Approach for uncertain multi-objective programming problems with correlated objective functions under CEV criterion

doi:10.21629/JSEE.2018.06.08

Journal of Systems Engineering and Electronics ›› 2018, Vol. 29 ›› Issue (6): 1197-1208.doi: 10.21629/JSEE.2018.06.08

• Systems Engineering • Previous Articles Next Articles

Approach for uncertain multi-objective programming problems with correlated objective functions under C_EV criterion

Xiangfei MENG^1,*(), Ying WANG¹(), Chao LI¹(), Xiaoyang WANG²(), Maolong LYU¹()

¹ Equipment Management and Unmanned Aerial Vehicle Engineering College, Air Force Engineering University, Xi’an 710051, China
² Satellite Control Center, Xi’an 710043, China

Received:2017-07-20 Online:2018-12-25 Published:2018-12-26
Contact: Xiangfei MENG E-mail:mengxiangfeikgd@163.com;yingwangkgd@163.com;leecharle@sina.com;wangxiaoyang1987@163.com;18037707161@163.com
About author:MENG Xiangfei was born in 1989. He received his M.S. degree in control science and engineering from Air Force Engineering University in 2014. Now he is a Ph.D. candidate in Air Force Engineering University. His research interests are uncertain multiobjective programming and air traffic management. E-mail: mengxiangfeikgd@163.com|WANG Ying was born in 1967. She received her Ph.D. degree in management science and engineering from Xi’an Jiaotong University in 2003. She is a professor in Air Force Engineering University. Her research interests are uncertainty theory and supply chain management. E-mail: yingwangkgd@163.com|LI Chao was born in 1984. He received his Ph.D. degree from Air Force Engineering University in 2014. Now he is a teacher in Air Force Engineering University. His research interests are uncertainty theory and integer programming. E-mail: leecharle@sina.com|WANG Xiaoyang was born in 1987. He received his Ph.D. degree from Air Force Engineering University in 2016. Now he is an engineer in Satellite Control Center. His research interests include multiobjective programming and resource scheduling. E-mail: wangxiaoyang1987@163.com|LYU Maolong was born in 1991. He received his M.S. degree in control science and engineering from Air Force Engineering University in 2016. Now he is a Ph.D. candidate in Air Force Engineering University. His research interests include multi-objective programming and security control of system. E-mail: 18037707161@163.com
Supported by:
the National Natural Science Foundation of China(71601183);the National Natural Science Foundation of China(71571190);This work was supported by the National Natural Science Foundation of China (71601183; 71571190)

Abstract

Abstract:

An uncertain multi-objective programming problem is a special type of mathematical multi-objective programming involving uncertain variables. This type of problem is important because there are several uncertain variables in real-world problems. Therefore, research on the uncertain multi-objective programming problem is highly relevant, particularly those problems whose objective functions are correlated. In this paper, an approach that solves an uncertain multi-objective programming problem under the expected-variance value criterion is proposed. First, we define the basic framework of the approach and review concepts such as a Pareto efficient solution and expected-variance value criterion using an order relation between various uncertain variables. Second, the uncertain multi-objective problem is converted into an uncertain single-objective programming problem via a linear weighted method or ideal point method. Then the problem is transformed into a deterministic single objective programming problem under the expected-variance value criterion. Third, four lemmas and two theorems are proved to illustrate that the optimal solution of the deterministic single-objective programming problem is an efficient solution to the original uncertainty problem. Finally, two numerical examples are presented to validate the effectiveness of the proposed approach.

Key words: uncertainty theory, uncertain multi-objective programming, expected-variance value criterion

Xiangfei MENG, Ying WANG, Chao LI, Xiaoyang WANG, Maolong LYU. Approach for uncertain multi-objective programming problems with correlated objective functions under C_EV criterion[J]. Journal of Systems Engineering and Electronics, 2018, 29(6): 1197-1208.

