TY - JOUR
T1 - Approximating Covering Problems by Randomized Search Heuristics Using Multi-Objective Models
AU - Friedrich, Tobias
AU - He, Jun
AU - Hebbinghaus, Nils
AU - Neumann, Frank
AU - Witt, Carsten
N1 - Friedrich, T., He, J., Hebbinghaus, N., Neumann, F., Witt, C. (2010). Approximating Covering Problems by Randomized Search Heuristics Using Multi-Objective Models. Evolutionary Computation, 18 (4), 617-633.
PY - 2010
Y1 - 2010
N2 - The main aim of randomized search heuristics is to produce good approximations of optimal solutions within a small amount of time. In contrast to numerous experimental results, there are only a few theoretical explorations on this subject. We consider the approximation ability of randomized search heuristics for the class of covering problems and compare single-objective and multi-objective models for such problems. For the VertexCover problem, we point out situations where the multi-objective model leads to a fast construction of optimal solutions while in the single-objective case, no good approximation can be achieved within the expected polynomial time. Examining the more general SetCover problem, we show that optimal solutions can be approximated within a logarithmic factor of the size of the ground set, using the multi-objective approach, while the approximation quality obtainable by the single-objective approach in expected polynomial time may be arbitrarily bad.
AB - The main aim of randomized search heuristics is to produce good approximations of optimal solutions within a small amount of time. In contrast to numerous experimental results, there are only a few theoretical explorations on this subject. We consider the approximation ability of randomized search heuristics for the class of covering problems and compare single-objective and multi-objective models for such problems. For the VertexCover problem, we point out situations where the multi-objective model leads to a fast construction of optimal solutions while in the single-objective case, no good approximation can be achieved within the expected polynomial time. Examining the more general SetCover problem, we show that optimal solutions can be approximated within a logarithmic factor of the size of the ground set, using the multi-objective approach, while the approximation quality obtainable by the single-objective approach in expected polynomial time may be arbitrarily bad.
UR - http://hdl.handle.net/2160/11826
U2 - 10.1162/EVCO_a_00003
DO - 10.1162/EVCO_a_00003
M3 - Article
C2 - 20583912
SN - 1063-6560
VL - 18
SP - 617
EP - 633
JO - Evolutionary Computation
JF - Evolutionary Computation
IS - 4
ER -