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haversine_salvador (v27)

Revision 27 of this benchmark created on January 28, 2016

Description

Different haversine formulas

Setup

function deg2rad(deg) {
      return deg * Math.PI / 180
    }

Test runner

Ready to run.


function distance(lat1, lon1, lat2, lon2) {
  var R = 6371; // Radius of the earth in km
  var dLat = deg2rad(lat2 - lat1); // deg2rad below
  var dLon = deg2rad(lon2 - lon1);
  var a =
    Math.sin(dLat / 2) * Math.sin(dLat / 2) +
    Math.cos(deg2rad(lat1)) * Math.cos(deg2rad(lat2)) *
    Math.sin(dLon / 2) * Math.sin(dLon / 2);

  var c = 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a));
  var d = R * c; // Distance in km
  return d;
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2) {
  var R = 6371;
  var dLat = deg2rad(lat2 - lat1);
  var dLon = deg2rad(lon2 - lon1);
  var a =
    0.5 - Math.cos(dLat) / 2 +
    Math.cos(deg2rad(lat1)) * Math.cos(deg2rad(lat2)) *
    (1 - Math.cos(dLon)) / 2;

  return R * 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a));
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2) {
  var R = 6371; // Radius of the earth in km
  var dLat = (lat2 - lat1) * Math.PI / 180; // deg2rad below
  var dLon = (lon2 - lon1) * Math.PI / 180;
  var a =
    0.5 - Math.cos(dLat) / 2 +
    Math.cos(lat1 * Math.PI / 180) * Math.cos(lat2 * Math.PI / 180) *
    (1 - Math.cos(dLon)) / 2;

  return R * 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a));
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2) {
  var R = 6371; // Radius of the earth in km
  var dLat = (lat2 - lat1) * Math.PI / 180; // deg2rad below
  var dLon = (lon2 - lon1) * Math.PI / 180;
  var a =
    0.5 - Math.cos(dLat) / 2 +
    Math.cos(lat1 * Math.PI / 180) * Math.cos(lat2 * Math.PI / 180) *
    (1 - Math.cos(dLon)) / 2;

  return R * 2 * Math.asin(Math.sqrt(a));
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2) {
  var deg2rad = Math.PI / 180;
  lat1 *= deg2rad;
  lon1 *= deg2rad;
  lat2 *= deg2rad;
  lon2 *= deg2rad;
  var diam = 12742; // Diameter of the earth in km (2 * 6371)
  var dLat = lat2 - lat1;
  var dLon = lon2 - lon1;
  var a = (
    (1 - Math.cos(dLat)) +
    (1 - Math.cos(dLon)) * Math.cos(lat1) * Math.cos(lat2)
  ) / 2;

  return diam * Math.asin(Math.sqrt(a));
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2) {
  var deg2rad = 0.017453292519943295; // === Math.PI / 180
  var cos = Math.cos;
  lat1 *= deg2rad;
  lon1 *= deg2rad;
  lat2 *= deg2rad;
  lon2 *= deg2rad;
  var diam = 12742; // Diameter of the earth in km (2 * 6371)
  var dLat = lat2 - lat1;
  var dLon = lon2 - lon1;
  var a = (
    (1 - cos(dLat)) +
    (1 - cos(dLon)) * cos(lat1) * cos(lat2)
  ) / 2;

  return diam * Math.asin(Math.sqrt(a));
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2) {
  var deg2rad = 0.017453292519943295; // === Math.PI / 180
  var cos = Math.cos;
  lat1 *= deg2rad;
  lon1 *= deg2rad;
  lat2 *= deg2rad;
  lon2 *= deg2rad;
  var a = (
    (1 - cos(lat2 - lat1)) +
    (1 - cos(lon2 - lon1)) * cos(lat1) * cos(lat2)
  ) / 2;

  return 12742 * Math.asin(Math.sqrt(a)); // Diameter of the earth in km (2 * 6371)
}

distance(48, -122, 49, -121);
function distance(lat1, lon1, lat2, lon2){
        var R = 6371; // km
var x = (lon2 - lon1) * Math.cos((lat1 + lat2) / 2);
var y = (lat2 - lat1);
return Math.sqrt(x * x + y * y) * R;
}
distance(48, -122, 49, -121);

