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PIER PIER B PIER C PIER M PIER Letters
2004-06-22
A Novel Evolutionary Learning Technique for Multi-Objective Array Antenna Optimization
By
Yee Hui Lee,

    Dr. Yee Hui Lee

    School of Electrical and Electronic Engineering

    Nanyang Technological University

    Singapore

    Homepage

Brian Cahill,

    Dr. Brian Cahill

    Sky LINC Limited

    United Kingdom

    Homepage

Stuart Porter,

    Dr. Stuart Porter

    Department of Electronics

    University of York

    UK

    Homepage

Andrew Marvin

    Dr. Andrew Marvin

    Department of Electronics

    University of York

    UK

    Homepage

, Vol. 48, 125-144, 2004
doi:10.2528/PIER04012202 | Google Scholar

Abstract
In this paper, a neural network is used to implement an optimized objective function for a genetic algorithm (GA) for application on array antenna design optimization. Traditional GAs are inefficient because a large amount of data that describes the problem space is discarded after each generation. Using the neural network enhanced genetic algorithm (NNEGA), this redundant information is fed back into the GA's objective function via the neural network. The neural network learns the optimal weights of the objective function by identifying trends and optimizing weights depending on the knowledge that it accumulates in-situ. The NNEGA is successfully applied to challenging array antenna design problems. This use of neural network to optimize a multi-objective function for the GA is a new idea that is different from other hybridization of GA and NN.
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Citation
Yee Hui Lee, Brian Cahill, Stuart Porter, and Andrew Marvin, "A Novel Evolutionary Learning Technique for Multi-Objective Array Antenna Optimization," , Vol. 48, 125-144, 2004.
doi:10.2528/PIER04012202
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