I am trying to **fit more than one line** to a list of points in 2D. My points are quite low in number (16 or 32).

These points are coming from a simulated environment of a **robot with laser range finders** attached to its side. If the points lie on a line it means that they **detected a wall**, if not, it means they **detected an obstacle**. I am trying to detect the walls and calculate their intersection, and for this I thought the best idea is to fit lines on the dataset.

Fitting one line to a set of points is not a problem, if we know all those points line on or around a line.

My problem is that **I don't know how can I detect which sets of points should be classified for fitting on the same line** and which should not be, for each line. Also, I don't even now the number of points on a line, while naturally it would be the best to detect the longest possible line segment.

How would you solve this problem? If I look at all the possibilities for example for groups of 5 points for all the 32 points then it gives 32 choose 5 = 201376 possibilities. I think **it takes way too much time to try all the possibilities** and try to fit a line to all 5-tuples.

So **what would be a better algorithm** what would run much faster? I could connect points within limit and create polylines. But even connecting the points is a hard task, as the edge distances change even within a single line.

Do you think it is possible to do some kind of **Hough transform on a discrete dataset** with such a low number of entries?

Note: if this problem is too hard to solve, I was thinking about using the order of the sensors and use it for filtering. This way the algorithm could be easier but if there is a small obstacle in front of a wall, it would distract the continuity of the line and thus break the wall into two halves.