Testing in
Test	Ops/sec
1	`function distance(lat1, lon1, lat2, lon2) { var R = 6371; // Radius of the earth in km var dLat = deg2rad(lat2 - lat1); // deg2rad below var dLon = deg2rad(lon2 - lon1); var a = Math.sin(dLat / 2) * Math.sin(dLat / 2) + Math.cos(deg2rad(lat1)) * Math.cos(deg2rad(lat2)) * Math.sin(dLon / 2) * Math.sin(dLon / 2); var c = 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a)); var d = R * c; // Distance in km return d; } distance(48, -122, 49, -121);`	ready
2	`function distance(lat1, lon1, lat2, lon2) { var R = 6371; var dLat = deg2rad(lat2 - lat1); var dLon = deg2rad(lon2 - lon1); var a = 0.5 - Math.cos(dLat) / 2 + Math.cos(deg2rad(lat1)) * Math.cos(deg2rad(lat2)) * (1 - Math.cos(dLon)) / 2; return R * 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a)); } distance(48, -122, 49, -121);`	ready
3	`function distance(lat1, lon1, lat2, lon2) { var R = 6371; // Radius of the earth in km var dLat = (lat2 - lat1) * Math.PI / 180; // deg2rad below var dLon = (lon2 - lon1) * Math.PI / 180; var a = 0.5 - Math.cos(dLat) / 2 + Math.cos(lat1 * Math.PI / 180) * Math.cos(lat2 * Math.PI / 180) * (1 - Math.cos(dLon)) / 2; return R * 2 * Math.atan2(Math.sqrt(a), Math.sqrt(1 - a)); } distance(48, -122, 49, -121);`	ready
4	`function distance(lat1, lon1, lat2, lon2) { var R = 6371; // Radius of the earth in km var dLat = (lat2 - lat1) * Math.PI / 180; // deg2rad below var dLon = (lon2 - lon1) * Math.PI / 180; var a = 0.5 - Math.cos(dLat) / 2 + Math.cos(lat1 * Math.PI / 180) * Math.cos(lat2 * Math.PI / 180) * (1 - Math.cos(dLon)) / 2; return R * 2 * Math.asin(Math.sqrt(a)); } distance(48, -122, 49, -121);`	ready
5	`function distance(lat1, lon1, lat2, lon2) { var deg2rad = Math.PI / 180; lat1 = deg2rad; lon1 = deg2rad; lat2 = deg2rad; lon2 = deg2rad; var diam = 12742; // Diameter of the earth in km (2 * 6371) var dLat = lat2 - lat1; var dLon = lon2 - lon1; var a = ( (1 - Math.cos(dLat)) + (1 - Math.cos(dLon)) * Math.cos(lat1) * Math.cos(lat2) ) / 2; return diam * Math.asin(Math.sqrt(a)); } distance(48, -122, 49, -121);`	ready
6	`function distance(lat1, lon1, lat2, lon2) { var deg2rad = 0.017453292519943295; // === Math.PI / 180 var cos = Math.cos; lat1 = deg2rad; lon1 = deg2rad; lat2 = deg2rad; lon2 = deg2rad; var diam = 12742; // Diameter of the earth in km (2 * 6371) var dLat = lat2 - lat1; var dLon = lon2 - lon1; var a = ( (1 - cos(dLat)) + (1 - cos(dLon)) * cos(lat1) * cos(lat2) ) / 2; return diam * Math.asin(Math.sqrt(a)); } distance(48, -122, 49, -121);`	ready
7	`function distance(lat1, lon1, lat2, lon2) { var deg2rad = 0.017453292519943295; // === Math.PI / 180 var cos = Math.cos; lat1 = deg2rad; lon1 = deg2rad; lat2 = deg2rad; lon2 = deg2rad; var a = ( (1 - cos(lat2 - lat1)) + (1 - cos(lon2 - lon1)) * cos(lat1) * cos(lat2) ) / 2; return 12742 * Math.asin(Math.sqrt(a)); // Diameter of the earth in km (2 * 6371) } distance(48, -122, 49, -121);`	ready
8	`function distance(lat1, lon1, lat2, lon2){ var R = 6371; // km var x = (lon2 - lon1) * Math.cos((lat1 + lat2) / 2); var y = (lat2 - lat1); return Math.sqrt(x * x + y * y) * R; } distance(48, -122, 49, -121);`	ready

Revisions

You can edit these tests or add more tests to this page by appending /edit to the URL.

Revision 1: published by Salvador Dali on February 7, 2014
Revision 2: published by decad on February 8, 2014
Revision 3: published by Salvador Dali on February 9, 2014
Revision 4: published on February 24, 2014
Revision 5: published by Bart on March 7, 2014
Revision 6: published by Salvador Dali on March 7, 2014
Revision 7: published by Bart on March 7, 2014
Revision 8: published on March 26, 2014
Revision 9: published on June 12, 2014
Revision 10: published on June 12, 2014
Revision 11: published on July 9, 2014
Revision 12: published by Vu.Ho on July 31, 2014
Revision 13: published by Ian on February 23, 2015
Revision 14: published on April 10, 2015
Revision 15: published on June 8, 2015
Revision 16: published by abbail on August 13, 2015
Revision 17: published by abbail on August 13, 2015
Revision 18: published on August 13, 2015
Revision 19: published on September 1, 2015
Revision 20: published by shojib on September 30, 2015
Revision 21: published by shojib on September 30, 2015
Revision 23: published by shojib on September 30, 2015
Revision 24: published by shojib on September 30, 2015
Revision 25: published on October 26, 2015
Revision 26: published by some on December 29, 2015
Revision 27: published on January 28, 2016
Revision 32: published by Rails Jack on May 8, 2019