**I'm going to recommend against this, now**

See the discussion below.

## Original thoughts

I would consider an iterative push-pull method.

- Guess where to put the center (simplest would be the mean position of all centers)
- Compute the vectors to the farthest point on each circle. These are always in the direction to the center of that circle and have length
`distance_to_center_of_circle[i]+radius_of_circle[i]`

and form the vector sum as you go. Also note that the necessary radius at the current location is the maximum of these lengths.
- Propose a step of (say) 1/5 or 1/10 of the vector sum from 2, and redo the computations from 2 for the new point
- If the new point needs a smaller circle than the old, make the new point the current point, otherwise, split the difference, reduce the size of the proposed step (say half it).
- goto 3

You're done when it stops[+] converging.

## Nikie poked at it until...

As requested clarifying step two. Call the position to be tested `\vec{P}`

(a vector quantity).[++] Call the centers of each circle `\vec{p}_i`

(also vector quantities) and the radius of each circle is `r_i`

. Form the sum `\sum_i=1^n \hat{p_i - P}*|(p_i-P)|+r_i)`

.[+++] Each element of the sum points in the direction from the current evaluation point towards the center of the circle in question, but is longer by `r_i`

. The sum itself it a vector quantity.

The radius `R`

need to enclose all the circle from `P`

is the `max(|p_i-P|_r_i)`

.

## Pathological case

I don't think the particular case nikie's brought up is a problem, but it has put me onto a case where this algorithm fails. The failure is one of failing to improve a solution, rather than one of diverging, but still...

Consider four circles all of radius 1 positioned at

```
(-4, 1)
(-5, 0)
(-4, 1)
( 5, 0)
```

and a starting position of `(-1, 0)`

. Symmetric by design so that all distances lie along the x axis.

The correct solution is `(0, 0)`

with radius 6, but the vector calculated in step 2 be about ::calculates furiously:: `(-.63, 0)`

, pointing in the wrong direction resulting in never finding the improvement towards the origin.

Now, the algorithm above would actual pick `(-2, 0)`

for the starting point, which gives an initial vector sum of ::calculates furiously:: about +1.1. So, a bad choice of step size on (3) would result in a less than optimal solution. ::sigh::

Possible solution:

- In (3) throw a random fraction between (say +1/5 and -1/5) possibly weighted towards the positive size.
- In (4) if the step is rejected, simply return to step three without altering the step size limits.

However, at this point it is not much better than a pure random walk, and you don't have an easy condition for knowing when it has converged. Meh.

[+] Or slows to your satisfaction, of course.
[++] Using latex notation.
[+++] Here `\hat{}`

means the normalized vector pointing in the same direction as the argument.

professionals. They don't want questions like this one. – balpha♦ Jan 18 '10 at 8:36willbecome code, so the questions is good for SO. – dmckee Jan 19 '10 at 3:58