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http://dx.doi.org/10.12989/was.2014.18.6.693

Simulation of non-Gaussian stochastic processes by amplitude modulation and phase reconstruction  

Jiang, Yu (Laboratory of Science and Technology on Integrated Logistics Support, College of Mechatronic Engineering & Automation, National University of Defense Technology)
Tao, Junyong (Laboratory of Science and Technology on Integrated Logistics Support, College of Mechatronic Engineering & Automation, National University of Defense Technology)
Wang, Dezhi (Centre for Engineering Dynamics, University of Liverpool)
Publication Information
Wind and Structures / v.18, no.6, 2014 , pp. 693-715 More about this Journal
Abstract
Stochastic processes are used to represent phenomena in many diverse fields. Numerical simulation method is widely applied for the solution to stochastic problems of complex structures when alternative analytical methods are not applicable. In some practical applications the stochastic processes show non-Gaussian properties. When the stochastic processes deviate significantly from Gaussian, techniques for their accurate simulation must be available. The various existing simulation methods of non-Gaussian stochastic processes generally can only simulate super-Gaussian stochastic processes with the high-peak characteristics. And these methodologies are usually complicated and time consuming, not sufficiently intuitive. By revealing the inherent coupling effect of the phase and amplitude part of discrete Fourier representation of random time series on the non-Gaussian features (such as skewness and kurtosis) through theoretical analysis and simulation experiments, this paper presents a novel approach for the simulation of non-Gaussian stochastic processes with the prescribed amplitude probability density function (PDF) and power spectral density (PSD) by amplitude modulation and phase reconstruction. As compared to previous spectral representation method using phase modulation to obtain a non-Gaussian amplitude distribution, this non-Gaussian phase reconstruction strategy is more straightforward and efficient, capable of simulating both super-Gaussian and sub-Gaussian stochastic processes. Another attractive feature of the method is that the whole process can be implemented efficiently using the Fast Fourier Transform. Cases studies demonstrate the efficiency and accuracy of the proposed algorithm.
Keywords
stochastic simulation; non-Gaussian; amplitude modulation; phase reconstruction;
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Times Cited By KSCI : 2  (Citation Analysis)
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1 Seong, S.H. and Peterka, J.A. (2001), "Experiments on fourier phases for synthesis of non-Gaussian spikes in turbulence time series", J. Wind Eng. Ind. Aerod., 89(5), 421-443.   DOI   ScienceOn
2 Yu J., Zhang, C. and Chen, X. (2008), "Simulation techniques of non-Gaussian random loadings in structural reliability analysis", Safety, Reliability and Risk Analysis: Theory, Methods and Applications, Proceedings of the Joint ESREL and SRA-Europe Conference,1663-1670.
3 Yura, H.T. and Hanson, S.G. (2012), "Digital simulation of two-dimensional random fields with arbitrary power spectra and non-Gaussian probability distribution functions", Appl. Optics, 51(10), 77-83.   DOI
4 Zentner, I., Poirion, F. and Cacciola, P. (2011), "Simulation of seismic ground motion time histories from data using a non Gaussian stochastic model", Applications of Statistics and Probability in Civil Engineering -Proceedings of the 11th International Conference on Applications of Statistics and Probability in Civil Engineering, 2474-2479.
5 Poirion, F. and Puig, B. (2010), "Simulation of non-Gaussian multivariate stationary processes", Int. J. Nonlinear Mech., 45(5), 587-597.   DOI
6 Seong, S.H. and Peterka, J.A (1998), "Digital generation of surface-pressure fluctuations with spiky features", J. Wind Eng. Ind. Aerod., 73(2), 181-192.   DOI   ScienceOn
7 Shields, M.D. and Deodatis, G. (2011), "Simulation of strongly non-Gaussian stochastic vector processes using translation process theory", Proceedings of the 11th International Conference on Applications of Statistics and Probability in Civil Engineering.
