I'm working on a small game geometry library, and among a bunch of other methods, I want to be able to find the midpoint of intersection between a circle and a rectangle. However, I'm having difficulty thinking of a fast algorithm to do so. Does anyone know of a good algorithm to do this?
I'm willing to sacrifice perfect accuracy if it means the algorithm will be significantly faster.
The basic way I represent each shape is:
- float x, y (center)
- float r (radius)
- float x, y (center)
- float w, h (width and height values, they represent the x and y distance from the center to the respective edge).
Since there seems to be confusion over what I mean by "midpoint," let me clarify:
Given that the circle and the rectangle intersect, there is an area created by their overlap. I wish to determine the geographic center of this area (either exactly, or to determine a close approximate).
You guys have given me some ideas, let me work on implementing some of them and I'll get back to you.
I marked Gareth's answer as the accepted one, because it gave me the ideas for what I ended up going with, but my final implementation is different that his, so I'll explain it here.
I came up with two general ways of doing this: one that would have been completely accurate (but required more complex programming and more math), and another, simpler/faster way that was fairly close all the time. I ended up going with the latter, but here are the two methods:
Method 1: Shape Fragmentation:
Basically, the idea is to break up the overlapping area into discrete segments that can have their midpoint and area be easily computed, and then take the weighted average for the entire result.
The example shown here had three sub-pieces: A center rectangle taking up the bulk of the area, and two curved segments for the edges of the circle.
Method 2: Line Interpolation
First off, you need to calculate a point in the rectangle which will be the base location. This should be a point that is easy to calculate and is in the overlap. What I use for this point is the average of all edge intersections of the circle and the rectangle (if no edge intersections exist, I default to the location of the circle as it means one shape is contained within the other).
Ccalculate the line between the center of the circle and that point. Then, calculate the segment that lies within the overlapping area. The midpoint of the area is taken to be the midpoint of that line segment.
This method is inaccurate, but always produces a point within both objects, and the resulting point is generally close to the middle (so it "looks" good to the casual eye). It's also far simpler and faster, so I went with it.