# Calculate distance between 2 GPS coordinates

How do I calculate distance between two gps coordinates (using latitude and longitude) ?

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Calculate the distance between two coordinates by latitude and longitude, including a Javascript implementation.

W and S locations are negative. Remember minutes and seconds are out of 60 so S31 30' is -31.50 degrees.

Don't forget to convert degrees to radians. Many languages have this function. Or its a simple calculation:

radians = degrees * PI / 180

``````var R = 6371; // km

var a = Math.sin(dLat/2) * Math.sin(dLat/2) +
Math.sin(dLon/2) * Math.sin(dLon/2) * Math.cos(lat1) * Math.cos(lat2);
var c = 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1-a));
var d = R * c;
``````
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In case it's not obvious, the toRad() method is a customization to the Number prototype such as: `Number.prototype.toRad = function() { return this * (Math.PI / 180); }; `. Or, as indicated below, you can replace `(Math.PI/2)` with 0.0174532925199433 (...whatever precision you deem necessary) for increased performance. –  Vinney Kelly Jul 23 '13 at 6:05
If anyone, specifically those of you who don't look for end of line comments, is staring at this formula and looking for a unit of distance, the unit is km. :) –  dylanlknowles Sep 27 '13 at 18:01

1. Earth radius is different on different Lat. This must be taken into consideration in Haversine algorithm.
2. Consider Bearing change, which turns straight lines to arches (which are longer)
3. Taking Speed change into account will turn arches to spirals (which are longer or shorter than arches)
4. Altitude change will turn flat spirals to 3D spirals (which are longer again). This is very important for hilly areas.

Below see the function in C which takes #1 and #2 into account:

``````double   calcDistanceByHaversine(double rLat1, double rLon1, double rHeading1,
double rLat2, double rLon2, double rHeading2){
double a = 0.0;
double c = 0.0;
double rResult = 0.0;

if ((rLat1 < -90.0) || (rLat1 > 90.0) || (rLat2 < -90.0) || (rLat2 > 90.0)
|| (rLon1 < -180.0) || (rLon1 > 180.0) || (rLon2 < -180.0)
|| (rLon2 > 180.0)) {
return -1;
};

if (a == 0.0) {
return 0.0;
}

c = 2 * atan2(sqrt(a), sqrt(1 - a));
rEarthRadius = 6378.1370 - (21.3847 * 90.0 / ((fabs(rLat1) + fabs(rLat2))
/ 2.0));

// Chord to Arc Correction based on Heading changes. Important for routes with many turns and U-turns

}
} else {
}
}
return rResult;
}
``````

II. There is an easier way which gives pretty good results.

By Average Speed.

Trip_distance = Trip_average_speed * Trip_time

Since GPS Speed is detected by Doppler effect and is not directly related to [Lon,Lat] it can be at least considered as secondary (backup or correction) if not as main distance calculation method.

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http://www.math.montana.edu/frankw/ccp/cases/Global-Positioning/spherical-coordinates/learn.htm

Edit: As pointed out this link is no longer valid.

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thanks for the link –  David Jul 21 '10 at 11:30
Oh no. My reply is no longer valid for this question. Would this link do instead? mathworld.wolfram.com/SphericalCoordinates.html –  fasih.ahmed Nov 14 '13 at 10:58
archive.org to the rescue: web.archive.org/web/20130814214811/http://www.math.montana.edu/… –  thelatemail Apr 14 at 22:12

