Positive discrepancy, MaxCut, and eigenvalues of graphs
Abstract
The positive discrepancy of a graph G of edge density p=e(G)/v(G)2 is defined as disc+(G)=U⊂ V(G)e(G[U])-p|U|2. In 1993, Alon proved (using the equivalent terminology of minimum bisections) that if G is d-regular on n vertices, and d=O(n1/9), then disc+(G)=(d1/2n). We greatly extend this by showing that if G has average degree d, then disc+(G)=(d12n) if d∈ [0,n23], (n2/d) if d∈ [n23,n45], and (d14n/ n) if d∈ [n45,(12-)n]. These bounds are best possible if d n3/4, and the complete bipartite graph shows that disc+(G)=(n) cannot be improved if d≈ n/2. Our proofs are based on semidefinite programming and linear algebraic techniques. An interesting corollary of our results is that every d-regular graph on n vertices with 12+≤ dn≤ 1- has a cut of size nd4+(n5/4/ n). This is not necessarily true without the assumption of regularity, or the bounds on d. The positive discrepancy of regular graphs is controlled by the second eigenvalue λ2, as disc+(G)≤ λ22 n+d. As a byproduct of our arguments, we present lower bounds on λ2 for regular graphs, extending the celebrated Alon-Boppana theorem in the dense regime.
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