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Approximation of Spatio-Temporal Random Processes Using Tensor Decomposition

Published online by Cambridge University Press:  03 June 2015

Debraj Ghosh*
Affiliation:
Department of Civil Engineering, Indian Institute of Science, Bangalore 560012, India
Anup Suryawanshi*
Affiliation:
Department of Civil Engineering, Indian Institute of Science, Bangalore 560012, India
*
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Abstract

A new representation of spatio-temporal random processes is proposed in this work. In practical applications, such processes are used to model velocity fields, temperature distributions, response of vibrating systems, to name a few. Finding an efficient representation for any random process leads to encapsulation of information which makes it more convenient for a practical implementations, for instance, in a computational mechanics problem. For a single-parameter process such as spatial or temporal process, the eigenvalue decomposition of the covariance matrix leads to the well-known Karhunen-Loève (KL) decomposition. However, for multiparameter processes such as a spatio-temporal process, the covariance function itself can be defined in multiple ways. Here the process is assumed to be measured at a finite set of spatial locations and a finite number of time instants. Then the spatial covariance matrix at different time instants are considered to define the covariance of the process. This set of square, symmetric, positive semi-definite matrices is then represented as a third-order tensor. A suitable decomposition of this tensor can identify the dominant components of the process, and these components are then used to define a closed-form representation of the process. The procedure is analogous to the KL decomposition for a single-parameter process, however, the decompositions and interpretations vary significantly. The tensor decompositions are successfully applied on (i) a heat conduction problem, (ii) a vibration problem, and (iii) a covariance function taken from the literature that was fitted to model a measured wind velocity data. It is observed that the proposed representation provides an efficient approximation to some processes. Furthermore, a comparison with KL decomposition showed that the proposed method is computationally cheaper than the KL, both in terms of computer memory and execution time.

