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Multi-objective Optimization by Uncrowded Hypervolume Gradient Ascent

Authors :
Deist, Timo M.
Maree, Stefanus C.
Alderliesten, Tanja
Bosman, Peter A. N.
Bäck, Thomas
Preuss, Mike
Deutz, André
Emmerich, Michael
Wang, Hao
Doerr, Carola
Trautmann, Heike
Centrum Wiskunde & Informatica, Amsterdam (CWI), The Netherlands
Graduate School
Source :
Parallel Problem Solving from Nature – PPSN XVI ISBN: 9783030581145, PPSN (2), Parallel Problem Solving from Nature – PPSN XVI-16th International Conference, PPSN 2020, Proceedings, 12270 LNCS, 186-200
Publication Year :
2020
Publisher :
Springer International Publishing, 2020.

Abstract

Evolutionary algorithms (EAs) are the preferred method for solving black-box multi-objective optimization problems, but when gradients of the objective functions are available, it is not straightforward to exploit these efficiently. By contrast, gradient-based optimization is well-established for single-objective optimization. A single-objective reformulation of the multi-objective problem could therefore offer a solution. Of particular interest to this end is the recently introduced uncrowded hypervolume (UHV) indicator, which is Pareto compliant and also takes into account dominated solutions. In this work, we show that the gradient of the UHV can often be computed, which allows for a direct application of gradient ascent algorithms. We compare this new approach with two EAs for UHV optimization as well as with one gradient-based algorithm for optimizing the well-established hypervolume. On several bi-objective benchmarks, we find that gradient-based algorithms outperform the tested EAs by obtaining a better hypervolume with fewer evaluations whenever exact gradients of the multiple objective functions are available and in case of small evaluation budgets. For larger budgets, however, EAs perform similarly or better. We further find that, when finite differences are used to approximate the gradients of the multiple objectives, our new gradient-based algorithm is still competitive with EAs in most considered benchmarks. Implementations are available at https://github.com/scmaree/uncrowded-hypervolume.

Details

ISBN :
978-3-030-58114-5
ISBNs :
9783030581145
Database :
OpenAIRE
Journal :
Parallel Problem Solving from Nature – PPSN XVI ISBN: 9783030581145, PPSN (2), Parallel Problem Solving from Nature – PPSN XVI-16th International Conference, PPSN 2020, Proceedings, 12270 LNCS, 186-200
Accession number :
edsair.doi.dedup.....28182c47c95eb60c447af5b74d253b5a
Full Text :
https://doi.org/10.1007/978-3-030-58115-2_13