# Geometrical Arc to Bezier Curve

When drawing an Arc in 2D, using a Bezier Curve approximation, how does one calculate the two control points given that you have a center point of a circle, a start and end angle and a radius?

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Is it correct to assume that you're trying to approximate a circular arc? –  Beska Apr 9 '09 at 13:01

This isn't easily explained in a StackOverflow post, particularly since proving it to you will involve a number of detailed steps. However, what you're describing is a common question and there's a number of thorough explanations. See here and here; I like #2 very much and have used it before.

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typo near the end of #2: "x3=x1" should be "x3=x0". –  xan Jan 11 '11 at 21:49
I have a slightly more generic explanation over at pomax.github.io/bezierinfo/#circles_cubic, which covers the second link's conclusion, while explaining what the coordinates would be for any arc length rather than for arcs with angles up to a quarter circle. –  Mike 'Pomax' Kamermans Apr 6 '14 at 18:04

There's Mathematica code at Wolfram MathWorld: Bézier Curve Approximation of an Arc, which should get you started.

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all of the links are not available ... –  d.raev Feb 28 '13 at 8:05
A working link explaining the same thing would be pomax.github.io/bezierinfo/#circles_cubic –  Mike 'Pomax' Kamermans Apr 6 '14 at 18:00

Raphael 2.1.0 has support for Arc->Cubic (path2curve-function), and after fixing a bug in S and T path normalization, it seems to work now. I updated *the Random Path Generator* so that it generates only arcs, so it's easy test all possible path combinations:

http://jsbin.com/oqojan/53/

Test and if some path fails, I'd be happy to get report.

EDIT: Just realized that this is 3 years old thread...

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I've had success with this general solution for any elliptical arc as a cubic Bezier curve. It even includes the start and end angles in the formulation, so there's no extra rotation needed (which would be a problem for a non-circular ellipse).

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