English

Connections Between Combinations Without Specified Separations and Strongly Restricted Permutations, Compositions, and Bit Strings

Combinatorics 2025-07-22 v4

Abstract

Let SnS_n and Sn,kS_{n,k} be, respectively, the number of subsets and kk-subsets of Nn={1,,n}\mathbb{N}_n=\{1,\ldots,n\} such that no two subset elements differ by an element of the set Q\mathcal{Q}, the largest element of which is qq. We prove a bijection between such kk-subsets when Q={m,2m,,jm}\mathcal{Q}=\{m,2m,\ldots,jm\} with j,m>0j,m>0 and permutations π\pi of Nn+jm\mathbb{N}_{n+jm} with kk excedances satisfying π(i)i{m,0,jm}\pi(i)-i\in\{-m,0,jm\} for all iNn+jmi\in\mathbb{N}_{n+jm}. We also identify a bijection between another class of restricted permutation and the cases Q={1,q}\mathcal{Q}=\{1,q\} and derive the generating function for SnS_n when q=4,5,6q=4,5,6. We give some classes of Q\mathcal{Q} for which SnS_n is also the number of compositions of n+qn+q into a given set of allowed parts. We also prove a bijection between kk-subsets for a class of Q\mathcal{Q} and the set representations of size kk of equivalence classes for the occurrence of a given length-(q+1q+1) subword within bit strings. We then formulate a straightforward procedure for obtaining the generating function for the number of such equivalence classes.

Keywords

Cite

@article{arxiv.2409.00624,
  title  = {Connections Between Combinations Without Specified Separations and Strongly Restricted Permutations, Compositions, and Bit Strings},
  author = {Michael A. Allen},
  journal= {arXiv preprint arXiv:2409.00624},
  year   = {2025}
}

Comments

27 pages, 10 figures. arXiv admin note: text overlap with arXiv:2210.08167 (the text overlap is with the original version, not the final version of 2210.08167)

R2 v1 2026-06-28T18:30:22.204Z