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Engineering with Computers

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31.08.2020 | Original Article

A multi-constraint failure-pursuing sampling method for reliability-based design optimization using adaptive Kriging

verfasst von: Xiaoke Li, Xinyu Han, Zhenzhong Chen, Wuyi Ming, Yang Cao, Jun Ma

Erschienen in: Engineering with Computers | Sonderheft 1/2022

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Abstract

Using surrogate models to substitute the computationally expensive limit state functions is a promising way to decrease the cost of implementing reliability-based design optimization (RBDO). To train the models efficiently, the active learning strategies have been intensively studied. However, the existing learning strategies either do not individually build the models according to importance measurement or do not completely relate to the reliability analysis results. Consequently, some points that are useless to refine the limit state functions or far away from the RBDO solutions are generated. This paper proposes a multi-constraint failure-pursuing sampling method to maximize the reward of adding new training points. A simultaneous learning strategy is employed to sequentially update the Kriging models with the points selected in the current approximate safe region. Moreover, the sensitive Kriging model as well as the sensitive sample point are identified based on the failure-pursuing scheme. A new point that is highly potential to improve the accuracy of reliability analysis and optimization can then be generated near the sensitive sample point and used to update the sensitive model. Besides, numerical examples and engineering application are used to validate the performance of the proposed method.

Vorheriger Artikel An adaptive sampling method for Kriging surrogate model with multiple outputs

Nächster Artikel Alternative multiscale material and structures modeling by the finite-element method

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Aoues Y, Chateauneuf A (2010) Benchmark study of numerical methods for reliability-based design optimization. Struct Multidiscip Optim 41(2):277–294MathSciNetMATH

Valdebenito MA, Schueller GI (2010) A survey on approaches for reliability-based optimization. Struct Multidiscip Optim 42(5):645–663MathSciNetMATH

Yu S, Wang Z (2019) A general decoupling approach for time- and space-variant system reliability-based design optimization. Comput Methods Appl Mech Eng 357:112608MathSciNetMATH

Zeng M et al (2015) A hybrid chaos control approach of the performance measure functions for reliability-based design optimization. Comput Struct 146:32–43

Xiao N-C, Zuo MJ, Zhou C (2018) A new adaptive sequential sampling method to construct surrogate models for efficient reliability analysis. Reliabil Eng Syst Saf 169:330–338

Zhang D, Han X (2020) Kinematic reliability analysis of robotic manipulator. J Mech Des 142(4):044502

Zhang J et al (2018) A novel projection outline based active learning method and its combination with Kriging metamodel for hybrid reliability analysis with random and interval variables. Comput Methods Appl Mech Eng 341:32–52MathSciNetMATH

Wu J et al (2019) A moment approach to positioning accuracy reliability analysis for industrial robots. IEEE Trans Reliabil. https://doi.org/10.1109/TR.2019.2919540CrossRef

Du X, Hu Z (2012) First order reliability method with truncated random variables. J Mech Des 134(9):091005

10.

Meng Z, Zhang Z, Zhou H (2020) A novel experimental data-driven exponential convex model for reliability assessment with uncertain-but-bounded parameters. Appl Math Model 77:773–787MathSciNetMATH

11.

Kim DW et al (2014) Composite first-order reliability method for efficient reliability-based optimization of electromagnetic design problems. IEEE Trans Magn 50(2):681–684

12.

Tu J, Choi KK, Park YH (1999) A new study on reliability-based design optimization. J Mech Des 121(4):557–564

13.

Chen Z et al (2013) An adaptive decoupling approach for reliability-based design optimization. Comput Struct 117:58–66

14.

Jiang C et al (2020) Iterative reliable design space approach for efficient reliability-based design optimization. Eng Comput 36(1):151–169

15.

Jiang C et al (2017) An adaptive hybrid single-loop method for reliability-based design optimization using iterative control strategy. Struct Multidiscip Optim 56(6):1271–1286MathSciNet

16.

