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Structural and Multidisciplinary Optimization

Erschienen in:

28.06.2017 | RESEARCH PAPER

A multi-objective robust optimization approach based on Gaussian process model

verfasst von: Qi Zhou, Ping Jiang, Xiang Huang, Feng Zhang, Taotao Zhou

Erschienen in: Structural and Multidisciplinary Optimization | Ausgabe 1/2018

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Abstract

The design and optimization of engineering products is usually multi-objective, constrained and has uncertainties in the inputs. It is of great importance for taking these uncertainties into consideration during the design process because these uncertainties can significantly degrade the performance of optimal solutions and even change the feasibility of obtained solutions. Most existing Multi-objective robust optimization (MORO) approaches rely on outer-inner nested optimization structures, where a large number of function evaluations is required. In this work, a MORO approach based on Gaussian process (GP) model is proposed to ease the computational burden of MORO under interval uncertainty. To consider the interpolation uncertainty introduced by GP model, an objective switching criterion is developed, which is according to whether the robust status of the individual can be changed because of the interpolation uncertainties from GP model or not. Six numerical and engineering cases with different degrees of difficulty are used to demonstrate the applicability and efficiency of the proposed approach. The objective and feasibility robustness of the obtained optimal solutions are verified via the design of experiment.

Vorheriger Artikel Optimal design of compliant mechanisms using functionally graded materials

Nächster Artikel Sequential exploration-exploitation with dynamic trade-off for efficient reliability analysis of complex engineered systems

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Arendt PD, Apley DW, Chen W (2013) Objective-oriented sequential sampling for simulation based robust design considering multiple sources of uncertainty. J Mech Des 135(5):051005CrossRef

Bachoc F (2013) Cross validation and maximum likelihood estimations of hyper-parameters of gaussian processes with model misspecification. Computational Statistics & Data Analysis 66:55–69MathSciNetCrossRef

Carpinelli G, Caramia P, Varilone P (2015) Multi-linear monte carlo simulation method for probabilistic load flow of distribution systems with wind and photovoltaic generation systems. Renew Energy 76:283–295CrossRef

Chen S, Jiang Z, Yang S, Chen W (2016) Multimodel fusion based sequential optimization. AIAA J 55(1), 241–254

Cheng S, Li M (2015) Robust optimization using hybrid differential evolution and sequential quadratic programming. Eng Optim 47(1):87–106MathSciNetCrossRef

Cheng S, Zhou J, Li M (2015) A new hybrid algorithm for multi-objective robust optimization with interval uncertainty. J Mech Des 137(2):021401CrossRef

Deb K 2014 Multi-objective optimization. Search Methodologies. Springer, pp. 403–449

Deb K, Gupta H (2006) Introducing robustness in multi-objective optimization. Evol Comput 14(4):463–494CrossRef

Deb K, Pratap A, Agarwal S, Meyarivan T (2002) A fast and elitist multiobjective genetic algorithm: Nsga-ii. IEEE Trans Evol Comput 6(2):182–197CrossRef

Gabrel V, Murat C, Thiele A (2014) Recent advances in robust optimization: an overview. Eur J Oper Res 235(3):471–483MathSciNetCrossRefMATH

Gaspar-Cunha A, Covas JA (2008) Robustness in multi-objective optimization using evolutionary algorithms. Comput Optim Appl 39(1):75–96MathSciNetCrossRefMATH

Gunawan S (2004) Parameter sensitivity measures for single objective, multi-objective, and feasibility robust design optimization. PhD diss., University of Maryland, College Park

Gunawan S, Azarm S (2005) Multi-objective robust optimization using a sensitivity region concept. Struct Multidiscip Optim 29(1):50–60CrossRef

Hu W (2012) Approximation assisted multiobjective and collaborative robust optimization under interval uncertainty. PhD diss., University of Maryland, College Park

Hu W, Li M, Azarm S, Al Hashimi S, Almansoori A, Al-Qasas N (2009). Improving multi-objective robust optimization under interval uncertainty using worst possible point constraint cutsed. In: ASME 2009 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, pp. 1193–1203

Hu W, Li M, Azarm S, Almansoori A (2011) Multi-objective robust optimization under interval uncertainty using online approximation and constraint cuts. J Mech Des 133(6):061002CrossRef

Kim N-K, Kim D-H, Kim D-W, Kim H-G, Lowther D, Sykulski JK (2010) Robust optimization utilizing the second-order design sensitivity information. Magnetics, IEEE Transactions on 46(8):3117–3120CrossRef

Kleijnen JPC (2014) Simulation-optimization via kriging and bootstrapping: a survey. Journal of Simulation 8(4):241–250CrossRef

Kurpati A, Azarm S, Wu J (2002) Constraint handling improvements for multiobjective genetic algorithms. Struct Multidiscip Optim 23(3):204–213CrossRef

Lee K-H, Park G-J (2001) Robust optimization considering tolerances of design variables. Comput Struct 79(1):77–86CrossRef

Li M, Azarm S, Boyars A (2006) A new deterministic approach using sensitivity region measures for multi-objective robust and feasibility robust design optimization. J Mech Des 128(4):874–883CrossRef

