I'm trying to reduce and combine a number of points to the center point of those locations. Right now I'm brute-forcing it by finding the closest pair, combining those and repeating until I've reduced it to my target (side note: actually I reduced the problem by sorting by `(lat*lat+long*long)`

then searching 10% on either side of each point, which with my tests has always found the shortest distance within that range).

For an example I'd want to reduce 4000 points down to 1000, ideally combining the closest points into the center of those closest points. Basically to build marker points that reflect the number of addresses in that area.

Is there any better algorithm that would give me as accurate as possible results? Or a quicker distance algorithm? I guess it does only need to be accurate at short distances

Right now I'm finding the distance with (Wikipedia had it under "spherical earth projected to a plane"):

```
double dLat = pos2.LatitudeR - pos1.LatitudeR;
double dLon = pos2.LongitudeR - pos1.LongitudeR;
double cosLatM = Math.Cos((pos2.LatitudeR + pos1.LatitudeR)/2) * dLon;
double a = dLat*dLat + cosLatM*cosLatM;
```

I've thought about grouping all the points within x distance of each other, then expanding x until I get to my target number of final points, but I'm not sure how to make that as accurate as my perfectionism would want it. That is all the ways I can think of would vary slightly depending on the order of the input list of points.

Edit to describe how my current algorithm processes (This is the ideal way to find the results I want, but an approximation that is much quicker would be worth it):

Describing it linearly, if you had `x=1,4,5,6,10,20,22`

- It would combine 4+5=4.5 [first 1.0 distance it finds]
- (4.5*2+6)/3=5 --
`x=1,5,10,20,22`

[1.5 distance] - 20+22=21 --
`x=1,5,10,21`

[2.0 distance] - (5*3+1)/4=4 --
`x=4,10,21`

[4.0 distance] - (4*4+10)/5.2 -- So you'd end up with
`x=5.2,21`

. (It keeps track of the CombineCount so it can find the correct average center in this way)

**Results:**
Here is my current Distance function, with lookup table generation for cos^2. Haven't had time to check how close together my points are, so haven't implemented Joey's suggestion of approximating the cos^2, but that could improve the speed over the lookup table here.

The K-Cluster algorithm I tried (see my comment on that answer) did not combine them as I wanted, it ended up with a ton of points near the center of the map and few points toward the edges. So unless I can correct that I'm using my algorithm which is slower.

```
public static double Distance(AddressCoords pos1, AddressCoords pos2, DistanceType type)
{
if (LookupTable == null) LookupTable = BuildLookup();
double R = (type == DistanceType.Miles) ? 3960 : 6371;
double dLat = pos2.LatitudeR - pos1.LatitudeR;
double dLon = pos2.LongitudeR - pos1.LongitudeR;
double LatM = ((pos2.LatitudeR + pos1.LatitudeR)/2);
if (LatM < 0) LatM = -LatM; //Don't allow any negative radian values
double cosLatM2 = LookupTable[(int)(LatM * _cacheStepInverse)];
double a = dLat*dLat + cosLatM2 * dLon*dLon;
//a = Math.Sqrt(a);
double d = a * R;
return d;
}
private const double _cacheStep = 0.00002;
private const double _cacheStepInverse = 50000;
private static double[] LookupTable = null;
public static double[] BuildLookup()
{
// set up array
double maxRadian = Math.PI*2;
int elements = (int)(maxRadian * _cacheStepInverse) + 1;
double[] _arrayedCos2 = new double[elements];
int i = 0;
for (double angleRadians = 0; angleRadians <= maxRadian;
angleRadians += _cacheStep)
{
double cos = Math.Cos(angleRadians);
_arrayedCos2[i] = cos*cos;
i++;
}
return _arrayedCos2;
}
```