Pappus configuration

In geometry, the Pappus configuration is a configuration of nine points and nine lines in the Euclidean plane, with three points per line and three lines through each point.^[1]

History and construction[edit]

This configuration is named after Pappus of Alexandria. Pappus's hexagon theorem states that every two triples of collinear points $ABC$ and $abc$ (none of which lie on the intersection of the two lines) can be completed to form a Pappus configuration, by adding the six lines $Ab$ , $aB$ , $Ac$ , $aC$ , $Bc$ , and $bC$ , and their three intersection points $X = Ab \cdot aB$ , $Y = Ac \cdot aC$ , and $Z = Bc \cdot bC$ . These three points are the intersection points of the "opposite" sides of the hexagon $AbCaBc$ . According to Pappus' theorem, the resulting system of nine points and eight lines always has a ninth line containing the three intersection points $X$ , $Y$ , and $Z$ , called the Pappus line.^[2]

The Pappus configuration can also be derived from two triangles $△ XcC$ and $△ YbB$ that are in perspective with each other (the three lines through corresponding pairs of points meet at a single crossing point) in three different ways, together with their three centers of perspectivity $Z$ , $a$ , and $A$ . The points of the configuration are the points of the triangles and centers of perspectivity, and the lines of the configuration are the lines through corresponding pairs of points.

Related constructions[edit]

The Levi graph of the Pappus configuration is known as the Pappus graph. It is a bipartite symmetric cubic graph with 18 vertices and 27 edges.^[3]

Adding three more parallel lines to the Pappus configuration, through each triple of points that are not already connected by lines of the configuration, produces the Hesse configuration.^[4]

Like the Pappus configuration, the Desargues configuration can be defined in terms of perspective triangles, and the Reye configuration can be defined analogously from two tetrahedra that are in perspective with each other in four different ways, forming a desmic system of tetrahedra.

For any nonsingular cubic plane curve in the Euclidean plane, three real inflection points of the curve, and a fourth point on the curve, there is a unique way of completing these four points to form a Pappus configuration in such a way that all nine points lie on the curve.^[5]

Applications[edit]

A variant of the Pappus configuration provides a solution to the orchard-planting problem, the problem of finding sets of points that have the largest possible number of lines through three points. The nine points of the Pappus configuration form only nine three-point lines. However, they can be arranged so that there is another three-point line, making a total of ten. This is the maximum possible number of three-point lines through nine points.^[6]

References[edit]

^ Grünbaum, Branko (2009), Configurations of points and lines, Graduate Studies in Mathematics, vol. 103, Providence, RI: American Mathematical Society, ISBN 978-0-8218-4308-6, MR 2510707.
^ Grünbaum (2009), p. 9.
^ Grünbaum (2009), p. 28.
^ Coxeter, H. S. M. (1950), "Self-dual configurations and regular graphs", Bulletin of the American Mathematical Society, 56 (5): 413–455, doi:10.1090/S0002-9904-1950-09407-5
^ Mendelsohn, N. S.; Padmanabhan, R.; Wolk, Barry (1987), "Some remarks on "n"-clusters on cubic curves", in Colbourn, Charles J.; Mathon, R. A. (eds.), Combinatorial Design Theory, Annals of Discrete Mathematics, vol. 34, Elsevier, pp. 371–378, doi:10.1016/S0304-0208(08)72903-7, ISBN 9780444703286, MR 0920661.
^ Sloane, N. J. A. (ed.), "Sequence A003035", The On-Line Encyclopedia of Integer Sequences, OEIS Foundation

External links[edit]

Weisstein, Eric W., "Pappus Configuration", MathWorld

[1] Grünbaum, Branko (2009), Configurations of points and lines, Graduate Studies in Mathematics, vol. 103, Providence, RI: American Mathematical Society, ISBN 978-0-8218-4308-6, MR 2510707.

[2] Grünbaum (2009), p. 9.

[3] Grünbaum (2009), p. 28.

[4] Coxeter, H. S. M. (1950), "Self-dual configurations and regular graphs", Bulletin of the American Mathematical Society, 56 (5): 413–455, doi:10.1090/S0002-9904-1950-09407-5

[5] Mendelsohn, N. S.; Padmanabhan, R.; Wolk, Barry (1987), "Some remarks on "n"-clusters on cubic curves", in Colbourn, Charles J.; Mathon, R. A. (eds.), Combinatorial Design Theory, Annals of Discrete Mathematics, vol. 34, Elsevier, pp. 371–378, doi:10.1016/S0304-0208(08)72903-7, ISBN 9780444703286, MR 0920661.

[6] Sloane, N. J. A. (ed.), "Sequence A003035", The On-Line Encyclopedia of Integer Sequences, OEIS Foundation

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v t e Incidence structures
Representation	Incidence matrix Incidence graph
Fields	Combinatorics Block design Steiner system Geometry Incidence Projective plane Graph theory Hypergraph Statistics Blocking
Configurations	Complete quadrangle Fano plane Möbius–Kantor configuration Pappus configuration Hesse configuration Desargues configuration Reye configuration Schläfli double six Cremona–Richmond configuration Kummer configuration Grünbaum–Rigby configuration Klein configuration Dual
Theorems	Sylvester–Gallai theorem De Bruijn–Erdős theorem Szemerédi–Trotter theorem Beck's theorem Bruck–Ryser–Chowla theorem
Applications	Design of experiments Kirkman's schoolgirl problem