Li M, Hamel J, Azarm S (2010) Optimal uncertainty reduction for multi-disciplinary multi-output systems using sensitivity analysis. Struct Multidiscip Optim 40(1–6):77–96CrossRef

Li M, Li G, Azarm S (2008) A kriging metamodel assisted multi-objective genetic algorithm for design optimization. J Mech Des 130(3):031401CrossRef

Li M, Williams N, Azarm S (2009) Interval uncertainty reduction and single-disciplinary sensitivity analysis with multi-objective optimization. J Mech Des 131(3):031007CrossRef

Mckay MD, Beckman RJ, Conover WJ (1979) Comparison of three methods for selecting values of input variables in the analysis of output from a computer code. Technometrics 21(2):239–245MathSciNetMATH

Mortazavi A, Azarm S, Gabriel S (2013) Adaptive gradient-assisted robust design optimization under interval uncertainty. Eng Optim 45(11):1287–1307MathSciNetCrossRef

Papadimitriou D, Giannakoglou K (2013) Third-order sensitivity analysis for robust aerodynamic design using continuous adjoint. Int J Numer Methods Fluids 71(5):652–670MathSciNetCrossRef

Pedersen SN, Christensen ME, Howard TJ (2016) Robust design requirements specification: a quantitative method for requirements development using quality loss functions. J Eng Des 27(8):544–567CrossRef

Rasmussen CE (2004). Gaussian processes in machine learning. In: Bousquet O, von Luxburg U, Rätsch G (eds) Advanced lectures on machine learning. Springer, Heidelberg, Berlin, pp 63–71

Renaud J (1997) Automatic differentiation in robust optimization. AIAA J 35(6):1072–1079CrossRefMATH

Schott JR (1995) Fault tolerant design using single and multicriteria genetic algorithm optimization (No. AFIT/CI/CIA-95-039). Air Force Inst of Tech Wright-Patterson AFB OH

Song X, Sun G, Li Q (2016) Sensitivity analysis and reliability based design optimization for high-strength steel tailor welded thin-walled structures under crashworthiness. Thin-Walled Struct 109:132–142CrossRef

Sun G, Song X, Baek S, Li Q (2013) Robust optimization of foam-filled thin-walled structure based on sequential kriging metamodel. Struct Multidiscip Optim 49(6):897–913CrossRef

Taguchi G (1978) Performance analysis design. The International Journal of Production Research 16(6):521–530CrossRef

Van Albada SJ, Robinson PA (2007) Transformation of arbitrary distributions to the normal distribution with application to eeg test-retest reliability. J Neurosci Methods 161 (2): 205–11 Available from: http://www.ncbi.nlm.nih.gov/pubmed/17204332

Wang Y, Chaib-Draa B (2016) Knn-based kalman filter: an efficient and non-stationary method for gaussian process regression. Knowl-Based Syst 114:148–155CrossRef

Williams CKI, Rasmussen CE (1996) Gaussian processes for regression. In: Touretzky DS, Mozer MC, Hasselmo ME (eds) Adv Neural Inf Proces Syst. Cambridge, MIT Press, 8:514–520

Wu J, Azarm S (2001) Metrics for quality assessment of a multiobjective design optimization solution set. J Mech Des 123(1):18–25CrossRef

Xiao M, Gao L, Xiong H, Luo Z (2015) An efficient method for reliability analysis under epistemic uncertainty based on evidence theory and support vector regression. J Eng Des 26(10-12): 340–364

Zhang S, Zhu P, Chen W, Arendt P (2012) Concurrent treatment of parametric uncertainty and metamodeling uncertainty in robust design. Struct Multidiscip Optim 47(1):63–76MathSciNetCrossRefMATH

Zhang Y, Li M, Zhang J, Li G (2016) Robust optimization with parameter and model uncertainties using gaussian processes. J Mech Des 138(11):111405CrossRef

Zhao L, Choi KK, Lee I (2011) Metamodeling method using dynamic kriging for design optimization. AIAA J 49(9):2034–2046CrossRef

Zheng K, Yang R-J, Xu H, Hu J (2016) A new distribution metric for comparing pareto optimal solutions. Struct Multidiscip Optim 55(1):53–62MathSciNetCrossRef

Zhou Q, Shao X, Jiang P, Gao Z, Wang C, Shu L (2016) An active learning metamodeling approach by sequentially exploiting difference information from variable-fidelity models. Adv Eng Inform 30(3):283–297CrossRef

Zhou Q, Shao XY, Jiang P, Zhou H, Cao LC, Zhang L (2015) A deterministic robust optimisation method under interval uncertainty based on the reverse model. J Eng Des 26(10–12):416–444CrossRef

Titel: A multi-objective robust optimization approach based on Gaussian process model
verfasst von: Qi Zhou
Ping Jiang
Xiang Huang
Feng Zhang
Taotao Zhou
Publikationsdatum: 28.06.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Structural and Multidisciplinary Optimization / Ausgabe 1/2018
Print ISSN: 1615-147X
Elektronische ISSN: 1615-1488
DOI: https://doi.org/10.1007/s00158-017-1746-9

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