Jim Geelen scite author profile

We prove that a class of matroids representable over a fixed finite field and with bounded branch-width is well-quasi-ordered under taking minors. With some extra work, the result implies Robertson and Seymour's result that graphs with bounded tree-width (or equivalently, bounded branch-width) are well-quasi-ordered under taking minors. We will not only derive their result from our result on matroids, but we will also use the main tools for a direct proof that graphs with bounded branchwidth are well-quasi-ordered under taking minors. This proof also provides a model for the proof of the result on matroids, with all specific matroid technicalities stripped off. © 2002 Elsevier Science (USA)

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The Highly Connected Matroids in Minor-Closed Classes

Geelen

Gerards

Whittle

2015

Ann. Comb.

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On the odd-minor variant of Hadwiger's conjecture

Geelen

Gerards

Reed

et al. 2009

Journal of Combinatorial Theory, Series B

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A K l -expansion consists of l vertex-disjoint trees, every two of which are joined by an edge. We call such an expansion odd if its vertices can be two-coloured so that the edges of the trees are bichromatic but the edges between trees are monochromatic. We show that, for every l, if a graph contains no odd K l -expansion then its chromatic number is O (l log l ). In doing so, we obtain a characterization of graphs which contain no odd K l -expansion which is of independent interest. We also prove that given a graph and a subset S of its vertex set, either there are k vertex-disjoint odd paths with endpoints in S, or there is a set X of at most 2k − 2 vertices such that every odd path with both ends in S contains a vertex in X. Finally, we discuss the algorithmic implications of these results.

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Packing Non-Zero A-Paths In Group-Labelled Graphs

et al. 2006

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Let G = (V, E) be an oriented graph whose edges are labelled by the elements of a group Γ and let A ⊆ V . An A-path is a path whose ends are both in A. The weight of a path P in G is the sum of the group values on forward oriented arcs minus the sum of the backward oriented arcs in P . (If Γ is not abelian, we sum the labels in their order along the path.) We are interested in the maximum number of vertex-disjoint A-paths each of non-zero weight. When A = V this problem is equivalent to the maximum matching problem. The general case also includes Mader's S-paths problem. We prove that for any positive integer k, either there are k vertex-disjoint A-paths each of non-zero weight, or there is a set of at most 2k − 2 vertices that meets each of the non-zero A-paths. This result is obtained as a consequence of an exact min-max theorem.

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Jim Geelen

The Excluded Minors for GF(4)-Representable Matroids

Branch-Width and Well-Quasi-Ordering in Matroids and Graphs

The Highly Connected Matroids in Minor-Closed Classes

On the odd-minor variant of Hadwiger's conjecture

Packing Non-Zero A-Paths In Group-Labelled Graphs

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