Abstract
Let $b(k,\theta)$ be the maximum order of a connected bipartite $k$-regular graph whose second largest eigenvalue is at most $\theta$. In this paper, we obtain a general upper bound for $b(k,\theta)$ for any $0\leq \theta< 2\sqrt{k-1}$. Our bound gives the exact value of $b(k,\theta)$ whenever there exists a bipartite distance-regular graph of degree $k$, second largest eigenvalue $\theta$, diameter $d$ and girth $g$ such that $g\geq 2d-2$. For certain values of $d$, there are infinitely many such graphs of various valencies $k$. However, for $d=11$ or $d\geq 15$, we prove that there are no bipartite distance-regular graphs with $g\geq 2d-2$.
Highlights
Let Γ = (V, E) be a connected k-regular simple graph with n vertices
Equality holds in (1) if and only if there is a distance-regular graph of valency k with second largest eigenvalue θ, girth g and diameter d satisfying g 2d
Our bound gives the exact value of b(k, θ) whenever there exists a bipartite distance-regular graph of degree k with second largest eigenvalue θ, diameter d and girth g such that g 2d − 2
Summary
Let Γ = (V, E) be a connected k-regular simple graph with n vertices. For 1 i n, let λi(Γ) denote the i-th largest eigenvalue of the adjacency matrix of Γ. Let v(k, θ) d√enote the maximum order of a connected k-regular graph Γ with λ2(Γ) θ. Let T (k, t, c) be the t × t tridiagonal matrix with lower diagonal If θ is the second largest eigenvalue of T (k, t, c), (1). Equality holds in (1) if and only if there is a distance-regular graph of valency k with second largest eigenvalue θ, girth g and diameter d satisfying g 2d. Second eigenvalue, bipartite regular graph, bipartite distance-regular graph, expander, linear programming bound Keywords. second eigenvalue, bipartite regular graph, bipartite distance-regular graph, expander, linear programming bound
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