Entirely untested.

What if you took the directions of the lines from the intersections and got the Principle Component

This would get you the direction they're going in. Then create a plane using that direction and an arbitrary point, Project all the points from the plane intersection calculations onto the plane, and find the mean point of these projected points.

Use that mean point and the principle component to define your line.

Something like...

```
class Plane
{
public:
Vector3 Point;
Vector3 Normal;
Line Intersect (const Plane &other);
Vector3 Project (const Vector3 &point);
}
class Line
{
public:
Vector3 Point;
Vector3 Direction;
Line (Vector3 point, Vector3 dir);
};
Vector3 PrincipleComponent (const std::vector<Line> &lines)
{
//You could use the covariance matrix to get this but I will try the interative method on wikipedia.
Vector3 p(1,2,3); //a random vector?
static const int c = 10;
for (int i = 0; i < c; ++i)
{
Vector3 t;
for (auto i = lines.begin(); i != lines.end (); ++i)
{
t = t + ((*i).Direction.Dot (p)) * (*i).Direction;
}
t.Normalize();
p = t;
}
return p;
}
int main ()
{
std::vector<Line> LinesFromPlaneIntersections;
Vector3 direction = PrincipleComponent (LinesFromPlaneIntersections);
Plane projplane;
projplane.Normal = direction;
projplane.Point = LinesFromPlaneIntersections[0].Point;
Vector3 meanpoint;
for (auto i = LinesFromPlaneIntersections.begin(); i != LinesFromPlaneIntersections.end (); ++i)
{
meanpoint += projplane.Project ((*i).Point);
}
meanpoint /= LinesFromPlaneIntersections.size ();
Line result (meanpoint,direction);
}
```