Hippopede: Difference between revisions

Content deleted Content added

Inline

Latest revision as of 12:18, 10 March 2024

Hippopede (red) given as the pedal curve of an ellipse (black). The equation of this hippopede is: $4x^{2}+y^{2}=(x^{2}+y^{2})^{2}$

In geometry, a hippopede (from Ancient Greek ἱπποπέδη (hippopédē) 'horse fetter') is a plane curve determined by an equation of the form

(x^{2}+y^{2})^{2}=cx^{2}+dy^{2},

where it is assumed that $c > 0$ and $c > d$ since the remaining cases either reduce to a single point or can be put into the given form with a rotation. Hippopedes are bicircular, rational, algebraic curves of degree 4 and symmetric with respect to both the $x$ and $y$ axes.

Special cases

When d > 0 the curve has an oval form and is often known as an oval of Booth, and when d < 0 the curve resembles a sideways figure eight, or lemniscate, and is often known as a lemniscate of Booth, after 19th-century mathematician James Booth who studied them. Hippopedes were also investigated by Proclus (for whom they are sometimes called Hippopedes of Proclus) and Eudoxus. For d = −c, the hippopede corresponds to the lemniscate of Bernoulli.

Definition as spiric sections

Hippopedes with a = 1, b = 0.1, 0.2, 0.5, 1.0, 1.5, and 2.0.

Hippopedes with b = 1, a = 0.1, 0.2, 0.5, 1.0, 1.5, and 2.0.

Hippopedes can be defined as the curve formed by the intersection of a torus and a plane, where the plane is parallel to the axis of the torus and tangent to it on the interior circle. Thus it is a spiric section which in turn is a type of toric section.

If a circle with radius a is rotated about an axis at distance b from its center, then the equation of the resulting hippopede in polar coordinates

r^{2}=4b(a-b\sin ^{2}\!\theta )

or in Cartesian coordinates

(x^{2}+y^{2})^{2}+4b(b-a)(x^{2}+y^{2})=4b^{2}x^{2}

.

Note that when a > b the torus intersects itself, so it does not resemble the usual picture of a torus.

References

Lawrence JD. (1972) Catalog of Special Plane Curves, Dover Publications. Pp. 145–146.
Booth J. A Treatise on Some New Geometrical Methods, Longmans, Green, Reader, and Dyer, London, Vol. I (1873) and Vol. II (1877).
Weisstein, Eric W. "Hippopede". MathWorld.
"Hippopede" at 2dcurves.com
"Courbes de Booth" at Encyclopédie des Formes Mathématiques Remarquables

