Hmm, very interesting problem. My approach would probably be something along the lines of the following:

- Work out a way of working out what the areas of intersection between an arbitrary number of circles is, i.e. if I have 3 circles, I need to be able to work out what the intersection between those circles is. The "Monte-Carlo" method would be a good way of approximating this (http://local.wasp.uwa.edu.au/~pbourke/geometry/circlearea/).
- Eliminate any circles that are contained entirely in another larger circle (look at radius and the modulus of the distance between the centre of the two circles) I dont think is mandatory.
- Choose 2 circles (call them A and B) and work out the total area using this formula:

(this is true for any shape, be it circle or otherwise)

```
area(A∪B) = area(A) + area(B) - area(A∩B)
```

Where `A ∪ B`

means A union B and `A ∩ B`

means A intersect B (you can work this out from the first step.

- Now keep on adding circles and keep on working out the area added as a sum / subtraction of areas of circles and areas of intersections between circles. For example for 3 circles (call the extra circle C) we work out the area using this formula:

(This is the same as above where `A`

has been replaced with `A∪B`

)

```
area((A∪B)∪C) = area(A∪B) + area(C) - area((A∪B)∩C)
```

Where `area(A∪B)`

we just worked out, and `area((A∪B)∩C)`

can be found:

```
area((A∪B)nC) = area((A∩C)∪(B∩C)) = area(A∩C) + area(A∩B) - area((A∩C)∩(B∩C)) = area(A∩C) + area(A∩B) - area(A∩B∩C)
```

Where again you can find area(A∩B∩C) from above.

The tricky bit is the last step - the more circles get added the more complex it becomes. I believe there is an expansion for working out the area of an intersection with a finite union, or alternatively you may be able to recursively work it out.

Also with regard to using Monte-Carlo to approximate the area of itersection, I believe its possible to reduce the intersection of an arbitrary number of circles to the intersection of 4 of those circles, which can be calculated exactly (no idea how to do this however).

There is probably a better way of doing this btw - the complexity increases significantly (possibly exponentially, but I'm not sure) for each extra circle added.