## Game Plan

The following is basically just a more precise restatement of your problem, but it might help:

- Enumerate every connected region in the plane that results when the boundaries of all disks are drawn. By assumption, each of these regions is covered by 1 or more disks.
- Each region is a "thing to be covered", and each disk is a "covering thing". Find the minimum set cover on this set of regions. This is NP-hard unfortunately.

This might not be exploiting all the structure available in the problem, but it will definitely give you an optimal answer.

## Enumerating Regions

Enumerating the regions and recording which disks cover each in step 1 is the tricky part. Regions are not in general convex which makes intersection tests tricky, and every circle you add potentially doubles the number of regions. Here is how I would approach that:

Forget about the actual location of each region, and define a region only in terms of which disks it is inside and which it is outside. I.e. a region is defined by a length-n vector of 0/1 values, each indicating whether the region inside or outside that disk is to be included in the intersection -- the region in question is formed by intersecting all these n regions. So in principle you could have up to 2^n regions, but in practice some (most) vectors produce empty regions because they entail intersecting two disks that have no intersection -- this is easy to test for, thankfully. It should be straightforward to recursively generate all non-empty regions, except that...

## Bad News

Unfortunately I now see that it *is* necessary to perform full intersection testing, because it's not always possible to tell when a region will be empty. The critical counterexample is that, given two disks A and B that have a small sliver of overlap and another disk C that overlaps each of A and B, depending on the positions of all 3 disks, the intersection of all 3 either may or may not be non-empty. (To see this, draw 3 disks in different colours with 50% opacity in a drawing program, and move them around.)

## A Workable Hack

Since generating the exact list of non-empty regions looks like it will be a lot of work and take a long time due to intersection testing, and you claim you don't need optimal solutions, you could try just using a grid of sample points as the set of "things to be covered" instead of the exact list of non-empty regions. It's straightforward to determine which disks cover a given sample point. Then solve maximum set cover as before.

To get confidence that there are no gaps, rerun several times, randomly jittering the sample points' co-ordinates each time. Increase the density of sample points until there is no change in the final result.