Cassini oval

Cassini oval: ${\displaystyle |PP_{1}|\cdot |PP_{2}|=b^{2}}$ for any location of P on the curve

• A Cassini oval is a set of points, such that for any point ${\displaystyle P}$ of the set, the product of the distances ${\displaystyle |PP_{1}|,\ |PP_{2}|}$ to two fixed points ${\displaystyle P_{1},\;P_{2}}$, is constant, usually denoted by ${\displaystyle b^{2},\ b>0,}$:

${\displaystyle \{P\mid |PP_{1}|\cdot |PP_{2}|=b^{2}\}\ .}$

As with an ellipse, the fixed points ${\displaystyle P_{1},P_{2}}$ are called the foci of the Cassini oval.

If the foci are (a, 0) and (−a, 0), then the equation of the curve is

${\displaystyle ((x-a)^{2}+y^{2})((x+a)^{2}+y^{2})=b^{4}.\,}$

When expanded this becomes

${\displaystyle (x^{2}+y^{2})^{2}-2a^{2}(x^{2}-y^{2})+a^{4}=b^{4}.\,}$

The equivalent polar equation is

${\displaystyle r^{4}-2a^{2}r^{2}\cos 2\theta =b^{4}-a^{4}.\,}$

Some Cassini ovals. (b = 0.6a, 0.8a, a, 1.2a, 1.4a, 1.6a)

The curve depends, up to similarity, on e = b/a. When e < 1, the curve consists of two disconnected loops, each of which contains a focus. When e = 1, the curve is the lemniscate of Bernoulli having the shape of a sideways figure eight with a double point (specifically, a crunode) at the origin.[2][3] When e > 1, the curve is a single, connected loop enclosing both foci. It is peanut-shaped for ${\displaystyle 1<e<{\sqrt {2}}}$ and convex for ${\displaystyle e\geq {\sqrt {2}}}$.[4] The limiting case of a → 0 (hence e → ${\displaystyle \infty }$), in which case the foci coincide with each other, is a circle.

The curve always has x-intercepts at ±c where c² = a² + b². When e < 1 there are two additional real x-intercepts and when e > 1 there are two real y-intercepts, all other x and y-intercepts being imaginary.[5]

The curve has double points at the circular points at infinity, in other words the curve is bicircular. These points are biflecnodes, meaning that the curve has two distinct tangents at these points and each branch of the curve has a point of inflection there. From this information and Plücker's formulas it is possible to deduce the Plücker numbers for the case e ≠ 1: degree = 4, class = 8, number of nodes = 2, number of cusps = 0, number of double tangents = 8, number of points of inflection = 12, genus = 1.[6]

The tangents at the circular points are given by x ± iy = ±a which have real points of intersection at (±a, 0). So the foci are, in fact, foci in the sense defined by Plücker.[7] The circular points are points of inflection so these are triple foci. When e ≠ 1 the curve has class eight, which implies that there should be at total of eight real foci. Six of these have been accounted for in the two triple foci and the remaining two are at

${\displaystyle (\pm a{\sqrt {1-e^{4}}},0)\quad (e<1)}$

${\displaystyle (0,\pm a{\sqrt {e^{4}-1}})\quad (e>1).}$

So the additional foci are on the x-axis when the curve has two loops and on the y-axis when the curve has a single loop.[8]

Cassini ovals and their orthogonal trajectories (hyperbolas)

Orthogonal trajectories of a given pencil of curves are curves which intersect all given curves orthogonally. For example the orthogonal trajectories of a pencil of confocal ellipses are the confocal hyperbolas with the same foci. For Cassini ovals one has:

• The orthogonal trajectories of the Cassini curves with foci ${\displaystyle P_{1},P_{2}}$ are the equilateral hyperbolas containing ${\displaystyle P_{1},P_{2}}$ with the same center as the Cassini ovals (see picture).

Proof:
For simplicity one chooses ${\displaystyle P_{1}=(1,0),\;P_{2}=(-1,0)}$.

