link. sunearthtools.com/tools/distance.php – Vishal Jadav Feb 24 '17 at 7:27

I know this question is old, but here is an easier solution:

float bearing = loc1.bearingTo(loc2);

In the formula

float possibleAzimuth = (M_PI * .5f) - atan(latitudinalDifference / longitudinalDifference);

the term (M_PI * .5f) means π/2 which is 90°. That means that it is the same formula that you stated at first, because regarding to the figure above it holds

β = arctan (a/b) = 90° - arctan(b/a).

So both formulas are similar if a refers to the difference in longitude and b in the difference in latitude. The last formula calculates again the same using the first part of my equation.

• You refer to a as difference in lat and b as difference in long. See my response for how a should actually the difference in long and b the difference in lat. It might be useful to edit your answer to be consistent with the diagram so we don't confuse future readers any more than necessary? – Dolbz Nov 14 '11 at 15:21
• Thank you, Dolbz, you are right, a and b should be changed. I edited my main answer in order to have a right one. :) – Palund Nov 14 '11 at 16:02

a in the diagram is the longitude difference, b is the latitude difference therefore in the method you have written you've got them the wrong way round.

a = destination.latitude - user.latitude; // should be b
b = destination.longitude - user.longitude; // should be a

Try switching them and see what happens.

• Thanks, you are right: I've make a mistake with a and b. I've switched them, and I get beta = 9 degrees. But, if I use LatLon.prototype.bearingTo, with the same locations, I get beta = 7 degrees. I think the second one is more accurate, but I don't understand it isn't implemented in iPhone AR Toolkit. Thanks again. – VansFannel Nov 14 '11 at 15:53
• This solve the issue. Just use arctan(b, a) instead of (a,b). – Juan Carlos Oropeza Jul 10 '14 at 22:24

Try this for accurate result:

private static double degreeToRadians(double latLong) {
return (Math.PI * latLong / 180.0);
}

private static double radiansToDegree(double latLong) {
return (latLong * 180.0 / Math.PI);
}

public static double getBearing() {

//Source
JSONObject source = step.getJSONObject("start_location");
double lat1 = Double.parseDouble(source.getString("lat"));
double lng1 = Double.parseDouble(source.getString("lng"));

// destination
JSONObject destination = step.getJSONObject("end_location");
double lat2 = Double.parseDouble(destination.getString("lat"));
double lng2 = Double.parseDouble(destination.getString("lng"));

double dLon = (tLong - fLong);

double degree = radiansToDegree(Math.atan2(sin(dLon) * cos(tLat),
cos(fLat) * sin(tLat) - sin(fLat) * cos(tLat) * cos(dLon)));

if (degree >= 0) {
return degree;
} else {
return 360 + degree;
}
}

You can test bearing result on http://www.sunearthtools.com/tools/distance.php .

• I've implemented the math portion of this (starting with double dLon =) and when I calculate reciprocal headings, the results aren't +/- 180*, but rather +/- 180* +/- 0.25*. Am I the only one seeing this issue? Is it just how the math is (imprecise) or did I do something wrong? – ManEatingCheese Feb 14 at 1:23
here is the code for calculating bearing angle between two points(startPoint, endPoint):

public float CalculateBearingAngle(double startLatitude,double startLongitude, double endLatitude, double endLongitude){
double DeltaLambda = Math.toRadians(endLongitude - startLongitude);

double Theta = atan2((sin(DeltaLambda)*cos(Phi2)) , (cos(Phi1)*sin(Phi2) - sin(Phi1)*cos(Phi2)*cos(DeltaLambda)));
return (float)Math.toDegrees(Theta);
}

call for function:
float angle = CalculateBearingAngle(startLatitude, startLongitude, endLatitude, endLongitude);

import static java.lang.Math.atan2;
import static java.lang.Math.cos;
import static java.lang.Math.sin;

If you want you can take a look at the code used in mixare augmented reality engine, it's on github and there's an iPhone version as well: github.com/mixare