Figures/Tables 9

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References 30

1	MIETTINEN K. Nonlinear multiobjective optimization. Dordrecht: Kluwer Academic Publishers, 1998.
2	PADHAN S K, NAHAK C. Higher-order symmetric duality in multiobjective programming problems under higher-order invexity. Applied Mathematics and Computation, 2011, 218 (5): 1705- 1712. doi: 10.1016/j.amc.2011.06.049
3	LAI H C, HO S C. Optimality and duality for nonsmooth multiobjective fractional programming problems involving exponential V-r-invexity. Nonlinear Analysis: Theory, Methods & Applications, 2012, 75 (6): 3157- 3166. doi: 10.1016/j.na.2011.12.013
4	HU Y, BIE Z, DING T, et al. An NSGA-II based multiobjective optimization for combined gas and electricity network expansion planning. Applied Energy, 2015, 167, 280- 293.
5	ZHENG J H, WU Q H, JING Z X. Coordinated scheduling strategy to optimize conflicting benefits for daily operation of integrated electricity and gas networks. Applied Energy, 2017, 192, 370- 381. doi: 10.1016/j.apenergy.2016.08.146
6	ZHANG W. The study of orderly power utility analysis, evaluation and optimization model of electricity customers. Beijing, China: North China Electric Power University, 2016. (in Chinese)
7	GONZALEZ-LONGATT F M. Impact of emulated inertia from wind power on under-frequency protection schemes of future power systems. Journal of Modern Power Systems & Clean Energy, 2016, 4 (2): 211- 218. doi: 10.1007/s40565-015-0143-x
8	BAI L, LI F, CUI H, et al. Interval optimization based operating strategy for gas-electricity integrated energy systems considering demand response and wind uncertainty. Applied Energy, 2016, 167, 270- 279. doi: 10.1016/j.apenergy.2015.10.119
9	YAO D. Research on air traffic control system growth planning in our country. Xi’an, China: Air Force Engineering University, 2016. (in Chinese)
10	CHEN Y, ZHANG D. Dynamic airspace configuration method based on a weighted graph model. Chinese Journal of Aeronautics, 2014, 27 (4): 903- 912. doi: 10.1016/j.cja.2014.06.009
11	AGUSTI’N A, ALONSO-AYUSO A, ESCUDERO L F, et al. On air traffic flow management with rerouting. Part I: deterministic case. European Journal of Operational Research, 2012, 219 (1): 156- 166.
12	LIU Y, CHEN X, RALESCU D A. Uncertain currency model and currency option pricing. International Journal of Intelligent Systems, 2015, 30 (1): 40- 51.
13	PADHAN S K, NAHAK C. Higher-order symmetric duality in multiobjective programming problems under higher-order invexity. Applied Mathematics and Computation, 2011, 218 (5): 1705- 1712.
14	LAI H C, HO S C. Optimality and duality for nonsmooth multiobjective fractional programming problems involving exponential V-r-invexity. Nonlinear Analysis: Theory, Methods & Applications, 2012, 75 (6): 3157- 3166.
15	LIU B D. Uncertainty distribution and independence of unceitain processes. Fuzzy Optimization and Decision Making, 2014, 8 (1): 3- 12.
16	WANG Z T, GUO J S, ZHENG M F. A new approach for uncertain multiobjective programming problem based on PE principle. Journal of Industrial and Management Optimization, 2014, 11 (1): 13- 26.
17	XIE G H, ZHANG J S, LIU R G. Application of matrix-based system reliability method in complex slopes. Journal of Central South University, 2013, 20 (3): 812- 820. doi: 10.1007/s11771-013-1552-5
18	LIU B D. Why is there a need for uncertainty theory?. Journal of Uncertain System, 2012, 6 (1): 3- 10.
19	WANG Z T. Research on multi-objective programming and apply based on uncertainty theory. Xi’an, China: Air Force Engineering University, 2015. (in Chinese)
20	LIU B, CHEN X. Uncertain multiobjective programming and uncertain goal programming. Journal of Uncertainty Analysis & Applications, 2015, 3 (1): 1- 8.
21	ZHAO J S, QIU X Y, MA J M, et al. Multi-objective optimization method of microgrid based on fuzzy clustering analysis and model recognition. Power System Technology, 2016, 40 (8): 2316- 2323.
22	ZADEH L A. Fuzzy sets as a basis for a theory of possibility. Fuzzy Sets and Systems, 1978, 1 (1): 3- 28.
23	WANG X J, YANG H F, QIU Z P. Fuzzy theory for uncertain structural analysis based on measurement data. Journal of Beijing University of Aeronautics and Astronautics, 2010, 36 (8): 887- 891.
24	WANG Z, GUO J, ZHENG M, et al. Uncertain multiobjective traveling salesman problem. European Journal of Operational Research, 2015, 241 (2): 478- 489. doi: 10.1016/j.ejor.2014.09.012
25	ZHANG X, WANG Q, ZHOU J. Two uncertain programming models for inverse minimum spanning tree problem. Industrial Engineering & Management Systems, 2013, 12 (1): 9- 15.
26	LIU B D. Uncertainty theory. 5th ed Berlin: Springer-Verlag, 2016.
27	LIU B D. Uncertain set theory and uncertain inference rule with application to uncertain control. Journal of Uncertain Systems, 2014, 4 (2): 83- 98.
28	LIU B D, YAO K. Uncertain multilevel programming: algorithm and applications. Computers & Industrial Engineering, 2015, 89, 235- 240.
29	ZHANG G Q, GONG X S. Structural collaborative optimization based on hybrid GA-PSO algorithm with correlated variables. Journal of Mechanical Engineering, 2012, 48 (15): 113- 125. doi: 10.3901/JME.2012.15.113
30	WU H S, ZHANG F M, ZHAN R J, et al. Improved binary wolf pack algorithm for solving multidimensional knapsack problem. Systems Engineering and Electronics, 2015, 37 (5): 1084- 1091.

Uncertain variable	Uncertainty distribution	Inverse uncertainty distribution
ξ₁	L(1, 3)	Φ¹^-1(α)	2α+1
ξ₂	L(2, 4)	Φ¹^-1(α)	2α+2

Control parameter	Value
Crossover probability	0.7
Mutation probability	0.1
Learning factor c₁	1.49445
Learning factor c₂	1.49445
Evolution times	1000
Population size	30
Minimum particle update rate	-1

Objective function	Proposed approach	Traditional approach
f₁(x, ξ₁, ξ₂)	2.397 5	2.526 1
f₂(x, ξ₁, ξ₂)	28.250 1	29.180 5
f₃(x, ξ₁, ξ₂)	– 0.803 6	– 0.722 6
Optimal solution	(0.574 8, 2.473 9)	(0.549 3, 2.681 5)

Parameter	Value
Population number n	400
Maximum number of iterations N_max	200
Maximum number of walks T_max	10
Population update factor β	4

Objective function	Upper limit value	Resource consumption	Optimal solution
f₁(η, x)	2.397 5	2.526 1
f₂(η, x)	3740.9	1000	I₂
f₃(η, x)	73.6	1000	I₃

Approach for uncertain multi-objective programming problems with correlated objective functions under C_EV criterion

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Objective function	I₁, I₂	I₃	I_B	Traditional approach
f₁(η, x)	4 445.7	3 734.3	4 111.4	4045.7
f₂(η, x)	3 740.9	3 142.3	3 459.6	3 404.4
f₃(η, x)	66.9	73.6	73.3	73.2
Resource consumption	1 000	1 000	998	985