Which algorithm does Google maps use to compute the direction between 2 points?

I wonder which algorithm Google maps use to compute the direction between 2 points ? Has Google ever mentioned about it ?

p/s : I am asking the algorithm which google use to find the shortest route between 2 points.

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If you mean google maps direction api and the shortest route between 2 points then it's a graph-theory problem that can be solved using the dijktstra algorithm. It' a DFS with a backtracking.

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Hi, Is it really which Google Maps is using ? Was the algorithm metioned in any article by Google ? –  IT-Fan Aug 6 '11 at 16:32
The short answer is yes. Maybe it's an A+ pathfinding. But backtraking means to try all solution until you find the best or the solution is not wanted (i.e. longer then the current shortest solution). –  Phpdna Aug 6 '11 at 16:42
Here is the post from one of the google guys: stackoverflow.com/questions/430142/… –  Phpdna Aug 6 '11 at 16:49

Take a look at this site... http://www.movable-type.co.uk/scripts/latlong.html

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Hi, thanks but it seems to be not what I am asking. I am asking the algorithm which google use to find the shortest route between 2 points. –  IT-Fan Aug 6 '11 at 16:39
I think they are using Encoded Polyline Algorithm, Just have a look at these sites code.google.com/apis/maps/documentation/utilities/… code.google.com/apis/maps/documentation/premier.... –  Nikhil Dinesh Aug 26 '11 at 12:07

You should always check on the android source code for doubts like this.

`````` private static void computeDistanceAndBearing(double lat1, double lon1,
double lat2, double lon2, float[] results) {

int MAXITERS = 20;
// Convert lat/long to radians
lat1 *= Math.PI / 180.0;
lat2 *= Math.PI / 180.0;
lon1 *= Math.PI / 180.0;
lon2 *= Math.PI / 180.0;

double a = 6378137.0; // WGS84 major axis
double b = 6356752.3142; // WGS84 semi-major axis
double f = (a - b) / a;
double aSqMinusBSqOverBSq = (a * a - b * b) / (b * b);

double L = lon2 - lon1;
double A = 0.0;
double U1 = Math.atan((1.0 - f) * Math.tan(lat1));
double U2 = Math.atan((1.0 - f) * Math.tan(lat2));

double cosU1 = Math.cos(U1);
double cosU2 = Math.cos(U2);
double sinU1 = Math.sin(U1);
double sinU2 = Math.sin(U2);
double cosU1cosU2 = cosU1 * cosU2;
double sinU1sinU2 = sinU1 * sinU2;

double sigma = 0.0;
double deltaSigma = 0.0;
double cosSqAlpha = 0.0;
double cos2SM = 0.0;
double cosSigma = 0.0;
double sinSigma = 0.0;
double cosLambda = 0.0;
double sinLambda = 0.0;

double lambda = L; // initial guess
for (int iter = 0; iter < MAXITERS; iter++) {
double lambdaOrig = lambda;
cosLambda = Math.cos(lambda);
sinLambda = Math.sin(lambda);
double t1 = cosU2 * sinLambda;
double t2 = cosU1 * sinU2 - sinU1 * cosU2 * cosLambda;
double sinSqSigma = t1 * t1 + t2 * t2; // (14)
sinSigma = Math.sqrt(sinSqSigma);
cosSigma = sinU1sinU2 + cosU1cosU2 * cosLambda; // (15)
sigma = Math.atan2(sinSigma, cosSigma); // (16)
double sinAlpha = (sinSigma == 0) ? 0.0 :
cosU1cosU2 * sinLambda / sinSigma; // (17)
cosSqAlpha = 1.0 - sinAlpha * sinAlpha;
cos2SM = (cosSqAlpha == 0) ? 0.0 :
cosSigma - 2.0 * sinU1sinU2 / cosSqAlpha; // (18)

double uSquared = cosSqAlpha * aSqMinusBSqOverBSq; // defn
A = 1 + (uSquared / 16384.0) * // (3)
(4096.0 + uSquared *
(-768 + uSquared * (320.0 - 175.0 * uSquared)));
double B = (uSquared / 1024.0) * // (4)
(256.0 + uSquared *
(-128.0 + uSquared * (74.0 - 47.0 * uSquared)));
double C = (f / 16.0) *
cosSqAlpha *
(4.0 + f * (4.0 - 3.0 * cosSqAlpha)); // (10)
double cos2SMSq = cos2SM * cos2SM;
deltaSigma = B * sinSigma * // (6)
(cos2SM + (B / 4.0) *
(cosSigma * (-1.0 + 2.0 * cos2SMSq) -
(B / 6.0) * cos2SM *
(-3.0 + 4.0 * sinSigma * sinSigma) *
(-3.0 + 4.0 * cos2SMSq)));

lambda = L +
(1.0 - C) * f * sinAlpha *
(sigma + C * sinSigma *
(cos2SM + C * cosSigma *
(-1.0 + 2.0 * cos2SM * cos2SM))); // (11)

double delta = (lambda - lambdaOrig) / lambda;
if (Math.abs(delta) < 1.0e-12) {
break;
}
}

float distance = (float) (b * A * (sigma - deltaSigma));
results[0] = distance;
if (results.length > 1) {
float initialBearing = (float) Math.atan2(cosU2 * sinLambda,
cosU1 * sinU2 - sinU1 * cosU2 * cosLambda);
initialBearing *= 180.0 / Math.PI;
results[1] = initialBearing;
if (results.length > 2) {
float finalBearing = (float) Math.atan2(cosU1 * sinLambda,
-sinU1 * cosU2 + cosU1 * sinU2 * cosLambda);
finalBearing *= 180.0 / Math.PI;
results[2] = finalBearing;
}
}
}
``````
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Hi, thanks but it seems to be not what I am asking. I am asking the algorithm which google use to find the shortest route between 2 points. –  IT-Fan Aug 6 '11 at 16:37

