Using a Grassmann graph to recover the underlying projective geometry

Abstract

Let n,k denote integers with n>2k≥ 6. Let Fq denote a finite field with q elements, and let V denote a vector space over Fq that has dimension n. The projective geometry Pq(n) is the partially ordered set consisting of the subspaces of V; the partial order is given by inclusion. For the Grassmann graph Jq(n,k) the vertex set consists of the k-dimensional subspaces of V. Two vertices of Jq(n,k) are adjacent whenever their intersection has dimension k-1. The graph Jq(n,k) is known to be distance-regular. Let ∂ denote the path-length distance function of Jq(n,k). Pick two vertices x,y in Jq(n,k) such that 1<∂(x,y)<k. The set Pq(n) contains the elements x,y,x y,x+y. In our main result, we describe x y and x+y using only the graph structure of Jq(n,k). To achieve this result, we make heavy use of the Euclidean representation of Jq(n,k) that corresponds to the second largest eigenvalue of the adjacency matrix.

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