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I am following this paper here using de Casteljau's Algorithm and I have tried using the topic Drawing Bezier curves using De Casteljau Algorithm in C++ , OpenGL to help. No success.

My bezier curves look like this when evaluated As you can see, even though it doesn't work the wanted I wanted it to, all the points are indeed on the curve. I do not think that this algorithm is inaccurate for this reason.

Here are my points on the top curve in that image: (0,0) (2,0) (2,2) (4,2) The second curve uses the same set of points, except the third point is (0,2), that is, two units above the first point, forming a steeper curve.

Something is wrong. I should put in 0.25 for t and it should spit out 1.0 for the X value, and .75 should always return 3. Assume t is time. It should progress at a constant rate, yeah? Exactly 25% of the way in, the X value should be 1.0 and then the Y should be associated with that value.

Are there any adequate ways to evaluate a bezier curve? Does anyone know what is going on here?

Thanks for any help! :)


I found this book in a google search and here is the page I found on explicit / non-parametric bezier curves. They are polynomials represented as bezier curves, which is what I am going for here. Here is that page from the book:

Anyone know how to convert a bezier curve to a parametric curve? I may open a different thread now...


I've realized that I was only asking the question about half as clear as I should have. What I'm trying to build is like Maya's animation graph editor such as this where the bezier control points that are used to modify the curve are more like tangent modifiers of equal length. I didn't remember them as being equal length, to be honest. By forcing a system like this, you can insure 100% that the result is a function and contains no overlapping segments.

I found this, which may have my answer

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Your assumption is incorrect: 25% of the way in, the X coordinate is just as variable as the Y coordinate. Both X and Y are described by formulas on t. –  Mark Ransom Oct 30 '11 at 1:56
@Mark, so how you do you suggest getting the Y value at absolute X values the way I am looking for? –  Thomas Havlik Oct 30 '11 at 2:01
@Thomas Havlik i didin't check there - sry for that –  fazo Oct 30 '11 at 2:02
@Mark, I think I get what you are saying. This algorithm allows for circles and other non-functional shapes. What I'm aiming at is evaluating the curve as if it were indeed a function. It makes sense that a parametric function used to evaluate a non-polynomial would not produce the results I am looking for. Now I am wondering how I should work around this :/ –  Thomas Havlik Oct 30 '11 at 2:07
I don't quite know enough about Beziers to answer the question, sorry. But I believe getting the curve intercepts for any arbitrary X is a tough problem. –  Mark Ransom Oct 30 '11 at 4:13

4 Answers 4

Here you can see the algorithm implemented in Mathematica following the nomenclature in your link, and your two plots:

(*Function Definitions*)

lerp[a_, b_, t_] := (1 - t) a + t b;
pts1[t_] := {
   lerp[pts[[1]], pts[[2]], t],
   lerp[pts[[2]], pts[[3]], t],
   lerp[pts[[3]], pts[[4]], t]};
pts2[t_] := {
   lerp[pts1[t][[1]], pts1[t][[2]], t],
   lerp[pts1[t][[2]], pts1[t][[3]], t]};
pts3[t_] := {
   lerp[pts2[t][[1]], pts2[t][[2]], t]};


pts = {{0, 0}, {2, 0}, {2, 2}, {4, 2}};
Framed@Show[ParametricPlot[pts3[t], {t, 0, 1}, Axes -> True], 
            Graphics[{Red, PointSize[Large], Point@pts}]]

pts = {{0, 0}, {2, 0}, {0, 2}, {4, 2}};
Framed@Show[ParametricPlot[pts3[t], {t, 0, 1}, Axes -> True], 
            Graphics[{Red, PointSize[Large], Point@pts}]]

enter image description here

BTW, the curves are defined by the following parametric equations, which are the functions pts3[t] in the code above:

c1[t_] := {2 t (3 + t (-3 + 2 t)), (* <- X component *)
                 2 (3 - 2 t) t^2}  (* <- Y component *)


c2[t_] := {2 t (3 + t (-6 + 5 t)), (* <- X component *)
               , 2 (3 - 2 t) t^2}  (* <- Y component *)

Try plotting them!

