Steiner conic

1. Definition of the Steiner generation of a conic section
2. Perspective mapping between lines
Example of a Steiner generation: generation of a point

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

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 sequence of perspective mappings.

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,[5] 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).[5]

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.[2]

Remark:

  1. 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.
  2. The figure that appears while constructing a point (figure 3) is the 4-point-degeneration of Pascal's theorem.[6]

Steiner generation of a dual conic

dual ellipse
Steiner generation of a dual conic
definition of a perspective mapping
example of a 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 homogenous coordinates. A nondegenerate dual conic section is analogously defined by a quadratic form.

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

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.

Example

For the following example 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:

1) \pi_B is the perspectivity of the point set of line u onto the point set of line o with centre B.
2) \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{G\pi(G)} 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.

Notes

  1. Coxeter 1993, p. 80
  2. 1 2 Hartmann, p. 38
  3. Merserve 1983, p. 65
  4. Jacob Steiner’s Vorlesungen über synthetische Geometrie, B. G. Teubner, Leipzig 1867 (from Google Books: (German) Part II follows Part I) Part II, pg. 96
  5. 1 2 Hartmann, p. 19
  6. Hartmann, p. 32

References

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