Polar space

In mathematics, in the field of geometry, a polar space of rank n (n ≥ 3), or projective index n − 1, consists of a set P, conventionally called the set of points, together with certain subsets of P, called subspaces, that satisfy these axioms: In mathematics, in the field of geometry, a polar space of rank n (n ≥ 3), or projective index n − 1, consists of a set P, conventionally called the set of points, together with certain subsets of P, called subspaces, that satisfy these axioms: It is possible to define and study a slightly bigger class of objects using only relationship between points and lines: a polar space is a partial linear space (P,L), so that for each point p ∈ P andeach line l ∈ L, the set of points of l collinear to p, is either a singleton or the whole l. Finite polar spaces (where P is a finite set) are also studied as combinatorial objects. A polar space of rank two is a generalized quadrangle; in this case, in the latter definition, the set of points of a line ℓ collinear with a point p is the whole ℓ only if p ∈ ℓ. One recovers the former definition from the latter under the assumptions that lines have more than 2 points, points lie on more than 2 lines, and there exist a line ℓ and a point p not on ℓ so that p is collinear to all points of ℓ. Let P G ( n , q ) {displaystyle PG(n,q)} be the projective space of dimension n {displaystyle n} over the finite field F q {displaystyle mathbb {F} _{q}} and let f {displaystyle f} be a reflexive sesquilinear form or a quadratic form on the underlying vector space. Then the elements of the finite classical polar space associated with this form consists of the totally isotropic subspaces (when f {displaystyle f} is a sesquilinear form) or the totally singular subspaces (when f {displaystyle f} is a quadratic form) of P G ( n , q ) {displaystyle PG(n,q)} with respect to f {displaystyle f} . The Witt index of the form is equal to the largest vector space dimension of the subspace contained in the polar space, and it is called the rank of the polar space. These finite classical polar spaces can be summarised by the following table, where n {displaystyle n} is the dimension of the underlying projective space and r {displaystyle r} is the rank of the polar space. The number of points in a P G ( k , q ) {displaystyle PG(k,q)} is denoted by θ k ( q ) {displaystyle heta _{k}(q)} and it is equal to q k + q k − 1 + ⋯ + 1 {displaystyle q^{k}+q^{k-1}+cdots +1} . When r {displaystyle r} is equal to 2 {displaystyle 2} , we get a generalized quadrangle. Jacques Tits proved that a finite polar space of rank at least three, is always isomorphic with one of the three types of classical polar spaces given above. This leaves open only the problem of classifying the finite generalized quadrangles.