Robert Hancock scite author profile

Many important problems in combinatorics and other related areas can be phrased in the language of independent sets in hypergraphs. Recently Balogh, Morris and Samotij [3], and independently Saxton and Thomason [62] developed very general container theorems for independent sets in hypergraphs; both of which have seen numerous applications to a wide range of problems. In this paper we use the container method to give relatively short and elementary proofs of a number of results concerning Ramsey (and Turán properties) of (hyper)graphs and the integers. In particular:• We generalise the random Ramsey theorem of Rödl and Ruciński [54, 55, 56] by providing a resilience analogue. Our result unifies and generalises several fundamental results in the area including the random version of Turán's theorem due to Conlon and Gowers [14] and Schacht [64]. • The above result also resolves a general subcase of the asymmetric random Ramsey conjecture of Kohayakawa and Kreuter [40]. • All of the above results in fact hold for uniform hypergraphs.• For a (hyper)graph H, we determine, up to an error term in the exponent, the number of nvertex (hyper)graphs G that have the Ramsey property with respect to H (that is, whenever G is r-coloured, there is a monochromatic copy of H in G). • We strengthen the random Rado theorem of Friedgut, Rödl and Schacht [24] by proving a resilience version of the result. • For partition regular matrices A we determine, up to an error term in the exponent, the number of subsets of {1, . . . , n} for which there exists an r-colouring which contains no monochromatic solutions to Ax = 0. Along the way a number of open problems are posed. MSC2000: 5C30, 5C55, 5D10, 11B75.

show abstract

Long paths and connectivity in 1‐independent random graphs

Day

Falgas–Ravry

Hancock

2020

Random Struct Algorithms

View full text Add to dashboard Cite

A probability measure on the subsets of the edge set of a graph G is a 1-independent probability measure (1-ipm) on G if events determined by edge sets that are at graph distance at least 1 apart in G are independent. Given a 1-ipm , denote by G the associated random graph model. Let  1,⩾p (G) denote the collection of 1-ipms on G for which each edge is included in G with probability at least p. For G = Z 2 , Balister and Bollobás asked for the value of the least p ⋆ such that for all p > p ⋆ and all ∈  1,⩾p (G), (G) almost surely contains an infinite component. In this paper, we significantly improve previous lower bounds on p ⋆. We also determine the 1-independent critical probability for the emergence of long paths on the line and ladder lattices. Finally, for finite graphs G we study f 1,G (p), the infimum over all ∈  1,⩾p (G) of the probability that G is connected. We determine f 1,G (p) exactly when G is a path, a complete graph and a cycle of length at most 5.

show abstract

On solution-free sets of integers

Hancock

Treglown

2017

European Journal of Combinatorics

View full text Add to dashboard Cite

show abstract

Limits of Latin squares

Garbe¹,

Hancock²,

Hladký³

et al. 2020

Preprint

View full text Add to dashboard Cite

We develop a limit theory of Latin squares, paralleling the recent limit theories of dense graphs and permutations. We introduce a notion of density, an appropriate version of the cut distance, and a space of limit objects -so-called Latinons. Key results of our theory are the compactness of the limit space and the equivalence of the topologies induced by the cut distance and the left-convergence. Last, using Keevash's recent results on combinatorial designs, we prove that each Latinon can be approximated by a finite Latin square.

show abstract

On solution-free sets of integers II

Hancock

Treglown

2017

Acta Arith.

View full text Add to dashboard Cite

Abstract. Given a linear equation L, a set A ⊆ [n] is L-free if A does not contain any 'non-trivial' solutions to L. We determine the precise size of the largest L-free subset of [n] for several general classes of linear equations L of the form px + qy = rz for fixed p, q, r ∈ N where p ≥ q ≥ r. Further, for all such linear equations L, we give an upper bound on the number of maximal L-free subsets of [n]. In the case when p = q ≥ 2 and r = 1 this bound is exact up to an error term in the exponent. We make use of container and removal lemmas of Green [12] to prove this result. Our results also extend to various linear equations with more than three variables.MSC2010: 11B75, 05C69.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Robert Hancock

Independent Sets in Hypergraphs and Ramsey Properties of Graphs and the Integers

Long paths and connectivity in 1‐independent random graphs

On solution-free sets of integers

Limits of Latin squares

On solution-free sets of integers II

Contact Info

Product

Resources

About