Here's a method to try: an iterative search using a simulated repulsive force.

**Algorithm**

First initialize the data set by arranging the circles across the surface in any kind of algorithm. This is just for initialization, so it doesn't have to be great. The periodic table code will do nicely. Also, assign each circle a "mass" using its radius as its mass value.

Now begin the iteration to converge on a solution. For each pass through the main loop, do the following:

Compute repulsive forces for each circle. Model your repulsive force after the formula for gravitational force, with two adjustments: (a) objects should be pushed *away* from each other, not attracted toward each other, and (b) you'll need to tweak the "force constant" value to fit the scale of your model. Depending on your math ability you may be able to calculate a good constant value during planning; other wise just experiment a little at first and you'll find a good value.

After computing the total forces on each circle (please look up the n-body problem if you're not sure how to do this), move each circle along the vector of its total calculated force, using the length of the vector as the distance to move. This is where you may find that you have to tweak the force constant value. At first you'll want movements with lengths that are less than 5% of the radius of the sphere.

The movements in step 2 will have pushed the circles off the surface of the sphere (because they are repelling each other). Now move each circle back to the surface of the sphere, in the direction toward the center of the sphere.

For each circle, calculate the distance from the circle's old position to its new position. The largest distance moved is the movement length for this iteration in the main loop.

Continue iterating through the main loop for a while. Over time the movement length should become smaller and smaller as the relative positions of the circles stabilize into an arrangement that meets your criteria. Exit the loop when the movement legth drops below some very small value.

**Tweaking**

You may find that you have to tweak the force calculation to get the algorithm to converge on a solution. How you tweak depends on the type of result you're looking for. Start by tweaking the force constant. If that doesn't work, you may have to change the mass values up or down. Or maybe change the exponent of the radius in the force calculation. For example, instead of this:

```
f = ( k * m[i] * m[j] ) / ( r * r );
```

You might try this:

```
f = ( k * m[i] * m[j] ) / pow( r, p );
```

Then you can experiment with different values of p.

You can also experiment with different algorithms for the initial distribution.

The amount of trial-and-error will depend on your design goals.