The solution really depends on what you are actually looking for.

If you seek the average position of all points in a shape, then averaging them does indeed give you that. But it can be far off from the point which you'd intuitively say is "in the middle". For example, consider a box where one side has twice as many vertices as the opposite side. The average position would be on the half of that side, not in the middle of the box.

More likely, I'd say you are looking for the point defined by calculating the max and min bounds in each dimension and then averaging the two. Because you tagged this with C++, here's some example code:

```
// Define max and min
double max[DIMENSIONALITY];
double min[DIMENSIONALITY];
// Init max and min to max and min acceptable values here. (see numeric_limits)
// Find max and min bounds
for(size_t v_i = 0; v_i < num_vertices; ++v_i)
{
for(int dim = 0; dim < DIMENSIONALITY; ++dim)
{
if(shape[v_i][dim] < min[dim]) min[dim] = shape[v_i][dim];
if(shape[v_i][dim] > max[dim]) max[dim] = shape[v_i][dim];
}
}
// Calculate middle
double middle[DIMENSIONALITY];
for(int dim = 0; dim < DIMENSIONALITY; ++dim)
middle[dim] = 0.5 * (max[dim] + min[dim]);
```

For either solution, the dimensionality of the problem doesn't matter.

**Edit:**
As pointed out in the comment below, this may result in a middle point which lies outside of the shape itself. If you need a point which lies **inside** the shape, an alternative approach must be used. A simple solution could be to use ray-marching across each axis.

manyways to define what "center" means. Saying "approximate center" isn't enough information to know what you're asking for. – Nicol Bolas Dec 4 '12 at 8:56