2005 | OriginalPaper | Buchkapitel
Linear Kernels in Linear Time, or How to Save k Colors in O(n 2) Steps
verfasst von : Benny Chor, Mike Fellows, David Juedes
Erschienen in: Graph-Theoretic Concepts in Computer Science
Verlag: Springer Berlin Heidelberg
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This paper examines a parameterized problem that we refer to as
n
–
k
Graph Coloring
, i.e., the problem of determining whether a graph
G
with
n
vertices can be colored using
n
–
k
colors. As the main result of this paper, we show that there exists a
O
(
kn
2
+
k
2
+ 2
3.8161k
)=
O
(
n
2
) algorithm for
n
–
k
Graph Coloring
for each fixed
k
. The core technique behind this new parameterized algorithm is kernalization via maximum (and certain maximal) matchings.
The core technical content of this paper is a near linear-time kernelization algorithm for
n
–
k
Clique Covering
. The near linear-time kernelization algorithm that we present for
n
–
k
Clique Covering
produces a linear size (3
k
–3) kernel in
O
(
k
(
n
+
m
)) steps on graphs with
n
vertices and
m
edges. The algorithm takes an instance 〈
G
,
k
〉 of
Clique Covering
that asks whether a graph
G
can be covered using |
V
|–
k
cliques and reduces it to the problem of determining whether a graph
G
′=(
V
′,
E
′) of size ≤ 3
k
–3 can be covered using |
V
′| –
k
′ cliques. We also present a similar near linear-time algorithm that produces a 3
k
kernel for
Vertex Cover
. This second kernelization algorithm is the
crown reduction rule
.