Strictly, you'd want to use the Haversine formula.

However, while you could perhaps be just slightly out in far northern or far southern points, you could probably get by by pretending that Mercator projections are accurate for distance, and ignoring the curvature of the earth. This is especially true if you are going to have lots of cities, as the error is greater, the further points are from the target point. Hence you would just use Pythagoras':

```
relDist = √((xLat - yLat) × (xLat - yLat) + (xLng - yLng) × (xLng - yLng))
```

But since you only care about (and only get) a relative ordering, you can skip the square-root bit, which is the heaviest step:

```
relDist = (xLat - yLat) × (xLat - yLat) + (xLng - yLng) × (xLng - yLng)
```

As well as being faster in and of itself, it can also be reasonably preformed on integers, should you store your coordinates as multiples of the actual coordinate (e.g. storing New York's (40.664167, -73.938611) as the pair (406642, -739386). This can be a big boost if you want to quickly sort a large number of places in order of proximity to a given point.

If however you really care about precision in the face of the fact that the earth is round, then the following implements Haversine:

```
private const double radiusE = 6378135; // Equatorial radius
private const double radiusP = 6356750; // Polar radius
private const double radianConv = 180 / Math.PI;
public static double GetDistanceBetweenPoints(double lat1, double long1, double lat2, double long2)
{
double dLat = (lat2 - lat1) / radianConv;
double dLong = (long2 - long1) / radianConv;
double a = Math.Sin(dLat / 2) * Math.Sin(dLat / 2) + Math.Cos(lat2) * Math.Sin(dLong/2) * Math.Sin(dLong/2);
return Math.Sqrt((Math.Pow(radiusE * radiusP * Math.Cos(lat1 / radianConv), 2)) / (Math.Pow(radiusE * Math.Cos(lat1 / radianConv), 2) + Math.Pow(radiusP * Math.Sin(lat1 / radianConv), 2))) * (2 * Math.Atan2(Math.Sqrt(a), Math.Sqrt(1 - a)));
}
```