Epicycloid

The red curve is an epicycloid traced as the small circle (radius r = 1) rolls around the outside of the large circle (radius R = 3).

In geometry, an epicycloid or hypercycloid is a plane curve produced by tracing the path of a chosen point on the circumference of a circle—called an epicycle—which rolls without slipping around a fixed circle. It is a particular kind of roulette.

Equations

If the smaller circle has radius r, and the larger circle has radius R = kr, then the parametric equations for the curve can be given by either:

x(\theta )=(R+r)\cos \theta \ -r\cos \left({\frac {R+r}{r}}\theta \right)

y(\theta )=(R+r)\sin \theta \ -r\sin \left({\frac {R+r}{r}}\theta \right),

or:

x(\theta )=r(k+1)\cos \theta -r\cos \left((k+1)\theta \right)\,

y(\theta )=r(k+1)\sin \theta -r\sin \left((k+1)\theta \right).\,

If k is an integer, then the curve is closed, and has k cusps (i.e., sharp corners, where the curve is not differentiable).

If k is a rational number, say k=p/q expressed in simplest terms, then the curve has p cusps.

If k is an irrational number, then the curve never closes, and forms a dense subset of the space between the larger circle and a circle of radius R + 2r.

When measured in radian, $\theta$ takes value from $0$ to $2*\pi *{\frac {LCM(r,R)}{r}}$ where LCM is least common multiple.

Epicycloid examples
k = 1
k = 2
k = 3
k = 4
k = 2.1 = 21/10
k = 3.8 = 19/5
k = 5.5 = 11/2
k = 7.2 = 36/5

The epicycloid is a special kind of epitrochoid.

An epicycle with one cusp is a cardioid, two cusps is a nephroid.

An epicycloid and its evolute are similar.^[1]

Proof

sketch for proof

We assume that the position of $p$ is what we want to solve, $\alpha$ is the radian from the tangential point to the moving point $p$ , and $\theta$ is the radian from the starting point to the tangential point.

Since there is no sliding between the two cycles, then we have that

\ell _{R}=\ell _{r}

By the definition of radian (which is the rate arc over radius), then we have that

\ell _{R}=\theta R,\ell _{r}=\alpha r

From these two conditions, we get the identity

\theta R=\alpha r

By calculating, we get the relation between $\alpha$ and $\theta$ , which is

\alpha ={\frac {R}{r}}\theta

From the figure, we see the position of the point $p$ clearly.

x=\left(R+r\right)\cos \theta -r\cos \left(\theta +\alpha \right)=\left(R+r\right)\cos \theta -r\cos \left({\frac {R+r}{r}}\theta \right)

y=\left(R+r\right)\sin \theta -r\sin \left(\theta +\alpha \right)=\left(R+r\right)\sin \theta -r\sin \left({\frac {R+r}{r}}\theta \right)

References

J. Dennis Lawrence (1972). A catalog of special plane curves. Dover Publications. pp. 161, 168–170, 175. ISBN 0-486-60288-5.

↑ Epicycloid Evolute - from Wolfram MathWorld

External links

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[1] Epicycloid Evolute - from Wolfram MathWorld

Epicycloid

Equations

Proof

See also

References

External links