Powers of Hamiltonian cycles in randomly augmented P\'osa-Seymour graphs
Abstract
We study the question of the least number of random edges that need to be added to a P\'osa-Seymour graph, that is, a graph with minimum degree exceeding kk+1n, to secure the existence of the m-th power of a Hamiltonian cycle, m>k. It turns out that, depending on k and m, this quantity may be captured by two types of thresholds, with one of them, called over-threshold, becoming dominant for large m. Indeed, for each k2 and m>m0(k), we establish asymptotically tight lower and upper bounds on the over-thresholds (provided they exist) and show that for infinitely many instances of m the two bounds coincide. In addition, we also determine the thresholds for some small values of k and m.
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