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This study introduces a novel neurocontroller design using hybrid genetic search and reinforcement learning for rule extraction in temporal control problems. The system effectively generates macro rules, outperforming traditional methods in complex applications.

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Area of Science:

  • Control Systems Engineering
  • Artificial Intelligence
  • Machine Learning

Background:

  • Temporal control problems present significant challenges in system design.
  • Existing neurocontroller design methods often require supervision or reference models.
  • Rule extraction for complex control systems remains an area for innovation.

Purpose of the Study:

  • To propose a novel system for rule extraction in temporal control problems.
  • To present a new methodology for designing neurocontrollers.
  • To develop a learning strategy that is unsupervised and requires no reference model.

Main Methods:

  • A hybrid genetic search and reinforcement learning strategy is employed for rule extraction.
  • Extracted rules are refined through further genetic search and reinforcement learning, creating macro rules.
  • The system generates weighted micro rules operating on small neighborhoods of the control space.
  • Macro rules are used to train feedforward multilayer perceptron neurocontrollers or directly in table look-up controllers.

Main Results:

  • The system successfully extracted macro rules applicable to neurocontrollers and table look-up controllers.
  • Neurocontrollers trained with macro rules generally outperformed table look-up controllers in benchmark tests.
  • The developed controllers demonstrated robustness against noise disturbances and plant parameter variations.

Conclusions:

  • The proposed system offers an effective approach for designing neurocontrollers through unsupervised rule extraction.
  • The hybrid genetic search and reinforcement learning strategy provides a viable alternative for complex control tasks.
  • The macro rules-based neurocontrollers show superior performance and robustness compared to table look-up methods.