The first comment from Amit is your answer. I'll explain why.

Let `p_i`

be your points of intersection and `c = 1/n sum(p_i)`

. Let's show that `c`

minimizes the average distance, `d(a)`

between the `p_i`

and an arbitrary point `a`

:

```
d(a) = 1/n sum( |a-p_i|^2 )
```

What is being averaged in `d(a)`

is, using inner product notation,

```
|a-p_i|^2 = <a-p_i, a-p_i> = |a|^2 + |p_i|^2 - 2<a,p_i>`
```

The average of `<a,p_i>`

is just `<a,c>`

, using the bilinear properties of dot product. So,

```
d(a) = |a|^2 - 2<a,c> + 1/n sum( |p_i|^2 )
```

And so likewise

```
d(c) = |c|^2 - 2<c,c> + 1/n sum( |p_i|^2 ) = -|c|^2 + 1/n sum( |p_i|^2 )
```

Subtracting the two

```
d(a) - d(c) = |a|^2 - 2<a,c> + |c|^2 = |a-c|^2
```

So, adding `d(c)`

to both sides, the average distance to an arbitrary point `a`

is

```
d(a) = d(c) + |a-c|^2
```

which since all terms are positive is minimized when `|a-c|^2`

is zero, in other words, when `a = c`

.