Given four spheres L, M, N, O - with initial radius rL, rM, rN, rO and centers cL, cM, cN, cO and common additional radius "a".

L intersects M when

```
Distance(cL, cM) <= rL + rM + 2a
```

With four spheres, there's these possible constraints.

```
//at least one of
Distance(cL, cM) <= rL + rM + 2a
Distance(cL, cN) <= rL + rN + 2a
Distance(cL, cO) <= rL + rO + 2a
//and at least one of
Distance(cM, cL) <= rM + rL + 2a
Distance(cM, cN) <= rM + rN + 2a
Distance(cM, cO) <= rM + rO + 2a
//and at least one of
Distance(cN, cL) <= rN + rL + 2a
Distance(cN, cM) <= rN + rM + 2a
Distance(cN, cO) <= rN + rO + 2a
//and at least one of
Distance(cO, cL) <= rO + rL + 2a
Distance(cO, cM) <= rO + rM + 2a
Distance(cO, cN) <= rO + rN + 2a
```

But that's "writing tedious math equations for all spheres".

Here's a short (n^2) implementation in c# with Linq.

```
decimal aResult =
(
from left in spheres
from right in spheres
let dist = Distance(left.Center, right.Center)
let aRaw = (dist - left.startRadius - right.startRadius)/2
let a = aRaw < 0 ? 0 : aRaw //spheres might start out touching!
group a by left into g
select g.Min() //the smallest extra radius for each group
).Max();
//the largest extra radius that makes at least one equation true for each group.
// any smaller, and there exists a disconnected sphere with no true equation.
```

It should be possible to prune the matchings using prior calculations to beat n^2.

Analogous to the 2D case, where 3 circles may mutually intersect the other two without having a common area intersected by all 3 circles.

Oh, well that's a different problem. Hmm.

Suppose you have three oranges arranged in a triangle lying flat on the surface of the earth. Each sphere touches the other three, yet there is no common point shared by all four spheres.

You want the smallest "a" such that a common point (x, y, z) exists.

```
//all must be true
(x - cL)^2 + (y - yL)^2 + (z - zL)^2 <= (a + rL)^2
(x - cM)^2 + (y - yM)^2 + (z - zM)^2 <= (a + rM)^2
(x - cN)^2 + (y - yN)^2 + (z - zN)^2 <= (a + rN)^2
(x - cO)^2 + (y - yO)^2 + (z - zO)^2 <= (a + rO)^2
```

`a`

the spheres will be disjoint. – Kerrek SB Nov 3 '11 at 2:57