Peter J. Angeline scite author profile

Standard methods for inducing both the structure and weight values of recurrent neural networks fit an assumed class of architectures to every task. This simplification is necessary because the interactions between network structure and function are not well understood. Evolutionary computation, which includes genetic algorithms and evolutionary programming, is a population-based search method that has shown promise in such complex tasks. This paper argues that genetic algorithms are inappropriate for network acquisition and describes an evolutionary program, called GNARL, that simultaneously acquires both the structure and weights for recurrent networks. This algorithm's empirical acquisition method allows for the emergence of complex behaviors and topologies that are potentially excluded by the artificial architectural constraints imposed in standard network induction methods. To Appear in: IEEE Transactions on Neural NetworksThe Ohio State University AbstractStandard methods for inducing both the structure and weight values of recurrent neural networks fit an assumed class of architectures to every task. This simplification is necessary because the interactions between network structure and function are not well understood. Evolutionary computation, which includes genetic algorithms and evolutionary programming, is a population-based search method that has shown promise in such complex tasks. This paper argues that genetic algorithms are inappropriate for network acquisition and describes an evolutionary program, called GNARL, that simultaneously acquires both the structure and weights for recurrent networks. This algorithm's empirical acquisition method allows for the emergence of complex behaviors and topologies that are potentially excluded by the artificial architectural constraints imposed in standard network induction methods.

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Evolutionary optimization versus particle swarm optimization: Philosophy and performance differences

Angeline

1998

866

343

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Using selection to improve particle swarm optimization

Angeline

570

269

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Tracking extrema in dynamic environments

Angeline

1997

116

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Inductive reasoning and bounded rationality reconsidered

Fogel

Chellapilla

Angeline

1999

IEEE Trans. Evol. Computat.

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Peter J. Angeline

An evolutionary algorithm that constructs recurrent neural networks

Evolutionary optimization versus particle swarm optimization: Philosophy and performance differences

Using selection to improve particle swarm optimization

Tracking extrema in dynamic environments

Inductive reasoning and bounded rationality reconsidered

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