English

A $q$-Queens Problem. I. General Theory

Combinatorics 2016-10-18 v2

Abstract

By means of the Ehrhart theory of inside-out polytopes we establish a general counting theory for nonattacking placements of chess pieces with unbounded straight-line moves, such as the queen, on a polygonal convex board. The number of ways to place qq identical nonattacking pieces on a board of variable size nn but fixed shape is given by a quasipolynomial function of nn, of degree 2q2q, whose coefficients are polynomials in qq. The number of combinatorially distinct types of nonattacking configuration is the evaluation of our quasipolynomial at n=1n=-1. The quasipolynomial has an exact formula that depends on a matroid of weighted graphs, which is in turn determined by incidence properties of lines in the real affine plane. We study the highest-degree coefficients and also the period of the quasipolynomial, which is needed if the quasipolynomial is to be interpolated from data, and which is bounded by some function, not well understood, of the board and the piece's move directions. In subsequent parts we specialize to the square board and then to subsets of the queen's moves, and we prove exact formulas (most but not all already known empirically) for small numbers of queens, bishops, and nightriders. Each part concludes with open questions, both specialized and broad.

Keywords

Cite

@article{arxiv.1303.1879,
  title  = {A $q$-Queens Problem. I. General Theory},
  author = {Seth Chaiken and Christopher R. H. Hanusa and Thomas Zaslavsky},
  journal= {arXiv preprint arXiv:1303.1879},
  year   = {2016}
}

Comments

28 pp., no figures, submitted. v2 = first half of v1 with much stronger results

R2 v1 2026-06-21T23:38:34.896Z