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For a personal project, I'd need to find out if two cubic Bézier curves intersect. I don't need to know where: I just need to know if they do. However, I'd need to do it fast.

I've been scavenging the place and I found several resources. Mostly, there's this question here that had a promising answer.

So after I figured what is a Sylvester matrix, what is a determinant, what is a resultant and why it's useful, I thought I figured how the solution works. However, reality begs to differ, and it doesn't work so well.

Messing Around

I've used my graphing calculator to draw two Bézier splines (that we'll call B0 and B1) that intersect. Their coordinates are as follow (P0, P1, P2, P3):

(1, 1) (2, 4) (3, 4) (4, 3)
(3, 5) (3, 6) (0, 1) (3, 1)

The result is the following, B0 being the "horizontal" curve and B1 the other one:

Two cubic Bézier curves that intersect

Following directions from the aforementioned question's top-voted answer, I've subtracted B0 to B1. It left me with two equations (the X and the Y axes) that, according to my calculator, are:

x = 9t^3 - 9t^2 - 3t + 2
y = 9t^3 - 9t^2 - 6t + 4

The Sylvester Matrix

And from that I've built the following Sylvester matrix:

9  -9  -3   2   0   0
0   9  -9  -3   2   0
0   0   9  -9  -3   2
9  -9  -6   4   0   0
0   9  -9  -6   4   0
0   0   9  -9  -6   4

After that, I've made a C++ function to calculate determinants of matrices using Laplace expansion:

template<int size>
float determinant(float* matrix)
    float total = 0;
    float sign = 1;
    float temporaryMatrix[(size - 1) * (size - 1)];
    for (int i = 0; i < size; i++)
        if (matrix[i] != 0)
            for (int j = 1; j < size; j++)
                float* targetOffset = temporaryMatrix + (j - 1) * (size - 1);
                float* sourceOffset = matrix + j * size;
                int firstCopySize = i * sizeof *matrix;
                int secondCopySize = (size - i - 1) * sizeof *matrix;
                memcpy(targetOffset, sourceOffset, firstCopySize);
                memcpy(targetOffset + i, sourceOffset + i + 1, secondCopySize);
            float subdeterminant = determinant<size - 1>(temporaryMatrix);
            total += matrix[i] * subdeterminant * sign;
        sign *= -1;
    return total;

float determinant<1>(float* matrix)
    return matrix[0];

It seems to work pretty well on relatively small matrices (2x2, 3x3 and 4x4), so I'd expect it to work on 6x6 matrices too. I didn't conduct extensive tests however, and there's a possibility that it's broken.

The Problem

If I understood correctly the answer from the other question, the determinant should be 0 since the curves intersect. However, feeding my program the Sylvester matrix I made above, it's -2916.

Is it a mistake on my end or on their end? What's the correct way to find out if two cubic Bézier curves intersect?

share|improve this question
Please don't compute determinants if you don't have to. If you want to check for a singularity compute the lowest and highest singular value. And if you need the determinant for some reason, don't use the Laplace-Expansion! It has exponential time complexity. You can do it on O(n^3)! – sellibitze Oct 28 '10 at 2:45
Plugging your Sylvester Matrix into the matrix calculator at gave -2916 for the determinant. You may need to fix your determinant function. – Kyle Lutz Oct 28 '10 at 2:46
@Kyle Lutz Yeah I found that about 5 minutes after my post, and I fixed my determinant function. – zneak Oct 28 '10 at 2:50
@sellibitze I'll gladly drop it once someone explains another way of finding Bézier curves intersections. – zneak Oct 28 '10 at 2:54
This is a perfect algorithm, but it finds if two parametric curves intersect at the exact same parameter value (It is is what @PaulBaker answer points to). The real problem ("Do curves intersect at all ?") is a bi-variadic polynom for which you want to find roots, a problem for which I do not know if there is an analytic solution. I think the question should edited to include this remark. – Ad N Sep 19 '13 at 11:38
up vote 11 down vote accepted

Intersection of Bezier curves is done by the (very cool) Asymptote vector graphics language: look for intersect() here.

