Combined energy method and regularization to solve the Cauchy problem for the heat equation

Baranger, Thouraya; Andrieux, Stéphane; Rischette, Romain

doi:10.1080/17415977.2013.836191

Cited by 10 publications

(9 citation statements)

References 23 publications

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“…Moreover, within lsqnonlin , we apply the interior-reflective Newton approach based Trust Region Reflective algorithm (Coleman and Li, 1996). Each iteration involves a large linear system of equations whose solution, based on a preconditioned conjugate gradient method, allows a regular and sufficiently smooth decrease of the objective functional (40) or (41), (Baranger et al , 2014). We have compiled this routine with the following specifications: Number of variables M = N = 40. Maximum number of iterations =10 2 × (number of variables). Maximum number of objective function evaluations = 10 3 × (number of variables). Termination tolerance on the function value, (TolFun) = 10 –20 . Solution tolerance, (xTolx) = 10 –20 . …”

Section: Numerical Solution For the Inverse Problemsmentioning

confidence: 99%

Simultaneous identification of timewise terms and free boundaries for the heat equation

Huntul

Tamsir

2020

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Purpose The purpose of this paper is to provide an insight and to solve numerically the identification of timewise terms and free boundaries coefficient appearing in the heat equation from over-determination conditions. Design/methodology/approach The formulated coefficient identification problem is inverse and ill-posed, and therefore, to obtain a stable solution, a nonlinear Tikhonov regularization least-squares approach is used. For the numerical discretization, the finite difference method combined with a regularized nonlinear minimization is performed using the MATLAB subroutine lsqnonlin. Findings The numerical results presented for two examples show the efficiency of the computational method and the accuracy and stability of the numerical solution even in the presence of noise in the input data. Research limitations/implications The mathematical formulation is restricted to identify coefficients in unknown components dependent on time, and this may be considered as a research limitation. However, there is no research implication to overcome this, as the known input data is also limited to single temperature in heat equation with Stefan conditions, and the first- and second-order heat moments measurements at a particular time location. Practical implications As noisy data are inverted, the study models real situations in which practical measurements are inherently contaminated with noise. Social implications The identification of the timewise terms and free boundaries will be of great interest in the heat transfer community and related fluid flow applications. Originality/value The current investigation advances previous studies, which assumed that the coefficient multiplying the lower order temperature term depends on time. The knowledge of this physical property coefficient is very important in heat transfer and fluid flow. The originality lies in the insight gained by performing for the numerical simulations of inversion to find the timewise terms and free boundaries coefficient dependent on time in the heat equation from noisy measurements.

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Section: Numerical Solution For the Inverse Problemsmentioning

confidence: 99%

Simultaneous identification of timewise terms and free boundaries for the heat equation

Huntul

Tamsir

2020

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“…The particularity of the related mathematical problem is the ill-posedness. Missing data to reconstruct suffer from high instabilities generated by unavoidable perturbations affecting the available data because of the finite accuracy of measuring instruments (see [2,3,14,17,18,22,31,32]). As a consequence, computing methods crudely employed for numerical handling of these inverse problems are most often doomed to fail unless they are used with relevant regularization techniques combined to suitable automatic selection rules of the regularization parameter(s).…”

Section: Introductionmentioning

confidence: 99%

Data Recovery from Cauchy Measurements in Transient Heat Transfer

null¹,

Belgacem²

2022

JMS

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We study the ill-posedness degree of the reconstruction processes of missing boundary data or initial states in the transient heat conduction. Both problems are severely ill-posed. This is a powerful indicator about the way the instabilities will affect the computations in the numerical recovery methods. We provide rigorous proofs of this result where the conductivites are space dependent. The theoretical work is concerned with the unsteady heat equation in one dimension even though most of the results obtained here are readily extended to higher dimensions.

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“…The considered inverse problem encountered in many practical applications such as the identification of multiple leak zones in saturated unsteady flow, see previous work 13 and obstacle identification problems. In the framework of the parabolic equation, many approaches have been proposed in the literature for solving this ill‐posed inverse problem with varying degrees of success, we can cite the boundary integral equation approach, see Chapko and Johansson 14 and Onyango et al, 15 iterative regularization methods, we quote previous works 13,16 and Johansson, 17 quasi‐reversibility process, see Dardé, 18 the minimization of a cost functional, see Rischette et al, 19 and the decomposition approach see Lesnic and Elliott 20 …”

Section: Introductionmentioning

confidence: 99%

Missing boundary data reconstruction for the heat equation

Abda

Benmeghnia

Guetat

2021

Math Methods in App Sciences

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This work is concerned with the boundary data completion problem related to the heat equation in the special case of an annular domain. We first reformulate this inverse problem into an interfacial equation involving Steklov‐Poincaré operator based on fictitious domain decomposition techniques. We present some theoretical results. For solving the problem under consideration, we suggest a new numerical point of view which helps to reduce the computational cost using the Schur complement algorithm. We perform then the convergence analysis of this new approach in the annular domain. Several numerical experiments are shown to illustrate the efficiency of the proposed method.

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Combined energy method and regularization to solve the Cauchy problem for the heat equation

Cited by 10 publications

References 23 publications

Simultaneous identification of timewise terms and free boundaries for the heat equation

Simultaneous identification of timewise terms and free boundaries for the heat equation

Data Recovery from Cauchy Measurements in Transient Heat Transfer

Missing boundary data reconstruction for the heat equation

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