Biased dyadic crossover for variable-length multi-objective optimal control problems

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Abstract

This paper presents an enabling technique for social cooperation suitable for variable-length multi-objective direct optimal control problems. Using this approach, individualistic mesh-refinement may be performed across a population of discretised optimal control solutions within a real-coded evolutionary algorithm. Structural homology between individual solutions is inferred via the exploitation of non-uniform dyadic grid structures. Social actions, including genetic crossover, are enabled by identifying nodal intersections between parent vectors in normalised time. Several alternative crossover techniques are discussed, where effectiveness is evaluated based on the likelihood of producing dominating solutions with respect to the current archive. Each technique is demonstrated and compared using a simple numerical test case representing the controlled descent of a Lunar-landing vehicle. Of the examined methods, it is found that a hybrid one/two-point crossover, biased towards higher levels of grid resolution consistently outperforms those based on more traditional, unbiased crossover.
Original languageEnglish
Title of host publication2024 IEEE Congress on Evolutionary Computation (CEC)
Place of PublicationPiscataway, NJ
PublisherIEEE
Number of pages9
ISBN (Electronic)9798350308365
DOIs
Publication statusPublished - 8 Aug 2024
Event2024 IEEE World Congress on Computational Intelligence (WCCI) - Yokohama, Japan
Duration: 30 Jun 20245 Jul 2024
https://djordjebatic.github.io/wcci-citosses/

Conference

Conference2024 IEEE World Congress on Computational Intelligence (WCCI)
Country/TerritoryJapan
CityYokohama
Period30/06/245/07/24
Internet address

Keywords

  • multi-objective optimal control
  • mesh refinements
  • evolutionary algorithm
  • variable-length chromosomes

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