Running time analysis of the (1+1)-EA for robust linear optimization

Evolutionary algorithms (EAs) have found many successful real-world applications, where the optimization problems are often subject to a wide range of uncertainties. To understand the practical behaviors of EAs theoretically, there are a series of efforts devoted to analyzing the running time of EAs...

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Bibliographic Details
Published inTheoretical computer science Vol. 843; pp. 57 - 72
Main Authors Bian, Chao, Qian, Chao, Tang, Ke, Yu, Yang
Format Journal Article
LanguageEnglish
Published Elsevier B.V 02.12.2020
Subjects
Computational complexity
Evolutionary algorithms
Robust optimization
Running time analysis
Robust optimization
Evolutionary algorithms
Computational complexity
Running time analysis
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Summary:Evolutionary algorithms (EAs) have found many successful real-world applications, where the optimization problems are often subject to a wide range of uncertainties. To understand the practical behaviors of EAs theoretically, there are a series of efforts devoted to analyzing the running time of EAs for optimization under uncertainties. Existing studies mainly focus on noisy and dynamic optimization, while another common type of uncertain optimization, i.e., robust optimization, has been rarely touched. In this paper, we analyze the expected running time of the (1+1)-EA solving robust linear optimization problems (i.e., linear problems under robust scenarios) with a cardinality constraint k. Two common robust scenarios, i.e., deletion-robust and worst-case, are considered. Particularly, we derive tight ranges of the robust parameter d or budget k allowing the (1+1)-EA to find an optimal solution in polynomial running time, which disclose the potential of EAs for robust optimization.
ISSN:0304-3975
1879-2294
DOI:10.1016/j.tcs.2020.07.001