Direct and Inverse Problems for a Fourth Order Anomalous Diffusion Model

The second order equation (also known as Fick’s equation) is derived from a classical well-known theory, but it is not enough to model all applications of interest. Recently, fractional equations and higher order equations began to receive more attention, demanding increased research efforts. They a...

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Veröffentlicht in:	Diffusion and defect data. Solid state data. Pt. A, Defect and diffusion forum Defect and diffusion forum, 2020-02, Vol.399, p.55-64
Hauptverfasser:	Bevilacqua, Luiz, da Silva Neto, Antônio José, Junior, Jader Lugon
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Differential equations Diffusion Ecological monitoring Finite difference method Heat transfer Inverse problems Mass transfer Mathematical models Organic chemistry Parameter estimation Sensitivity analysis Simulated annealing
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container_title	Diffusion and defect data. Solid state data. Pt. A, Defect and diffusion forum
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creator	Bevilacqua, Luiz da Silva Neto, Antônio José Junior, Jader Lugon
description	The second order equation (also known as Fick’s equation) is derived from a classical well-known theory, but it is not enough to model all applications of interest. Recently, fractional equations and higher order equations began to receive more attention, demanding increased research efforts. They are used to simulate the diffusion process in many important applications in sciences, such as chemistry, heat and mass transfer, biology and ecology. In this work, the sensitivity analysis is performed for a recently developed anomalous diffusion model in order to evaluate the possibility of estimating a set of parameters that are part of the fourth order equation model, including the parameters representing the variation of the fraction of particles that are allowed to diffuse using a sigmoid function. Finally, after the sensitivity analysis the Inverse Problem approach is used to estimate viable parameters that are necessary for simulation in the cases considered. The differential equation was approximated using the Finite Difference Method, and that solution was implemented in the RStudio platform. The Sensitivity Matrix was calculated and the Inverse Problem was solved using the same RStudio platform, and the Simulated Annealing Method.
doi_str_mv	10.4028/www.scientific.net/DDF.399.55
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subjects	Computer simulation Differential equations Diffusion Ecological monitoring Finite difference method Heat transfer Inverse problems Mass transfer Mathematical models Organic chemistry Parameter estimation Sensitivity analysis Simulated annealing
title	Direct and Inverse Problems for a Fourth Order Anomalous Diffusion Model
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