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I'm looking for an algorithm to insert a new control point on a bezier curve, without deforming:

alt text

did anybody knows a library or reference for bezier algorithms (insertion, optimize, de Casteljau ...)

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comp.graphics.algorithms FAQ, questions 4.02 and 4.03. In what language are you looking for a library? –  bobince Apr 10 '10 at 15:48
    
@bobince: python, c++ or c# –  sorush-r Apr 10 '10 at 17:42
    
.Image down.... –  Pacerier Feb 19 '13 at 16:10

2 Answers 2

up vote 11 down vote accepted

This is called the "knot insertion problem". For Bézier curves, the de Casteljau algorithm will give you the right answer. Here is the simple algorithm for a degree 3 Bézier.

Say you want to insert a knot at a fraction t of the parameter space inside the Bézier curve defined by P0, P1, P2, P3. Here's what you do:

P0_1 = (1-t)*P0 + t*P1
P1_2 = (1-t)*P1 + t*P2
P2_3 = (1-t)*P2 + t*P3

P01_12 = (1-t)*P0_1 + t*P1_2
P12_23 = (1-t)*P1_2 + t*P2_3

P0112_1223 = (1-t)*P01_12 + t*P12_23

Then your first Bézier will be defined by: P_0, P0_1, P01_12, P0112_1223; your second Bézier is defined by: P0112_1223, P12_23, P2_3, P3.

The geometrical interpretation is simple: you split each segment of the Bézier polygon at fraction t, then connect these split points in a new polygon and iterate. When you're left with 1 point, this point lies on the curve and the previous/next split points form the previous/next Bézier polygon. The same algorithm also works for higher degree Bézier curves.

Now it can get trickier if you want to insert the control point not at a specific value of t but at a specific location in space. Personally, what I would do here is simply a binary search for a value of t that falls close to the desired split point... But if performance is critical, you can probably find a faster analytic solution.

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For a more efficient way to find the value t closest to a specific location in space, take a look at the paper referenced in my reply to this question: stackoverflow.com/questions/2742610/… –  Adrian Lopez May 1 '10 at 18:13

You could also take the mathematical approach.

A qubic Bézier curve with control points p_1,p_2,p_3,p_4 can be written as:

b(t)=(1-t)^3 p_1+3t(1-t)^2 p_2+3t^2 (1-t) p_3+t^3 p_4

Its derivative w.r.t. t is

\frac{\partial b}{\partial t} = 3(1-t)^2 (p_2-p_1 )+6t(1-t)(p_3-p_2 )+3t^2 (p_3-3p_4 )

To limit the curve from t0 to t1, you get new control points q_1,q_2,q_3,q_4:

q_1=b(t_0),q_4=b(t_1)

q_2=q_1+\frac{1}{3}(t_1-t_0)\frac{\partial{b}}{\partial{t}}_{(t=t_0)}

q_3=q_4-\frac{1}{3}(t_1-t_0)\frac{\partial{b}}{\partial{t}}_{(t=t_1)}

Proof

Substituting

s=\frac{t-t_0}{t_1-t_0}

t=t_0+s(t_1-t_0 )

We get

\frac{\partial b}{\partial s} = \frac{\partial b}{\partial t} \frac{\partial t}{\partial s} = (t_1-t_0) \frac{\partial b}{\partial t}

The first and last points of the sub-curve are the first and last new control points

q_1=b(t_0),q_4=b(t_1)

And the tangent at those points is

\frac{\partial{b}}{\partial{s}}_{(s=0)}=(t_1-t_0)\frac{\partial{b}}{\partial{t}}_{(t=t_0)}=3(q_2-q_1)

\frac{\partial{b}}{\partial{s}}_{(s=1)}=(t_1-t_0)\frac{\partial{b}}{\partial{t}}_{(t=t_1)}=3(q_4-q_3)

So

q_2=q_1+\frac{1}{3}(t_1-t_0)\frac{\partial{b}}{\partial{t}}_{(t=t_0)}

q_3=q_4-\frac{1}{3}(t_1-t_0)\frac{\partial{b}}{\partial{t}}_{(t=t_1)}

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