Type
Research Article
Copyright
Copyright © Global Science Press Limited 2014

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References

[1]Ghanem, R. and Spanos, P. D.Stochastic Finite Elements: A Spectral Approach. Revised Edition, Dover Publications, 2003.Google Scholar
[2]Van Trees, H. L.Detection, Estimation and Modulation Theory, Part I. Wiley, 2001.Google Scholar
[3]Xiu, D. and Karniadakis, G. E.A new stochastic approach to transient heat conduction modeling with uncertainty. International Journal of Heat and Mass Transfer, 46:46814693, 2003.CrossRefGoogle Scholar
[4]Sang, H. and Huang, J. Z.A full scale approximation of covariance functions for large spatial data sets. Journal of the Royal Statistical Society: Series B (Statistical Methodology), 74(1): 111132, 2011.Google Scholar
[5]Yang, J., Zhang, D., and Lu, Z.Stochastic analysis of saturated-unsaturated flow in heterogeneous media by combining Karhunen-Loève expansion and perturbation method. Journal of Hydrology, 294: 1838, 2004.CrossRefGoogle Scholar
[6]Schenk, C. A. and Schueller, G. I.Uncertainty Assessment of Large Finite Element Systems. Springer Berlin/Heidelberg, 2005.Google Scholar
[7]Stein, M. L.Space-time covariance functions. Journal of the American Statistical Association, 100(469): 310321, 2005.Google Scholar
[8]Gneiting, T.Nonseparable, stationary covariance functions for space-time data. Journal of the American Statistical Association, 97(458): 590600, 2002.CrossRefGoogle Scholar
[9]Kolda, T. G. and Badder, B. W.Tensor decompositions and applications. SIAM Review, 51(3): 455500, 2009.Google Scholar
[10]De Lathauwer, L., De Moor, B., and Vandewalle, J.On the best rank-1 and rank-(R1, R2, …, Rn) approximation of higher-order tensors. SIAM Journal on Matrix Analysis and Applications, 21(4): 13241342, 2000.CrossRefGoogle Scholar
[11]Hitchcock, F. L.The expression of a tensor or a polyadic as a sum of products. Journal of Mathematical Physics, 6: 164189, 1927.CrossRefGoogle Scholar
[12]Kruskal, J. B.Three-way arrays: Rank and uniqueness of trilinear decompositions, with application to arithmetic complexity and statistics. Linear Algebra and its Applications, 18: 95138, 1977.Google Scholar
[13]Carroll, J. D. and Chang, J. J.Analysis of individual differences in multidimensional scaling via an N-way generalization of Eckart-Young decomposition. Psychometrika, 35(3): 283319, 1970.Google Scholar
[14]Harshman, R. A.Foundations of the PARAFAC procedure: Models and conditions for an explanatory multi-modal factor analysis. UCLA Working Papers in Phonetics, Available at http://publish.uwo.ca/~harshman/wpppfac0.pdf, 16: 184, 1970.Google Scholar
[15]Tucker, L. R.Implications of factor analysis of three-way matrices for measurement of change. Problems in Measuring Change, Edited by CW, Harris, University of Wisconsin Press, pages 122137, 1963.Google Scholar
[16]Tucker, L. R.Some mathematical notes on three-mode factor analysis. Psychometrika, 31(3): 279311, 1966.Google Scholar
[17]De Lathauwer, L., De Moor, B., and Vandewalle, J.A multilinear singular value decomposition. SIAM Journal on Matrix Analysis and Applications, 21(4): 12581278, 2000.Google Scholar
[18]Wikle, C. K.Spatio-temporal methods in climatology. Encyclopedia of Life Support Systems (EOLSS), 2003.Google Scholar
[19]Van Trees, H. L.Detection, Estimation and Modulation Theory, Part IV. Wiley, 2002.Google Scholar
[20]Graham, M. D. and Kevrikedis, I. G.Alternative approaches to the Karhunen-Loève decomposition for model reduction and data analysis. Computers & Chemical Engineering, 20(5): 495506, 1996.Google Scholar
[21]Bellizzi, S. and Sampaio, R.Poms analysis of randomly vibrating systems obtained from Karhunen-Loève expansion. Journal of Sound and Vibration, 297: 774793, 2006.Google Scholar
[22]Nott, D. J. and Dunsmuir, W. T. M.Estimation of nonstationary spatial covariance structure. Biometrica, 89(4): 819829, 2002.Google Scholar
[23]To, C. W. S.Time-dependent variance and covariance of responses of structures to nonstationary random excitations. Journal of Sound and Vibration, 93(1): 135156, 1984.Google Scholar
[24]Das, S., Ghanem, R., and Finette, S.Polynomial chaos representation of spatio-temporal random fields from experimental measurements. Journal of Computational Physics, 228: 87268751, 2009.Google Scholar
[25]Ma, C.Recent developments on the construction of spatio-temporal covariance models. Stochastic Environmental Research and Risk Assessment, 22: 3947, 2008.Google Scholar
[26]Bruno, F., Guttorp, P., Sampson, P. D., and Cocchi, D.A simple non-separable, non-stationary spatiotemporal model for ozone. Environ Ecol Stat, 16: 515529, 2009.CrossRefGoogle Scholar
[27]Iaco, S. D., Posa, D., and Myers, D. E.Characteristics of some classes of spaceVtime covariance functions. Journal of Statistical Planning and Inference, 143: 20022015, 2013.Google Scholar
[28]Ma, C.Families of spatio-temporal stationary covariance models. Journal of Statistical Planning and Inference, 116: 489501, 2003.CrossRefGoogle Scholar
[29]Ma, C.Linear combinations of space-time covariance functions and variograms. IEEE Transactions on Signal Processing, 53(3): 857864, 2005.Google Scholar
[30]Kolovos, A., Christakos, G., Hristopulos, D. T., and Serre, M. L.Methods for generating non- separable spatiotemporal covariance models with potential environmental applications. Advances in Water Resources, 27: 815V830, 2004.Google Scholar
[31]Khoromskij, B. N. and Schwab, C.Tensor-structured Galerkin approximation of parametric and stochastic elliptic PDEs. Research Report No. 2010-04, Swiss Federal Institute of Technology Zurich, 2010.Google Scholar
[32]Bader, B. W. and Kolda, T. G. MATLAB Tensor Toolbox. http://csmr.ca.sandia.gov/~tgkolda/TensorToolbox/.Google Scholar
[33]Haslett, J. and Raftery, A. E.Space-time modelling with long-memory dependence: Assessing Ireland’s wind-power resource. Applied Statistics, 38: 150, 1989.CrossRefGoogle Scholar