Completions of epsilon-dense partial Latin squares; quasirandom k-colorings of graphs

Abstract

A classical question in combinatorics is the following:\ given a partial Latin square P, when can we complete P to a Latin square L? In this paper, we investigate the class of ε-dense partial Latin squares:\ partial Latin squares in which each symbol, row, and column contains no more than ε n-many nonblank cells. Based on a conjecture of Nash-Williams, Daykin and H\"aggkvist conjectured that all 14-dense partial Latin squares are completable. In this paper, we will discuss the proof methods and results used in previous attempts to resolve this conjecture, introduce a novel technique derived from a paper by Jacobson and Matthews on generating random Latin squares, and use this novel technique to study ε-dense partial Latin squares that contain no more than δ n2 filled cells in total. In particular, we construct completions for all ε-dense partial Latin squares containing no more than δ n2 filled cells in total, given that ε < 112, δ < (1-12ε)210409. In particular, we show that all 9.8 · 10-5-dense partial Latin squares are completable. We further show that such completions can always be found in polynomial time. This contrasts a result of Colbourn. In Chapter 3, we strengthen Colbourn's result to the claim that completing an arbitrary (12 + ε)-dense partial Latin square is NP-complete, for any ε > 0. Additional results on triangulations of graphs are found. In an unrelated vein, Chapter 6 explores the class of quasirandom graphs. In specific, we study quasirandom k-edge colorings, and create an analogue of Chung, Graham and Wilson's well-known results for such colorings.