TY - JOUR
T1 - On a vector space representation in genetic algorithms for sensor scheduling in wireless sensor networks
AU - Martins, F.V.C.
AU - Carrano, E.G.
AU - Wanner, E. F.
AU - Takahashi, R.H.C.
AU - Mateus, G.R.
AU - Nakamura, F.G.
PY - 2014/9/13
Y1 - 2014/9/13
N2 - Recent works raised the hypothesis that the assignment of a geometry to the decision variable space of a combinatorial problem could be useful both for providing meaningful descriptions of the fitness landscape and for supporting the systematic construction of evolutionary operators (the geometric operators) that make a consistent usage of the space geometric properties in the search for problem optima. This paper introduces some new geometric operators that constitute the realization of searches along the combinatorial space versions of the geometric entities descent directions and subspaces. The new geometric operators are stated in the specific context of the wireless sensor network dynamic coverage and connectivity problem (WSN-DCCP). A genetic algorithm (GA) is developed for the WSN-DCCP using the proposed operators, being compared with a formulation based on integer linear programming (ILP) which is solved with exact methods. That ILP formulation adopts a proxy objective function based on the minimization of energy consumption in the network, in order to approximate the objective of network lifetime maximization, and a greedy approach for dealing with the system’s dynamics. To the authors’ knowledge, the proposed GA is the first algorithm to outperform the lifetime of networks as synthesized by the ILP formulation, also running in much smaller computational times for large instances.
AB - Recent works raised the hypothesis that the assignment of a geometry to the decision variable space of a combinatorial problem could be useful both for providing meaningful descriptions of the fitness landscape and for supporting the systematic construction of evolutionary operators (the geometric operators) that make a consistent usage of the space geometric properties in the search for problem optima. This paper introduces some new geometric operators that constitute the realization of searches along the combinatorial space versions of the geometric entities descent directions and subspaces. The new geometric operators are stated in the specific context of the wireless sensor network dynamic coverage and connectivity problem (WSN-DCCP). A genetic algorithm (GA) is developed for the WSN-DCCP using the proposed operators, being compared with a formulation based on integer linear programming (ILP) which is solved with exact methods. That ILP formulation adopts a proxy objective function based on the minimization of energy consumption in the network, in order to approximate the objective of network lifetime maximization, and a greedy approach for dealing with the system’s dynamics. To the authors’ knowledge, the proposed GA is the first algorithm to outperform the lifetime of networks as synthesized by the ILP formulation, also running in much smaller computational times for large instances.
KW - dynamic optimization
KW - genetic algorithms
KW - geometric operators
KW - wireless sensor networks
UR - http://www.mitpressjournals.org/doi/10.1162/EVCO_a_00112#.WMqXy8mxWuw
UR - http://www.scopus.com/inward/record.url?scp=84927170301&partnerID=8YFLogxK
U2 - 10.1162/EVCO_a_00112
DO - 10.1162/EVCO_a_00112
M3 - Article
C2 - 24102647
AN - SCOPUS:84927170301
SN - 1063-6560
VL - 22
SP - 361
EP - 403
JO - Evolutionary Computation
JF - Evolutionary Computation
IS - 3
ER -