Meng Z, Keshtegar B (2019) Adaptive conjugate single-loop method for efficient reliability-based design and topology optimization. Comput Methods Appl Mech Eng 344:95–119MathSciNetMATH

17.

Yang X et al (2020) System reliability analysis with small failure probability based on active learning Kriging model and multimodal adaptive importance sampling. Struct Multidiscip Optim 62:581–596MathSciNet

18.

Zhang D et al (2017) Time-dependent reliability analysis through response surface method. J Mech Des 139(4):041404

19.

Zhang Z et al (2014) A response surface approach for structural reliability analysis using evidence theory. Adv Eng Softw 69:37–45

20.

Papadopoulos V et al (2012) Accelerated subset simulation with neural networks for reliability analysis. Comput Methods Appl Mech Eng 223–224:70–80MathSciNetMATH

21.

Cheng K, Lu Z (2018) Adaptive sparse polynomial chaos expansions for global sensitivity analysis based on support vector regression. Comput Struct 194:86–96

22.

Zhang Y et al (2020) Multiscale topology optimization for minimizing frequency responses of cellular composites with connectable graded microstructures. Mech Syst Signal Process 135:106369

23.

Qian J et al (2019) A sequential constraints updating approach for Kriging surrogate model-assisted engineering optimization design problem. Eng Comput 36:993–1009

24.

Zhou Q et al (2017) A sequential multi-fidelity metamodeling approach for data regression. Knowl Based Syst 134:199–212

25.

Zhou Q et al (2018) A robust optimization approach based on multi-fidelity metamodel. Struct Multidiscip Optim 57(2):775–797

26.

Jiang C et al (2020) A sequential calibration and validation framework for model uncertainty quantification and reduction. Comput Methods Appl Mech Eng 368:113172MathSciNetMATH

27.

Xiao N-C, Yuan K, Zhou C (2020) Adaptive kriging-based efficient reliability method for structural systems with multiple failure modes and mixed variables. Comput Methods Appl Mech Eng 359:112649MathSciNetMATH

28.

Zhang J et al (2019) A combined projection-outline-based active learning Kriging and adaptive importance sampling method for hybrid reliability analysis with small failure probabilities. Comput Methods Appl Mech Eng 344:13–33MathSciNetMATH

29.

Xiao M et al (2019) An efficient Kriging-based subset simulation method for hybrid reliability analysis under random and interval variables with small failure probability. Struct Multidiscip Optim 59(6):2077–2092MathSciNet

30.

Yang X et al (2019) A system reliability analysis method combining active learning Kriging model with adaptive size of candidate points. Struct Multidiscip Optim 60(1):137–150

31.

Jiang C et al (2020) EEK-SYS: system reliability analysis through estimation error-guided adaptive Kriging approximation of multiple limit state surfaces. Reliabil Eng Syst Saf 198:106906

32.

Yuan K et al (2020) System reliability analysis by combining structure function and active learning kriging model. Reliabil Eng Syst Saf 195:106734

33.

Jiang C et al (2020) Real-time estimation error-guided active learning Kriging method for time-dependent reliability analysis. Appl Math Model 77:82–98MathSciNetMATH

34.

Hu Z, Mahadevan S (2016) A single-loop kriging surrogate modeling for time-dependent reliability analysis. J Mech Des 138(6):061406

35.

Jiang C et al (2019) An active failure-pursuing Kriging modeling method for time-dependent reliability analysis. Mech Syst Signal Process 129:112–129

36.

Hu Z, Du X (2015) Mixed efficient global optimization for time-dependent reliability analysis. J Mech Des 137(5):051401

37.

Li X et al (2018) Reliability-based NC milling parameters optimization using ensemble metamodel. Int J Adv Manuf Technol 97(9–12):3359–3369

38.

Moustapha M, Sudret B (2019) Surrogate-assisted reliability-based design optimization: a survey and a unified modular framework. Struct Multidiscip Optim 60(5):2157–2176MathSciNet

39.

