Sinusoidal spiral

Sinusoidal spirals: equilateral hyperbola (n = -2), line (n = -1), parabola (n = -1/2), cardioid (n = 1/2), circle (n = 1) and lemniscate of Bernoulli (n = 2), where rn = 1n cos(nθ) in polar coordinates and their equivalents in rectangular coordinates.

In geometry, the sinusoidal spirals are a family of curves defined by the equation in polar coordinates

r^n = a^n \cos(n \theta)\,

where a is a nonzero constant and n is a rational number other than 0. With a rotation about the origin, this can also be written

r^n = a^n \sin(n \theta).\,

The term "spiral" is a misnomer, because they are not actually spirals, and often have a flower-like shape. Many well known curves are sinusoidal spirals including:

The curves were first studied by Colin Maclaurin.

Equations

Differentiating

r^n = a^n \cos(n \theta)\,

and eliminating a produces a differential equation for r and θ:

\frac{dr}{d\theta}\cos n\theta + r\sin n\theta =0.

Then

\left(\frac{dr}{ds},\ r\frac{d\theta}{ds}\right)\cos n\theta \frac{ds}{d\theta}
= \left(-r\sin n\theta ,\ r \cos n\theta \right)
= r\left(-\sin n\theta ,\ \cos n\theta \right)

which implies that the polar tangential angle is

\psi = n\theta \pm \pi/2

and so the tangential angle is

\varphi = (n+1)\theta \pm \pi/2.

(The sign here is positive if r and cos nθ have the same sign and negative otherwise.)

The unit tangent vector,

\left(\frac{dr}{ds},\ r\frac{d\theta}{ds}\right),

has length one, so comparing the magnitude of the vectors on each side of the above equation gives

\frac{ds}{d\theta} = r \cos^{-1} n\theta = a \cos^{-1+\tfrac{1}{n}} n\theta.

In particular, the length of a single loop when n>0 is:

a\int_{-\tfrac{\pi}{2n}}^{\tfrac{\pi}{2n}} \cos^{-1+\tfrac{1}{n}} n\theta\ d\theta

The curvature is given by

\frac{d\varphi}{ds} = (n+1)\frac{d\theta}{ds} = \frac{n+1}{a} \cos^{1-\tfrac{1}{n}} n\theta.

Properties

The inverse of a sinusoidal spiral with respect to a circle with center at the origin is another sinusoidal spiral whose value of n is the negative of the original curve's value of n. For example, the inverse of the lemniscate of Bernoulli is a hyperbola.

The isoptic, pedal and negative pedal of a sinusoidal spiral are different sinusoidal spirals.

One path of a particle moving according to a central force proportional to a power of r is a sinusoidal spiral.

When n is an integer, and n points are arranged regularly on a circle of radius a, then the set of points so that the geometric mean of the distances from the point to the n points is a sinusoidal spiral. In this case the sinusoidal spiral is a polynomial lemniscate

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References

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