Taking any of these curve equations, and by solving a cubic polynomial you can in these cases get an expression for y[x], which is certainly not always possible. Just for you to get a flavor of it, from the first curve you get (C syntax):

y[x]= 3 - x - 3/Power(-2 + x + Sqrt(5 + (-4 + x)*x),1/3) + 
              3*Power(-2 + x + Sqrt(5 + (-4 + x)*x),1/3)

Try plotting it!


Just an amusement:

Mathematica is a quite powerful functional language, and in fact the whole algorithm can be expressed as a one liner:

f = Nest[(1 - t) #[[1]] + t #[[2]] & /@ Partition[#, 2, 1] &, #, Length@# - 1] &

Such as

f@{{0, 0}, {2, 0}, {0, 2}, {4, 2}}

gives the above results, but supports any number of points.

Let's try with six random points:

p = RandomReal[1, {6, 2}];
  Graphics[{Red, PointSize[Large], Point@p}],
  ParametricPlot[f@p, {t, 0, 1}, Axes -> True]]

enter image description here

Moreover, the same function works in 3D:

p = RandomReal[1, {4, 3}];
  Graphics3D[{Red, PointSize[Large], Point@p}],
  ParametricPlot3D[f[p], {t, 0, 1}, Axes -> True]]

enter image description here

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A bezier curve can be solved by solving the following parametric equations for the x, y, and z coordinates (if it's just 2D, do only x and y):

Px = (1-t)^3(P1x) + 3t(1-t)^2(P2x) + 3t^2(1-t)(P3x) + t^3(P4x)
Py = (1-t)^3(P1y) + 3t(1-t)^2(P2y) + 3t^2(1-t)(P3y) + t^3(P4y)
Pz = (1-t)^3(P1z) + 3t(1-t)^2(P2z) + 3t^2(1-t)(P3z) + t^3(P4z)

You can also solve this by multiplying the matrix equation ABC = X where:

  1. matrix A is a 1x4 matrix and represents the values of the powers of t
  2. matrix B are the coefficients of the powers of t, and is a lower-triangular 4x4 matrix
  3. matrix C is a 4x3 matrix that represents each of the four bezier points in 3D-space (it would be a 4x2 matrix in 2D-space)

This would look like the following:

matrix equation

(Update - the bottom left 1 ought to be a -1)

An important note in both forms of the equation (the parametric and the matrix forms) is that t is in the range [0, 1].

Rather than attempting to solve the values for t that will give you integral values of x and y, which is going to be time-consuming given that you're basically solving for the real root of a 3rd-degree polynomial, it's much better to simply create a small enough differential in your t value such that the difference between any two points on the curve is smaller than a pixel-value increment. In other words the distance between the two points P(t1) and P(t2) is such that it is less than a pixel value. Alternatively, you can use a larger differential in t, and simply linearly interpolate between P(t1) and P(t2), keeping in mind that the curve may not be "smooth" if the differential between P(t1) and P(t2) is not small enough for the given range of t from [0, 1].

A good way to find the necessary differential in t to create a fairly "smooth" curve from a visual standpoint is to actually measure the distance between the four points that define the bezier curve. Measure the distance from P1 to P2, P2, to P3, and P3 to P4. Then take the longest distance, and use the inverse of that value as the differential for t. You may still need to-do some linear interpolation between points, but the number of pixels in each "linear" sub-curve should be fairly small, and therefore the curve itself will appear fairly smooth. You can always decrease the differential value on t from this initial value to make it "smoother".

Finally, to answer your question:

Assume t is time. It should progress at a constant rate, yeah? Exactly 25% of the way in, the X value should be 1.0 and then the Y should be associated with that value.

No, that is not correct, and the reason is that the vectors (P2 - P1) and (P3 - P4) are not only tangent to the bezier curve at P1 and P4, but their lengths define the velocity along the curve at those points as well. Thus if the vector (P2 - P1) is a short distance, then that means for a given amount of time t, you will not travel very far from the point P1 ... this translates into the x,y values along the curve being packed together very closely for a given fixed differential of t. You are effectively "slowing down" in velocity as you move towards P1. The same effect takes place at P4 on the curve depending on the length of the vector (P3 - P4). The only way that the velocity along the curve would be "constant", and therefore the distance between any points for a common differential of t would be the same, would be if the lengths of all three segements (P2 - P1), (P3 - P2), and (P4 - P3) were the same. That would then indicate that there was no change in velocity along the curve.

