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Descent c-Wilf Equivalence

Abstract

Let SnS_n denote the symmetric group. For any σSn\sigma \in S_n, we let des(σ)\mathrm{des}(\sigma) denote the number of descents of σ\sigma, inv(σ)\mathrm{inv}(\sigma) denote the number of inversions of σ\sigma, and LRmin(σ)\mathrm{LRmin}(\sigma) denote the number of left-to-right minima of σ\sigma. For any sequence of statistics stat1,statk\mathrm{stat}_1, \ldots \mathrm{stat}_k on permutations, we say two permutations α\alpha and β\beta in SjS_j are (stat1,statk)(\mathrm{stat}_1, \ldots \mathrm{stat}_k)-c-Wilf equivalent if the generating function of i=1kxistati\prod_{i=1}^k x_i^{\mathrm{stat}_i} over all permutations which have no consecutive occurrences of α\alpha equals the generating function of i=1kxistati\prod_{i=1}^k x_i^{\mathrm{stat}_i} over all permutations which have no consecutive occurrences of β\beta. We give many examples of pairs of permutations α\alpha and β\beta in SjS_j which are des\mathrm{des}-c-Wilf equivalent, (des,inv)(\mathrm{des},\mathrm{inv})-c-Wilf equivalent, and (des,inv,LRmin)(\mathrm{des},\mathrm{inv},\mathrm{LRmin})-c-Wilf equivalent. For example, we will show that if α\alpha and β\beta are minimally overlapping permutations in SjS_j which start with 1 and end with the same element and des(α)=des(β)\mathrm{des}(\alpha) = \mathrm{des}(\beta) and inv(α)=inv(β)\mathrm{inv}(\alpha) = \mathrm{inv}(\beta), then α\alpha and β\beta are (des,inv)(\mathrm{des},\mathrm{inv})-c-Wilf equivalent.Comment: arXiv admin note: text overlap with arXiv:1510.0431

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