Here's a Haversine function in Python that I use:

``````def haversine(pos1, pos2):
lat1 = float(pos1['lat'])
long1 = float(pos1['long'])
lat2 = float(pos2['lat'])
long2 = float(pos2['long'])

d_lat = (lat2 - lat1) * degree_to_rad
d_long = (long2 - long1) * degree_to_rad

a = pow(sin(d_lat / 2), 2) + cos(lat1 * degree_to_rad) * cos(lat2 * degree_to_rad) * pow(sin(d_long / 2), 2)
c = 2 * atan2(sqrt(a), sqrt(1 - a))
km = 6367 * c
mi = 3956 * c

return {"km":km, "miles":mi}
``````
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Java Version of Haversine Algorithm based on Roman Makarov`s reply to this thread

``````public class HaversineAlgorithm {

static final double _eQuatorialEarthRadius = 6378.1370D;
static final double _d2r = (Math.PI / 180D);

public static int HaversineInM(double lat1, double long1, double lat2, double long2) {
return (int) (1000D * HaversineInKM(lat1, long1, lat2, long2));
}

public static double HaversineInKM(double lat1, double long1, double lat2, double long2) {
double dlong = (long2 - long1) * _d2r;
double dlat = (lat2 - lat1) * _d2r;
double a = Math.pow(Math.sin(dlat / 2D), 2D) + Math.cos(lat1 * _d2r) * Math.cos(lat2 * _d2r)
* Math.pow(Math.sin(dlong / 2D), 2D);
double c = 2D * Math.atan2(Math.sqrt(a), Math.sqrt(1D - a));
double d = _eQuatorialEarthRadius * c;

return d;
}

}
``````
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If you need something more accurate then have a look at this.

Vincenty's formulae are two related iterative methods used in geodesy to calculate the distance between two points on the surface of a spheroid, developed by Thaddeus Vincenty (1975a) They are based on the assumption that the figure of the Earth is an oblate spheroid, and hence are more accurate than methods such as great-circle distance which assume a spherical Earth.

The first (direct) method computes the location of a point which is a given distance and azimuth (direction) from another point. The second (inverse) method computes the geographical distance and azimuth between two given points. They have been widely used in geodesy because they are accurate to within 0.5 mm (0.020″) on the Earth ellipsoid.

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I needed to implement this in PowerShell, hope it can help someone else. Some notes about this method

1. Don't split any of the lines or the calculation will be wrong
2. To calculate in KM remove the * 1000 in the calculation of \$distance
3. Change \$earthsRadius = 3963.19059 and remove * 1000 in the calculation of \$distance the to calulate the distance in miles
4. I'm using Haversine, as other posts have pointed out Vincenty's formulae is much more accurate

``````Function MetresDistanceBetweenTwoGPSCoordinates(\$latitude1, \$longitude1, \$latitude2, \$longitude2)
{

\$dLat = (\$latitude2 - \$latitude1) * \$Rad
\$dLon = (\$longitude2 - \$longitude1) * \$Rad

\$a = [math]::Sin(\$dLat / 2) * [math]::Sin(\$dLat / 2) + [math]::Sin(\$dLon / 2) * [math]::Sin(\$dLon / 2) * [math]::Cos(\$latitude1) * [math]::Cos(\$latitude2)
\$c = 2 * [math]::ATan2([math]::Sqrt(\$a), [math]::Sqrt(1-\$a))

\$distance = [math]::Round(\$earthsRadius * \$c * 1000, 0) #Multiple by 1000 to get metres

Return \$distance
}
``````
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This is version from "Henry Vilinskiy" adapted for MySQL and Kilometers:

``````CREATE FUNCTION `CalculateDistanceInKm`(
fromLatitude float,
fromLongitude float,
toLatitude float,
toLongitude float
) RETURNS float
BEGIN
declare distance float;

select
6367 * ACOS(
round(
,15)
)
into distance;

return  round(distance,3);
END;
``````
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Here is rubygems version - https://rubygems.org/gems/haversine_distance

