Confocal conic sections

In geometry, two conic sections are called confocal, if they have the same foci. Because ellipses and hyperbolas possess two foci, there are confocal ellipses, confocal hyperbolas and confocal mixtures of ellipses and hyperbolas. In the mixture of confocal ellipses and hyperbolas, any ellipse intersects any hyperbola orthogonally (at right angles). Parabolas possess only one focus, so, by convention, confocal parabolas have the same focus ''and'' the same axis of symmetry. Consequently, any point not on the axis of symmetry lies on two confocal parabolas which intersect orthogonally (see below).

The formal extension of the concept of confocal conics to surfaces leads to confocal quadrics.

Confocal ellipses

An ellipse which is not a circle is uniquely determined by its foci $F_1,\; F_2$ and a point not on the major axis (see the definition of an ellipse as a locus of points). The pencil of confocal ellipses with the foci $F_1=(c,0),\; F_2=(-c,0)$ can be described by the equation
* $\frac+\frac=1 \ , \quad a>c \ ,$
with semi-major axis $a$ as parameter. (The linear eccentricity $c$ is uniquely determined by the foci.)
Because a point of an ellipse uniquely determines the parameter $a$,
* any two ellipses of the pencil have no points in common.

Confocal hyperbolas

A hyperbola is uniquely determined by its foci $F_1,\; F_2$ and a point not on the axes of symmetry. The pencil of confocal hyperbolas with the foci $F_1=(c,0),\; F_2=(-c,0)$ can be described by the equation
* \frac-\frac=1 \ , \quad 0
with the semi-axis $a$ as parameter. (The linear eccentricity $c$ is uniquely determined by the foci.)
Because a point of the hyperbola determines the parameter $a$ uniquely,
* any two hyperbolas of the pencil have no points in common.

Confocal ellipses and hyperbolas

Common representation

From the previous representations of confocal ellipses and hyperbolas one gets a common representation: The equation
* $\frac+\frac=1$
describes an ''ellipse,'' if c, and a ''hyperbola,'' if 0.

In the literature one finds another common representation:
* $\frac+\frac=1\ ,$
with $a,b$ the semi-axes of a given ellipse (hence the foci $F_1,\; F_2$ are given) and $\lambda$ is the parameter of the pencil.

For \lambda one gets confocal ''ellipses'' (it is $a^2-\lambda-(b^2-\lambda)=c^2$) and

for b^2<\lambda confocal ''hyperbolas'' with the foci $F_1,\; F_2$ in common.

Limit curves

At position $\lambda=b^2$ the pencil of confocal curves have as left sided limit curve (infinite flat ellipse) the line section e,e/math> on the x-axis and the right sided limit curve (infinite flat hyperbola) the two intervals $(-\infty,-e],[e,\infty)$. Hence:
*The limit curves at position $\lambda=b^2$ have the two foci $\ F_1=(-e,0), F_2=(e,0)\$ in common.

This property appears in the 3-dimensional case (see below) in an analogous one and leads to the definition of the focal curves (infinite many foci) of confocal quadrics.

Twofold orthogonal system

Considering the pencils of confocal ellipses and hyperbolas (see lead diagram) one gets from the geometrical properties of the normal and tangent at a point (the Ellipse#The Normal bisects the angle between the lines to the foci, normal of an ellipse and the Hyperbola#The tangent bisects the angle between the lines to the foci, tangent of a hyperbola bisect the angle between the lines to the foci) :
* Any ellipse of the pencil intersects any hyperbola orthogonally (see diagram).

Hence, the plane can be covered by an orthogonal net of confocal ellipses and hyperbolas.

This orthogonal net can be used as the base of an elliptic coordinate system.

Confocal parabolas

Parabolas possess only one focus. A parabola can be considered as a limit curve of a pencil of confocal ellipses (hyperbolas), where one focus is kept fixed, while the second one is moved to infinity. If one performs this transformation for a net of confocal ellipses and hyperbolas, one gets a net of two pencils of confocal parabolas.

The equation $y^2=2p(x+p/2)=2px+p^2$ describes a parabola with the origin as focus and the ''x''-axis as axis of symmetry. One considers the two pencils of parabolas:

* $y^2=2px+p^2\ ,\quad p>0\ ,$ are parabolas opening to the ''right'' and
: $y^2=-2qx+q^2\ ,\quad q>0\ ,$ are parabolas opening to the ''left''
: with the focus $F=(0,0)$ in common.
From the definition of a parabola one gets
* the parabolas opening to the right (left) have no points in common.

It follows by calculation that,
* any parabola $y^2=2px+p^2$ opening to the right intersects any parabola $y^2=-2qx+q^2$ opening to the left orthogonally (see diagram). The points of intersection are $(\tfrac,\pm\sqrt)\$.
($\vec n_1=\left(p,\mp \sqrt\right)^T,\ \vec n_2=\left(q,\pm \sqrt\right)^T)$ are normal vectors at the intersection points. Their scalar product is $0$.)

