Strong computational lower bounds via parameterized complexity

We develop new techniques for deriving strong computational lower bounds for a class of well-known NP-hard problems. This class includes weighted satisfiability, dominating set, hitting set, set cover, clique, and independent set. For example, although a trivial enumeration can easily test in time O...

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Vydáno v:Journal of computer and system sciences Ročník 72; číslo 8; s. 1346 - 1367
Hlavní autoři: Chen, Jianer, Huang, Xiuzhen, Kanj, Iyad A., Xia, Ge
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Inc 01.12.2006
Témata:
Clique
Computational complexity
Lower bound
Parameterized computation
Polynomial time approximation scheme
Lower bound
Clique
Polynomial time approximation scheme
Parameterized computation
Computational complexity
ISSN:0022-0000, 1090-2724
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Shrnutí:We develop new techniques for deriving strong computational lower bounds for a class of well-known NP-hard problems. This class includes weighted satisfiability, dominating set, hitting set, set cover, clique, and independent set. For example, although a trivial enumeration can easily test in time O ( n k ) if a given graph of n vertices has a clique of size k, we prove that unless an unlikely collapse occurs in parameterized complexity theory, the problem is not solvable in time f ( k ) n o ( k ) for any function f, even if we restrict the parameter values to be bounded by an arbitrarily small function of n. Under the same assumption, we prove that even if we restrict the parameter values k to be of the order Θ ( μ ( n ) ) for any reasonable function μ, no algorithm of running time n o ( k ) can test if a graph of n vertices has a clique of size k. Similar strong lower bounds on the computational complexity are also derived for other NP-hard problems in the above class. Our techniques can be further extended to derive computational lower bounds on polynomial time approximation schemes for NP-hard optimization problems. For example, we prove that the NP-hard distinguishing substring selection problem, for which a polynomial time approximation scheme has been recently developed, has no polynomial time approximation schemes of running time f ( 1 / ϵ ) n o ( 1 / ϵ ) for any function f unless an unlikely collapse occurs in parameterized complexity theory.
ISSN:0022-0000
1090-2724
DOI:10.1016/j.jcss.2006.04.007