The Cassini ovals are a family of quartic curves, also called Cassini ellipses, described by a point such that the product
of its distances from two fixed points a distance  apart is a constant
 . The shape of the curve depends on  . If  , the curve
is a single loop with an oval (left figure
above) or dog bone (second figure) shape. The case  produces a lemniscate (third figure). If  , then the curve consists of two loops (right
figure). Cassini ovals are anallagmatic
curves.
A series of ovals for values of  to 1.5 are
illustrated above.
The curve was first investigated by Cassini in 1680 when he was studying the relative motions of the Earth and the Sun. Cassini believed that the Sun traveled around the
Earth on one of these ovals, with the Earth at one focus
of the oval.
The Cassini ovals are defined in two-center bipolar
coordinates by the equation
 |
(1)
|
with the origin at a focus. Even more incredible curves are produced by the locus of a point the product of whose distances
from 3 or more fixed points is a constant.
The Cassini ovals have the Cartesian
equation
![[(x-a)^2+y^2][(x+a)^2+y^2]=b^4](/images/equations/CassiniOvals/NumberedEquation2.gif) |
(2)
|
or the equivalent form
 |
(3)
|
and the polar equation
 |
(4)
|
Solving for  using the quadratic equation gives
Let a torus of tube radius  be cut by a plane
perpendicular to the plane of the torus's centroid. Call the distance of this plane
from the center of the torus hole  , let  , and consider
the intersection of this plane with the torus as  is varied. The
resulting curves are Cassini ovals, with a lemniscate
occurring at  . Cassini ovals are therefore toric sections.
If  , the curve has area
 |
(10)
|
where the integral has been done over half the curve and then multiplied by two and  is the complete elliptic integral of the second kind. If  , the curve becomes
![r^2=a^2[cos(2theta)+sqrt(1-sin^2theta)]=2a^2cos(2theta),](/images/equations/CassiniOvals/NumberedEquation6.gif) |
(11)
|
which is a lemniscate having area
 |
(12)
|
(two loops of a curve  the linear scale of the usual
lemniscate  , which has area  for each loop). If  , the curve
becomes two disjoint ovals with equations
 |
(13)
|
where ![theta in [-theta_0,theta_0]](/images/equations/CassiniOvals/Inline36.gif) and
![theta_0=1/2sin^(-1)[(b/a)^2].](/images/equations/CassiniOvals/NumberedEquation9.gif) |
(14)
|
Beyer, W. H. CRC Standard Mathematical Tables, 28th ed. Boca Raton,
FL: CRC Press, p. 221, 1987.
Gray, A. "Cassinian Ovals." §4.2 in Modern Differential Geometry of Curves and Surfaces with Mathematica,
2nd ed. Boca Raton, FL: CRC Press, pp. 82-86, 1997.
Kabai, S. Mathematical Graphics I: Lessons in Computer Graphics Using Mathematica.
Püspökladány, Hungary: Uniconstant, p. 145, 2002.
Lawrence, J. D. A Catalog of Special Plane Curves. New York: Dover, pp. 153-155,
1972.
Lockwood, E. H. A Book of Curves. Cambridge, England: Cambridge University
Press, pp. 187-188, 1967.
MacTutor History of Mathematics Archive. "Cassinian Ovals." http://www-groups.dcs.st-and.ac.uk/~history/Curves/Cassinian.html.
Piziak, R. and Turner, D. "Exploring Gerschgorin Circles and Cassini Ovals."
Mathematica Educ. 3, 13-21, 1994.
Wells, D. The Penguin Dictionary of Curious and Interesting Geometry.
London: Penguin, pp. 25-26, 1991.
Yates, R. C. "Cassinian Curves." A Handbook on Curves and Their Properties. Ann Arbor, MI:
J. W. Edwards, pp. 8-11, 1952.
| 
![a^2cos(2theta)+/-sqrt(a^4[cos^2(2theta)-1]+b^4)](/images/equations/CassiniOvals/Inline17.gif)
![a^2[cos(2theta)+/-sqrt((b/a)^4-sin^2(2theta))].](/images/equations/CassiniOvals/Inline23.gif)
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