To the best of my knowledge Google has never publicly stated which algorithm it uses of P2P queries. Although the current state of the art from the literature in terms of query times is the Hub labelling algorithm proposed by Abraham et al. http://link.springer.com/chapter/10.1007/978-3-642-20662-7_20 . A through and excellently written survey of the field was recently published as a Microsoft technical report http://research.microsoft.com/pubs/207102/MSR-TR-2014-4.pdf .

The short version is...

The Hub labelling algorithm provides the fastest queries for static road networks but requires a large amount of ram to run (18 GiB).

Transit node routing is slightly slower, although, it only requires around 2 GiB of memory and has a quicker preprocessing time.

Contraction Hierarchies provide a nice trade off between quick preprocessing times, low space requirements (0.4 GiB) and fast query times.

No one algorithm is completely dominate...

This Google tech talk by Peter Sanders may be of interest

Also this talk by Andrew Goldberg

An open source implementation of contraction hierarchies is available from Peter Sanders research group website at KIT. http://algo2.iti.kit.edu/english/routeplanning.php

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The geometry library in google maps api provide the algorithm, you can find it in the source code.

I'm not sure if google map use the same algorithm.

The algorithm is simple:

``````function toRadians(deg){
return deg * (Math.PI / 180);
}

function getDistance(from, to) {
var c = toRadians(from.lat()),
return 2 * Math.asin(Math.sqrt(Math.pow(Math.sin((c - d) / 2), 2) + Math.cos(c) * Math.cos(d) * Math.pow(Math.sin((toRadians(from.lng()) - toRadians(to.lng())) / 2), 2))) * 6378137;
``````

}

These two lines of codes would have the same result:

``````console.log(google.maps.geometry.spherical.computeDistanceBetween(new google.maps.LatLng(39.915, 116.404), new google.maps.LatLng(38.8871, 113.3113)));