On generalized list -free colorings of graphs

Abstract

For given graph H and graphical property P, the conditional chromatic number (H,P) of H, is the smallest number k, so that V(H) can be decomposed into sets V1,V2,…, Vk, in which H[Vi] satisfies the property P, for each 1≤ i≤ k. When property P be that each color class contains no copy of G, we write G(H) instead of (G,P), which is called the G-free chromatic number. Due to this, we say H has a k-G-free coloring if there is a map c : V(H) \1,…,k\, so that each of the color classes of c be G-free. Assume that for each vertex v of a graph H is assigned a set L(V) of colors, called a color list. Set g(L) = \g(v): v∈ V(H)\, that is the set of colors chosen for the vertices of H under g. An L-coloring g is called G-free, so that: itemize g(v)∈ L(v), for any v∈ V(H). H[Vi] is G-free for each i=1,2,…, L. itemize If there exists an L-coloring of H, then H is called L-G-free-colorable. A graph H is said to be k-G-free-choosable if there exists an L-coloring for any list-assignment L satisfying |L(V)|≥ k for each v∈ V(H), and H[Vi] be G-free for each i=1,2,…, L. Let graph H and a collection of graphs are given, the L(H) of H is the last integer k, so that H is k--free-choosable i.e. H[Vi] is -free for each i=1,2,…, k i.e. contains no copy of any member of . In this article, we show that GL(H)=G(H) for some graph H and G, GL(H H')≤ GL(H)+GL(H') for each G, H, and H'. Also, we show that (H Kn)=L(H Kn), where is a collection of all d-regular graphs, and some n.