While the accepted answer given is correct, I think it's worth exploring this answer in a way that will make the rationale for the answer completely obvious. This is too common an algorithm to have an incomplete (or worse, controversial) answer. Furthermore, with only a passing glance at the given formula, you may miss the beauty and extensibility of the algorithm, and the implicit decisions that are being made.
First, consider one way to define a two dimensional box is with:
- (x, y) for the top left point
- (x, y) for the bottom right point
This might look like:
I indicate the top left with a triangle and the bottom right with a circle. This is to avoid opaque syntax like
x1, x2 for this example.
Two overlapping rectangles might look like this:
Notice that to find the overlap you're looking for the place where the orange and the blue collide:
Once you recognize this, it becomes obvious that overlap is the result of finding and multiplying these two darkened lines:
The length of each line is the minimum value of the circle points, minus the maximum value of the triangle points.
Here, I'm using a two-toned shape to show that both the orange and the blue points are compared. The small letter after the two-toned shape indicates that the triangles are compared along that axis (x or y).
For example, to find the length of the darkened blue line you can see the orange and blue triangles are compared to look for the maximum value between the two. The attribute that is compared is the x attribute. The maximum x value between the orange and blue triangles is 210.
Another way to say the same thing is:
The length of the new line that fits onto both of the lines that we are comparing is found by subtracting the closest point on the longest side of the line from the furthest point on the closest side of the line.
Finding those lines gives complete information of the overlapping areas.
Once you have this, finding the percentage of overlap is trivial:
But wait, if the orange rectangle does not overlap with the blue one then you're going to have a problem:
With this example, you get a -850 for our overlapping area, that can't be right. Even worse, if a detection doesn't overlap with either dimension (neither on the x or y axis) then you will still get a positive number because both dimensions are negative. This is why you see the
Max(0, ...) * Max(0, ...) as part of the solution; it ensures that if any of the overlaps are negative you'll get a 0 back from your function.
The final formula in keeping with our symbology:
It's worth noting that using the
max(0, ...) function may not be necessary. You may want to know if something overlaps along one of its dimensions rather than all of them; if you use max then you will obliterate that information. For that reason, consider how you want to deal with non-overlapping images. Normally, the max function is fine to use, but it's worth being aware what it's doing.
Finally, notice that since this comparison is only concerned with linear measurements it can be scaled to arbitrary dimensions or arbitrary overlapping quadrilaterals.
max(0, min(orange.circle.x, blue.circle.x) - max(orange.triangle.x, blue.triangle.x)) * max(0, min(orange.circle.y, blue.circle.y) - max(orange.triangle.y, blue.triangle.y))
percent_coverage = intersecting_area / (orange_area + blue_area - intersecting_area)