Unknown source identification problem for space-time fractional diffusion equation: optimal error bound analysis and regularization method

IF 1.1 4区工程技术 Q3 ENGINEERING, MULTIDISCIPLINARY Inverse Problems in Science and Engineering Pub Date : 2021-03-19 DOI:10.1080/17415977.2021.1900841

Fan Yang, Qian-Chao Wang, Xiao-Xiao Li

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引用次数: 6

Abstract

In this paper, the problem of unknown source identification for the space-time fractional diffusion equation is studied. In this equation, the time fractional derivative used is a new fractional derivative, namely, Caputo-Fabrizio fractional derivative. We have illustrated that this problem is an ill-posed problem. Under the assumption of a priori bound, we obtain the optimal error bound analysis of the problem under the source condition. Moreover, we use a modified quasi-boundary regularization method and Landweber iterative regularization method to solve this ill-posed problem. Based on a priori and a posteriori regularization parameter selection rules, the corresponding convergence error estimates of the two regularization methods are obtained, respectively. Compared with the modified quasi-boundary regularization method, the convergence error estimate of Landweber iterative regularization method is order-optimal. Finally, the advantages, stability and effectiveness of the two regularization methods are illustrated by examples with different properties.

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时空分数阶扩散方程的未知源识别问题：最优误差界分析和正则化方法

本文研究了时空分数阶扩散方程的未知源辨识问题。在这个方程中，使用的时间分数导数是一个新的分数导数，即Caputo-Fabrizio分数导数。我们已经说明，这个问题是一个不适定的问题。在先验界的假设下，我们得到了源条件下问题的最优误差界分析。此外，我们使用一种改进的准边界正则化方法和Landweber迭代正则化方法来解决这个不适定问题。基于先验和后验正则化参数选择规则，分别获得了两种正则化方法的收敛误差估计。与改进的拟边界正则化方法相比，Landweber迭代正则化方法的收敛误差估计是阶最优的。最后，通过不同性质的例子说明了这两种正则化方法的优点、稳定性和有效性。

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来源期刊

Inverse Problems in Science and Engineering 工程技术-工程：综合

自引率

0.00%

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审稿时长

6 months

期刊介绍： Inverse Problems in Science and Engineering provides an international forum for the discussion of conceptual ideas and methods for the practical solution of applied inverse problems. The Journal aims to address the needs of practising engineers, mathematicians and researchers and to serve as a focal point for the quick communication of ideas. Papers must provide several non-trivial examples of practical applications. Multidisciplinary applied papers are particularly welcome. Topics include: -Shape design: determination of shape, size and location of domains (shape identification or optimization in acoustics, aerodynamics, electromagnets, etc; detection of voids and cracks). -Material properties: determination of physical properties of media. -Boundary values/initial values: identification of the proper boundary conditions and/or initial conditions (tomographic problems involving X-rays, ultrasonics, optics, thermal sources etc; determination of thermal, stress/strain, electromagnetic, fluid flow etc. boundary conditions on inaccessible boundaries; determination of initial chemical composition, etc.). -Forces and sources: determination of the unknown external forces or inputs acting on a domain (structural dynamic modification and reconstruction) and internal concentrated and distributed sources/sinks (sources of heat, noise, electromagnetic radiation, etc.). -Governing equations: inference of analytic forms of partial and/or integral equations governing the variation of measured field quantities.