1 / 37

On-line list colouring of graphs

On-line list colouring of graphs. Xuding Zhu Zhejiang Normal University. Suppose G is a graph. A list assignment L assigns to each vertex x a set L(x) of permissible colours. An L -colouring h of G assigns to each vertex x a colour. such that for every edge x y. choice number.

shel
Download Presentation

On-line list colouring of graphs

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. On-line list colouring of graphs Xuding Zhu Zhejiang Normal University

  2. Suppose G is a graph A list assignment L assigns to each vertex x a set L(x) of permissible colours. An L-colouring h of G assigns to each vertex x a colour such that for every edge xy choice number

  3. Given a colour i, is the set of vertices having i as a permissible colour. Given a vertex x, L(x) tells us which colours are permissible. Alternately, given a colour i, one can ask which vertices have i as a permissible colour. A list assignment L can be given as An L-colouring is afamily of independent subsets and

  4. is the number of permissible colours for x At round i, Alice choose a set of uncoloured vertices. is the set of vertices which has colour i as a permissible colour. Bob chooses an independent subset of and colour vertices in by colour i. on-line f-list colouring game on G played by Alice and Bob Alice wins the game if there is a vertex x, which has been given f(x) permissible colours and remains uncoloured. Otherwise, eventually all vertices are coloured and Bob wins the game.

  5. The on-line choice number of G is the minimum k for which G is on-line k-choosable. G is on-line f-choosable if Bob has a winning strategy for the on-line f-list colouring game. G is on-line k-choosable if G is on-line f-choosable for f(x)=k for every x.

  6. is not on-line 2-choosable Theorem [Erdos-Rubin-Taylor (1979)] is 2-choosable.

  7. is not on-line 2-choosable Alice wins the game

  8. Question: Can the difference be arbitrarily large ? Question: Can the ratio be arbitrarily large ?

  9. Theorem [Schauz,2009] For planar G, Theorem [Chung-Z,2011] For planar G, triangle free + no 4-cycle adjacent to a 4-cycle or a 5-cycle, Most upper bounds for choice number are also upper bounds for on-line choice number. Currently used method in proving upper bounds for choice number Induction Some works for on-line choice number, Kernel method Combinatorial Nullstellensatz Theorem [Schauz,2009] Upper bounds for ch(G) proved by Combinatorial nullstellensatz works for on-line choice number

  10. Theorem [Schauz,2009] If G has an orientation D with then G is on-line The proof is by induction (no polynomial is involved). Theorem [Schauz,2009] Upper bounds for ch(G) proved by Combinatorial nullstellensatz works for on-line choice number

  11. Probabilistic method Does not work for on-line choice number Theorem [Alon, 1992] The proof is by probabilistic method Theorem[Z,2009] Proof: If G is bipartite and has n vertices, then

  12. Assume Alice has given set If Bob colours , double the weight of each vertex in If a vertex x has permissible colours, Bob will be able to colour it. Initially, each vertex x has weight w(x)=1 A B The total weight of uncoloured vertices is not increased. If a vertex is given a permissible colour but is not coloured by that colour, then it weight doubles. If a vertex x has given k permissible colours, but remains uncoloured, then

  13. Conjecture [Ohba] Graphs G with are chromatic choosable. Conjecture: For any G, for any k > 1, is chromatic choosable. A graph G is chromatic choosable if Conjecture: Line graphs are chromatic choosable. Conjecture: Claw-free graphs are chromatic choosable. Conjecture: Total graphs are chromatic choosable. Theorem [Noel-Reed-Wu]

  14. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. NOT TRUE 3 3 33|33|333 3 3 3 3 3

  15. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. 3 3 33|33|333 3 3 Alice’s move 3 3 3

  16. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. 3|23|233 3 3 33|33|333 3 3 23|23|33 Alice’s move 3 3 3 Bob’s (2 possible) moves

  17. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. 13|222 3|23|233 3 3 2|3|222 33|33|333 3 3 23|23|33 Alice’s move 3 3 3 Bob’s (2 possible) moves

  18. 3|111 On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. 13|222 3|23|233 3 3 2|3|222 33|33|333 3 3 23|23|33 Alice’s move 3 3 3 Bob’s (2 possible) moves

  19. 3|111 On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. 13|222 3|23|233 3 3 2|3|222 33|33|333 3 3 2|112 23|23|33 Alice’s move 3 3 3 Bob’s (2 possible) moves

  20. 3|111 On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. 13|222 3|23|233 3 3 2|3|222 33|33|333 3 3 2|112 23|23|33 Alice’s move 3 3 3 3|13|22 2|3|11

  21. Theorem [Kim-Kwon-Liu-Z,2012] For n > 1, is not on-line -choosable

  22. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable.

  23. If for some k, have a common permissible colour and Theorem [Erdos-Rubin-Taylor (1979)] is chromatic choosable. Proof Assume each vertex is given n permissible colours. then colour them by a common colour use induction to colour the rest.

  24. Assume no partite set has a common permissible colour Build a bipartite graph V The proof does not work for on-line list colouring C colours By Hall’s theorem, there is a matching that covers all the vertices of V

  25. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. Question: is on-line n-choosable ?

  26. Question: Theorem [Huang-Wong-Z,2010] is on-line n-choosable. Proof Combinatorial Nullstellensatz An explicit winning strategy for Bob ( Kim-Kwon-Liu-Z, 2012)

  27. Theorem [Kim-Kwon-Liu-Z, 2012] G: complete multipartite graph with partite sets satisfying the following i.e., G is on-line f-choosable. Then (G,f) is feasible, is on-line n-choosable.

  28. Alice’s choice Bob’s choice After this round, G changed and f changed. Need to prove: new (G,f) still satisfies the condition

  29. Alice’s choice

  30. Alice’s choice Bob colours v

  31. Alice’s choice

  32. Alice’s choice Bob colours v

  33. Theorem [Kim-Kwon-Liu-Z, 2012] G: complete multipartite graph with partite sets satisfying the following i.e., G is on-line f-choosable. Then (G,f) is feasible, is on-line n-choosable.

  34. Theorem [Kozik-Micek-Z, 2012] G: complete multipartite graph with partite sets satisfying the following Then (G,f) is feasible.

  35. On-line version of Ohba Conjecture: Graphs G with are on-line chromatic choosable. Conjecture holds for graphs with independence number 3

  36. Open Problems Can the difference ch^{OL}-ch be arbitrarily big? On-line Ohba conjecture true?

  37. Nine Dragon Tree Thank you

More Related