A scalable framework for the solution of stochastic inverse problems using a sparse grid collocation approach

Experimental evidence suggests that the dynamics of many physical phenomena are significantly affected by the underlying uncertainties associated with variations in properties and fluctuations in operating conditions. Recent developments in stochastic analysis have opened the possibility of realisti...

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Veröffentlicht in:	Journal of computational physics 2008-04, Vol.227 (9), p.4697-4735
Hauptverfasser:	Zabaras, N., Ganapathysubramanian, B.
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Sprache:	eng
Schlagworte:	ALGORITHMS CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Collocation methods Computational techniques EVOLUTION Exact sciences and technology FLUCTUATIONS Inverse problems Mathematical methods in physics MATHEMATICAL SOLUTIONS OPTIMIZATION PARTIAL DIFFERENTIAL EQUATIONS Physics RANDOMNESS Scalable algorithms SENSITIVITY SENSITIVITY ANALYSIS SIMULATION Sparse grids Stochastic optimization Stochastic partial differential equations STOCHASTIC PROCESSES THERMAL CONDUCTION
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container_title	Journal of computational physics
container_volume	227
creator	Zabaras, N. Ganapathysubramanian, B.
description	Experimental evidence suggests that the dynamics of many physical phenomena are significantly affected by the underlying uncertainties associated with variations in properties and fluctuations in operating conditions. Recent developments in stochastic analysis have opened the possibility of realistic modeling of such systems in the presence of multiple sources of uncertainties. These advances raise the possibility of solving the corresponding stochastic inverse problem: the problem of designing/estimating the evolution of a system in the presence of multiple sources of uncertainty given limited information. A scalable, parallel methodology for stochastic inverse/design problems is developed in this article. The representation of the underlying uncertainties and the resultant stochastic dependant variables is performed using a sparse grid collocation methodology. A novel stochastic sensitivity method is introduced based on multiple solutions to deterministic sensitivity problems. The stochastic inverse/design problem is transformed to a deterministic optimization problem in a larger-dimensional space that is subsequently solved using deterministic optimization algorithms. The design framework relies entirely on deterministic direct and sensitivity analysis of the continuum systems, thereby significantly enhancing the range of applicability of the framework for the design in the presence of uncertainty of many other systems usually analyzed with legacy codes. Various illustrative examples with multiple sources of uncertainty including inverse heat conduction problems in random heterogeneous media are provided to showcase the developed framework.
doi_str_mv	10.1016/j.jcp.2008.01.019
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subjects	ALGORITHMS CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Collocation methods Computational techniques EVOLUTION Exact sciences and technology FLUCTUATIONS Inverse problems Mathematical methods in physics MATHEMATICAL SOLUTIONS OPTIMIZATION PARTIAL DIFFERENTIAL EQUATIONS Physics RANDOMNESS Scalable algorithms SENSITIVITY SENSITIVITY ANALYSIS SIMULATION Sparse grids Stochastic optimization Stochastic partial differential equations STOCHASTIC PROCESSES THERMAL CONDUCTION
title	A scalable framework for the solution of stochastic inverse problems using a sparse grid collocation approach
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