University of TabrizComputational Methods for Differential Equations2345-39828420201101Wavelet-Picard iterative method for solving singular fractional nonlinear partial differential equations with initial and boundary conditions610638990910.22034/cmde.2020.31627.1479ENAmirMohammadiDepartment of Mathematics,
Azarbaijan Shahid Madani University, Tabriz, Iran.NaserAghazadehDepartment of Mathematics,
Azarbaijan Shahid Madani University, Tabriz, Iran.0000-0003-2705-8942ShahramRezapourDepartment of Mathematics,
Azarbaijan Shahid Madani University, Tabriz, Iran.Journal Article20190120The present study applies the Picard iterative method to nonlinear singular partial fractional differential equations. The Haar and second-kind Chebyshev wavelets operational matrix of fractional integration will be used to solve problems combining linearization technique with the Picard method. The singular problem will be converted to an algebraic system of equations, which can be easily solved. Numerical examples are provided to illustrate the efficiency and accuracy of the technique.University of TabrizComputational Methods for Differential Equations2345-39828420201101Study of new monotone iterative technique for a class of arbitrary order differential equations639647992710.22034/cmde.2020.29957.1442ENFazalHaqDepartment of Mathematics and Statistics,
University of Swat, Khyber Pakhtunkhwa, Pakistan.MohammadAkramDepartment of Mathematics, Faculty of Science,
Islamic University of Madinah, Madinah, Kingdom of Saudi Arabia.KamalShahDepartment of Mathematics, University of Malakand,
Dir(Lower), KPK, Pakistan.GhausRahmanDepartment of Mathematics and Statistics,
University of Swat, Khyber Pakhtunkhwa, Pakistan.Journal Article20181022In this paper, we apply new type monotone iterative technique which is very rarely used to find iterative solutions for boundary value problem (BVPs) of nonlinear fractional order differential equations (NFODEs). With the help of the aforesaid technique, we establish two sequences of upper and lower solutions for the considered BVP. Further the procedure is testified by providing suitable examples.University of TabrizComputational Methods for Differential Equations2345-39828420201101Fractional Ostrovsky equation648660992410.22034/cmde.2020.26702.1346ENHassanAskariDepartment of Applied Mathematics, Faculty of Mathematical Sciences,
Shahrekord University, P.O. Box 115, Shahrekord, Iran.AlirezaAnsariDepartment of Applied Mathematics, Faculty of Mathematical Sciences,
Shahrekord University, P.O. Box 115, Shahrekord, Iran.Journal Article20180408In this paper, we find an integral representation for the fundamental solution of the fractional Ostrovsky equation in terms of the Airy and Bessel-Wright functions. The equation is studied in the sense of the Weyl fractional derivative and the solution is presented as the Airy transforms of Wright functions. Using the asymptotic expansion of Wright function the asymptotic behavior of solution is also discussed.University of TabrizComputational Methods for Differential Equations2345-39828420201101Shortest Path Problem With Ordinary Differential Equations Constrained661672992510.22034/cmde.2020.33231.1537ENAliBabapour AzarSchool of Mathematics, University of Tabriz,Tabriz, Iran.0000-0002-9314-047XZohrehHosseini NodehSchool of Mathematics, University of Tabriz,Tabriz, Iran.0000-0002-6910-4831Journal Article20190504Many quick-link optimization models of transferring corrosive materials, need some constraints to change the output space such that all of the criteria are met, which forms a nonlinear problem with specific constraints. So we use an approach for finding global solutions of mixed-integer nonlinear optimization problems with ordinary differential equation constraints on the shortest path problem connective body composition because we need to save time. For the solution of constrained differential equations, we present a numerical method by coupling an implicit numerical method, and the results will be expressed by showing that the optimal path is selected.University of TabrizComputational Methods for Differential Equations2345-39828420201101A Computational Method for Solving the Lane-Emden Initial Value Problems673684993010.22034/cmde.2020.31901.1488ENMortezaBisheh-NiasarDepartment of Applied Mathematics, Faculty of Mathematical Sciences, University of Kashan, Kashan, Iran.Journal Article20190205In this work, we propose an efficient numerical algorithm based upon compact finite difference to solve Lane-Emden equations which are nonlinear ordinary differential equations. The presented method reduces the solution of Lane-Emden equations to the solution of a nonlinear system of equations. The numerical experiments show the accuracy and efficiency of this method.University of TabrizComputational Methods for Differential Equations2345-39828420201101The use of CESTAC method to find optimal shape parameter and optimal number of points in RBF-meshless methods to solve differential equations685707992210.22034/cmde.2020.27817.1374ENHasanBarzegar KelishamiDepartment of Mathematics, Central Tehran Branch,
Islamic Azad University, Tehran, Iran.Mohammad AliFariborzi AraghiDepartment of Mathematics, Central Tehran Branch,
Islamic Azad University, Tehran, Iran.MajidAmirfakhrianDepartment of Mathematics, Central Tehran Branch, Islamic Azad University, Tehran, Iran.Journal Article20180609One of the schemes to find the optimal shape parameter and optimal number of points in the radial basis function (RBF) methods is to apply the stochastic arithmetic (SA) in place of the common floating-point arithmetic (FPA). The main purpose of this work is to introduce a reliable approach based on this new arithmetic to compute the local optimal shape parameter and number of points in multiquadric and Gaussian RBF-meshless methods for solving differential equations, in the iterative process. To this end, the CESTAC method is applied. Also, in order to implement the proposed algorithms, the CADNA library is performed. The examples illustrate the efficiency and importance of using this library to validate the results.University of TabrizComputational Methods for Differential Equations2345-39828420201101Applications of the Newton-Raphson method in a SDFEM for inviscid Burgers equation708732992010.22034/cmde.2020.32615.1513ENMohammadIzadiDepartment of Applied Mathematics,