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This was very informative. Thank you very much. However, it does not necessarily solve my problem. Know that I am grateful for you response, though. De Casteljau's Algorithm is excellent for tessellating a bezier curve for rendering, though, as it provides more segments in the areas of the curve with a steeper tangent. –  Thomas Havlik Nov 1 '11 at 22:19

It sounds like you actually just want a 1D cubic Bezier curve instead of the 2D that you have. Specifically, what you actually want is just a cubic polynomial segment that starts at 0 and goes up to 2 when evaluated over the domain of 0 to 4. So you could use some basic math and just find the polynomial:

f(x) = a + b*x + c*x^2 + d*x^3
f(0) = 0
f(4) = 2

That leaves two degrees of freedom.
Take the derivative of the function:

f'(x) = b + 2*c*x + 3*d*x^2

If you want it to be steep at the beginning and then level off at the end you might say something like:

f'(0) = 10
f'(4) = 0

Then we can plug in values. a and b come for free because we're evaluating at zero.

a = 0
b = 10

So then we have:

f(4) = 2 = 40 + c*16 + d*64
f'(4) = 0 = 10 + c*8 + d*48

That's a pretty easy linear system to solve. For completeness, we get:

16c + 64d = -38
 8c + 48d = -10


1/(16*48 - 8*64)|48 -64||-38| = |c| = |-37/8 |
                |-8  16||-10|   |d|   |  9/16|

f(x) = 10*x - (37/8)*x^2 + (9/16)*x^3

If, instead, you decide that you want to use Bezier control points, just pick your 4 y-value control points and recognize that in order to get t in [0,1], you just have to say t=x/4 (remembering that if you also need derivatives, you'll have to do a change there too).


If you happen to know the points and derivatives you want to begin and end with, but you want to use Bezier control points P1, P2, P3, and P4, the mapping is just this (assuming a curve parametrized over 0 to 1):

P1 = f(0)
P2 = f'(0)/3 + f(0)
P3 = f(1) - f'(1)/3
P4 = f(1)

If, for some reason, you wanted to stick with your 2D Bezier control points and wanted to ensure that the x dimension advanced linearly from 0 to 2 as t advanced from 0 to 1, then you could do that with control points (0,y1) (2/3,y2) (4/3,y3) (2,y4). You can see that I just made the x dimension start at 0, end at 2, and have a constant slope (derivative) of 2 (with respect to t). Then you just make the y-coordinate be whatever you need it to be. The different dimensions are essentially independent of each other.

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The only thing you'll need to watch out for with the interpolating polynomial is that it is not guaranteed to say within the area of the trapezoid that four bezier control points create since it is not an affine curve like a bezier curve ... Please correct me if I'm wrong ... –  Jason Nov 1 '11 at 12:30
@Jason You're right. Finding the polynomial algebraically doesn't really involve control points, just interpolating points and derivatives; so there's no trapezoid to fit inside. However, there is a direct mapping between the curves found by either method. There's nothing particularly specially about a polynomial in Bezier form as far as I know. –  JCooper Nov 1 '11 at 18:30
The most important facet of the Bezier parametric polynomial is that it's an affine transform, meaning that all the coefficients add up to 1, thus the polynomial describes the barycentric coordinates of the actual bezier curve point itself contained inside the trapezoid defined by the control points. I'm not sure if that's what you were getting at, but I think it's an important distinction between a Bezier parametric equation and an interpolating polynomial. Thus for some forms of the curve, the interpolated points may not nicely model the bezier form. –  Jason Nov 1 '11 at 18:51
I think this answer was the easiest to apply to my situation. If I was aiming at accomplishing what I wanted at the start, I'd probably try and keep the control point X values in 25% increments like this. –  Thomas Havlik Nov 1 '11 at 23:03
up vote 0 down vote accepted

After all this time, I was looking for hermite curves. Hermites are good because in one dimension they're guaranteed to produce a functional curve that can be evaluated to an XY point. I was confusing Hermites with Bezier.

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