Based on your description, the shortest line distance need be discussed separately based on the zone defined by the line segment. For example, if the line segment is (0,0) to (0,1), then we must slice the space into three sub-spaces (d denotes the minimum distance function):
- y < 0: d = sqrt(x^2 + y^2)
- 0 < y < 1: d = |x| (zone defined by this line segment)
- 1 < y: d = sqrt(x^2 + (y-1)^2)
The function d has the convex property, therefore you can solve the optimization problem by running though some standard convex optimization software, cvx package is a good one. For more information on convex optimization theory, convex optimization is a good book to refer to.
If you don't bother to go though some optimization solver to get the result, solving an alternative version based on heuristic can be much simpler.
Notice that the problem would be trivial if line segments extend indefinitely on both ends. So what I can think of is to treat the segments as if they are lines, but add a penalty distance to the end points. With that said, the following metric satisfy the need:
L = [(ax + by - c)^2] + [(x-x1)^2 + (x-y1)^2] + [(x-x2)^2 + (y-y2)^2]
here (x, y) is the point you need to decide, ax* + by* = c defines the line, (x1,y1), (x2,y2) is the two end points. Therefore the 1st [...] term is the squared distance to the line; 2nd and 3rd [...] term is the squared distance to the two end points.
Minimize L means:
- Prefer to relies on or close to the line;
- Prefer to resides in the zone defined by the segment;
It falls into least square distance problem, so you can get the solution by simply solving a set of linear equations. This is also the very reason I stick to quadratic form in L.
Of course this is just a heuristic method that leads to simpler solution. Other formulations of the term L might lead to better outcome, in terms of visual cognition. You might consider play with different L's, and then choose the best one based on visual outcome.