Here is a little Mathematica program.

Although it is only two lines of code (**!**) you'll probably need more in a conventional language, as well as a math library able to find maximum of functions.

I assume you are not fluent in Mathematica, so I'll explain and comment line by line.

First we create a table with 10 random points in {0,1}x{0,1}, and name it **p**.

```
p = Table[{RandomReal[], RandomReal[]}, {10}];
```

Now we create a function to maximize:

```
f[x_, y_] = Min[ x^2,
y^2,
(1 - x)^2,
(1 - y)^2,
((x - #[[1]])^2 + (y - #[[2]])^2) & /@ p];
```

Ha! Syntax got tricky! Let's explain:

The function gives you for any point in {0,1}x{0,1} the **minimum distance** from that point to our set p AND the edges. The first four terms are the distances to the edges and the last (difficult to read, I know) is a set containing the distance to all points.

What we will do next is **maximizing** this function, so we will get THE point where the minimum distance to our targets in maximal.

But first lets take a look at f[]. If you look at it critically, you'll see that it is not really the distance, but the distance squared. I defined it so, because that way the function is much easier to maximize and the results are the same.

Also note that f[] is not a "pretty" function. If we plot it in {0,1}, we get something like:

That's why you will need a nice math package to find the maximum.

Mathematica is such a nice package, that we can maximize the thing straightforward:

```
max = Maximize[{f[x, y], {0 <= x <= 1, 0 <= y <= 1}}, {x, y}];
```

And that is it. The Maximize function returns the point, and the squared distance to its nearest border/point.

HTH! If you need help translating to another language, leave a comment.

**Edit**

Although I'm not a C# person, after looking for references in SO and googling, came to this:

One candidate package is DotNumerics

You should follow the following example provided in the package:

```
file: \DotNumerics Samples\Samples\Optimization.cs
Example header:
[Category("Constrained Minimization")]
[Title("Simplex method")]
[Description("The Nelder-Mead Simplex method. ")]
public void OptimizationSimplexConstrained()
```

HTH!