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C# Version of Haversine

``````double _eQuatorialEarthRadius = 6378.1370D;
double _d2r = (Math.PI / 180D);

private int HaversineInM(double lat1, double long1, double lat2, double long2)
{
return (int)(1000D * HaversineInKM(lat1, long1, lat2, long2));
}

private double HaversineInKM(double lat1, double long1, double lat2, double long2)
{
double dlong = (long2 - long1) * _d2r;
double dlat = (lat2 - lat1) * _d2r;
double a = Math.Pow(Math.Sin(dlat / 2D), 2D) + Math.Cos(lat1 * _d2r) * Math.Cos(lat2 * _d2r) * Math.Pow(Math.Sin(dlong / 2D), 2D);
double c = 2D * Math.Atan2(Math.Sqrt(a), Math.Sqrt(1D - a));
double d = _eQuatorialEarthRadius * c;

return d;
}
``````
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you can find a implementation of this (with some good explanation) in F# on fssnip

here are the important parts:

``````
let GreatCircleDistance<[<Measure>] 'u> (R : float<'u>) (p1 : Location) (p2 : Location) =

let sq x = x * x
// take the sin of the half and square the result
let sinSqHf (a : float<rad>) = (System.Math.Sin >> sq) (a / 2.0<rad>)

let dLat = (p2.Latitude - p1.Latitude) |> degToRad
let dLon = (p2.Longitude - p1.Longitude) |> degToRad

let a = sinSqHf dLat + cos p1.Latitude * cos p2.Latitude * sinSqHf dLon
let c = 2.0 * System.Math.Atan2(System.Math.Sqrt(a), System.Math.Sqrt(1.0-a))

R * c
``````
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A T-SQL function, that I use to select records by distance for a center

``````Create Function  [dbo].[DistanceInMiles]
(  @fromLatitude float ,
@fromLongitude float ,
@toLatitude float,
@toLongitude float
)
returns float
AS
BEGIN
declare @distance float

)as float)
return  round(@distance,1)
END
``````
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// Maybe a typo error ?
We have an unused variable dlon in GetDirection,
I assume

``````double y = Math.Sin(dlon) * Math.Cos(lat2);
// cannot use degrees in Cos ?
``````

should be

``````double y = Math.Sin(dlon) * Math.Cos(dlat);
``````
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This isn't an answer, it's at best a comment. –  Kevin Nov 14 '12 at 4:18
``````    private double deg2rad(double deg)
{
return (deg * Math.PI / 180.0);
}

{
return (rad / Math.PI * 180.0);
}

private double GetDistance(double lat1, double lon1, double lat2, double lon2)
{
//code for Distance in Kilo Meter
double theta = lon1 - lon2;
dist = Math.Abs(Math.Round(rad2deg(Math.Acos(dist)) * 60 * 1.1515 * 1.609344 * 1000, 0));
return (dist);
}

private double GetDirection(double lat1, double lon1, double lat2, double lon2)
{
//code for Direction in Degrees
double y = Math.Sin(dlon) * Math.Cos(lat2);
double direct = Math.Round(rad2deg(Math.Atan2(y, x)), 0);
if (direct < 0)
direct = direct + 360;
return (direct);
}

private double GetSpeed(double lat1, double lon1, double lat2, double lon2, DateTime CurTime, DateTime PrevTime)
{
//code for speed in Kilo Meter/Hour
TimeSpan TimeDifference = CurTime.Subtract(PrevTime);
double TimeDifferenceInSeconds = Math.Round(TimeDifference.TotalSeconds, 0);
double theta = lon1 - lon2;
dist = rad2deg(Math.Acos(dist)) * 60 * 1.1515 * 1.609344;
double Speed = Math.Abs(Math.Round((dist / Math.Abs(TimeDifferenceInSeconds)) * 60 * 60, 0));
return (Speed);
}

private double GetDuration(DateTime CurTime, DateTime PrevTime)
{
//code for speed in Kilo Meter/Hour
TimeSpan TimeDifference = CurTime.Subtract(PrevTime);
double TimeDifferenceInSeconds = Math.Abs(Math.Round(TimeDifference.TotalSeconds, 0));
return (TimeDifferenceInSeconds);
}
``````
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Here it is in C# (lat and long in radians):

``````double CalculateGreatCircleDistance(double lat1, double long1, double lat2, double long2, double radius)
{
Math.Sin(lat1) * Math.Sin(lat2)
+ Math.Cos(lat1) * Math.Cos(lat2) * Math.Cos(long2 - long1));
}
``````

If your lat and long are in degrees then divide by 180/PI to convert to radians.

