Lemniscate of Bernoulli

A lemniscate of Bernoulli and its two foci F₁ and F₂

The lemniscate of Bernoulli is the pedal curve of a rectangular hyperbola

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

r n = -1 n cos nθ

in polar coordinates and their equivalents in rectangular coordinates.

In geometry, the lemniscate of Bernoulli is a plane curve defined from two given points F₁ and F₂, known as foci, at distance 2a from each other as the locus of points P so that PF₁·PF₂ = a². The curve has a shape similar to the numeral 8 and to the ∞ symbol. Its name is from lemniscus, which is Latin for "pendant ribbon". It is a special case of the Cassini oval and is a rational algebraic curve of degree 4.

This lemniscate was first described in 1694 by Jakob Bernoulli as a modification of an ellipse, which is the locus of points for which the sum of the distances to each of two fixed focal points is a constant. A Cassini oval, by contrast, is the locus of points for which the product of these distances is constant. In the case where the curve passes through the point midway between the foci, the oval is a lemniscate of Bernoulli.

This curve can be obtained as the inverse transform of a hyperbola, with the inversion circle centered at the center of the hyperbola (bisector of its two foci). It may also be drawn by a mechanical linkage in the form of Watt's linkage, with the lengths of the three bars of the linkage and the distance between its endpoints chosen to form a crossed square.^[1]

Equations

Its Cartesian equation is (up to translation and rotation):
$(x^{2}+y^{2})^{2}=2a^{2}(x^{2}-y^{2})\,$
In polar coordinates:
$r^{2}=2a^{2}\cos 2\theta \,$
As a parametric equation:
$x={\frac {a{\sqrt {2}}\cos(t)}{\sin ^{2}(t)+1}};\qquad y={\frac {a{\sqrt {2}}\cos(t)\sin(t)}{\sin ^{2}(t)+1}}$
In two-center bipolar coordinates:
$rr'=a^{2}\,$
In rational polar coordinates:
$Q=2s-1\,$

Arc length and elliptic functions

The determination of the arc length of arcs of the lemniscate leads to elliptic integrals, as was discovered in the eighteenth century. Around 1800, the elliptic functions inverting those integrals were studied by C. F. Gauss (largely unpublished at the time, but allusions in the notes to his Disquisitiones Arithmeticae). The period lattices are of a very special form, being proportional to the Gaussian integers. For this reason the case of elliptic functions with complex multiplication by √−1 is called the lemniscatic case in some sources.

Using the elliptic integral

F(x){\stackrel {\text{def}}{{}={}}}\int _{0}^{x}{\frac {dt}{\sqrt {1-t^{4}}}}

the formula of the arc length $L$ can be given as

L=2{\sqrt {2}}a\int _{-1}^{1}{\frac {dt}{\sqrt {1-t^{4}}}}=4{\sqrt {2}}aF(1)\approx 7{,}416\cdot a

Angles

relation between angles at Bernoulli's lemniscate

The following theorem about angles occurring in the lemniscate is due to German mathematician Gerhard Christoph Hermann Vechtmann, who described it 1843 in his dissertation on lemniscates.^[2]

F₁ and F₂ are the foci of the lemniscate, O is the midpoint of the line segment F₁F₂ and P is any point on the lemniscate outside the line connecting F₁ and F₂. The normal n of the lemniscate in P intersects the line connecting F₁ and F₂ in R. Now the interior angle of the triangle OPR at O is one third of the triangle's exterior angle at R. In addition the interior angle at P is twice the interior angle at O.

Further properties

The inversion of hyperbola yields a lemniscate

The lemniscate is symmetric to the line connecting its foci F₁ and F₂ and as well to the perpendicular bisector of the line segment F₁F₂.
The lemniscate is symmetric to the midpoint of the line segment F₁F₂.
The area enclosed by the lemniscate is 2a².
The lemniscate is the circle inversion of a hyperbola and vice versa.
The two tangents at the midpoint O are orthogonal and each of them forms an angle of $\tfrac{\pi}{4}$ with line connecting F₁ and F₂.

Applications

Dynamics on this curve and its more generalized versions are studied in quasi-one-dimensional models.

Notes

↑ Bryant, John; Sangwin, Christopher J. (2008), How round is your circle? Where Engineering and Mathematics Meet, Princeton University Press, pp. 58–59, ISBN 978-0-691-13118-4 .
↑ Alexander Ostermann, Gerhard Wanner: Geometry by Its History. Springer, 2012, pp. 207-208

References

J. Dennis Lawrence (1972). A catalog of special plane curves. Dover Publications. pp. 4–5,121–123,145,151,184. ISBN 0-486-60288-5.

External links

Wikimedia Commons has media related to Lemniscate of Bernoulli.

Weisstein, Eric W. "Lemniscate". MathWorld.

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