# Calculating the distance between 2 latitudes and longitudes that are saved in a text file?

I've looked around and still couldn't find anything to help me really! I've written a program to calculate the distance between 2 cities using their Latitudes and Longitudes, the cities details are saved in a file then loaded in my program into a BST! So far everything works fine except when i run the codes that is suppose to calculate the distance i get the same answer for every cities! Am not quite sure as to why i keep getting the same answer for every cities! Please help point me into the right direction?

here are the codes to calculate the distance

``````#include <cmath>
#define pi 3.14159265358979323846

string userResponse;
float globalLat1, globalLon1, globalLat2, globalLon2;

for(int j= 0; j < 2; j++){
string whatever;
if (j==0){
bool hasbeenfound = false;
do{
//ask the user to enter their first city of their choice
whatever = "first ";
cout << "Enter your " + whatever + "City" << endl;
cout << "-------------------" << endl;
cin >> userResponse;
cout << endl;
if (Cities->search(userResponse)) //check if the entered city already exist
{
hasbeenfound = true;
}
else{
cout << endl;
}
//globalCity1 = Cities->sRootName;
globalLat1 = Cities->sLatitude;
globalLon1 = Cities->sLongitude;
}
while(hasbeenfound == false); //while the entered city hasn't been found, repeat the process

}else
{
bool hasbeenfound = false;
do{
//ask the user to enter their second city of their choice
whatever = "second ";
cout << endl;
cout << "Enter your " + whatever + "City" << endl;
cout << "-------------------" << endl;
cin >> userResponse;
cout << endl;
if (Cities->search(userResponse)) //check if the entered city already exist
{
hasbeenfound = true;
}
else{
}
//globalCity2 = Cities->sRootName;
globalLat2 = Cities->sLatitude;
globalLon2 = Cities->sLongitude;
}
while(hasbeenfound == false); //while the entered city hasn't been found, repeat the process

}
}

// This function converts decimal degrees to radians
return (deg * pi / 180);
};

//  This function converts radians to decimal degrees
return (rad * 180 / pi);
};

//distance calculations
cout << endl;
distan = distan * 60 * 1.1515;
distan = (6371 * pi * distan)/180;
cout << "The Distance between the to cities is: " << distan << " kilometers" << endl;
``````
• The most important part is missing... How you populate `globalLat/Lon/1/2`.
– Joe
Commented Apr 17, 2012 at 20:55
• may i ask what you mean by "populate"?
– Ange
Commented Apr 17, 2012 at 20:57
• @Kap The code with which you populate them is the important thing, since that's almost certainly where the error is. (Apart from minor glitches in the formula.) Commented Apr 17, 2012 at 21:09
• @Kap: try using some `printf()` debugging: Add `printf("distan(%f, %f, %f, %f) == %f\n", globalLat1, globalLat2, globalLon1, globalLon2, distan);` just after your calculation of `distan` and see if the output shows anything interesting. Commented Apr 17, 2012 at 21:17
• @RobKennedy - these are the only codes that is supposed to get the cities Lonand Lat then do the calculations. `Cities->search` does find the city when i run the program! I just checked and as you mentioned it seems that the latitudes and longitudes aren't being stored as i was hoping. Thanks for pointing that out for me!
– Ange
Commented Apr 17, 2012 at 21:50

``````#include <math.h>
#include <cmath>

// This function converts decimal degrees to radians
return (deg * M_PI / 180);
}

//  This function converts radians to decimal degrees
return (rad * 180 / M_PI);
}

/**
* Returns the distance between two points on the Earth.
* Direct translation from http://en.wikipedia.org/wiki/Haversine_formula
* @param lat1d Latitude of the first point in degrees
* @param lon1d Longitude of the first point in degrees
* @param lat2d Latitude of the second point in degrees
* @param lon2d Longitude of the second point in degrees
* @return The distance between the two points in kilometers
*/
double distanceEarth(double lat1d, double lon1d, double lat2d, double lon2d) {
double lat1r, lon1r, lat2r, lon2r, u, v;
u = sin((lat2r - lat1r)/2);
v = sin((lon2r - lon1r)/2);
return 2.0 * earthRadiusKm * asin(sqrt(u * u + cos(lat1r) * cos(lat2r) * v * v));
}
``````
• This is the correct answer and the results are also matching with Online Distance Calculator written in Javascript. Commented Jul 10, 2015 at 12:23
• can you also get bearing by adding a few lines to this? thanks Commented Jan 17, 2016 at 0:17

Using `boost.geometry`

``````typedef boost::geometry::model::point<
double, 2, boost::geometry::cs::spherical_equatorial<boost::geometry::degree>
> spherical_point;

spherical_point p(lon1_degree, lat1_degree);
spherical_point q(lon2_degree, lat2_degree);
double dist = boost::geometry::distance(p, q);
double const earth_radius = 6371.0; // Km
``````

for people who need in swift:

``````  // Haversine formula:

func deg2rad(_ deg: Double) ->Double {
return deg * Double.pi  / 180.0
}

func distanceEarth(lat1d: Double, lon1d: Double, lat2d: Double, lon2d: Double) ->Double {

let u = sin((lat2r - lat1r)/2);
let v = sin((lon2r - lon1r)/2);
return 2.0 * earthRadiusKm * asin(sqrt(u * u + cos(lat1r) * cos(lat2r) * v * v));
}

//test here.... https://andrew.hedges.name/experiments/haversine/

func doTestHaversine(){

let km = distanceEarth(lat1d: 38.898556, lon1d: -77.037852, lat2d: 38.897147, lon2d: -77.043934)
print(km)  // should show : 0.549 or similar..
}
``````

This is the method that I would use for finding the distance

Or this, not concidering the "bend" of the Earth

• It's subtraction, multiplication, addition, and square root, Kap. Which part of "that" do you need to know how to do? Commented Apr 17, 2012 at 21:01
• This is the formula for the Euclidian distance, it doesn't apply to the Earth since it's not a linear. The lat/long space is not a plane. Commented Apr 17, 2012 at 21:02
• @Spidey: you'll never convince those flat-earthers. Commented Apr 17, 2012 at 21:05
• You don't have x,y,z. You have latitude and longitude, a coordinate system where one of the coordinates is not parallel, on a spherical surphace to boot. Neither of your formulas works. Commented Apr 17, 2012 at 21:08
• @Kap First, the earth is kind of spherical, second, the parallels are curved on the spherical surface because they are not the shortest line between two points (the definition of straight). The meridians are. A useful formula has to take this into account. The first formula above can be a useful approximation when the distance isn't too big. Commented Apr 17, 2012 at 21:18