TY - JOUR
T1 - Objective-Domain Dual Decomposition: An Effective Approach to Optimizing Partially Differentiable Objective Functions
AU - Cheung, Yiu Ming
AU - Gu, Fangqing
AU - Liu, Hai Lin
AU - Tan, Kay Chen
AU - Huang, Han
N1 - Funding Information:
Manuscript received April 8, 2018; revised July 16, 2018; accepted September 11, 2018. Date of publication October 8, 2018; date of current version January 21, 2020. This work was supported in part by the National Natural Science Foundation of China under Grant 61672444, Grant 61272366, and Grant 61673121, in part by the Natural Science Foundation of SZU under Grant 2017078, in part by the Faculty Research Grant of Hong Kong Baptist University (HKBU) under Project FRG2/17-18/082 and Project FRG2/16-17/051, in part by the KTO Grant of HKBU under Project MPCF-004-2017/18, in part by the SZSTI under Grant JCYJ20160531194006833, in part by the Projects of Science and Technology of Guangzhou under Grant 201508010008, and in part by the Natural Science Foundation of Guangdong Province under Grant 2017A030310467. This paper was recommended by Associate Editor G. G. Yen. (Corresponding authors: Yiu-ming Cheung; Fangqing Gu.) Y.-M. Cheung is with the Department of Computer Science, Hong Kong Baptist University, Hong Kong (e-mail: [email protected]).
Publisher Copyright:
© 2013 IEEE.
PY - 2020/3
Y1 - 2020/3
N2 - This paper addresses a class of optimization problems in which either part of the objective function is differentiable while the rest is nondifferentiable or the objective function is differentiable in only part of the domain. Accordingly, we propose a dual-decomposition-based approach that includes both objective decomposition and domain decomposition. In the former, the original objective function is decomposed into several relatively simple subobjectives to isolate the nondifferentiable part of the objective function, and the problem is consequently formulated as a multiobjective optimization problem (MOP). In the latter decomposition, we decompose the domain into two subdomains, that is, the differentiable and nondifferentiable domains, to isolate the nondifferentiable domain of the nondifferentiable subobjective. Subsequently, the problem can be optimized with different schemes in the different subdomains. We propose a population-based optimization algorithm, called the simulated water-stream algorithm (SWA), for solving this MOP. The SWA is inspired by the natural phenomenon of water streams moving toward a basin, which is analogous to the process of searching for the minimal solutions of an optimization problem. The proposed SWA combines the deterministic search and heuristic search in a single framework. Experiments show that the SWA yields promising results compared with its existing counterparts.
AB - This paper addresses a class of optimization problems in which either part of the objective function is differentiable while the rest is nondifferentiable or the objective function is differentiable in only part of the domain. Accordingly, we propose a dual-decomposition-based approach that includes both objective decomposition and domain decomposition. In the former, the original objective function is decomposed into several relatively simple subobjectives to isolate the nondifferentiable part of the objective function, and the problem is consequently formulated as a multiobjective optimization problem (MOP). In the latter decomposition, we decompose the domain into two subdomains, that is, the differentiable and nondifferentiable domains, to isolate the nondifferentiable domain of the nondifferentiable subobjective. Subsequently, the problem can be optimized with different schemes in the different subdomains. We propose a population-based optimization algorithm, called the simulated water-stream algorithm (SWA), for solving this MOP. The SWA is inspired by the natural phenomenon of water streams moving toward a basin, which is analogous to the process of searching for the minimal solutions of an optimization problem. The proposed SWA combines the deterministic search and heuristic search in a single framework. Experiments show that the SWA yields promising results compared with its existing counterparts.
KW - Domain decomposition
KW - hybrid process
KW - objective decomposition
KW - partial differentiable objective function
KW - simulated water-stream algorithm (SWA
UR - http://www.scopus.com/inward/record.url?scp=85054544900&partnerID=8YFLogxK
U2 - 10.1109/TCYB.2018.2870487
DO - 10.1109/TCYB.2018.2870487
M3 - Journal article
C2 - 30296248
AN - SCOPUS:85054544900
SN - 2168-2267
VL - 50
SP - 923
EP - 934
JO - IEEE Transactions on Cybernetics
JF - IEEE Transactions on Cybernetics
IS - 3
M1 - 8485333
ER -