Neural network crossover in genetic algorithms using genetic programming

IF 1.7 3区计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Genetic Programming and Evolvable Machines Pub Date : 2024-02-21 DOI:10.1007/s10710-024-09481-7

Kyle Pretorius, Nelishia Pillay

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Abstract

The use of genetic algorithms (GAs) to evolve neural network (NN) weights has risen in popularity in recent years, particularly when used together with gradient descent as a mutation operator. However, crossover operators are often omitted from such GAs as they are seen as being highly destructive and detrimental to the performance of the GA. Designing crossover operators that can effectively be applied to NNs has been an active area of research with success limited to specific problem domains. The focus of this study is to use genetic programming (GP) to automatically evolve crossover operators that can be applied to NN weights and used in GAs. A novel GP is proposed and used to evolve both reusable and disposable crossover operators to compare their efficiency. Experiments are conducted to compare the performance of GAs using no crossover operator or a commonly used human designed crossover operator to GAs using GP evolved crossover operators. Results from experiments conducted show that using GP to evolve disposable crossover operators leads to highly effectively crossover operators that significantly improve the results obtained from the GA.

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使用遗传编程的遗传算法中的神经网络交叉

近年来，使用遗传算法（GA）来进化神经网络（NN）权重的做法越来越流行，尤其是将梯度下降算法作为突变算子一起使用时。然而，此类遗传算法通常不使用交叉算子，因为交叉算子被认为具有很强的破坏性，会损害遗传算法的性能。设计能有效应用于网络的交叉算子一直是一个活跃的研究领域，但其成功仅限于特定的问题领域。本研究的重点是使用遗传编程（GP）来自动演化可应用于 NN 权重并在遗传算法中使用的交叉算子。我们提出了一种新颖的 GP，并将其用于进化可重复使用和一次性的交叉算子，以比较它们的效率。实验比较了不使用交叉算子或常用人工设计交叉算子的遗传算法与使用 GP 演化交叉算子的遗传算法的性能。实验结果表明，使用 GP 进化出的一次性交叉算子能产生高效的交叉算子，显著改善遗传算法的结果。

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来源期刊

Genetic Programming and Evolvable Machines 工程技术-计算机：理论方法

CiteScore

5.90

自引率

3.80%

发文量

审稿时长

6 months

期刊介绍： A unique source reporting on methods for artificial evolution of programs and machines... Reports innovative and significant progress in automatic evolution of software and hardware. Features both theoretical and application papers. Covers hardware implementations, artificial life, molecular computing and emergent computation techniques. Examines such related topics as evolutionary algorithms with variable-size genomes, alternate methods of program induction, approaches to engineering systems development based on embryology, morphogenesis or other techniques inspired by adaptive natural systems.