Given two Quadratic Beziers in 2D with integer coordinates, what is the best way to find their intersection point(s)? Also interesting is an early rejection if they do not intersect. If it makes it easier, they can both be assumed to be monotone in both x and y. Only intersections that are representable by subdivision to integers of the input curves are valid.
Assuming that a1, b1 and c1 are the the first, second and third control points (corresponding to P1, P2, and P3 in the image below). The same for a2, b2, and c2 for a second bezier.
We can solve t for:
If there is an intersection, we should find a solution (or two if there are two), and use the value(s) of t to find the point using (replace a1 for P1, and so on):
Note that control points are two dimensional, we have to solve separately for x and y. Also note that t must in the interval [0, 1] otherwise the intersection is outside the curve (i.e. beyond the end points).
For example in Java you can solve for t by using the built-in solveQuadratic:
Note that I'm only showing the code for x. For fast intersections with lines and rectangles you can check this post
The reasoning behind this is as follows.
The parametric equations of the two lines are:
Then the point on the bezier is:
which can be simplified (by magic) to:
If we want to solve for a value c
we can use the following formula (more magic):
which is a simple quadratic curve.
If we have two Beziers:
and we want to intersect them. All we have to do is find a value for t where the two are equal:
this can be expanded to the following:
which has the same form as a Bezier, and can be solved by the formula shown above (with c = 0):
You can use a similar reasoning for other types of intersection (Bezier-line, Bezier circle, etc.).
This document explains various methods for finding the intersection of curves.
Nope, that doesn't work. This way, you'll only find a small (usually empty) subset of the intersections between Q1 and Q2, namely those where the intersection points lay at the same curve parameter t with respect to both curves involved.