Book contents
- Frontmatter
- Contents
- Preface
- 1 Ramsey classes: examples and constructions
- 2 Recent developments in graph Ramsey theory
- 3 Controllability and matchings in random bipartite graphs
- 4 Some old and new problems in combinatorial geometry I: around Borsuk's problem
- 5 Randomly generated groups
- 6 Curves over finite fields and linear recurring sequences
- 7 New tools and results in graph minor structure theory
- 8 Well quasi-order in combinatorics: embeddings and homomorphisms
- 9 Constructions of block codes from algebraic curves over finite fields
- References
7 - New tools and results in graph minor structure theory
Published online by Cambridge University Press: 05 July 2015
- Frontmatter
- Contents
- Preface
- 1 Ramsey classes: examples and constructions
- 2 Recent developments in graph Ramsey theory
- 3 Controllability and matchings in random bipartite graphs
- 4 Some old and new problems in combinatorial geometry I: around Borsuk's problem
- 5 Randomly generated groups
- 6 Curves over finite fields and linear recurring sequences
- 7 New tools and results in graph minor structure theory
- 8 Well quasi-order in combinatorics: embeddings and homomorphisms
- 9 Constructions of block codes from algebraic curves over finite fields
- References
Summary
Abstract
Graph minor theory of Robertson and Seymour is a far reaching generalization of the classical Kuratowski–Wagner theorem, which characterizes planar graphs in terms of forbidden minors. We survey new structural tools and results in the theory, concentrating on the structure of large t-connected graphs, which do not contain the complete graph Kt as a minor.
1 Introduction
Graphs in this paper are finite and simple, unless specified otherwise. A graph H is a minor of a graph G if H can be obtained from a subgraph of G by contracting edges. Numerous theorems in structural graph theory describe classes of graphs which do not contain a fixed graph or a collection of graphs as a minor. A classical example of such a description is the Kuratowski–Wagner theorem [92,93].
Theorem 1.1A graph is planar if and only if it does not contain K5 or K3,3 as a minor.
(We will say that G contains H as a minor, if H is isomorphic to a minor of G, and we will use the notation H ≤ G to denote this. The notation is justified as the minor containment is, indeed, a partial order. We say that G is H-minor free if G does not contain H as a minor.)
Clearly a graph is a forest if and only if it does not contain K3 as a minor. In [16] Dirac proved that a graph does not contain K4 as a minor if and only if it is series-parallel. In [93] Wagner characterizes graphs which do not contain K5 as a minor, as follows.
Theorem 1.2A graph does not contain K5 as a minor if and only if it can be obtained by 0-, 1 and 2 and 3-clique sum operations from planar graphs and V8. (The graph V8 is shown on Figure 1.)
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- Information
- Surveys in Combinatorics 2015 , pp. 221 - 260Publisher: Cambridge University PressPrint publication year: 2015
References
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