*complete rewrite:*

I have an array of integers (I'm calling them points) of length N (they represent indexes into an array). I want to pick X points from the N values where X < N such that the points are the most equidistant as possible. I've had trouble defining how to measure that, but I think variance is the key now.

For example, the ideal path is:

```
[5, 10, 15, 20] (distance is 5)
```

If you prefer, you can think of them as 2D points:

```
[(0, 5), (1, 10), (2, 15), (3, 20)]
```

But my actual N values to choose from may be something like:

```
[4, 6, 10, 13, 15, 17, 21]
```

And I want to select X (4 in this example) where their distances to each other are "the most equidistant". At the moment, I'm defining that as "the smallest variance when the distance is compared to the ideal distance," but am open to other definitions.

I think that's enough to describe my problem sufficiently. The rest that follows describes how I get to this point, which does have some assumptions about optimizing the equidistance:

I'm currently trimming my selection of points by looking at the ideal points/distances and removing any points as candidates that are outside of a given threshold.

e.g.,

If my width is 10 and I want two points, my ideal list of points is [10, 20]. But I may have [1, 9, 22, 25, 1000] available. If my (somewhat arbitrary) trim threshold is 5, I remove 1 and 1000, leaving me [9, 22, 25] (and an eventual answer of [9, 22])

I also *expand* the list of points if needed if there is nothing near the ideal point. So if I have a threshold of 5, width of 10 and only have [1, 21], then I will add in a 10 due to having no candidates near 10. 1 is thrown out due to trimming. The eventual answer would be [10, 21]

Here's a graphical representation as I'm realizing now geometry is a large component and why I also gave a 2D representation. In the following picture the blue line is the ideal equidistant selection of points. The error bars represent the trimming threshold. (All other points trimmed are not represented)

Now, how do I select the 5 points in this graph that most closely approximates the blue line?

I have an O(N!) answer below.

**Example for furins:**

Let's say our ideal is [ 10, 20, 30, 40, 50] and our existing points are [10,15,25,32,39,42,50]. Our existing points give us these possible combinations of paths, with threshold=5.

(20 could be replaced with 15 or 25, 30 can only be replace with 32, 40 could be replaced with 39 or 42)

```
[ 10, 15, 32, 39, 50 ] -> widths: 5, 17, 7, 11
[ 10, 15, 32, 42, 50 ] -> widths: 5, 17, 10, 8
[ 10, 25, 32, 39, 50 ] -> widths: 15, 7, 7, 11
[ 10, 25, 32, 42, 50 ] -> widths: 15, 7, 10, 8
```

Can't use average width to pick the best -- I get the same values, so I use variance to compare them. Variance from desired width sum of (width-10)^2:

```
(10-5)^2 + (10-17)^2 + (10-6)^2 + (10-12)^2 = 25 + 49 + 9 + 1 = 84
... = 25 + 49 + 0 + 4 = 79
... = 25 + 9 + 9 + 1 = 44
... = 25 + 9 + 0 + 2 = 36
```

To me, the optimal spacing is the last one with the smallest variance, 36. But 36 uses 42, not 39 -- 39 is the closest to 40. So this tells me you need to look beyond just the closest points to the ideal and how that points affects points beyond.

threshold of 5, width of 10 and only have [1, 21]why do you trim 1 and keep 21? Is [1,11] an acceptable answer as well? For the same reason, when you sayIf my width is 10 and I want two points, my ideal list of points is [10, 20]why [0,10] or [3,13] are not ideal answers? – furins Jan 9 '14 at 20:15