Combinatorial geometry(2)

A finite set together with a closure relation

defined for all subsets of (that is, , implies and , but not necessarily ), and satisfying the conditions: 1) for the empty set ; 2) for each element ; and 3) if and and if but , then (the "exchange" property). The closed sets, or subspaces, form a geometric lattice (cf. Semi-Dedekind lattice). A subset is independent if for all ; all maximal independent sets, or bases, have the same cardinality. The direct sum of combinatorial geometries and the restriction of a combinatorial geometry to a subset are defined in the usual way. The cardinality of the bases of the restriction of a combinatorial geometry to is called the rank of . The rank function satisfies the condition

A subset for which is said to be dependent; the minimal dependent sets of a combinatorial geometry are called circuits. By dropping conditions 1) and 2) in the definition of a combinatorial geometry one obtains the definition of a pre-geometry or matroid. Infinite combinatorial geometries are also considered, but here it is required that the bases be finite.

Example of a combinatorial geometry. A subset of a vector space with the relation

defined for all , where is the linear subspace in spanned by .

One of the fundamental problems in the theory of combinatorial geometries is the so-called critical problem. For the combinatorial geometry defined by a set in an -dimensional projective space over a Galois field, this problem consists in the determination of the smallest positive integer (the critical exponent) for which there exists a family of hyperplanes distinguishing . (A family of hyperplanes distinguishes a set if for every there is at least one hyperplane not containing .)

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