English

Integer concave cocirculations and honeycombs

Combinatorics 2010-11-15 v1

Abstract

A convex triangular grid is represented by a planar digraph GG embedded in the plane so that (a) each bounded face is surrounded by three edges and forms an equilateral triangle, and (b) the union \Rscr\Rscr of bounded faces is a convex polygon. A real-valued function hh on the edges of GG is called a concave cocirculation if h(e)=g(v)g(u)h(e)=g(v)-g(u) for each edge e=(u,v)e=(u,v), where gg is a concave function on \Rscr\Rscr which is affinely linear within each bounded face of GG. Knutson and Tao [J. Amer. Math. Soc. 12 (4) (1999) 1055--1090] proved an integrality theorem for so-called honeycombs, which is equivalent to the assertion that an integer-valued function on the boundary edges of GG is extendable to an integer concave cocirculation if it is extendable to a concave cocirculation at all. In this paper we show a sharper property: for any concave cocirculation hh in GG, there exists an integer concave cocirculation hh' satisfying h(e)=h(e)h'(e)=h(e) for each boundary edge ee with h(e)h(e) integer and for each edge ee contained in a bounded face where hh takes integer values on all edges. On the other hand, we explain that for a 3-side grid GG of size nn, the polytope of concave cocirculations with fixed integer values on two sides of GG can have a vertex hh whose entries are integers on the third side but h(e)h(e) has denominator Ω(n)\Omega(n) for some interior edge ee. Also some algorithmic aspects and related results on honeycombs are discussed.

Cite

@article{arxiv.math/0401313,
  title  = {Integer concave cocirculations and honeycombs},
  author = {Alexander V. Karzanov},
  journal= {arXiv preprint arXiv:math/0401313},
  year   = {2010}
}

Comments

20 pages, 12 figures, submitted to IPCO2004