1 / 79

Acyclic List Edge Coloring of Graphs

Acyclic List Edge Coloring of Graphs. Ko-Wei Lih 李國偉 Institute of Mathematics Academia Sinica A Joint Work with Hsin-Hao Lai (賴欣豪) NTU Math Month July 7, 2009. All graphs in this talk are finite, without loops or parallel edges.

michiko-hanabishi
Download Presentation

Acyclic List Edge Coloring 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. Acyclic List Edge Coloring of Graphs Ko-Wei Lih 李國偉 Institute of Mathematics Academia Sinica A Joint Work with Hsin-Hao Lai(賴欣豪) NTU Math Month July 7, 2009

  2. All graphs in this talk are finite, without loops or parallel edges. The chromatic number(G) of G is the least number of colors in a proper vertex coloring of G. The chromatic index(G) of G is the least number of colors in a proper edge coloring of G.

  3. A proper coloring of the vertices or edges of a graph G is called acyclic if there is no 2-colored cycle in G.  Every cycle of G is colored with at least 3 colors.  The union of any two color classes induces a subgraph of G which is a forest.

  4. 5-edge coloring

  5. acyclic 5-edge coloring

  6. The acyclic chromatic numbera(G) of G is the least number of colors in an acyclic vertex coloring of G. There has been a large number of works on a(G). The acyclic chromatic indexa(G) of G is the least number of colors in an acyclic edge coloring of G. Lesser is known about a(G).

  7. Vizing’s Theorem (1964) (G)  (G)  (G) + 1 (G): the maximum degree of G Question: (G)  a(G)  (G) + 1 ? No! a(K2n) > (K2n) + 1 = 2n for n  2.

  8. Acyclic Edge Coloring Conjecture: a(G)  (G) + 2 Proposed independently by Fiamčík in 1978 and Alon, Sudakov, Zaks in 2001.

  9. Fiamčík (1984): If (G)  3 and no component of G is K4 or K3,3, then a(G)  4, whereas a(K4) = a(K3,3) = 5. Alon, Sudakov, Zaks (2001): There exists a constant c such that a(G)  (G) + 2 for any G whose girth, the length of a shortest cycle, of G is at least c(G)log(G).

  10. Molloy, Reed (1998): a(G)  16(G) Muthu, Narayanan, Subramanian (2005): When the girth of G is at least 220, a(G)  4.52(G)

  11. Muthu, Narayanan, Subramaniann (2005): a(G)  (G) + 1 if G is a partial 2-tree, an outerplanar graph, or a partial torus. Basavaraju, Sunil Chandran (2008): a(G)  (G) + 1 if G is a 2-degenerate graph.

  12. Basavaraju, Sunil Chandran (2009): a(G)  6 if G is connected, (G)  4 and m  2n ‒ 1, where m is the number of edges of G and n is the number of vertices of G. In general, a(G)  7 if (G)  4.

  13. Nĕsetříl, Wormald (2005): a(G)  (G) + 1 for a random –regular graph. Skulrattankulchai (2004): A polynomial time algorithm to color a subcubic graph using 5 colors. Alon, Zaks (2002): It is NP-complete to determine whether a(G)  3.

  14. Fiedorowica, Hałusaczak, Narayanan (2008): a(G)  (G) + 6 if G is a planar graph without 3-cycles or G has an edge-partition into two forests. a(G)  2(G) + 29 if G is a planar graph.

  15. Borowiecki, Fiedorowicz (2009): a(G)  (G) + 2 for any planar graph G if the girth of G is at least 5 or G contains no cycles of length 4, 6, 8, 9. a(G)  (G) + 1 for any planar graph G of girth at least 6. a(G)  (G) + 15 for any planar graph G without 4-cycles.

  16. Hou, Wu, Liu, Liu (2009): Let G be a planar graph. (i) a(G)  max{2(G) ‒ 2, (G) + 22} when girth(G)  3. (ii) a(G)  (G) + 2 when girth(G)  5. (iii) a(G)  (G) + 1 when girth(G)  7. (iv) a(G) = (G) when girth(G)  16 and (G)  3.

  17. Hou, Wu, Liu, Liu (2009): Let G be an outerplanar graph with (G)  3. Then (i) If (G) = 3, then a(G) = 4if G contains a subgraph isomorphic to the graph Pm. Otherwise a(G) = 3. Vertices marked • have no edges of G incident with them other than those shown and pair of vertices marked with ◦ can be connected to each other.

  18. Hou, Wu, Liu, Liu (2009): (continued) Let G be an outerplanar graph with (G)  3. Then (ii) If (G) = 4, then a(G) = 5if G contains a subgraph isomorphic to the graph Q. Otherwise a(G) = 4. Vertices marked • have no edges of G incident with them other than those shown and pair of vertices marked with ◦ can be connected to each other.

  19. Hou, Wu, Liu, Liu (2009): (continued) Let G be an outerplanar graph with (G)  3. Then (iii) If (G)  5, then a(G) = (G).

  20. A perfect 1-factorization of K2n is a decomposition of the edges of K2n into 2n ‒ 1 perfect matchings such that the union of any two matchings forms a Hamiltonian cycle. A perfect near-1-factorization of K2n+1 is a decomposition of the edges of K2n+1 into 2n + 1 matchings each having n edges such that the union of any two matchings forms a Hamiltonian path.

