论文信息 - Evolutionary learning of general fuzzy rules with biased evaluation functions: competition and cooperation

Evolutionary learning of general fuzzy rules with biased evaluation functions: competition and cooperation

Fuzzy rules cooperate in a fuzzy logic controller (FLC) to produce the best action for a given situation. If we have a population of fuzzy rules controlling a device, and we would like to evolve the population to obtain optimal performance by reinforcement learning, rules should compete each other, since we would like to judge their proposals. Therefore, in this approach, cooperation and competition are two opposite, desired activities done by the population members. This may be a problem, if we consider that the evaluation function may be biased, as it may happen, for instance, when we are designing a controlled device such as an autonomous agent. The problem becomes even harder if we would like to learn general rules, i.e., rules containing don't care symbols in their antecedents, thus competing with many groups of other rules, in many different situations. We discuss these issues, and present a solution, implemented in ELF (evolutionary learning of fuzzy rules). We successfully applied ELF to develop autonomous agents, and other fuzzy controlled devices.<<ETX>>

Andrea Bonarini | Andrea Bonarini

[1] H. Takagi,et al. Integrating Design Stages of Fuzzy Systems using Genetic Algorithms 1 , 1993 .

[2] M.A. Lee,et al. Integrating design stage of fuzzy systems using genetic algorithms , 1993, [Proceedings 1993] Second IEEE International Conference on Fuzzy Systems.

[3] Philip R. Thrift,et al. Fuzzy Logic Synthesis with Genetic Algorithms , 1991, ICGA.

[4] Manuel Valenzuela-Rendón,et al. The Fuzzy Classifier System: A Classifier System for Continuously Varying Variables , 1991, ICGA.

[5] David S. Feldman,et al. Fuzzy Network Synthesis with Genetic Algorithms , 1993, ICGA.

[6] Bart Kosko,et al. Neural networks and fuzzy systems: a dynamical systems approach to machine intelligence , 1991 .

[7] Marco Dorigo,et al. Genetics-based machine learning and behavior-based robotics: a new synthesis , 1993, IEEE Trans. Syst. Man Cybern..

[8] Kurt Konolige,et al. Blending reactivity and goal-directedness in a fuzzy controller , 1993, [Proceedings 1993] Second IEEE International Conference on Fuzzy Systems.

[9] Marco Colombetti,et al. Robot shaping: developing situated agents through learning , 1992 .

[10] Charles L. Karr,et al. Improved Fuzzy Process Control of Spacecraft Autonomous Rendezvous Using a Genetic Algorithm , 1990, Other Conferences.