External links

"The Hippopede of Proclus" at The National Curve Bank

@@ Line 1: / Line 1: @@
+{{short description|1=Plane curves of the form (x² + y²)² = cx² + dy²}}
-{{mergefrom|Lemniscate of Booth|date=August 2008}}
+[[Image:PedalCurve1.gif|500px|right|thumb|Hippopede (red) given as the [[pedal curve]] of an [[ellipse]] (black). The equation of this hippopede is: <math>4x^2 + y^2 = (x^2 + y^2)^2</math>]]
-In [[geometry]], a '''hippopede''' (from ἱπποπέδη meaning "horse fetter" in ancient Greek) is a [[plane curve]] determined by an equation of the form
+In [[geometry]], a '''hippopede''' ({{ety|grc|''ἱπποπέδη'' (hippopédē)|horse [[Legcuffs|fetter]]}}) is a [[plane curve]] determined by an equation of the form
-:<math>(x^2+y^2)^2=cx^2+dy^2</math>,
+:<math>(x^2+y^2)^2=cx^2+dy^2,</math>
-where it is assumed that ''c''>0 and ''c''>''d'' since the remaining cases either reduce to a single point or be put into the given form with a rotation. Hippopedes are [[circular algebraic curve|bicircular]] [[Algebraic curve|rational algebraic curves]] of degree 4 and symmetric with respect to both the ''x'' and ''y'' axes. In fact, they are the only curves with these properties. Hippopedes were investigated by [[Proclus]], [[Eudoxus]] and, more recently, '''J.&nbsp;Booth''' (1810&ndash;1878).  For ''d''&nbsp;=&nbsp;−''c'', the hippopede corresponds to the [[lemniscate of Bernoulli]].
+where it is assumed that {{math|''c'' > 0}} and {{math|''c'' > ''d''}} since the remaining cases either reduce to a single point or can be put into the given form with a rotation. Hippopedes are [[circular algebraic curve|bicircular]], [[Rational number|rational]], [[algebraic curve]]s of [[Degree of a polynomial|degree]] 4 and symmetric with respect to both the {{mvar|x}} and {{mvar|y}} axes.
+==Special cases==
+When ''d'' > 0 the curve has an oval form and is often known as an '''oval of Booth''', and when {{nowrap|''d'' < 0}} the curve resembles a sideways figure eight, or [[lemniscate]], and is often known as a '''lemniscate of Booth''', after 19th-century mathematician [[James Booth (mathematician)|James Booth]] who studied them. Hippopedes were also investigated by [[Proclus]] (for whom they are sometimes called '''Hippopedes of Proclus''') and [[Eudoxus of Cnidus|Eudoxus]].  For {{nowrap|1=''d'' = −''c''}}, the hippopede corresponds to the [[lemniscate of Bernoulli]].
+{{-}}
 ==Definition as spiric sections==
-[[Image:Hippopede02.png|thumb|300px|Hippopedes with ''a'' = 1, ''b'' = 0.1, 0.2, 0.5, 1.0, 1.5, and 2.0.]]
+[[Image:Hippopede02.svg|right|thumb|350px|Hippopedes with ''a'' = 1, ''b'' = 0.1, 0.2, 0.5, 1.0, 1.5, and 2.0.]]
-[[Image:Hippopede01.png|thumb|300px|Hippopedes with ''b'' = 1, ''a'' = 0.1, 0.2, 0.5, 1.0, 1.5, and 2.0.]]
+[[Image:Hippopede01.svg|right|thumb|350px|Hippopedes with ''b'' = 1, ''a'' = 0.1, 0.2, 0.5, 1.0, 1.5, and 2.0.]]
 Hippopedes can be defined as the curve formed by the intersection of a [[torus]] and a plane, where the plane is parallel to the axis of the torus and tangent to it on the interior circle. Thus it is a [[spiric section]] which in turn is a type of [[toric section]].
 If a circle with radius ''a'' is rotated about an axis at distance ''b'' from its center, then the equation of the resulting hippopede in [[polar coordinate]]s
 :<math>
-r^2 = 4 b (a- b \sin^{2} \theta)\,
+r^2 = 4 b (a - b \sin^{2}\! \theta)
 </math>
 or in [[Cartesian coordinate]]s
 :<math>(x^2+y^2)^2+4b(b-a)(x^2+y^2)=4b^2x^2</math>.
-Note that when ''a''>''b'' the torus intersects itself, so it does not resemble the usual picture of a torus.
+Note that when ''a'' > ''b'' the torus intersects itself, so it does not resemble the usual picture of a torus.
-==See Also==
+==See also==
 * [[List of curves]]
 ==References==
+*Lawrence JD. (1972) ''Catalog of Special Plane Curves'', Dover Publications.  Pp.&nbsp;145&ndash;146.
+*Booth J. ''A Treatise on Some New Geometrical Methods'', Longmans, Green, Reader, and Dyer, London, Vol. I (1873) and Vol. II (1877).
-* Lawrence JD. (1972) ''Catalog of Special Plane Curves'', Dover.  Pp.145&ndash;146.
+*{{MathWorld|title=Hippopede|urlname=Hippopede}}
+*[http://www.2dcurves.com/quartic/quartich.html "Hippopede" at 2dcurves.com]
-* Booth J. ''A Treatise on Some New Geometrical Methods'', Longmans, Green, Reader, and Dyer, London, Vol. I (1873) and Vol. II (1877).
+*[http://www.mathcurve.com/courbes2d/booth/booth.shtml "Courbes de Booth" at Encyclopédie des Formes Mathématiques Remarquables]
 ==External links==
+*[https://web.archive.org/web/20090318143501/http://curvebank.calstatela.edu/hippopede/hippopede.htm "The Hippopede of Proclus" at The National Curve Bank]
+[[Category:Quartic curves]]
-* [http://mathworld.wolfram.com/Hippopede.html MathWorld description]
-* [http://www.2dcurves.com/quartic/quartich.html 2Dcurves.com description]
-[[Category:Curves]]
-[[Category:Algebraic curves]]
 [[Category:Spiric sections]]
-{{geometry-stub}}
-[[it:ippopede]]