  21. Kotzig’s Conjecture (1963): For any n 2, K2n has a perfect 1-factorization. • Proposition. The following statements are equivalent: • K2n+2 has a perfect 1-factorization. • 2. K2n+1 has a perfect near-1-factorization. • 3. a(K2n+1) = 2n + 1.

  22. Kotzig’s Conjecture is known to hold for the following cases: • 2n‒ 1 is a prime. • 2. n is a prime. • 3. 16 particular values of n. • Kotzig’s Conjecture implies a(K2n) = 2n + 1.

  23. Alon, Sudakov, Zaks (2001) suggested a possibility that complete graphs of even order are the only regular graphs which require  + 2 colors to be acyclically edge colored. Basavaraju, Sunil Chandran, Kummini (2009): Let G be a d-regular graph with 2n vertices and d > n, then a(G)  (G) + 2.

  24. Basavaraju, Sunil Chandran, Kummini (2009): For any d and n such that dn is even and d  5, n  2d + 3, then there exists a connected d-regular graph with n vertices that requires d + 2 colors to be acyclically edge colored. a(Kn,n)  n+ 2 = (Kn,n) + 2, when n is odd.

  25. Basavaraju, Sunil Chandran (2009): (continued) a(Kp,p) = p+ 2 = (Kp,p) + 2, when p is an odd prime. If G is obtained from Kp,p by removing an edge, then a(G)  (G) + 1.

  26. An edge-listL assigns a finite set of positive integers to each edge of G. Let f: E(G) → N. An edge-list L is an f-edge-list if |L(e)| = f(e) for every edge e. An acyclic edge coloring  of G such that (e)  L(e) for every edge e is called an acyclic L-edge coloring of G.

  27. A graph G is said to be acyclically f-edge choosable if it has an acyclic L-edge coloring for any f-edge-list L. The acyclic list chromatic indexalist(G) is the least integer k such that G is acyclically k-edge choosable. Obviously, (G)  (G)  a(G)  alist(G).

  28. e u v Let e = uv be an edge of the graph G. Let N0(e) and N1(e) denote the sets {u, v} and {x : xuE(G) or xvE(G)}, respectively. e u v N0(e) N1(e)

  29. Let e = uv be an edge of the graph G. Let N0(e) and N1(e) denote the sets {u, v} and {x : xuE(G) or xvE(G)}, respectively. For i = 0 and 1, let i denote the mapping i(e) = max{deg(x) : xNi(e)} for each edge e.

  30. Lemma. Assume that f1 and f2 are two mappings from E(G) to N such that f1(e) f2(e) for each e. If G is acyclically f1-edge choosable, then G is acyclically f2-edge choosable. Lemma. If H is a subgraph of a graph G, then alist(H) alist(G). Lemma. If G1, G2, . . . , Gk are all the components of G, then alist(G) = max{alist(G1), alist(G2), . . . , alist(Gk)}.

  31. Adding a leaf: Let u be a leaf of G. If G  u is acyclically 0-edge choosable, so is G. If u is a leaf of G, then alist(G) = max{alist(G  u), (G)}. If G is a tree, then G is acyclically 0-edge choosable and alist(G) = (G). u

  32. Adding a vertex of degree 2: Let w be a vertex of degree 2 in G. Let P = uvwx be a path of G such that (i) vx  E(G); (ii) deg(v)  3; (iii) deg(u)  2 when deg(v) = 3. If G w is acyclically (0 + 1)-edge choosable, so is G.

  33. Subdividing an edge: If G is obtained from an acyclically (1 + 1)-edge choosable graph H by subdividing an edge, then G is acyclically (1 + 1)-edge choosable. H G

  34. Joining two vertices of degree 2: If G is obtained from an acyclically (1 + 1)-edge choosable graph H by adding an edge between two vertices of degree 2 with a unique common neighbor (under some conditions), then G is acyclically (1 + 1)-edge choosable.

  35. Some conditions: (i) max{deg(u), deg(w), deg(y)}  3; (ii) deg(u)  deg(y); (iii) max{deg(u), deg(y)}  deg(w).

  36. Outerplanar graphs • Let G be an outerplanar graph. Then one of the following holds. • (i) there exists a leaf w; • there exists an edge vw such that deg(v)  3 and deg(w) = 2; • (iii) there exists edges uv and vw such that deg(u) = 2, deg(v) = 4, and deg(w) = 2.

  37. Outerplanar graphs

  38. Outerplanar graphs Theorem. If G is an outerplanar graph, then G is acyclically (0 + 1)-edge choosable and alist(G)  (G) + 1.

  39. Non-regular subcubic graphs Theorem. If G satisfies (G)  3 and (G)  2, then G is acyclically (0 + 1)-edge choosable and alist(G)  (G) + 1.

  40. Cubic graphs with triangles Theorem. If G is a cubic graph, G contains a triangle, and GK4, then G is acyclically (0 + 1)-edge choosable and alist(G)  (G) + 1.

  41. Attaching a cycle of type (2,1,1,1,2,3,1,1,4,1,2) 2+1+1+1+2+3+1+1+4+1+2 =19 vertices

  42. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  43. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  44. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  45. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  46. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  47. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  48. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  49. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

  50. Attaching a cycle of type(2,1,1,1,2,3,1,1,4,1,2)

More Related