Abstract
Soft computing (SC) is an evolving collection of methodologies, i.e., fuzzy, neuro, and evolutionary computing. Chaotic computing and immune systems are added later to enhance the soft computing capabilities. The fusion of SC components creates new functions i.e. flexible knowledge representation (symbol and pattern), acquisition and inference (tractability, machine intelligent quotient), and robust and low cost product. Among them immune systems are very suitable for control and diagnosis of multi-agent systems (large-scale and complex systems) that interact among human beings, environment and artificial objects corresponding to the usage of complex interactions among antibodies and antigens in the immune systems. This paper describes novel sensor fault diagnosis for an uninterruptible power supply control system and new decision making of a robot in a changeable environment using immune networks. Simulation studies show that the proposed methods are feasible and promising for control and diagnosis of large-scale and complex dynamical systems.
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Dote, Y. (2002). Diagnosis and Control for Multi-agent Systems Using Immune Networks. In: Roy, R., Köppen, M., Ovaska, S., Furuhashi, T., Hoffmann, F. (eds) Soft Computing and Industry. Springer, London. https://doi.org/10.1007/978-1-4471-0123-9_1
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DOI: https://doi.org/10.1007/978-1-4471-0123-9_1
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