Vertex-Based Localization of Erdos-Gallai Theorems for Paths and Cycles
Abstract
For a simple graph G, let n and m denote the number of vertices and edges in G, respectively. The Erdos-Gallai theorem for paths states that in a simple Pk-free graph, m ≤ n(k-1)2, where Pk denotes a path with length k (that is, with k edges). In this paper, we generalize this result as follows: For each v ∈ V(G), let p(v) be the length of the longest path that contains v. We show that \[m ≤ Σv ∈ V(G) p(v)2\] The Erdos-Gallai theorem for cycles states that in a simple graph G with circumference (that is, the length of the longest cycle) at most k, we have m ≤ k(n-1)2. We strengthen this result as follows: For each v ∈ V(G), let c(v) be the length of the longest cycle that contains v, or 2 if v is not part of any cycle. We prove that \[m ≤ ( Σv ∈ V(G) c(v)2 ) - c(u)2\] where c(u) denotes the circumference of G. Furthermore, we characterize the class of extremal graphs that attain equality in these bounds.
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