Besseris GJ (2010) A methodology for product reliability enhancement via saturated–unreplicated fractional factorial designs. Reliabil Eng Syst Saf 95(7):742–749

40.

Onwuamaeze CU (2019) Optimal prediction variance properties of some central composite designs in the hypercube. Commun Stat Theory Methods. https://doi.org/10.1080/03610926.2019.1656746MathSciNetCrossRef

41.

Husslage BG et al (2011) Space-filling Latin hypercube designs for computer experiments. Optim Eng 12(4):611–630MATH

42.

Li X et al (2015) A local sampling method with variable radius for RBDO using Kriging. Eng Comput 32:908–1933

43.

Lee TH, Jung JJ (2008) A sampling technique enhancing accuracy and efficiency of metamodel-based RBDO: constraint boundary sampling. Comput Struct 86(13–14):1463–1476

44.

Bichon BJ et al. (2012) Efficient global surrogate modeling for reliability-based design optimization. J Mech Des 135(1)

45.

Chen Z et al (2014) A local adaptive sampling method for reliability-based design optimization using Kriging model. Struct Multidiscip Optim 49(3):401–416MathSciNet

46.

Li X et al (2016) A local Kriging approximation method using MPP for reliability-based design optimization. Comput Struct 162:102–115

47.

Gaspar B, Teixeira A, Soares CG (2017) Adaptive surrogate model with active refinement combining Kriging and a trust region method. Reliabil Eng Syst Saf 165:277–291

48.

Zhang J, Taflanidis A, Medina J (2017) Sequential approximate optimization for design under uncertainty problems utilizing Kriging metamodeling in augmented input space. Comput Methods Appl Mech Eng 315:369–395MathSciNetMATH

49.

Meng Z et al (2019) An importance learning method for non-probabilistic reliability analysis and optimization. Struct Multidiscip Optim 59(4):1255–1271

50.

Jiang C et al (2019) A general failure-pursuing sampling framework for surrogate-based reliability analysis. Reliabil Eng Syst Saf 183:47–59

51.

Cadini F, Santos F, Zio E (2014) An improved adaptive kriging-based importance technique for sampling multiple failure regions of low probability. Reliabil Eng Syst Saf 131:109–117

52.

Echard B, Gayton N, Lemaire M (2011) AK-MCS: an active learning reliability method combining Kriging and Monte Carlo Simulation. Struct Saf 33(2):145–154

53.

Bichon BJ et al (2008) Efficient global reliability analysis for nonlinear implicit performance functions. AIAA J 46(10):2459–2468

54.

Meng Z et al (2020) A comparative study of metaheuristic algorithms for reliability-based design optimization problems. Arch Comput Methods Eng. https://doi.org/10.1007/s11831-020-09443-zCrossRef

55.

Hyeon Ju B, Chai Lee B (2008) Reliability-based design optimization using a moment method and a kriging metamodel. Eng Optim 40(5):421–438MathSciNet

56.

Li X et al (2019) RBF and NSGA-II based EDM process parameters optimization with multiple constraints. Math Biosci Eng 16(5):5788–5803MathSciNet

57.

Jun M et al (2019) Reliability-based EDM process parameter optimization using kriging model and sequential sampling. Math Biosci Eng 16(6):7421–7432MATH

58.

Sacks J et al (1989) Design and analysis of computer experiments. Stat Sci 4(4):409–423MathSciNetMATH

Titel: A multi-constraint failure-pursuing sampling method for reliability-based design optimization using adaptive Kriging
verfasst von: Xiaoke Li
Xinyu Han
Zhenzhong Chen
Wuyi Ming
Yang Cao
Jun Ma
Publikationsdatum: 31.08.2020
Verlag: Springer London
Erschienen in: Engineering with Computers / Ausgabe Sonderheft 1/2022
Print ISSN: 0177-0667
Elektronische ISSN: 1435-5663
DOI: https://doi.org/10.1007/s00366-020-01135-3

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