# Find a point that maximizes total distance from a set of points within a bounded area

Given a set of points `p`, I would like to find a point within the space `b` that bounds the region of `p` that is as far distant as possible from all points within `p`.

This is in regards to implementing neighbor avoidance in a flocking simulation as per Craig Reynolds' Boids - if this isn't the best way to avoid neighbors I would love suggestions.

EDIT: In other words, I'd like to find an arbitrary point that is as far from the other points in `p` as possible, while remaining within the bounding box around `p`.

By bounding box I mean the solution should be a point that has a y-coordinate that is between the upper and lowermost points, and an x coordinate that is between the left and rightmost points.

To put the question more abstractly, I am looking at this algorithm as a way to find a target for an agent that wants to stay within `M` units of its nearest neighbors while not getting closer than `m` units of them. The solution returned by this algorithm should return a point that has the largest distance between it and its closest neighbor.

This is in a 2D plane.

-
That is, find the point `p'` inside `b` for which the sum of all squared distances to all other points is minimal? Try least squares? –  zerm Nov 29 '11 at 17:04
zerm: You have it backwards - he wants to maximize the sum of distances. My sense is that minimizing the appropriate dual problem ought to work nicely, if you can set it up. –  Novelocrat Nov 29 '11 at 17:14
Another solution would be to maximize the nearest-neighbour distance. Could you please specify your problem more concretely, javanix? –  thiton Nov 29 '11 at 17:34
I'd also expect the energy landscape of the sum of distances function to be very bad for iterative fitting - with maxima close to edges and all. –  thiton Nov 29 '11 at 17:35
what exactly do yo mean by bounding box? The convex hull of the points? Is this in a two dimensional plane (since you are talking about area)? You are not very specific. –  Thomas Nov 29 '11 at 17:42