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Main Authors: Yu, Tian-Li, Chang, Chi-Hsien, Chen, Ying-ping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.10777
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author Yu, Tian-Li
Chang, Chi-Hsien
Chen, Ying-ping
author_facet Yu, Tian-Li
Chang, Chi-Hsien
Chen, Ying-ping
contents The concepts of linkage, building blocks, and problem decomposition have long existed in the genetic algorithm field and have guided the development of model-based genetic algorithms for decades. However, their definitions are usually vague, making it difficult to develop theoretical support. This paper provides an algorithm-independent definition to describe the concept of linkage. With this definition, the paper proves that any problem with a bounded degree of linkage is decomposable and that proper problem decomposition is possible via linkage learning. The way of decomposition given in this paper also offers a new perspective on nearly decomposable problems with bounded difficulty and building blocks from the theoretical aspect. Finally, this paper relates problem decomposition to probably approximately correct (PAC) learning and proves that the global optima of problems with bounded decomposition difficulty are PAC learnable and the decomposition is decidable in polynomial time under certain conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2501_10777
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The working principles of model-based GAs fall within the PAC framework: A mathematical theory of problem decomposition
Yu, Tian-Li
Chang, Chi-Hsien
Chen, Ying-ping
Neural and Evolutionary Computing
The concepts of linkage, building blocks, and problem decomposition have long existed in the genetic algorithm field and have guided the development of model-based genetic algorithms for decades. However, their definitions are usually vague, making it difficult to develop theoretical support. This paper provides an algorithm-independent definition to describe the concept of linkage. With this definition, the paper proves that any problem with a bounded degree of linkage is decomposable and that proper problem decomposition is possible via linkage learning. The way of decomposition given in this paper also offers a new perspective on nearly decomposable problems with bounded difficulty and building blocks from the theoretical aspect. Finally, this paper relates problem decomposition to probably approximately correct (PAC) learning and proves that the global optima of problems with bounded decomposition difficulty are PAC learnable and the decomposition is decidable in polynomial time under certain conditions.
title The working principles of model-based GAs fall within the PAC framework: A mathematical theory of problem decomposition
topic Neural and Evolutionary Computing
url https://arxiv.org/abs/2501.10777