Counting edges of different types in a local graph of a Grassmann graph

Abstract

Let Fq denote a finite field with q elements. Let n,k denote integers with n>2k≥ 6. Let V denote a vector space over Fq that has dimension n. The vertex set of the Grassmann graph Jq(n,k) consists of the k-dimensional subspaces of V. Two vertices of Jq(n,k) are adjacent whenever their intersection has dimension k-1. Let ∂ denote the path-length distance function of Jq(n,k). Pick a vertex y. In this paper we define three types of edges in X, namely type 0, type +, and type -; for adjacent vertices w,z such that ∂(w,y)=∂(z,y), the type of the edge wz depends on the subspaces w+z,w,z,w z and their intersections with y. Pick a vertex x such that 1<∂(x,y)<k. Let (x) denote the local graph of x in Jq(n,k). Our general goal is to count the number of edges in (x) for each type. Consider a two-vertex stabilizer Stab(x,y) in GL(V); it is known that the Stab(x,y)-action on (x) has five orbits. Pick two orbits O,N that are not necessarily distinct; for a given w∈ O, we find the number of vertices in z∈ N such that the edge wz has (i) type 0, (ii) type +, (iii) type -. To find these numbers, we use many results that involve a projective geometry Pq(n), which is the set of all subspaces of V.