A Block-Coordinate Descent EMO Algorithm: Theoretical and Empirical Analysis
Abstract
We consider whether conditions exist under which block-coordinate descent is asymptotically efficient in evolutionary multi-objective optimization, addressing an open problem. Block-coordinate descent, where an optimization problem is decomposed into blocks of decision variables and each of the blocks is optimized (with the others fixed) in a sequence, is a technique used in some large-scale optimization problems such as airline scheduling, however its use in multi-objective optimization is less studied. We propose a block-coordinate version of GSEMO and compare its running time to the standard GSEMO algorithm. Theoretical and empirical results on a bi-objective test function, a variant of LOTZ, serve to demonstrate the existence of cases where block-coordinate descent is faster. The result may yield wider insights into this class of algorithms.
Cite
@article{arxiv.2404.03838,
title = {A Block-Coordinate Descent EMO Algorithm: Theoretical and Empirical Analysis},
author = {Benjamin Doerr and Joshua Knowles and Aneta Neumann and Frank Neumann},
journal= {arXiv preprint arXiv:2404.03838},
year = {2024}
}
Comments
Accepted at GECCO 2024