KenichiKawarabayashi

Archive of posts with tag 'KenichiKawarabayashi'

  • KAIST Graph Theory Day 2011

    KAIST Graph Theory Day 2011
    2011/5/10 Tuesday (Room: 1501, Building E6-1)

    Poster (KAIST Graph Theory Day)
    Registration

    List of speakers</p>
    • 11AM-12PM Maria Chudnovsky (Columbia University, USA) : Coloring some perfect graphs
    • 2PM-3PM Ken-ichi Kawarabayashi (NII, Japan) : A separator theorem in minor-closed class of graphs
    • 4PM-5PM Bojan Mohar (SFU, Canada) : On the chromatic number of digraphs
    • 5PM-6PM Paul Seymour (Princeton University, USA) : Colouring Tournaments

    Coloring some perfect graphs
    Maria Chudnovsky
    A graph G is called perfect if for every induced subgraph H of G, the chromatic number and the clique number of H are equal. After the recent proof of the Strong Perfect Graph Theorem, and the discovery of a polynomial-time recognition algorithm, the central remaining open question about perfect graphs is finding a combinatorial polynomial-time coloring algorithm. (There is a polynomial-time algorithm known, using the ellipsoid method). Recently, we were able to find such an algorithm for a certain class of perfect graphs, that includes all perfect graphs admitting no balanced skew-partition. The algorithm is based on finding special “extremal” decompositions in such graphs; we also use the idea of “trigraphs”.
    This is joint work with Nicolas Trotignon, Theophile Trunck and Kristina Vuskovic.

    A separator theorem in minor-closed class of graphs
    Ken-ichi Kawarabayashi
    It is shown that for each t, there is a separator of size O(t \sqrt{n}) in any n-vertex graph G with no Kt-minor.
    This settles a conjecture of Alon, Seymour and Thomas (J. Amer. Math. Soc., 1990 and STOC’90), and generalizes a result of Djidjev (1981), and Gilbert, Hutchinson and Tarjan (J. Algorithm, 1984), independently, who proved that every graph with n vertices and genus g has a separator of order O(\sqrt{gn}), because Kt has genus Ω(t2).
    Joint work with Bruce Reed.

    On the chromatic number of digraphs
    Bojan Mohar
    Several reasons will be presented why the natural extension of the notion of undirected graph colorings is to partition the vertex set of a digraph into acyclic sets. Additionally, some recent results in this area, the proofs of which use probabilistic techniques, will be outlined.

    Colouring Tournaments
    Paul Seymour
    A tournament is a digraph obtained from a complete graph by directing its edges, and colouring a tournament means partitioning its vertex set into acyclic subsets (acyclic means the subdigraph induced on the subset has no directed cycles). This concept is quite like that for graph-colouring, but different. For instance, there are some tournaments H such that every tournament not containing H as a subdigraph has bounded chromatic number. We call them heroes; for example, all tournaments with at most four vertices are heroes.
    It turns out to be a fun problem to figure out exactly which tournaments are heroes. We have recently managed to do this, in joint work with Berger, Choromanski, Chudnovsky, Fox, Loebl, Scott and Thomassé, and this talk is about the solution.
  • (Colloquium) Ken-ichi Kawarabayashi, The disjoint paths problem: Algorithm and Structure

    FYI (Department Colloquium)
    The disjoint paths problem: Algorithm and Structure
    Ken-ichi Kawarabayashi (河原林 健一)
    National Institute of Informatics, Tokyo, Japan.
    2009/11/26 Thursday 4:30PM-5:30PM (Room 1501)

    In this talk, we shall discuss the following well-known problem, which
    is called the disjoint paths problem.

    Given a graph G with n vertices and m edges, k pairs of vertices (s1,t1),(s2,t2),…,(sk,tk) in G (which are sometimes called terminals). Are there disjoint paths P1,…,Pk in G such that Pi joins si and ti for i=1,2,…,k?

    We discuss recent progress on this topic, including algorithmic aspect of the disjoint paths problem.

    We also discuss some structure theorems without the k disjoint paths. Topics include the uniquely linkage problem and the connectivity function that guarantees the existence of the k disjoint paths.

  • Ken-ichi Kawarabayashi, Graphs without subdivisions

    Graphs without subdivisions
    Ken-ichi Kawarabayashi (河原林 健一)
    National Institute of Informatics, Tokyo, Japan.
    2009/11/24 Tuesday 4PM-5PM

    Hajos’ conjecture is false, and it seems that graphs without a subdivision of a big complete graph do not behave as well as those without a minor of a big complete graph.

    In fact, the graph minor theorem (a proof of Wagner’s conjecture) is not true if we replace the minor relation by the subdivision relation. I.e, For every infinite sequence G1,G2, … of graphs, there exist distinct integers i<j such that Gi is a minor of Gj, but if we replace ”minor” by ”subdivision”, this is no longer true.

    This is partially because we do not really know what the graphs without a subdivision of a big complete graph look like.

    In this talk, we shall discuss this issue. In particular, assuming some moderate connectivity condition, we can say something, which we will present in this talk.

    Topics also include coloring graphs without a subdivision of a large complete graph, and some algorithmic aspects. Some of the results are joint work with Theo Muller.

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