论文信息 - Combining Reliability and Pareto Optimality—An Approach Using Stochastic Multi-Objective Genetic Algorithms

Combining Reliability and Pareto Optimality—An Approach Using Stochastic Multi-Objective Genetic Algorithms

Genetic Algorithms have been successfully applied to numerous water resources problems, including problems with multiple objectives or uncertainty (noise). GAs tackle multi-objective optimization by following three basic principles — advancing the non-dominated frontier; maintaining diversity in the population (through various techniques like sharing, niching, and crowding); and using an elitist. However finding Pareto-optimal solutions becomes complicated when we add uncertainty to the problem. It was found that the solutions obtained using existing multi-objective solvers, although Pareto optimal were not the most robust or reliable solutions. In single-objective problems noise has typically been dealt with using Monte-Carlo-type sampling and some form of aggregate statistics (e.g., the average of the sample fitness). With multiple objectives the noise can interfere in determining non-domination of individuals, diversity preservation, and elitism (the three basic steps in multi-objective optimization). This paper proposes and tests several approaches to tackling some of these problems. These approaches strike a balance between finding the most optimal and the most reliable solution to the problem, thus giving decision makers and designers a practical and robust optimization tool.

[1] C. Fonseca,et al. GENETIC ALGORITHMS FOR MULTI-OBJECTIVE OPTIMIZATION: FORMULATION, DISCUSSION, AND GENERALIZATION , 1993 .

[2] R. Wardlaw,et al. EVALUATION OF GENETIC ALGORITHMS FOR OPTIMAL RESERVOIR SYSTEM OPERATION , 1999 .

[3] Samir W. Mahfoud. Niching methods for genetic algorithms , 1996 .

[4] Kalyanmoy Deb,et al. Multi-objective Genetic Algorithms: Problem Difficulties and Construction of Test Problems , 1999, Evolutionary Computation.

[5] T. Culver,et al. Optimizing Groundwater Remediation Design under Uncertainty , 2000 .

[6] David E. Goldberg,et al. Genetic Algorithms in Search Optimization and Machine Learning , 1988 .

[7] Kalyanmoy Deb,et al. Muiltiobjective Optimization Using Nondominated Sorting in Genetic Algorithms , 1994, Evolutionary Computation.

[8] Peter J. Fleming,et al. Genetic Algorithms for Multiobjective Optimization: FormulationDiscussion and Generalization , 1993, ICGA.

[9] Kalyanmoy Deb,et al. A Fast Elitist Non-dominated Sorting Genetic Algorithm for Multi-objective Optimisation: NSGA-II , 2000, PPSN.

[10] Alan D. Christiansen,et al. An empirical study of evolutionary techniques for multiobjective optimization in engineering design , 1996 .

[11] Evan J. Hughes,et al. Evolutionary Multi-objective Ranking with Uncertainty and Noise , 2001, EMO.

[12] Brad L. Miller,et al. Noise, sampling, and efficient genetic algorthms , 1997 .