TL-MOMFEA: a transfer learning-based multi-objective multitasking optimization evolutionary algorithm

IF 3.3 2区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Memetic Computing Pub Date : 2024-08-12 DOI:10.1007/s12293-024-00431-5

Xuan Lu, Lei Chen, Hai-Lin Liu

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引用次数: 0

Abstract

Evolutionary multi-objective multitasking optimization (MTO) has emerged as a popular research field in evolutionary computation. By simultaneously considering multiple objectives and tasks while identifying valuable knowledge for intertask transfer, MTO aims to discover solutions that deliver optimal performance across all objectives and tasks. Nevertheless, MTO presents a substantial challenge concerning the effective transport of high-quality information between tasks. To handle this challenge, this paper introduces a novel approach named TL-MOMFEA (multi-objective multifactorial evolutionary algorithm based on domain transfer learning) for MTO problems. TL-MOMFEA uses domain-transfer learning to adapt the population from one task to another, resulting in the reproduction of higher-quality solutions. Furthermore, TL-MOMFEA employs a model transfer strategy where population distribution rules learned from one task are succinctly summarized and applied to similar tasks. By capitalizing on the knowledge acquired from solved tasks, TL-MOMFEA effectively circumvents futile searches and accurately identifies global optimum predictions with increased precision. The effectiveness of TL-MOMFEA is evaluated through experimental studies in two widely used test suites, and experimental comparisons have shown that the proposed paradigm achieves excellent results in terms of solution quality and search efficiency, thus demonstrating its clear superiority over other state-of-the-art MTO frameworks.

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TL-MOMFEA：基于迁移学习的多目标多任务优化进化算法

进化多目标多任务优化（MTO）已成为进化计算的一个热门研究领域。通过同时考虑多个目标和任务，同时识别任务间传输的有价值知识，多任务优化旨在发现能在所有目标和任务中实现最佳性能的解决方案。然而，MTO 在任务间有效传输高质量信息方面提出了巨大挑战。为了应对这一挑战，本文针对 MTO 问题提出了一种名为 TL-MOMFEA（基于领域转移学习的多目标多因素进化算法）的新方法。TL-MOMFEA 利用领域转移学习来调整从一个任务到另一个任务的群体，从而产生更高质量的解决方案。此外，TL-MOMFEA 还采用了模型转移策略，将从一项任务中学到的群体分布规则进行简明总结，并应用于类似任务。通过利用从已解决任务中获得的知识，TL-MOMFEA 有效地避免了徒劳无益的搜索，并以更高的精度准确确定了全局最优预测。通过在两个广泛使用的测试套件中进行实验研究，对 TL-MOMFEA 的有效性进行了评估，实验比较表明，所提出的范式在解决方案质量和搜索效率方面都取得了优异的结果，从而证明了它明显优于其他最先进的 MTO 框架。

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来源期刊

Memetic Computing COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-OPERATIONS RESEARCH & MANAGEMENT SCIENCE

CiteScore

6.80

自引率

12.80%

发文量

期刊介绍： Memes have been defined as basic units of transferrable information that reside in the brain and are propagated across populations through the process of imitation. From an algorithmic point of view, memes have come to be regarded as building-blocks of prior knowledge, expressed in arbitrary computational representations (e.g., local search heuristics, fuzzy rules, neural models, etc.), that have been acquired through experience by a human or machine, and can be imitated (i.e., reused) across problems. The Memetic Computing journal welcomes papers incorporating the aforementioned socio-cultural notion of memes into artificial systems, with particular emphasis on enhancing the efficacy of computational and artificial intelligence techniques for search, optimization, and machine learning through explicit prior knowledge incorporation. The goal of the journal is to thus be an outlet for high quality theoretical and applied research on hybrid, knowledge-driven computational approaches that may be characterized under any of the following categories of memetics: Type 1: General-purpose algorithms integrated with human-crafted heuristics that capture some form of prior domain knowledge; e.g., traditional memetic algorithms hybridizing evolutionary global search with a problem-specific local search. Type 2: Algorithms with the ability to automatically select, adapt, and reuse the most appropriate heuristics from a diverse pool of available choices; e.g., learning a mapping between global search operators and multiple local search schemes, given an optimization problem at hand. Type 3: Algorithms that autonomously learn with experience, adaptively reusing data and/or machine learning models drawn from related problems as prior knowledge in new target tasks of interest; examples include, but are not limited to, transfer learning and optimization, multi-task learning and optimization, or any other multi-X evolutionary learning and optimization methodologies.