convert bezier curve to polygonal chain?

I want to split a bezier curve into a polygonal chain with n straight lines. The number of lines being dependent on a maximum allowed angle between 2 connecting lines. I'm looking for an algorithm to find the most optimal solution (ie to reduce as much as possible the number of straight lines).

I know how to split a bezier curve using Casteljau or Bernstein polynomals. I tried dividing the bezier into half calculate the angle between the straight lines, and split again if the angle between the connecting lines is within a certain threshold range, but i may run into shortcuts.

Is there a known algorithm or pseudo code available to do this conversion?

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I assume that you have the control polygon for the Bezier available? Wouldn't that make a good starting point? Why does the angle matter here? I'm very curious about what you are trying to achieve. –  batbrat Feb 12 '12 at 8:57
2 controlpoints are available. It's indeed another option to start at the startingpoint of the curve, but I'm curious whether there are documented optimal solutions available. I want to use it to generate input for a cnc routing device. This machine only understands straight lines, so a bezier curve needs to be split in a set of straight lines. –  dr jerry Feb 12 '12 at 9:06
I dint knew about Bezier curve before I read your post, but thinking of dividing a curve into n st. lines makes me reminds me of Cantor's infinity theory. ;) –  uDaY Feb 12 '12 at 9:30

Use de Casteljau algorithm recursively until the control points are approximately collinear. See for instance http://www.antigrain.com/research/adaptive_bezier/index.html.

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There are some alternatives for RSA flattening that are reported to be faster:

RSA vs CAA vs PAA: http://www.cis.usouthal.edu/~hain/general/Theses/Racherla_thesis.pdf

RSA = Recursive Subdivision Algorithm PAA = Parabolic Approximation Algorithm CAA = Circular Approximation Algorithm

According to Rachela, CAA is slower than the PAA by a factor of 1.5–2. CAA is as slow as RSA, but achieves required flatness better in offset curves.

It seems that PAA is best choice for actual curve and CAA is best for offset's of curve (when stroking curves).

I have tested PAA of both thesis, but they fail in some cases. Ahmad's PAA fails in collinear cases (all points on same line) and Rachela's PAA fails in collinear cases and in cases where both control points are equal. With some fixes, it may be possible to get them work as expected.

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A visual example on my website -> DXF -> polybezier. it is basically a recursive split with casteljau.

``````Bezier2Poly.prototype.convert = function(array,init) {
if (init) {
this.vertices = [];
}
if (!init && (Math.abs(this.controlPointsDiff(array[0], array[2])) < this.threshold
|| Math.abs(this.controlPointsDiff({x:array[2].x-array[1].x, y:array[2]-array[1].y}, array[2])) < this.threshold)) {
this.vertices.push(array[2]);
} else {
var split = this.splitBezier(array);
this.convert(split.b1);
this.convert(split.b2);
}
return this.vertices;
}
``````

And judgement by: calculating the angle between the controlpoints and the line through the endpoint.

``````Bezier2Poly.prototype.controlPointsDiff = function (vector1, vector2) {
var angleCp1 = Math.atan2(vector1.y, vector1.x);
var angleCp2 = Math.atan2(vector2.y, vector2.x);
return angleCp1 - angleCp2;
}
``````
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Here's another criterion for determining when to stop the recursion: Piecewise linear approximation of Bézier curves –  Hbf Feb 28 '13 at 0:13