Although they don't explain the algorithm they actually use there, except to say that it's from p. 137 of "The Metafont Book", it appears that the key to it is two important properties of Bezier curves (which are explained elsewhere on that site though I can't find the page right now):

  • A Bezier curve is always contained within the bounding box defined by its 4 control points
  • A Bezier curve can always be subdivided at an arbitrary t value into 2 sub-Bezier curves

With these two properties and an algorithm for intersecting polygons, you can recurse to arbitrary precision:

bezInt(B1, B2):

  1. Does bbox(B1) intersect bbox(B2)?
    • No: Return false.
    • Yes: Continue.
  2. Is area(bbox(B1)) + area(bbox(B2)) < threshold?
    • Yes: Return true.
    • No: Continue.
  3. Split B1 into B1a and B1b at t = 0.5
  4. Split B2 into B2a and B2b at t = 0.5
  5. Return bezInt(B1a, B2a) || bezInt(B1a, B2b) || bezInt(B1b, B2a) || bezInt(B1b, B2b).

This will be fast if the curves don't intersect -- is that the usual case?

[EDIT] It looks like the algorithm for splitting a Bezier curve in two is called de Casteljau's algorithm.

share|improve this answer
I've been thinking about using this solution instead. It's called Bézier clipping. – zneak Oct 28 '10 at 16:07
@zneak : actually, from the paper pointed to several times in this thread (, this is the Bézier subdivision method. – Ad N Sep 19 '13 at 13:43

If you're doing this for production code, I'd suggest the Bezier clipping algorithm. It's explained well in section 7.7 of this free online CAGD text (pdf), works for any degree of Bezier curve, and is fast and robust.

While using standard rootfinders or matrices might be more straightforward from a mathematical point of view, Bezier clipping is relatively easy to implement and debug, and will actually have less floating point error. This is because whenever it's creating new numbers, it's doing weighted averages (convex combinations) so there's no chance of extrapolating based on noisy inputs.

share|improve this answer
Yes, Bézier clipping is the currently accepted answer. But it's great that you have arguments that show it's a better solution. – zneak Dec 3 '12 at 15:54
I saw that.. using a fat line to clip against instead of the bounding boxes will give much faster convergence, and is not that much more work. – tfinniga Dec 3 '12 at 16:09

Is it a mistake on my end or on their end?

Are you basing your interpretation of the determinant on the 4th comment attached to this answer? If so, I believe that's where the mistake lies. Reproducing the comment here:

If the determinant is zero there is is a root in X and Y at *exactly the same value of t, so there is an intersection of the two curves. (the t may not be in the interval 0..1 though).

I don't see any problems with this part, but the author goes on to say:

If the determinant is <> zero you can be sure that the curves don't intersect anywhere.

I don't think that's correct. It's perfectly possible for the two curves to intersect in a location where the t values differ, and in that case, there will be an intersection even though the matrix has a non-zero determinant. I believe this is what's happening in your case.

share|improve this answer

I don't know how fast it will be, but if you have two curves C1(t) and C2(k) they intersect if C1(t) == C2(k). So you have two equations (per x and per y) for two variables (t, k). You can solve the system using numerical methods with enough for you accuracy. When you've found t,k parameters you should check if there is a parameter on [0, 1]. If it is they intersects on [0, 1].

share|improve this answer
I'm not good enough with maths to know how to solve parametric equations. Care to give an example with the two curves from my question? – zneak Oct 28 '10 at 16:02
I don't know how to do it exactly (what method to use). I just know that the are such methods. Maybe you can find c++ numerical methods library. – Andrew Oct 29 '10 at 4:21

I'm by no way an expert on this kind of thing, but I follow a nice blog that talks a lot about curves. He has link to two nice articles talking about your problem (the second link has an interactive demonstration and some source code). Other people may have much better insight into the problem but I hope this helps!

share|improve this answer
Thanks for the links. Though, the second is about quadratic curves, which I believe are an order of magnitude easier to solve, as I think you just have to subtract their equations and use the quadratic formula. I'll read your first link though. – zneak Oct 28 '10 at 2:36
Ah sorry about the second link, I hope the first helps. – GWW Oct 28 '10 at 2:42

This is a hard problem. I would split each of the 2 Bezier curves into say 5-10 discrete line segments, and just do line-line intersections.

enter image description here

foreach SampledLineSegment line1 in Bezier1
    foreach SampledLineSegment line2 in Bezier2
        if( line1 intersects line2 )
            then Bezier1 intersects Bezier2
share|improve this answer
That's probably a reasonable approximation, but I like the Bézier clipping method better because it provides measurable accuracy, and it's still pretty fast. – zneak Apr 3 '13 at 14:45
Agreed. At first I misread miserable accuracy, so I was concerned. – bobobobo Apr 3 '13 at 14:48

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