Steiner conic

The Steiner conic or more precisely Steiner's generation of a conic, named after the Swiss mathematician Jakob Steiner, is an alternative method to define a non-degenerate projective conic section in a projective plane over a field.

The usual definition of a conic uses a quadratic form (see Quadric (projective geometry)). Another alternative definition of a conic uses a ''hyperbolic polarity''. It is due to '' K. G. C. von Staudt'' and sometimes called a von Staudt conic. The disadvantage of von Staudt's definition is that it only works when the underlying field has odd characteristic (i.e., $Char\ne2$).

Definition of a Steiner conic

*Given two pencils $B(U),B(V)$ of lines at two points $U,V$ (all lines containing $U$ and $V$ resp.) and a projective but not perspective mapping $\pi$ of $B(U)$ onto $B(V)$. Then the intersection points of corresponding lines form a non-degenerate projective conic section (figure 1)

A ''perspective'' mapping $\pi$ of a pencil $B(U)$ onto a pencil $B(V)$ is a bijection (1-1 correspondence) such that corresponding lines intersect on a fixed line $a$, which is called the ''axis'' of the perspectivity $\pi$ (figure 2).

A ''projective'' mapping is a finite product of perspective mappings.

''Simple example:'' If one shifts in the first diagram point $U$ and its pencil of lines onto $V$ and rotates the shifted pencil around $V$ by a fixed angle $\varphi$ then the shift (translation) and the rotation generate a projective mapping $\pi$ of the pencil at point $U$ onto the pencil at $V$. From the inscribed angle theorem one gets: The intersection points of corresponding lines form a circle.

Examples of commonly used fields are the real numbers $\R$, the rational numbers $\Q$ or the complex numbers $\C$. The construction also works over finite fields, providing examples in finite projective planes.

''Remark:''
The fundamental theorem for projective planes states, that a projective mapping in a projective plane over a field ( pappian plane) is uniquely determined by prescribing the images of three lines. That means that, for the Steiner generation of a conic section, besides two points $U,V$ only the images of 3 lines have to be given. These 5 items (2 points, 3 lines) uniquely determine the conic section.

''Remark:''
The notation "perspective" is due to the dual statement: The projection of the points on a line $a$ from a center $Z$ onto a line $b$ is called a perspectivity (see below).

Example

For the following example the images of the lines $a,u,w$ (see picture) are given: $\pi(a)=b, \pi(u)=w, \pi(w)=v$. The projective mapping $\pi$ is the product of the following perspective mappings $\pi_b,\pi_a$: 1) $\pi_b$ is the perspective mapping of the pencil at point $U$ onto the pencil at point $O$ with axis $b$. 2) $\pi_a$ is the perspective mapping of the pencil at point $O$ onto the pencil at point $V$ with axis $a$.
First one should check that $\pi=\pi_a\pi_b$ has the properties: $\pi(a)=b, \pi(u)=w, \pi(w)=v$. Hence for any line $g$ the image $\pi(g)=\pi_a\pi_b(g)$ can be constructed and therefore the images of an arbitrary set of points. The lines $u$ and $v$ contain only the conic points $U$ and $V$ resp.. Hence $u$ and $v$ are tangent lines of the generated conic section.

A ''proof'' that this method generates a conic section follows from switching to the affine restriction with line $w$ as the line at infinity, point $O$ as the origin of a coordinate system with points $U,V$ as points at infinity of the ''x''- and ''y''-axis resp. and point $E=(1,1)$. The affine part of the generated curve appears to be the hyperbola $y=1/x$.

''Remark:''
#The Steiner generation of a conic section provides simple methods for the construction of ellipses, parabolas and hyperbolas which are commonly called the ''parallelogram methods''.
#The figure that appears while constructing a point (figure 3) is the 4-point-degeneration of Pascal's theorem.

Steiner generation of a dual conic

Definitions and the dual generation

Dualizing (see duality (projective geometry)) a projective plane means exchanging the ''points'' with the ''lines'' and the operations ''intersection'' and ''connecting''. The dual structure of a projective plane is also a projective plane. The dual plane of a pappian plane is pappian and can also be coordinatized by homogeneous coordinates. A nondegenerate ''dual conic'' section is analogously defined by a quadratic form.

A dual conic can be generated by Steiner's dual method:

*Given the point sets of two lines $u,v$ and a projective but not perspective mapping $\pi$ of $u$ onto $v$. Then the lines connecting corresponding points form a dual non-degenerate projective conic section.

A ''perspective mapping'' $\pi$ of the point set of a line $u$ onto the point set of a line $v$ is a bijection (1-1 correspondence) such that the connecting lines of corresponding points intersect at a fixed point $Z$, which is called the ''centre'' of the perspectivity $\pi$ (see figure).