8 Shields, M.D. and Deodatis, G. (2013), "A simple and efficient methodology to approximate a general non-Gaussian stationary stochastic vector process by a translation process with applications in wind velocity simulation", Probab. Eng. Mech., 31, 19-29.   DOI
9 Steinwolf, A. (1996), "Approximation and simulation of probability distributions with a variable kurtosis value", Comput. Stat. Data An., 21(2), 163-180.   DOI
10 Steinwolf, A. (2010), "Shaker random testing with low kurtosis: Review of the methods and application for sigma limiting", Shock Vib., 17(3), 219-231.   DOI
11 Steinwolf, A. (2007), "Forget clipping: Go random with non-Gaussian sigma limiting and double the shaker power!", Test Eng. Management, 69(3), 10-13.
12 Suresh Kumar, K. and Stathopoulos, T. (1999), "Synthesis of non-Gaussian wind pressure time series on low building roofs", Eng. Struct., 21(12), 1086-1100.   DOI   ScienceOn
13 Vargas-Guzman, J.A. (2012), "A Heavy tailed probability distributions for non-Gaussian simulations with higher-order cumulant parameters predicted from sample data", Stoch. Env. Res. Risk A., 26(6), 765-776.   DOI
14 Yamazaki, F. and Shinozuka, M. (1988), "Digital generation of non-Gaussian stochastic fields", J. Eng. Mech. - ASCE, 114(7),1183-1197.   DOI   ScienceOn
15 Ye, J., Ding, J. and Liu, C. (2012), "Numerical simulation of non-Gaussian wind load", Science China Technol. Sciences, 55(11), 3057-3069.   DOI
16 Aung, N.N. and Jihong, Y. (2011), "Simulation of non-Gaussian wind pressure fields on domed structures", Adv. Mater. Res., 163-167, 4142-4148.
17 Aung, N.N. and Jihong, Y. (2012), "Simulation of multivariate non-Gaussian wind pressure on spherical latticed structures", Wind Struct., 15( 3), 223-245.   DOI   ScienceOn
18 Bendat, J.S. and Piersol, A.G. (1986), Random data: analysis and measurement procedures, 2nd Ed., New York.
19 Bocchini, P. and Deodatis, G. (2008), "Critical review and latest developments of a class of simulation algorithms for strongly non-Gaussian random fields", Probab. Eng. Mech., 23(4), 393-407.   DOI
20 Gioffre, M., Gusella, V. and Grigoriu, M. (2000), "Simulation of non-Gaussian field applied to wind pressure fluctuations", Probab. Eng. Mech., 15(4), 339-345.   DOI   ScienceOn
21 Gurley, K.R., Kareem, A. and Tognarelli, M.A. (1996), "Simulation of a class of non-normal random processes", Int. J. Nonlinear Mech., 31(5), 601-617.   DOI   ScienceOn
22 Li, J. and Li, C. (2012), "Simulation of Non-Gaussian stochastic process with target power spectral density and lower-order moments", J. Eng. Mech.- ASCE, 138(5), 391-404.   DOI
23 Li, J. and Wang, X. (2012), "An exponential model for fast simulation of multivariate non-Gaussian processes with application to structural wind engineering", Probab. Eng. Mech., 30, 37-47.   DOI
24 Luo, J.J., Su, C. and Han, D.J. (2012), "A simulation methodology of the stationary non-Gaussian stochastic wind pressure field", Zhendong yu Chongji/J. Vib. Shock, 31(10), 111-117.
25 Phoon, K.K. and Huang, H.W. (2005), "Simulation of strongly non-Gaussian processes using Karhunen-Loeve expansion", Probab. Eng. Mech., 20(2), 188-198.   DOI
26 Choi, H. and Kanda, J. (2003), "Translation method: A historical review and its application to simulation of non-Gaussian stationary processes", Wind Struct., 6(5), 357-386.   DOI