The dynamics of a genetic algorithm for a simple learning problem


Autoria(s): Rattray, Magnus; Shapiro, Jon
Data(s)

07/12/1996

Resumo

A formalism for describing the dynamics of Genetic Algorithms (GAs) using method s from statistical mechanics is applied to the problem of generalization in a perceptron with binary weights. The dynamics are solved for the case where a new batch of training patterns is presented to each population member each generation, which considerably simplifies the calculation. The theory is shown to agree closely to simulations of a real GA averaged over many runs, accurately predicting the mean best solution found. For weak selection and large problem size the difference equations describing the dynamics can be expressed analytically and we find that the effects of noise due to the finite size of each training batch can be removed by increasing the population size appropriately. If this population resizing is used, one can deduce the most computationally efficient size of training batch each generation. For independent patterns this choice also gives the minimum total number of training patterns used. Although using independent patterns is a very inefficient use of training patterns in general, this work may also prove useful for determining the optimum batch size in the case where patterns are recycled.

Formato

application/pdf

Identificador

http://eprints.aston.ac.uk/686/1/misc96-010.pdf

Rattray, Magnus and Shapiro, Jon (1996). The dynamics of a genetic algorithm for a simple learning problem. Journal of Physics A: Mathematical and General, 29 (23), pp. 7451-7473.

Relação

http://eprints.aston.ac.uk/686/

Tipo

Article

PeerReviewed