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The problem:

I have trouble generating a random line that cuts through a polygon (not necessary convex). The lines should have the same distribution as completely random lines (random position, random angle), disregarding those that miss the polygon entirely.

My thoughts so far:

Picking a random point inside the polygon (I have that algorithm already) and picking a random angle won't do, because a hammer shaped object would be cut more often through the head (it has a larger area than the handle), where a completely random line would be more likely to cut through the handle. Also the angle would defenitely not be uniformly distributed.

For the same reasons it's not possible picking two points inside or on the surface and generating a line that goes through both points or any similar methods.

Edit: I have two methods that I can use but I'm not perfectly satisfied with either of them.

  1. Find a circle that contains the polygon. Pick random lines through the circle until you find one that also cuts through the polygon. This basically the definition that I wrote above only with a higher chance of hitting the polygon.

  2. Project the polygon in n directions (e.g. 0°, 10°, 20° etc.). The size of the projection is proportional to the likelyhood of getting hit from this direction. Then I pick a direction (using the projection-size as weighted probabilies). Finally, I can add a 360/n° jitter the the angle. This should approximate the distribution well enough but I wonder if there is a better way of doing it.

Edit2: -deleted-
I had written quite a lot but after thinking some more about it and discovering some mistakes I realized that this is getting over my head. The idea was to project a convex hull of the polygon in just a few, certain directions and finding a function that gives us all the other projections by blending between the known ones. But the details turned out to be quite convoluted and just too much for me at the moment.

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I assert from your story that any line should cut the polygon in exactly two pieces, correct? –  Pankrates Jan 19 '13 at 16:51
I don't care for the number of resulting pieces. Concave polygons could be split into more than two pieces. Theoretically, it could even result in only one piece if the line only just touches the polygon (but with probability 0). –  NounVerber Jan 19 '13 at 16:55
Interesting. Not a complete solution, but have you considered randomly selecting points within the convex hull of the polygon? –  beaker Jan 19 '13 at 17:01
As you, I think, correctly state that selecting a starting point(s) based on the polygon will yield a biased and non-uniformly distributed collection of lines. A good starting point therefore seems to define a canvas in which the polygon lies and generate random lines based on random coordinates and angles within the canvas. We should mathematically verify that if you omit all the lines that do not intersect the polygon, the remaining collection is still uniformly randomly distributed –  Pankrates Jan 19 '13 at 17:05
Once you have the first point inside the convex hull, you can either select a random angle or a second point anywhere (it doesn't have to be within the convex hull). –  beaker Jan 19 '13 at 18:03

1 Answer 1

The notion of random line intersecting with a figure is surprisingly awkward to define rigorously: see Bertrand's paradox for a well-known example of the ambiguity in this kind of idea. Even a random line in the plane is not easy to define: you might try something like "a line passing at a random angle through a random point", but how do you choose a random point? There's no uniform distribution over points in the plane.

Here's a way to precisely define random line intersecting with a figure F. Let w(θ) be the width of the figure F perpendicular to the angle θ:

When F is a polygon, then w(θ) is made out of piecewise sine functions, with as many pieces as the convex hull of the polygon has antipodal pairs of vertices.

Now, choose an angle θ using p(θ) as the probability density function, where

p(θ) = w(θ) / ∫ w(θ) dθ

and then choose the position of the line uniformly on the interval [0, w(θ)].

(Your method #2 tries to approximate p(θ) by sampling a small number of values of θ and constructing a piecewise-constant distribution. But we can get an exact result without too much extra difficulty.)

To compute the integral ∫ w(θ) dθ (and thus p(θ)), first find the convex hull of your polygon, and then use the rotating calipers method to find the antipodal pairs of vertices. Between adjacent antipodal pairs, the calipers move from θ0 to θ1, say, and in this range w(θ) is given by

w(θ) = d sin(θ − φ)

where φ is the angle of the line between the antipodal vertices d is its length, as shown in the two figures below:

Now over the range θ0 to θ1, the indefinite integral is:

w(θ) dθ = ∫ d sin(θ − φ) dθ = − d cos(θ − φ)

and so the definite integral of w(θ) for the range [θ0, θ1] is

d (cos(θ0 − φ) − cos(θ1 − φ))

Sum this up over all pairs of antipodal points and you've computed the whole integral.

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