**TL;DR** One optimal solution is as follows:

```
[{x: 0, y: 0},
{x: 0, y: 0.22222},
{x: 0, y: 0.44444},
{x: 0, y: 0.66667},
{x: 0, y: 0.88889},
{x: 0.11111, y: 1},
{x: 0.33333, y: 1},
{x: 0.55556, y: 1},
{x: 0.77778, y: 1},
{x: 1, y: 1}]
```

Long explanation: You can solve this problem as a mixed integer program (although the name is slightly misleading in this case as there are no integers). The basic model is very simple:

where *P* is the set of points. The individual points need to be constrained to lie within the unit square:

The objective is then:

There are many equivalent solutions for this problem, you can for example get another solution from one solution by rotating the square. To make solving it easier, we can break some of the symmetries by imposing an order on the points: the coordinates of each point must be at least as high as the ones of its predecessor.

This means that we can now use Manhattan distance instead of Euclidean and don't have to worry about negative numbers when computing the difference between coordinates, which removes the nasty squares:

Input the model into your favourite MIP system and out comes a solution like the above with smallest Manhattan distance between points at 0.22222. Note that, as I've mentioned, you can rotate the square to get a different, but equivalent solution.