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Symbolic and numeric scheme for solution of linear integro-differential equations with random parameter uncertainties and Gaussian stochastic process input

•A system of linear stochastic integro-differential equations is under consideration.•Gaussian nonstationary noises and random model uncertainties excite the system.•The problem is to find the mean and covariance functions of the state vector process.•Green matrix-valued functions are used to solve...

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Bibliographic Details
Published in:Applied Mathematical Modelling 2018-04, Vol.56, p.15-31
Main Authors: Poloskov, I.E., Soize, C.
Format: Article
Language:English
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Summary:•A system of linear stochastic integro-differential equations is under consideration.•Gaussian nonstationary noises and random model uncertainties excite the system.•The problem is to find the mean and covariance functions of the state vector process.•Green matrix-valued functions are used to solve the problem.•As example, a response of a thermoviscoelastic system is estimated by our scheme. The paper describes a theoretical apparatus and an algorithmic part of application of the Green matrix-valued functions for time-domain analysis of systems of linear stochastic integro-differential equations. It is suggested that these systems are subjected to Gaussian nonstationary stochastic noises in the presence of model parameter uncertainties that are described in the framework of the probability theory. If the uncertain model parameter is fixed to a given value, then a time-history of the system will be fully represented by a second-order Gaussian vector stochastic process whose properties are completely defined by its conditional vector-valued mean function and matrix-valued covariance function. The scheme that is proposed is constituted of a combination of two subschemes. The first one explicitly defines closed relations for symbolic and numeric computations of the conditional mean and covariance functions, and the second one calculates unconditional characteristics by the Monte Carlo method. A full scheme realized on the base of Wolfram Mathematica and Intel Fortran software programs, is demonstrated by an example devoted to an estimation of a nonstationary stochastic response of a mechanical system with a thermoviscoelastic component. Results obtained by using the proposed scheme are compared with a reference solution constructed by using a direct Monte Carlo simulation.
ISSN:0307-904X
1088-8691
0307-904X
1872-8480
DOI:10.1016/j.apm.2017.11.024