Andrea C. Burgess scite author profile

Given nonnegative integers v,m,n,α,β, the Hamilton–Waterloo problem asks for a factorization of the complete graph Kv into α Cm‐factors and β Cn‐factors. Without loss of generality, we may assume that n≥m. Clearly, v odd, n,m≥3, m∣v, n∣v and α+β=(v−1)/2 are necessary conditions. To date results have only been found for specific values of m and n. In this paper, we show that for any integers n≥m, these necessary conditions are sufficient when v is a multiple of mn and v>mn, except possibly when β=1 or 3. For the case where v=mn we show sufficiency when β>(n+5)/2 with some possible exceptions. We also show that when n≥m≥3 are odd integers, the lexicographic product of Cm with the empty graph of order n has a factorization into α Cm‐factors and β Cn‐factors for every 0≤α≤n, β=n−α, with some possible exceptions.

show abstract

Generalized packing designs

Bailey

Burgess

2013

Discrete Mathematics

View full text Add to dashboard Cite

Generalized t-designs, which form a common generalization of objects such as t-designs, resolvable designs and orthogonal arrays, were defined by Cameron [P.J. Cameron, A generalisation of t-designs, Discrete Math. 309 (2009), 4835-4842]. In this paper, we define a related class of combinatorial designs which simultaneously generalize packing designs and packing arrays. We describe the sometimes surprising connections which these generalized designs have with various known classes of combinatorial designs, including Howell designs, partial Latin squares and several classes of triple systems, and also concepts such as resolvability and block colouring of ordinary designs and packings, and orthogonal resolutions and colourings. Moreover, we derive bounds on the size of a generalized packing design and construct optimal generalized packings in certain cases. In particular, we provide methods for constructing maximum generalized packings with t = 2 and block size k = 3 or 4.

show abstract

Cops and Robbers on Graphs Based on Designs

Bonato

Burgess

2012

J of Combinatorial Designs

View full text Add to dashboard Cite

We investigate the cop number of graphs based on combinatorial designs. Incidence graphs, point graphs, and block intersection graphs are studied, with an emphasis on finding families of graphs with large cop number. We generalize known results on Meyniel extremal families by supplying bounds on the incidence graphs of transversal designs, certain G-designs, and BIBDs with λ ≥ 1. Families of graphs with diameter 2, C 4 -free, and with unbounded chromatic number are described with the conjectured asymptotically maximum cop number.

show abstract

On the Hamilton–Waterloo problem with odd cycle lengths

Burgess

Danziger

Traetta

2017

J of Combinatorial Designs

View full text Add to dashboard Cite

Let Kv∗ denote the complete graph Kv if v is odd and Kv−I, the complete graph with the edges of a 1‐factor removed, if v is even. Given nonnegative integers v,M,N,α,β, the Hamilton–Waterloo problem asks for a 2‐factorization of Kv∗ into α CM‐factors and β CN‐factors, with a Cℓ‐factor of Kv∗ being a spanning 2‐regular subgraph whose components are ℓ‐cycles. Clearly, M,N≥3, M∣v, N∣v and α+β=⌊v−12⌋ are necessary conditions. In this paper, we extend a previous result by the same authors and show that for any odd v≠MNgcd(M,N) the above necessary conditions are sufficient, except possibly when α=1, or when β∈{1,3}. Note that in the case where v is odd, M and N must be odd. If M and N are odd but v is even, we also show sufficiency but with further possible exceptions. In addition, we provide results on 2‐factorizations of the complete equipartite graph and the lexicographic product of a cycle with the empty graph.

show abstract

Mutually orthogonal cycle systems

2022

View full text Add to dashboard Cite

An ℓ-cycle system F of a graph Γ is a set of ℓ-cycles which partition the edge set of Γ. Two such cycle systems F and F ′ are said to be orthogonal if no two distinct cycles from F ∪ F ′ share more than one edge. Orthogonal cycle systems naturally arise from face 2-colourable polyehdra and in higher genus from Heffter arrays with certain orderings. A set of pairwise orthogonal ℓ-cycle systems of Γ is said to be a set of mutually orthogonal cycle systems of Γ.Let µ(ℓ, n) (respectively, µ ′ (ℓ, n)) be the maximum integer µ such that there exists a set of µ mutually orthogonal (cyclic) ℓ-cycle systems of the complete graph K n . We show that if ℓ ≥ 4 is even and n ≡ 1 (mod 2ℓ), then µ ′ (ℓ, n), and hence µ(ℓ, n), is bounded below by a constant multiple of n/ℓ 2 . In contrast, we obtain the following upper bounds:√ 2; and µ ′ (ℓ, n) ≤ n − 3 when n ≥ 4. We also obtain computational results for small values of n and ℓ.

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.

Andrea C. Burgess

On the Hamilton–Waterloo Problem with Odd Orders

Generalized packing designs

Cops and Robbers on Graphs Based on Designs

On the Hamilton–Waterloo problem with odd cycle lengths

Mutually orthogonal cycle systems

Contact Info

Product

Resources

About