768 research outputs found
Planar Induced Subgraphs of Sparse Graphs
We show that every graph has an induced pseudoforest of at least
vertices, an induced partial 2-tree of at least vertices, and an
induced planar subgraph of at least vertices. These results are
constructive, implying linear-time algorithms to find the respective induced
subgraphs. We also show that the size of the largest -minor-free graph in
a given graph can sometimes be at most .Comment: Accepted by Graph Drawing 2014. To appear in Journal of Graph
Algorithms and Application
Light subgraphs in graphs with average degree at most four
A graph is said to be {\em light} in a family of graphs if
at least one member of contains a copy of and there exists
an integer such that each member of
with a copy of also has a copy of such that
for all . In this
paper, we study the light graphs in the class of graphs with small average
degree, including the plane graphs with some restrictions on girth.Comment: 12 pages, 18 figure
Linear Choosability of Sparse Graphs
We study the linear list chromatic number, denoted \lcl(G), of sparse
graphs. The maximum average degree of a graph , denoted \mad(G), is the
maximum of the average degrees of all subgraphs of . It is clear that any
graph with maximum degree satisfies \lcl(G)\ge
\ceil{\Delta(G)/2}+1. In this paper, we prove the following results: (1) if
\mad(G)<12/5 and , then \lcl(G)=\ceil{\Delta(G)/2}+1, and
we give an infinite family of examples to show that this result is best
possible; (2) if \mad(G)<3 and , then
\lcl(G)\le\ceil{\Delta(G)/2}+2, and we give an infinite family of examples to
show that the bound on \mad(G) cannot be increased in general; (3) if is
planar and has girth at least 5, then \lcl(G)\le\ceil{\Delta(G)/2}+4.Comment: 12 pages, 2 figure
Choosability of the square of planar subcubic graphs with large girth
We first show that the choose number of the square of a subcubic graph with maximum average degree less than 18/7 is at most 6. As a corollary, we get that the choose number of the square of a planar graph with girth at least 9 is at most 6. We then show that the choose number of the square of a subcubic planar graph with girth at least 13 is at most 5
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