Analogous to confocal ellipses and hyperbolas, the plane can be covered by an orthogonal net of parabolas.

The net of confocal parabolas can be considered as the image of a net of lines parallel to the coordinate axes and contained in the right half of the complex plane by the conformal map $w=z^2$ (see External links).

Graves's theorem: the construction of confocal ellipses by a string

In 1850 the Irish bishop of Limerick Charles Graves proved and published the following method for the construction of confocal ellipses with help of a string:
*If one surrounds a given ellipse E by a closed string, which is longer than the given ellipse's circumference, and draws a curve similar to the gardener's construction of an ellipse (see diagram), then one gets an ellipse, that is confocal to E.
The proof of this theorem uses elliptical integrals and is contained in Klein's book.
Otto Staude extended this method to the construction of confocal ellipsoids (see Klein's book).

If ellipse E collapses to a line segment $F_1F_2$, one gets a slight variation of the gardener's method drawing an ellipse with foci $F_1,F_2$.

Confocal quadrics

Definition

The idea of confocal quadrics is a formal extension of the concept of confocal conic sections to quadrics in 3-dimensional space

Fix three real numbers $a,b,c$ with $a>b>c>0$.
The equation
* $\frac+\frac+\frac=1$ describes
: an '' ellipsoid'' if \lambda ,
: a '' hyperboloid of one sheet'' if c^2<\lambda (in the diagram: blue),
: a ''hyperboloid of two sheets'' if b^2<\lambda .
: For $a^2<\lambda$ there are no solutions.
(In this context the parameter $c$ is ''not'' the linear eccentricity of an ellipse !)

Focal curves

Limit surfaces for $\lambda\to c^2$:

Varying the ellipsoids by ''increasing'' parameter $\lambda$ such that it approaches the value $c^2$ from below one gets an infinite flat ellipsoid. More precise: the area of the x-y-plane, that consists of the ellipse $E$ with equation $\tfrac+\tfrac=1$ and its doubly covered ''interior'' (in the diagram: below, on the left, red).

Varying the 1-sheeted hyperboloids by ''decreasing'' parameter $\lambda$ such that it approaches the value $c^2$ from above one gets an infinite flat hyperboloid. More precise: the area of the x-y-plane, that consists of the same ellipse $E$ and its doubly covered ''exterior'' (in the diagram: bottom, on the left, blue).

That means: The two limit surfaces have the points of ellipse
:$E: \frac+\frac=1$
in common.

Limit surfaces for $\lambda\to b^2$:

Analogous considerations at the position $\lambda=b^2$ yields:

The two limit surfaces (in diagram: bottom, right, blue and purple) at position $b^2$ have the hyperbola
:$H:\ \frac-\frac=1$
in common.

Focal curves:

One easily checks, that the foci of the ellipse are the vertices of the hyperbola and vice versa. That means: Ellipse $E$ and hyperbola $H$ are a pair of focal conics.

Reverse: Because any quadric of the pencil of confocal quadrics determined by $a,b,c$ can be constructed by a pins-and-string method (see ellipsoid) the focal conics $E,H$ play the role of infinite many foci and are called focal curves of the pencil of confocal quadrics.

Threefold orthogonal system

Analogous to the case of confocal ellipses/hyperbolas one has:
* Any point $(x_0, y_0, z_0)\in \R^3$ with $x_0 \ne 0,\; y_0 \ne 0,\; z_0 \ne 0$ lies on ''exactly one surface'' of any of the three types of confocal quadrics.
: The three quadrics through a point $(x_0, y_0, z_0)$ intersect there ''orthogonally'' (see external link).

Proof of the ''existence and uniqueness'' of three quadrics through a point:

For a point $(x_0,y_0,z_0)$ with $x_0\ne 0, y_0\ne 0,z_0\ne 0$ let be
$f(\lambda)=\frac+\frac+\frac-1$.
This function has three vertical asymptotes c^2 and is in any of the open intervals $(-\infty,c^2),\;(c^2,b^2),\;(b^2,a^2),\;(a^2,\infty)$ a continuous and monotone increasing function. From the behaviour of the function near its vertical asymptotes and from $\lambda \to \pm \infty$ one finds (see diagram):

Function $f$ has exactly 3 zeros $\lambda_1, \lambda_2, \lambda_3$ with

Proof of the ''orthogonality'' of the surfaces:

Using the pencils of functions
$F_\lambda(x,y,z)=\frac+\frac+\frac$
with parameter $\lambda$ the confocal quadrics can be described by $F_\lambda(x,y,z)=1$. For any two intersecting quadrics with $F_(x,y,z)=1,\; F_(x,y,z)=1$ one gets at a common point $(x,y,z)$
:$0=F_(x,y,z) - F_(x,y,z)= \dotsb$
:$\ =(\lambda_i-\lambda_k)\left(\frac+\frac+\frac\right)\ .$
From this equation one gets for the scalar product of the gradients at a common point
: $\operatorname F_\cdot \operatorname F_=4\;\left(\frac+\frac+\frac\right)=0\ ,$
which proves the orthogonality.

