# Bezier Algorithms - an algorithm for inserting points

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

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

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