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Look for haversine with Google; here is my solution:

``````#include <math.h>
#include "haversine.h"

#define d2r (M_PI / 180.0)

//calculate haversine distance for linear distance
double haversine_km(double lat1, double long1, double lat2, double long2)
{
double dlong = (long2 - long1) * d2r;
double dlat = (lat2 - lat1) * d2r;
double a = pow(sin(dlat/2.0), 2) + cos(lat1*d2r) * cos(lat2*d2r) * pow(sin(dlong/2.0), 2);
double c = 2 * atan2(sqrt(a), sqrt(1-a));
double d = 6367 * c;

return d;
}

double haversine_mi(double lat1, double long1, double lat2, double long2)
{
double dlong = (long2 - long1) * d2r;
double dlat = (lat2 - lat1) * d2r;
double a = pow(sin(dlat/2.0), 2) + cos(lat1*d2r) * cos(lat2*d2r) * pow(sin(dlong/2.0), 2);
double c = 2 * atan2(sqrt(a), sqrt(1-a));
double d = 3956 * c;

return d;
}
``````
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I used haversine in my projects too. –  Pascal Paradis Sep 13 '10 at 2:25
You can replace (M_PI / 180.0) with 0.0174532925199433 for better performance. –  Hlung Aug 1 '11 at 9:19
In terms of performance: one could calculate sin(dlat/2.0) only once, store it in variable a1, and instead of pow(,2) it's MUCH better to use a1*a1. The same for the other pow(,2). –  pms Oct 27 '11 at 23:34
Yeah, or just use a post-’60s compiler. –  rightfold Jan 28 at 10:45

This is very easy to do with geography type in SQL Server 2008.

``````SELECT geography::Point(lat1, lon1, 4326).STDistance(geography::Point(lat2, lon2, 4326))
-- computes distance in meters using eliptical model, accurate to the mm
``````

4326 is SRID for WGS84 elipsoidal Earth model

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Very useful answer ..Thanks. –  Pranav Jul 30 '13 at 6:11

It depends on how accurate you need it to be, if you need pinpoint accuracy, is best to look at an algorithm with uses an ellipsoid, rather than a sphere, such as Vincenty's algorithm, which is accurate to the mm. http://en.wikipedia.org/wiki/Vincenty%27s_algorithm

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I recently had to do the same thing. I found this website to be very helpful explaining spherical trig with examples that were easy to follow along with.

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This Lua code is adapted from stuff found on Wikipedia and in Robert Lipe's GPSbabel tool:

``````local EARTH_RAD = 6378137.0
-- earth's radius in meters (official geoid datum, not 20,000km / pi)

local multipliers = {
degrees = 360 / (2 * math.pi), min = 60 * 360 / (2 * math.pi)
}

function gcdist(pt1, pt2, units) -- return distance in radians or given units
--- this formula works best for points close together or antipodal
--- rounding error strikes when distance is one-quarter Earth's circumference
--- (ref: wikipedia Great-circle distance)
local sdlat = sin((pt1.lat - pt2.lat) / 2.0);
local sdlon = sin((pt1.lon - pt2.lon) / 2.0);
local res = sqrt(sdlat * sdlat + cos(pt1.lat) * cos(pt2.lat) * sdlon * sdlon);
res = res > 1 and 1 or res < -1 and -1 or res
res = 2 * asin(res);
if units then return res * assert(multipliers[units])
else return res
end
end
``````
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I guess you want it along the curvature of the earth. Your two points and the center of the earth are on a plane. The center of the earth is the center of a circle on that plane and the two points are (roughly) on the perimeter of that circle. From that you can calculate the distance by finding out what the angle from one point to the other is.

If the points are not the same heights, or if you need to take into account that the earth is not a perfect sphere it gets a little more difficult.

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This algorithm is known as the Great Circle distance.

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