Abstract
The spline-interpolation-based fast Fourier transform (FFT) algorithm, designated as the SFFT algorithm, is proposed in the present paper to further enhance the computational speed of simulating the multivariate stochastic processes. The proposed SFFT algorithm first introduces the spline interpolation technique to reduce the number of the Cholesky decomposition of a spectral density matrix and subsequently uses the FFT algorithm to further enhance the computational speed. In order to highlight the superiority of the SFFT algorithm, the simulations of the multivariate stationary longitudinal wind velocity fluctuations have been carried out, respectively, with resorting to the SFFT-based and FFT-based spectral representation SR methods, taking into consideration that the elements of cross-power spectral density matrix are the complex values. The numerical simulation results show that though introducing the spline interpolation approximation in decomposing the cross-power spectral density matrix, the SFFT algorithm can achieve the results without a loss of precision with reference to the FFT algorithm. In comparison with the FFT algorithm, the SFFT algorithm provides much higher computational efficiency. Likewise, the superiority of the SFFT algorithm is becoming more remarkable with the dividing number of frequency, the number of samples, and the time length of samples going up.
Highlights
Monte Carlo technique has widely been employed for simulating the stochastic processes which are either one-dimensional or multidimensional, univariate or multivariate, homogeneous or nonhomogeneous, stationary or nonstationary, and Gaussian or non-Gaussian
In order to cope with this issue, the fast Fourier transform Fast Fourier Transform (FFT) algorithm was introduced into the SR method
Yang 23, 24 showed that the FFT algorithm can remarkably enhance the computational efficiency of the SR method and proposed a formula to simulate the random envelop processes
Summary
Monte Carlo technique has widely been employed for simulating the stochastic processes which are either one-dimensional or multidimensional, univariate or multivariate, homogeneous or nonhomogeneous, stationary or nonstationary, and Gaussian or non-Gaussian. It is worth pointing out that the generated sample functions with resorting to the early algorithm of the SR method by Shinozuka and Jan 10 are not ergodic. Deodatis 12 further extended the SR method to simulate the multivariate ergodic stochastic processes. The capabilities and efficiency of the proposed algorithm were demonstrated in detail using a one-dimensional trivariate process as an example. Yang 23, showed that the FFT algorithm can remarkably enhance the computational efficiency of the SR method and proposed a formula to simulate the random envelop processes. Shinozuka extended the application of the FFT algorithm to the multidimensional cases. Li and Kareem used the FFT-based approach to simulate the multivariate nonstationary Gaussian random processes with the prescribed evolutionary spectral description
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