The Cassini ovals have the equation

${\displaystyle f(x,y)\;=\;(x^{2}+y^{2})^{2}-2(x^{2}-y^{2})+1-b^{4}=0.}$

The equilateral hyperbolas (their asymptotes are rectangular) containing ${\displaystyle (1,0),(-1,0)}$ with center ${\displaystyle (0,0)}$ can be described by the equation

${\displaystyle x^{2}-y^{2}-\lambda xy-1=0,\quad \lambda \in \mathbb {R} .}$

These conic sections have no points with the y-axis in common and intersect the x-axis at ${\displaystyle (\pm 1,0)}$. Their discriminants show that these curves are hyperbolas. A more detailed investigation reveals that the hyperbolas are rectangular. In order to get normals, which are independent from parameter ${\displaystyle \lambda }$ the following implicit representation is more convenient:

${\displaystyle g(x,y)\;=\;{\frac {x^{2}-y^{2}-1}{xy}}-\lambda ={\frac {x}{y}}-{\frac {y}{x}}-{\frac {1}{xy}}-\lambda =0\;.}$

A simple calculation shows, that ${\displaystyle \operatorname {grad} f(x,y)\cdot \operatorname {grad} g(x,y)=0}$ for all ${\displaystyle (x,y),\;x\neq 0\neq y}$. Hence the Cassini ovals and the hyperbolas intersect orthogonally.

Remark:
The image depicting the Cassini ovals and the hyperbolas looks like the equipotential curves of two equal point charges together with the lines of the generated electrical field. But for the potential of two equal point charges one has ${\displaystyle {\frac {1}{|PP_{1}|}}+{\frac {1}{|PP_{2}|}}={\text{constant}}}$. (See implicit curve.)

The second lemniscate of the Mandelbrot set is a Cassini oval defined by the equation ${\displaystyle L_{2}=\{c:\operatorname {abs} (c^{2}+c)=ER\}\,}$. Its foci are at the points c on the complex plane that have orbits where every second value of z is equal to zero, which are the values 0 and -1.

Cassini ovals as planar sections of a torus
(the torus on the right is a spindle torus)

Cassini ovals appear as planar sections of tori, but only when

• the cutting plane is parallel to the axis of the torus and its distance to the axis equals the radius of the generating circle (see picture).

The intersection of the torus with equation

${\displaystyle \left(x^{2}+y^{2}+z^{2}+R^{2}-r^{2}\right)^{2}=4R^{2}\left(x^{2}+y^{2}\right)}$

and the plane ${\displaystyle y=r}$ yields

${\displaystyle \left(x^{2}+z^{2}+R^{2}\right)^{2}=4R^{2}\left(x^{2}+r^{2}\right).}$

After partially resolving the first bracket one gets the equation

${\displaystyle \left(x^{2}+z^{2}\right)^{2}-2R^{2}(x^{2}-z^{2})=4R^{2}r^{2}-R^{4},}$

which is the equation of a Cassini oval with parameters ${\displaystyle b^{2}=2Rr,\;a=R}$.

Cassini's method is easy to generalize to curves and surfaces with an arbitrary set of defining points:

• ${\displaystyle |PP_{1}|\cdot |PP_{2}|\cdots |PP_{n}|=b^{n}\ .}$

describes in the planar case an implicit curve and in 3-space an implicit surface.

• 
  curve with 3 defining points
• 
  surface with 6 defining points

• Two-center bipolar coordinates

Bibliography

• J. Dennis Lawrence (1972). A catalog of special plane curves. Dover Publications. pp. 5, 153–155. ISBN 0-486-60288-5.
• R. C. Yates (1952). A Handbook on Curves and Their Properties. Ann Arbor, MI: J. W. Edwards. pp. 8 ff.
• A. B. Basset (1901). An Elementary Treatise on Cubic and Quartic Curves. London: Deighton Bell and Co. pp. 162 ff.
• Lawden, D. F., "Families of ovals and their orthogonal trajectories", Mathematical Gazette 83, November 1999, 410–420.

Wikimedia Commons has media related to Cassini oval.

• Hazewinkel, Michiel, ed. (2001) [1994], "Cassini oval", Encyclopedia of Mathematics, Springer Science+Business Media B.V. / Kluwer Academic Publishers, ISBN 978-1-55608-010-4
• MacTutor description
• Weisstein, Eric W. "Cassini Ovals". MathWorld.
• 2Dcurves.com description
• "MacTutor History of Mathematics" Famous Curves