210 likes | 392 Views
图的点荫度和点线性荫度. 马刚 山东大学数学院. The vertex arboricity va(G) of a graph G is the minimum number of colors that can be used to color the vertices of G so that each color class induces a forest of G.
E N D
图的点荫度和点线性荫度 马刚 山东大学数学院
The vertex arboricity va(G) of a graph G is the minimum number of colors that can be used to color the vertices of G so that each color class induces a forest of G. The vertex linear arboricity vla(G) of a graph G is the minimum number of colors that can be used to color the vertices of G so that each color class induces linear forest of G. For any graph G,
Theorem (Kronk and Mitchem, 1975) Let G be a simple connected graph. If G neither a cycle nor a clique of odd order, then
Theorem (Matsumoto,1990) Let G be a connected graph. Then (1)There exists a coloring of G such that each induced subgraph has only or as its connected components. (2) . (3)If for some positive integer n, then if and only if G is a cycle or .
Theorem (Akiyama, Era, Gervacio and Wtanabe, 1989) If G is a graph with maximum degree d, then
Theorem (Catlin and Lai, 1995) Let k be a natural number and let G be a connected simple graph with that is not a complete graph (if ) nor a cycle (if k=1). Then and there is a k-coloring of G such that each color class induces a forest, and such that one color class is a maximum induced forest in G.
Theorem (Catlin and Lai, 1995) Let G be a connected simple graph ,and let k be a positive integer, then G has a (k+1)-coloring ,where each color class is a forest .Further more ,if G is not a complete graph then for each property below, this coloring can be chosen to satisfy that property: (a) one color class is edgeless and one color class may be assumed to be a maximum induced forest, or (b) one color class may be assumed to be a maximum independent set.
Theorem (Burr, 1986) For every graph G, . Moreover, for every , there is a G with va(G)=a(G)=k.
Theorem (Michem 1970) Let G be any graph of order p. Then And the bounds are sharp.
Theorem (Alavi, Green, Liu, Wang,1991) Let G be any graph of order p. Then and the lower bounds are sharp except for the sum in the case .
Theorem (Alavi, Liu, Wang, 1994) Let G be any graph of order p. Then and for any graph G of order , where , , and all the bounds are sharp.
Theorem (Lam, Shiu, Sun, Wang, Yan, 2001) If G is a graph of order n, then and all of the bouds are sharp. Theorem (Lam, Shiu, Sun, Wang, Yan, 2001) If G is a graph of order n, then and all of the bouds are sharp.
Theorem(杨爱民,1998) (1) (2) If G is a tree , then
Theorem (左连翠,吴建良,刘家壮,2006) (1) If and , then for an interval D between 1 and . (2) Let , then for for for for
Theorem (马刚,吴建良,2006) (1)If T is a tree with maximum degree ,then (2)If T is a tree with maximum degree ,then (3) If G is an outerplanar graph with maximum degree ,then
J. Akiyama, H. Era, S.V. Gervacio, and M. Vatanabe, Path chromatic numbers of graphs. J. Graph Theory, 13 (1989) 569-575. • Y. Alavi, D. Green, J. Q. Liu and J. F. Wang, On linear vetex-arboricity of graphs. Congressus Numeratim, 1991, 82, 187-192 • Y. Alavi, P. C.B. Lam, D. R. Lick, P. Erdos, J. Q. Liu and J. F. Wang, Upper Bounds on linear-vertex arboricity of complementary Graphs. Utilitas Math. 52, (1997) 43-48. • Y. Alavi, J. Q. Liu and J. F. Wang, On linear vertex-arboricity of complementary graphs. J. Graph Theory 18 (1994) 315-322. • Y. Alavi, D. R. Lick, J. Q. Liu and J. F. Wang, Bounds for linear vertex-arboricity and domination number of graphs. Vishna International Journal of Graph Theory, 1992, 1 (2), 95-102. • S. A. Burr, An inequality involving the vertex arboricity and edge arboricity of a graph . J.Graph Theory 10 (1986) 403-404. • P. A. Catlin and H. J. Lai, Vertex arboricity and maximum degree. Dis. Math. 141 (1995) 37-46. • G. Chartrand, D. P. Geller, and S. Hedetniemi, A generalization of the chromatic number . Proc. Camb. Phil. Soc. 64 (1968) 265-271.
G. Chartrand and H. V. Kronk, The point-arboricity of planar graphs. J. London Math. Soc. 44 (1969), 612-616. • G. Chartrand, H. V. Kronk and C. E. Wall, The point-arboricity of a graph. Israel J. Math. 6 (1968).169-175. • F. Harary, R. Maddox and W. Staton. On the point linear arboricity of a graph. Mathematiche (Catania) 44 (1989) 281-286. • H. V. Kronk and J. Mitchem, Critical point-arboritic graphs. J. London Math. Sco. (2) ,9 (1975), 459-466. • P. C. B. Lam, W. C. Shiu, F. Sun, J. F. Wang and G. Y. Yan, Linear vertex arboricity, independence number and clique cover number. Ars Combin. 58 (2001) 121-128. • M. Matsumoto, Bounds for the vertex linear arboricity. J. Graph Theory 14 (1990) 117-126. • J. Mitchem, Doctoral thesis, Western Michigan University(1970). • K. S. Poh, On the linear vertex-arboricity of a planar graph. J. Graph Theory, 14 (1990) 73-75. • J. F. Wang, On point-linear arboricity of planar graphs. Discrete Math. 72 (1988) 381-384.
L. C. Zuo, J. L. Wu, J. Z. Liu, The vertex linear arboricity of an integer distance graph with a special distance set. Ars Combin. 79 (2) (2006), preprint. • L. C. Zuo, J. L. Wu, J. Z. Liu, The vertex linear arboricity of distance graphs. Discrete Math. 306 (2006) 284-289. • 房勇,吴建良,完全多部图和笛卡儿乘积图的线性点荫度. 山东矿业学院学报(自然科学版) 18(3),59-61,1999. • 杨爱民,线图的荫度. 山西大学学报(自然科学版)21(1):19-22,1998. • 张忠辅, 王建方, 图与补图全独立数间的关系。应用数学,1989,2(4)35-39. • 张忠辅,张建勋,王建方,陈波亮,荫度与全独立数全覆盖数的关系. 曲阜师范大学学报 18(4),9-14,1992. • 左连翠,李涛,李霞,整数距离图的点线性荫度. 山东大学学报(理学版)39(6),68-71,2004. • 左连翠,李霞,距离图的点荫度. 山东大学学报(理学版)39(2),12-15,2004.