# How do I QUICKLY find the closest intersection in 2D between a ray and m polylines?

How do I find the closest intersection in 2D between a ray:

``````x = x0 + t*cos(a), y = y0 + t*sin(a)
``````

and m polylines:

``````{(x1,y1), (x2,y2), ..., (xn,yn)}
``````

QUICKLY?

I started by looping trough all linesegments and for each linesegment; `{(x1,y1),(x2,y2)}` solving:

``````x1 + u*(x2-x1) = x0 + t*cos(a)

y1 + u*(y2-y1) = y0 + t*sin(a)
``````

by Cramer's rule, and afterward sorting the intersections on distance, but that was slow :-(

BTW: the polylines happens to be monotonically increasing in `x`.

# Coordinate system transformation

I suggest you first transform your setup to something with easier coordinates:

1. Take your point `p = (x, y)`.
2. Move it by `(-x0, -y0)` so that the ray now starts at the center.
3. Rotate it by `-a` so that the ray now lies on the x axis.

So far the above operations have cost you four additions and four multiplications per point:

``````ca = cos(a) # computed only once
sa = sin(a) # likewise

x' = x - x0
y' = y - y0
x'' = x'*ca + y'*sa
y'' = y'*ca - x'*sa
``````

# Checking for intersections

Now you know that a segment of the polyline will only intersect the ray if the sign of its `y''` value changes, i.e. `y1'' * y2'' < 0`. You could even postpone the computation of the `x''` values until after this check. Furthermore, the segment will only intersect the ray if the intersection of the segment with the x axis occurs for x > 0, which can only happen if either value is greater than zero, i.e. `x1'' > 0 or x2'' > 0`. If both `x''` are greater than zero, then you know there is an intersection.

The following paragraph is kind of optional, don't worry if you don't understand it, there is an alternative noted later on.
If one `x''` is positive but the other is negative, then you have to check further. Suppose that the sign of `y''` changed from negative to positive, i.e. `y1'' < 0 < y2''`. The line from `p1''` to `p2''` will intersect the x axis at x > 0 if and only if the triangle formed by `p1''`, `p2''` and the origin is oriented counter-clockwise. You can determine the orientation of that triangle by examining the sign of the determinant `x1''*y2'' - x2''*y1''`, it will be positive for a counter-clockwise triangle. If the direction of the sign change is different, the orientation has to be different as well. So to take this together, you can check whether

``````(x1'' * y2'' - x2'' * y1'') * y2'' > 0
``````

If that is the case, then you have an intersection. Notice that there were no costly divisions involved so far.

# Computing intersections

As you want to not only decide whether an intersection exists, but actually find a specific one, you now have to compute that intersection. Let's call it `p3`. It must satisfy the equations

``````(x2'' - x3'')/(y2'' - y3'') = (x1'' - x3'')/(y1'' - y3'') and
y3'' = 0
``````

which results in

``````x3'' = (x1'' * y1'' - x2'' * y2'')/(y1'' - y2'')
``````

Instead of the triangle orientation check from the previous paragraph, you could always compute this `x3''` value and discard any results where it turns out to be negative. Less code, but more divisions. Benchmark if in doubt about performance.

To find the point closest to the origin of the ray, you take the result with minimal `x3''` value, which you can then transform back into its original position:

``````x3 = x3''*ca + x0
y3 = x3''*sa + y0
``````

There you are.

Note that all of the above assumed that all numbers were either positive or negative. If you have zeros, it depends on the exact interpretation of what you actually want to compute, how you want to handle these border cases.

• Thanks for a very thorough answer! – Andy Oct 5 '12 at 19:38

To avoid checking intersection with all segments, some space partition is needed, like Quadtree, BSP tree. With space partition it is needed to check ray intersection with space partitions.

In this case, since points are sorted by x-coordinate, it is possible to make space partition with boxes `(min x, min y)-(max x, max y)` for parts of polyline. Root box is min-max of all points, and it is split in 2 boxes for first and second part of a polyline. Number of segments in parts is same or one box has one more segment. This box splitting is done recursively until only one segment is in a box.

To check ray intersection start with root box and check is it intersected with a ray, if it is than check 2 sub-boxes for an intersection and first test closer sub-box then farther sub-box.

Checking ray-box intersection is checking if ray is crossing axis aligned line between 2 positions. That is done for 4 box boundaries.

• Hi Ante. I think maybe the root should contain one bounding box per line. Then each line could be split into a bounding box for first and last half repeatedly until each box at the lowest level in the tree contains one segment? – Andy Oct 5 '12 at 20:53
• @Andy: I now see that you have more polylines :-/ Yes, you can make one box per a polyline, but I think that then is a better to use standard partitioning (e.g. BSP tree) on union of all line segments. I was describing alternative partition only to benefit from known input data structure. Are x values same (or similar) for all polylines? – Ante Oct 5 '12 at 21:06
• Well there are only a limited number of x values, and they are equally spaced from 0 to L. However a polyline may only cover a subrange of this span; so no the x values are not the same. There may be many polylines so I think a BSP would be great but I do not understand how this should work without having line segments crossing the boxes? – Andy Oct 6 '12 at 7:24
• If line segment crosses separation line than it is placed in both boxes. With that there is no guaranty to have leaf box with only one segment. It is standard to stop space splitting when number of segments in box is small. If ray intersect leaf box, than check ray intersection with all segments in a leaf box. – Ante Oct 6 '12 at 7:58