Applications:

Due to Dupin's theorem on threefold orthogonal systems of surfaces the following statement is true:
*The intersection curve of any two confocal quadrics is a line of curvature.
*Analogously to the planar elliptic coordinates there exist ellipsoidal coordinates.
In physics confocal ellipsoids appear as equipotential surfaces:
*The equipotential surfaces of a charged ellipsoid are its confocal ellipsoids. D. Fuchs, S. Tabachnikov: ''Ein Schaubild der Mathematik.'' Springer-Verlag, Berlin/Heidelberg 2011, , p. 480.

Ivory's theorem

Ivory's theorem, named after the Scottish mathematician and astronomer James Ivory (1765–1842), is a statement on the diagonals of a ''net-rectangle'', a quadrangle formed by orthogonal curves:
* For any net-rectangle, which is formed by two confocal ellipses and two confocal hyperbolas with the same foci, the ''diagonals have equal length'' (see diagram).

Intersection points of an ellipse and a confocal hyperbola:

Let $E(a)$ be the ellipse with the foci $F_1=(c,0),\; F_2=(-c,0)$ and the equation
: $\frac+\frac=1 \ , \quad a>c>0 \$
and $H(u)$ the confocal hyperbola with equation
: $\frac+\frac=1 \ , \quad c>u \ .$
Computing the ''intersection points'' of $E(a)$ and $H(u)$ one gets the four points:
* $\left(\pm \fracc,\; \pm \fracc\right)$

Diagonals of a net-rectangle:

In order to keep the calculation simple, it is supposed that
# $c=1$, which is no essential restriction, because any other confocal net can be obtained by a uniform scaling.
# From the possible alternatives $\pm$ (see Intersection points, above)) only $+$ is used. At the end, one considers easily, that any other combination of signs yields the same result.

Let be $E(a_1), E(a_2)$ two confocal ellipses and $H(u_1), H(u_2)$ two confocal hyperbolas with the same foci. The diagonals of the four points of the net-rectangle consisting of the points
: $P_=\left(a_1u_1,\; \sqrt\right)\ ,\quad P_=\left(a_2u_2,\; \sqrt\right)\ ,$
: $P_=\left(a_1u_2,\; \sqrt\right)\ ,\quad P_=\left(a_2u_1,\;\sqrt\right)$
are:
: $\begin , P_P_, ^2 &= (a_2u_2-a_1u_1)^2+\left(\sqrt-\sqrt\right)^2 = \dotsb \\ &= a_1^2+a_2^2+u_1^2+u_2^2-2\, \left(1+a_1a_2u_1u_2+\sqrt\right) \end$
Obviously the last expression is invariant, if one performs the exchange
$u_1\leftrightarrow u_2$. Exactly this exchange leads to $, P_P_, ^2$. Hence one gets :
*: $, P_P_, =, P_P_,$

The proof of the statement for confocal ''parabolas'' is a simple calculation.

Ivory even proved the 3-dimensional version of his theorem (s. Blaschke, p. 111):
*For a 3-dimensional rectangular cuboid formed by confocal quadrics the diagonals connecting opposite points have equal length.

See also

* Focaloid

References

* W. Blaschke: ''Analytische Geometrie.'' Springer, Basel 1954,, p. 111.
*G. Glaeser,H. Stachel,B. Odehnal: ''The Universe of Conics: From the ancient Greeks to 21st century developments'', Springer Spektrum, , p. 457.
* {{citation, title = Geometry and the Imagination , author = David Hilbert , author2=Stephan Cohn-Vossen, authorlink2=Stephan Cohn-Vossen, year = 1999 , publisher = American Mathematical Society , isbn = 0-8218-1998-4
* Ernesto Pascal: ''Repertorium der höheren Mathematik.'' Teubner, Leipzig/Berlin 1910, p. 257.
*A. Robson: ''An Introduction to Analytical Geometry'' Vo. I, Cambridge, University Press, 1940, p. 157.
*D.M.Y. Sommerville: ''Analytical Geometry of Three Dimensions'', Cambridge, University Press, 1959, p. 235.

External links

* T. Hofmann
Differentialgeometrie I, p. 48''
* B. Springborn: tp://ftp.math.tu-berlin.de/pub/Lehre/Diffgeo1/SS06/miniskript-kuf-SS06.pdf ''Kurven und Flächen'', 12. Vorlesung: Konfokale Quadriken(S. 22 f.).
* H. Walser:
Konforme Abbildungen.
' p. 8.

*