Stable method for solving the Cauchy problem with the use of Chebyshev polynomials

Joachimiak, Magda; Ciałkowski, Michał; Frąckowiak, Andrzej

doi:10.1108/hff-05-2019-0416

Cited by 16 publications

(14 citation statements)

References 43 publications

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“…The domain in the η -direction is [0, η ∞ ], where η ∞ is the end of the boundary layer is transformed into the computational domain [–1, 1], then the system of non-linear equations (13) to (20) can be solved by applying the CPS method usefully used by Elgazery (2008), Elshehawey et al (2004), Elbarbary and Elgazery (2004a, 2004b) and Joachimiak et al (2019). In view of CPS equations and the boundary conditions, we have the following system of equations: …”

Section: Numerical Techniquementioning

confidence: 99%

Blood flow of MHD non-Newtonian nanofluid with heat transfer and slip effects

Elelamy

Elgazery

Ellahi

2020

HFF

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Purpose This paper aims to investigate a mathematical model with numerical simulation for bacterial growth in the heart valve. Design/methodology/approach For antibacterial activities and antibodies properties, nanoparticles have been used. As antibiotics are commonly thought to be homogeneously dispersed through the blood, therefore, non-Newtonian fluid of Casson micropolar blood flow in the heart valve for two dimensional with variable properties is used. The heat transfer with induced magnetic field translational attraction under the influence of slip is considered for the resemblance of the heart valve prosthesis. The numeral results have been obtained by using the Chebyshev pseudospectral method. Findings It is proven that vascular resistance decreases for increasing blood velocity. It is noted that when the magnetic field will be induced from the heart valve prosthesis then it may cause a decrease in vascular resistance. The unbounded molecules and antibiotic concentration that are able to penetrate the bacteria are increased by increasing values of vascular resistance. The bacterial growth density cultivates for upswing values of magnetic permeability and magnetic parameters. Originality/value To the best of the authors’ knowledge, this is the first study to investigate a mathematical model with numerical simulation for bacterial growth in the heart valve.

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Section: Numerical Techniquementioning

confidence: 99%

Blood flow of MHD non-Newtonian nanofluid with heat transfer and slip effects

Elelamy

Elgazery

Ellahi

2020

HFF

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“…Solving the direct problem, where the temperature on boundaries Γ 1 , Γ 2 , Γ 3 and Γ 4 was known, was reduced to solving the matrix equation what was described in detail in the paper (Joachimiak et al , 2019a). Based on the solution to the direct problem, constants a k [Equation (12)] are of the following equation (14): where Hh,k=∑j=2m−1trueA˜k,jnWh−1true(yjtrue), while A ̃ k,jn ( k = 1, 2, …, mn ; j = 2, 3, …, m − 1) are elements of the matrix A −1 .…”

Section: Calculation Modelmentioning

confidence: 99%

“…There are many methods used to regularize inverse problems. Among them, there is the Tikhonov regularization (Beck and Woodbury, 2016; Chen et al , 2019; Djerrar et al , 2017; Frąckowiak et al , 2019a; Laneev, 2018; Marin, 2010, 2016; Niu et al , 2014; Sun, 2016; Tikhonov and Arsenin, 1977; Yaparova, 2016), the Tikhonov–Philips regularization (Joachimiak et al , 2019a), the discrete Fourier transform (Frąckowiak and Ciałkowski, 2018; Wróblewska et al , 2015) and SVD algorithm (Hasanov and Mukanova, 2015). In her article, Cheruvu (2017) applied the wavelet regularization of Laplace’s equation in the arbitrarily shaped domain.…”

Section: Introductionmentioning

confidence: 99%

“…In many cases, the regularization of the inverse problem concerns the problem of choosing the regularization parameter. The regularization parameter can be chosen based on the Morozov principle (Chen et al , 2019; Han et al , 2011; Joachimiak et al , 2019a; Marin, 2016; Morozov, 1984; Sun, 2016) or using the L-curve method (Jin and Zheng, 2006; Marin and Munteanu, 2010; Marin, 2005). In the study of Marin (2011), the optimal regularization parameter was sought based on the generalized cross-validation criterion.…”

Section: Introductionmentioning

confidence: 99%

“…In this article, the solution to the Cauchy problem for the Laplace’s equation was investigated with the use of the Chebyshev polynomials. To regularize the solution to the inverse problem, the modification of the Tikhonov and of the Tikhonov–Philips regularizations, described in the article (Joachimiak et al , 2019a) was applied. The choice of the regularization parameter was made based on the Morozov principle, the minimum energy integral criterion and the L-curve method.…”

Section: Introductionmentioning

confidence: 99%

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Choice of the regularization parameter for the Cauchy problem for the Laplace equation

Joachimiak

2020

HFF

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Purpose In this paper, the Cauchy-type problem for the Laplace equation was solved in the rectangular domain with the use of the Chebyshev polynomials. The purpose of this paper is to present an optimal choice of the regularization parameter for the inverse problem, which allows determining the stable distribution of temperature on one of the boundaries of the rectangle domain with the required accuracy. Design/methodology/approach The Cauchy-type problem is ill-posed numerically, therefore, it has been regularized with the use of the modified Tikhonov and Tikhonov–Philips regularization. The influence of the regularization parameter choice on the solution was investigated. To choose the regularization parameter, the Morozov principle, the minimum of energy integral criterion and the L-curve method were applied. Findings Numerical examples for the function with singularities outside the domain were solved in this paper. The values of results change significantly within the calculation domain. Next, results of the sought temperature distributions, obtained with the use of different methods of choosing the regularization parameter, were compared. Methods of choosing the regularization parameter were evaluated by the norm Nmax. Practical implications Calculation model described in this paper can be applied to determine temperature distribution on the boundary of the heated wall of, for instance, a boiler or a body of the turbine, that is, everywhere the temperature measurement is impossible to be performed on a part of the boundary. Originality/value The paper presents a new method for solving the inverse Cauchy problem with the use of the Chebyshev polynomials. The choice of the regularization parameter was analyzed to obtain a solution with the lowest possible sensitivity to input data disturbances.

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