[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sem.2015.56.4.549

A Gaussian process-based response surface method for structural reliability analysis

Su, Guoshao (School of Civil and Architecture Engineering, Key Laboratory of Disaster Prevention and Structural Safety of Ministry of Education, Guangxi Key Laboratory of Disaster Prevention and Engineering Safety, Guangxi University)
Jiang, Jianqing (School of Civil and Architecture Engineering, Key Laboratory of Disaster Prevention and Structural Safety of Ministry of Education, Guangxi Key Laboratory of Disaster Prevention and Engineering Safety, Guangxi University)
Yu, Bo (School of Civil and Architecture Engineering, Key Laboratory of Disaster Prevention and Structural Safety of Ministry of Education, Guangxi Key Laboratory of Disaster Prevention and Engineering Safety, Guangxi University)
Xiao, Yilong (School of Civil and Architecture Engineering, Key Laboratory of Disaster Prevention and Structural Safety of Ministry of Education, Guangxi Key Laboratory of Disaster Prevention and Engineering Safety, Guangxi University)

Publication Information

Structural Engineering and Mechanics / v.56, no.4, 2015 , pp. 549-567 More about this Journal

Abstract

A first-order moment method (FORM) reliability analysis is commonly used for structural stability analysis. It requires the values and partial derivatives of the performance to function with respect to the random variables for the design. These calculations can be cumbersome when the performance functions are implicit. A Gaussian process (GP)-based response surface is adopted in this study to approximate the limit state function. By using a trained GP model, a large number of values and partial derivatives of the performance functions can be obtained for conventional reliability analysis with a FORM, thereby reducing the number of stability analysis calculations. This dynamic renewed knowledge source can provide great assistance in improving the predictive capacity of GP during the iterative process, particularly from the view of machine learning. An iterative algorithm is therefore proposed to improve the precision of GP approximation around the design point by constantly adding new design points to the initial training set. Examples are provided to illustrate the GP-based response surface for both structural and non-structural reliability analyses. The results show that the proposed approach is applicable to structural reliability analyses that involve implicit performance functions and structural response evaluations that entail time-consuming finite element analyses.

Keywords

first-order moment method; structural reliability; response surface method; Gaussian process;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Bucher, C.G. and Bourgund, U. (1990), "A fast and efficient response surface approach for structural reliability problems", Struct. Saf., 7(1), 57-66. DOI
2	Chen, T., Morris, J. and Martin, E. (2007), "Gaussian process regression for multivariate spectroscopic calibration", Chemometr. Intell. Labs., 87(1), 59-71. DOI
3	Cheng, J., Li, Q.S. and Xiao, R.C. (2008), "A new artificial neural network-based response surface method for structural reliability analysis", Probab. Eng. Mech., 23(1), 51-63. DOI
4	Christian, B. and Thomas, M. (2008), "A comparison of approximate response functions in structural reliability analysis", Probab. Eng. Mech., 23(1), 154-163. DOI ScienceOn
5	Das, P.K. and Zheng, Y. (2000), "Cumulative formation of response surface and its use in reliability analysis", Probab. Eng. Mech., 15(4), 309-315. DOI
6	Deng, J., Gu, D.S., Li, X.B. and Yue, Z.Q. (2005), "Structural reliability analysis for implicit performance function using artificial neural network", Struct. Saf., 27(1), 25-48. DOI
7	Gayton, N., Bourinet, J.M. and Lemaire, M. (2003), "CQ2RS: a new statistical approach to the response surface method for reliability analysis", Struct. Saf., 25(1), 99-121. DOI
8	Guan, X.L. and Melchers, R.E. (2001), "Effect of response surface parameter variation on structural reliability estimates", Struct. Saf., 23(4), 429-444. DOI
9	Hensman, J., Mills, R., Pierce, S.G., Worden, K. and Eaton, M. (2010), "Locating acoustic emission sources in complex structures using Gaussian processes", Mech. Syst. Signal Pr., 24(1), 211-223. DOI
10	Herbert, M.G. and Armando, M.A. (2004), "Comparison of response surface and neural network with other methods for structural reliability analysis", Struct. Saf., 26(1), 49-67. DOI
11	Hurtado, J.E. (2007), "Filtered importance sampling with support vector margin: a powerful method for structural reliability analysis", Struct. Saf., 29(1), 2-15. DOI
12	Jiang, S.H., Li, D.Q., Zhou, C.B. and Zhang, L.M. (2014), "Capabilities of stochastic response surface method and response surface method in reliability analysis", Struct. Eng. Mech, 49(1), 111-128. DOI ScienceOn
13	Kim, S.H. and Na, S.W. (1997), "Response surface method using vector projected sampling points", Struct. Saf., 19(1), 3-19. DOI
14	Malur, R.R. and Bruce, R.E. (1993), "A new look at the response surface approach for reliability analysis", Struct. Saf., 12(3), 205-220. DOI
15	Li, H.S., Lv, Z.Z. and Yue, Z.F. (2006), "Support vector machine for structural reliability analysis", Appl. Math. Mech., 27(10-11), 35-43.
16	Luc, S. and Dionys, V.G. (2005), "Benefit of splines and neural networks in simulation based structural reliability analysis", Struct. Saf., 27(3), 246-261. DOI
17	MacKay, D.J.C. (1998), Introduction to Gaussian processes, Technical report, Cambridge University, London, UK.
18	Rackwitz, R. and Fiessler, B. (1976), Note on discrete safety checking when using non-normal stochastic models for basic variable, Loads Project Working Session, MIT Press, London.
19	Rasmusen, C.E. and Williams, C.K.I. (2006), Gaussian Processes for Machine Learning, MIT Press, London.
20	Rocco, C.M. and Moreno, J.A. (2002), "Fast Monte Carlo reliability evaluation using support vector machine", Reliab. Eng. Syst. Saf., 76(2), 37-43.
21	Su, G.S., Yan, L.B. and Song, Y.C. (2007), "Gaussian process for non-linear displacement time series prediction of landslide", J. China Univ. Geosci., 18, 212-219.
22	Vapnik, V. (1998), Statistical learning theory, John Wiley and Sons, New York.
23	Williams, C.K.I. (1998), Prediction with Gaussian processes: from the linear regression to linear prediction and beyond, Technical report, Aston University, Birmingham, UK.
24	Zhao, G.F. (1996), Reliability theory and its applications for engineering structures, Dalian University of Technology Press, Dalian, PRC.
25	Zhao, W.T., Qiu Z.P and Yang, Y. (2013), "An efficient response surface method considering the nonlinear trend of the actual limit state", Struct. Eng. Mech., 47(1), 45-58. DOI
26	Zhao, H.B. (2008), "Slope reliability analysis using a support vector machine", Comput. Geotech., 35(4), 59-67.

2	(2015) Structural engineering and mechanics : An international journal Structural reliability analysis using response surface method with improved genetic algorithm / 62 (2) , 139
None	(2015) Advances in civil engineering Gaussian Process-Based Response Surface Method for Slope Reliability Analysis / 2019 (None) , 1
6	(2015) Structural engineering and mechanics : An international journal A novel reliability analysis method based on Gaussian process classification for structures with discontinuous response / 75 (6) , 771
None	(2015) Shock and vibration Prediction of BlastInduced Ground Vibration (BIGV) of Metro Construction Using Difference Evolution AlgorithmOptimized Gaussian Process (DE-GP) / 2021 (None) , 1
None	(2015) Engineering structures Shear capacity prediction of slender reinforced concrete structures with steel fibers using machine learning / 227 (None) , 111470