A ''projective '' mapping is a finite sequence of perspective mappings.

It is usual, when dealing with dual and common conic sections, to call the common conic section a ''point conic'' and the dual conic a ''line conic''.

In the case that the underlying field has $Char =2$ all the tangents of a point conic intersect in a point, called the ''knot'' (or ''nucleus'') of the conic. Thus, the dual of a non-degenerate point conic is a subset of points of a dual line and not an oval curve (in the dual plane). So, only in the case that $Char\ne2$ is the dual of a non-degenerate point conic a non-degenerate line conic.

Examples

(1) Projectivity given by two perspectivities:

Two lines $u,v$ with intersection point $W$ are given and a projectivity $\pi$ from $u$ onto $v$ by two perspectivities $\pi_A,\pi_B$ with centers $A,B$. $\pi_A$ maps line $u$ onto a third line $o$, $\pi_B$ maps line $o$ onto line $v$ (see diagram). Point $W$ must not lie on the lines $\overline,o$. Projectivity $\pi$ is the composition of the two perspectivities: $\ \pi=\pi_B\pi_A$. Hence a point $X$ is mapped onto $\pi(X)=\pi_B\pi_A(X)$ and the line $x=\overline$ is an element of the dual conic defined by $\pi$.

(If $W$ would be a fixpoint, $\pi$ would be perspective.)

(2) Three points and their images are given:

The following example is the dual one given above for a Steiner conic.

The images of the points $A,U,W$ are given: $\pi(A)=B, \, \pi(U)=W,\, \pi(W)=V$. The projective mapping $\pi$ can be represented by the product of the following perspectivities $\pi_B,\pi_A$:
# $\pi_B$ is the perspectivity of the point set of line $u$ onto the point set of line $o$ with centre $B$.
# $\pi_A$ is the perspectivity of the point set of line $o$ onto the point set of line $v$ with centre $A$.
One easily checks that the projective mapping $\pi=\pi_A\pi_B$ fulfills $\pi(A)=B,\, \pi(U)=W, \, \pi(W)=V$. Hence for any arbitrary point $G$ the image $\pi(G)=\pi_A\pi_B(G)$ can be constructed and line $\overline$ is an element of a non degenerate dual conic section. Because the points $U$ and $V$ are contained in the lines $u$, $v$ resp.,the points $U$ and $V$ are points of the conic and the lines $u,v$ are tangents at $U,V$.

Intrinsic conics in a linear incidence geometry

The Steiner construction defines the conics in a planar linear incidence geometry (two points determine at most one line and two lines intersect in at most one point) ''intrinsically'', that is, using only the collineation group. Specifically, $E(T,P)$ is the ''conic at point'' $P$ ''afforded by the collineation'' $T$, consisting of the intersections of $L$ and $T(L)$ for all lines $L$ through $P$. If $T(P)=P$ or $T(L)=L$ for some $L$ then the conic is ''degenerate''. For example, in the real coordinate plane, the affine type (ellipse, parabola, hyperbola) of $E(T,P)$ is determined by the trace and determinant of the matrix component of $T$, independent of $P$.

By contrast, the collineation group of the real hyperbolic plane $\mathbb^2$consists of isometries. Consequently, the intrinsic conics comprise a small but varied subset of the ''general'' conics, curves obtained from the intersections of projective conics with a hyperbolic domain. Further, unlike the Euclidean plane, there is no overlap between the ''direct'' $E(T,P)$ - $T$ preserves orientation - and the ''opposite'' $E(T,P)$ - $T$ reverses orientation. The direct case includes ''central'' (two perpendicular lines of symmetry) and non-central conics, whereas every opposite conic is central. Even though direct and opposite central conics cannot be congruent, they are related by a quasi-symmetry defined in terms of complementary angles of parallelism. Thus, in any inversive model of $\mathbb^2$, each direct central conic is birationally equivalent to an opposite central conic. In fact, the central conics represent all genus 1 curves with real shape invariant $j\geq1$. A minimal set of representatives is obtained from the central direct conics with common center and axis of symmetry, whereby the shape invariant is a function of the ''eccentricity'', defined in terms of the distance between $P$ and $T(P)$. The orthogonal trajectories of these curves represent all genus 1 curves with $j\leq1$, which manifest as either irreducible cubics or bi-circular quartics. Using the elliptic curve addition law on each trajectory, every general central conic in $\mathbb^2$decomposes uniquely as the sum of two intrinsic conics by adding pairs of points where the conics intersect each trajectory.

Notes

References

*
* (PDF; 891 kB).
* {{citation, first=Bruce E., last=Merserve, title=Fundamental Concepts of Geometry, year=1983, origyear=1959, publisher=Dover, isbn=0-486-63415-9

Conic sections
Theorems in projective geometry