Projective configuration

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In mathematics, specifically projective geometry, a projective configuration consists of a finite set of points, and a finite set of lines, such that each point is incident to the same number of lines and each line is incident to the same number of points. A configuration is denoted by the notation (p_γl_π), where p denotes the number of points, l denotes the number of lines, γ denotes the number of lines per point, and π denotes the number of points per line. These numbers necessarily satisfy the equation

as this product is the number of point-line incidences.

The notation (p_γl_π) does not determine a projective configuration up to incidence isomorphism. For instance, there exist three different (9_{3 93) configurations: the Pappus configuration and two less notable configurations.}

The projective dual to a configuration (p_γl_π) is a configuration (l_πp_γ). Thus, types of configurations come in dual pairs, except when p = l and the configuration type is self-dual.

Contents 1 Examples 2 The number of (n3n3) configurations 3 Higher dimensions 4 References 5 External links

[edit] Examples

Notable projective configurations include the following:

• (1₁1₁), the simplest possible configuration, consisting of a point incident to a line.
• (3₂3₂), the triangle. Each of its three sides meets two of its three vertices, and vice versa. More generally any polygon of n sides forms a configuration of type (n₂n₂)
• (4₃6₂) and (6₂4₃), the complete quadrangle and complete quadrilateral respectively.
• (7₃7₃), the Fano plane. This configuration exists as an abstract incidence geometry, but cannot be constructed in the Euclidean plane.
• (8₃8₃), the Möbius-Kantor configuration. This configuration describes two quadrilaterals that are simultaneously inscribed and circumscribed in each other. It cannot be constructed in Euclidean plane geometry but the equations defining it have nontrivial solutions in complex numbers.
• (9₃9₃), the Pappus configuration.
• (10₃10₃), the Desargues configuration.

[edit] The number of (n₃n₃) configurations

The number of nonisomorphic configurations of type (n₃n₃), starting at n = 7, is given by the sequence

1, 1, 3, 10, 31, 229, 2036, 21399, 245342, ... (sequence A001403 in OEIS)

These numbers count configurations as abstract incidence structures, regardless of realizability. As Gropp (1997) discusses, nine of the ten (10₃10₃) configurations, and all of the (11₃11₃) and (12₃12₃) configurations, are realizable in the Euclidean plane, but for each n ≥ 16 there is at least one nonrealizable (n₃n₃) configuration. Gropp also points out a long-lasting error in this sequence: an 1895 paper attempted to list all (12₃12₃) configurations, and found 228 of them, but the 229th configuration was not discovered until 1988.

[edit] Higher dimensions

The concept of a configuration may be generalized to higher dimensions, for instance to points and lines or planes in space. Notable three-dimensional configurations are Reye's configuration, consisting of twelve points and twelve planes, with six points per plane and six planes per point, the Gray configuration consisting of a 3×3×3 grid of 27 points and the 27 orthogonal lines through them, and the Schläfli double six, a configuration with 45 points, 27 lines, three lines per point, and five points per line.

[edit] References

• Berman, Leah W.. "Movable (n₄) configurations". The Electronic Journal of Combinatorics 13 (1): R104.  See also Berman's animations of movable configurations.

• Gropp, Harald (1997). "Configurations and their realization". Discrete Mathematics 174 (1–3): 137–151. DOI:10.1016/S0012-365X(96)00327-5. 

• Grünbaum, Branko (2006). "Configurations of points and lines". Davis, Chandler; Ellers, Erich W. (Eds.) The Coxeter Legacy: Reflections and Projections: 179–225, American Mathematical Society. 

• Hilbert, David; Cohn-Vossen, Stephan (1952). Geometry and the Imagination, 2nd ed., Chelsea, 94–170. ISBN 0-8284-1087-9. 

[edit] External links

• Eric W. Weisstein, Configuration at MathWorld.