finite geometry Finite is the opposite of infinite. It may refer to: * Finite number (disambiguation) * Finite set, a set whose cardinality (number of elements) is some natural number * Finite verb, a verb form that has a subject, usually being inflected or marke ...

, PG(3,2) is the smallest three-dimensional projective space. It can be thought of as an extension of the

Fano plane In finite geometry, the Fano plane (after Gino Fano) is a finite projective plane with the smallest possible number of points and lines: 7 points and 7 lines, with 3 points on every line and 3 lines through every point. These points and lines ...

. It has 15 points, 35 lines, and 15 planes. It also has the following properties: * Each point is contained in 7 lines and 7 planes * Each line is contained in 3 planes and contains 3 points * Each plane contains 7 points and 7 lines * Each plane is isomorphic to the Fano plane * Every pair of distinct planes intersect in a line * A line and a plane not containing the line intersect in exactly one point

Constructions

Construction from ''K''₆

Take a

complete graph In the mathematical field of graph theory, a complete graph is a simple undirected graph in which every pair of distinct vertices is connected by a unique edge. A complete digraph is a directed graph in which every pair of distinct vertices is ...

''K''₆. It has 15 edges, 15

perfect matching In graph theory, a perfect matching in a graph is a matching that covers every vertex of the graph. More formally, given a graph , a perfect matching in is a subset of edge set , such that every vertex in the vertex set is adjacent to exactl ...

s and 20 triangles. Create a point for each of the 15 edges, and a line for each of the 20 triangles and 15 matchings. The

incidence structure In mathematics, an incidence structure is an abstract system consisting of two types of objects and a single relationship between these types of objects. Consider the points and lines of the Euclidean plane as the two types of objects and ignore al ...

between each triangle or matching (line) to its three constituent edges (points), induces a PG(3,2).

Construction from Fano planes

Take a Fano plane and apply all 5040 permutations of its 7 points. Discard duplicate planes to obtain a set of 30 distinct Fano planes. Pick any of the 30, and pick the 14 others that have exactly one line in common with the first, not 0 or 3. The

between the 1+14 = 15 Fano planes and the 35 triplets they mutually cover induces a PG(3,2).

Representations

Tetrahedral depiction

PG(3,2) can be represented as a tetrahedron. The 15 points correspond to the 4 vertices + 6 edge-midpoints + 4 face-centers + 1 body-center. The 35 lines correspond to the 6 edges + 12 face-medians + 4 face-incircles + 4 altitudes from a face to the opposite vertex + 3 lines connecting the midpoints of opposite edges + 6 ellipses connecting each edge midpoint with its two non-neighboring face centers. The 15 planes consist of the 4 faces + the 6 "medial" planes connecting each edge to the midpoint of the opposite edge + 4 "cones" connecting each vertex to the incircle of the opposite face + one "sphere" with the 6 edge centers and the body center. This was described by Burkhard Polster.

Square representation

PG(3,2) can be represented as a square. The 15 points are assigned 4-bit binary coordinates from 0001 to 1111, augmented with a point labeled 0000, and arranged in a 4x4 grid. Lines correspond to the equivalence classes of sets of four vertices that XOR together to 0000. With certain arrangements of the vertices in the 4x4 grid, such as the "natural"

row-major In computing, row-major order and column-major order are methods for storing multidimensional arrays in linear storage such as random access memory. The difference between the orders lies in which elements of an array are contiguous in memory. In ...

ordering or the

Karnaugh map The Karnaugh map (KM or K-map) is a method of simplifying Boolean algebra expressions. Maurice Karnaugh introduced it in 1953 as a refinement of Edward W. Veitch's 1952 Veitch chart, which was a rediscovery of Allan Marquand's 1881 ''logi ...

ordering, the lines form symmetric sub-structures like rows, columns, transversals, or rectangles, as seen in the figure. (There are 20160 such orderings, as seen below in the section on Automorphisms.) This representation is possible because geometrically the 35 lines are represented as a bijection with the 35 ways to partition a 4x4 affine space into 4 parallel planes of 4 cells each. This was described by Steven H. Cullinane.

Doily depiction

The Doily diagram often used to represent the

generalized quadrangle In geometry, a generalized quadrangle is an incidence structure whose main feature is the lack of any triangles (yet containing many quadrangles). A generalized quadrangle is by definition a polar space of rank two. They are the with ''n'' = 4 ...

GQ(2,2) is also used to represent PG(3,2). This was described by Richard Doily.

Kirkman's schoolgirl problem

PG(3,2) arises as a background in some solutions of

Kirkman's schoolgirl problem Kirkman's schoolgirl problem is a problem in combinatorics proposed by Rev. Thomas Penyngton Kirkman in 1850 as Query VI in '' The Lady's and Gentleman's Diary'' (pg.48). The problem states: Fifteen young ladies in a school walk out three abre ...

. Two of the seven non-isomorphic solutions to this problem can be embedded as structures in the Fano 3-space. In particular, a ''spread'' of PG(3,2) is a partition of points into disjoint lines, and corresponds to the arrangement of girls (points) into disjoint rows (lines of a spread) for a single day of Kirkman's schoolgirl problem. There are 56 different spreads of 5 lines each. A ''packing'' of PG(3,2) is a partition of the 35 lines into 7 disjoint spreads of 5 lines each, and corresponds to a solution for all seven days. There are 240 packings of PG(3,2), that fall into two conjugacy classes of 120 under the action of PGL(4,2) (the collineation group of the space); a correlation interchanges these two classes.

Automorphisms

The

automorphism group In mathematics, the automorphism group of an object ''X'' is the group consisting of automorphisms of ''X'' under composition of morphisms. For example, if ''X'' is a finite-dimensional vector space, then the automorphism group of ''X'' is the g ...

of PG(3,2) maps lines to lines. The number of automorphisms is given by finding the number of ways of selecting 4 points that are not coplanar; this works out to 15⋅14⋅12⋅8 = 20160 = 8!/2. It turns out that the automorphism group of PG(3,2) is isomorphic to the

alternating group In mathematics, an alternating group is the group of even permutations of a finite set. The alternating group on a set of elements is called the alternating group of degree , or the alternating group on letters and denoted by or Basic pr ...

on 8 elements A₈.

Coordinates

It is known that a PG(''n'',2) can be coordinatized with (GF(2))^{''n'' + 1}, i.e. a bit string of length ''n'' + 1. PG(3,2) can therefore be coordinatized with 4-bit strings. In addition, the line joining points and can be naturally assigned

Plücker coordinates In geometry, Plücker coordinates, introduced by Julius Plücker in the 19th century, are a way to assign six homogeneous coordinates to each line in projective 3-space, P3. Because they satisfy a quadratic constraint, they establish a one-to- ...

where , and the line coordinates satisfy . Each line in projective 3-space thus has six coordinates, and can be represented as a point in projective 5-space; the points lie on the surface .

Notes

References

* * * {{citation, first=Burkard, last=Polster, author-link=Burkard Polster, year=1998, title=A Geometrical Picture Book, publisher=Springer, isbn=978-0-387-98437-7, url-access=registration, url=https://archive.org/details/geometricalpictu0000pols Projective geometry Finite geometry Incidence geometry