Faculty of Mathematics and Computer,
Shahid Bahonar University of Kerman,
Kerman, Iran0000-0002-6116-4928Journal Article20190319In this paper we investigate in detail the applications of the classical Newton-Raphson method in connection with a space-time finite element discretization scheme for the inviscid Burgers equation in one dimensional space. The underlying discretization method is the so-called streamline diffusion method, which combines good stability properties with high accuracy. The coupled nonlinear algebraic equations thus obtained in each space-time slab are solved by the generalized Newton-Raphson method. Exploiting the band-structured properties of the Jacobian matrix, two different algorithms based on the Newton-Raphson linearization are proposed. In a series of examples, we show that in each time-step a quadratic convergence order is attained when the Newton-Raphson procedure applied to the corresponding system of nonlinear equations.University of TabrizComputational Methods for Differential Equations2345-39828420201101Residual Method for Nonlinear System of Initial Value Problems733744993710.22034/cmde.2020.32830.1527ENMeltemAdiyamanDepartment of Mathematics,
Faculty of Sciences, Dokuz Eylul University,
Tinaztepe, Buca, 35160 Izmir, Turkey.BurcuNoyanDepartment of Mathematics,
Faculty of Sciences, Dokuz Eylul University,
Tinaztepe, Buca, 35160 Izmir, Turkey.Journal Article20190415In this paper, the nonlinear system of initial value problems are solved numerically by using Residual method which is based on the minimizing residual function by the Taylor’s series expansion. The convergence analysis of the method is given. The significant feature of the method is reduction of nonlinear system of initial value problems to the system of linear equations. To emphasize the accuracy and potential of the method, we solve Lorenz system and primary HIV-1 infection problem numericallyUniversity of TabrizComputational Methods for Differential Equations2345-39828420201101Matrix inverse eigenvalue problem for stabilization of fractional descriptor discrete-time linear systems by forward and propositional output feedback745761992610.22034/cmde.2020.28597.1394ENSakineh BigomMirassadiFaculty of Mathematical Sciences,
Shahrood University of Technology, Shahrood, Iran.HojjatAhsani TehraniFaculty of Mathematical Sciences,
Shahrood University of Technology, Shahrood, Iran.nullJournal Article20180813In this paper, stabilization of unstable fractional descriptor discrete-time linear system via forward and propositional output feedback is done to obtain satisfactory responses. To gain forward and propositional output feedback matrices, two standard linear systems need to exist. Assigning nonzero arbitrary eigenvalues to the first standard system and inverted the desired eigenvalues for standard descriptor system to the second one, desired eigenvalues are assigned by matrix inverse eigenvalue problem. Numerical examples are also presented to illustrate our method.University of TabrizComputational Methods for Differential Equations2345-39828420201101Isospectral sixth order Sturm-Liouville eigenvalue problems762769993110.22034/cmde.2020.34001.1564ENHanifMirzaeiFaculty of Basic Sciences, Sahand University of Technology, Tabriz, Iran.Journal Article20190622In this research, we introduce an approach to find a family of sixth order SturmLiouville problems having the same spectrum. Using Darboux Lemma and the fact that any second order Sturm-Liouville problem with the Dirichlet boundary conditions is equivalent to a sixth order Sturm-Liouville problem, the considered problems are formulated.University of TabrizComputational Methods for Differential Equations2345-39828420201101Optimal homotopy asymptotic and multistage optimal homotopy asymptotic methods for Abel Volterra integral equation of the second kind770780991410.22034/cmde.2020.26806.1349ENJafarBiazarDepartment of Mathematics, Faculty of Sciences, University of Guilan, P.C. 41938 Rasht, Iran0000-0001-8026-2999RoyaMontazeriDepartment of Mathematics, Payame Noor University,
P. O. Box 19395-3697, Tehran, Iran.Journal Article20180415In this paper, optimal homotopy asymptotic method (OHAM) and multistage optimal homotopy asymptotic (MOHAM) method are applied to find an approximate solution to Abel’s integral equation, that is in fact a weakly singular Volterra integral equation. To illustrate these approaches one example is presented. The results confirm the efficiency and ability of these methods to such equations. The results will be compared with the exact solution to find out that which method of these two is more accurate.University of TabrizComputational Methods for Differential Equations2345-39828420201101Application of cubic B-spline quasi-interpolation for solving timefractional partial differential equation781793993210.22034/cmde.2020.32932.1531ENHamidehGafouriDepartment of Applied Mathematics,
Azarbaijan Shahid Madani University, Tabriz, Iran.MojtabaRanjbarDepartment of Applied Mathematics,
Azarbaijan Shahid Madani University, Tabriz, Iran.0000-0003-0491-526XAliKhaniDepartment of Applied Mathematics,
Azarbaijan Shahid Madani University, Tabriz, Iran.0000000289284235Journal Article20190418The purpose of this paper is to present a numerical scheme for solving time-fractional partial differential equation based on cubic B-spline quasi-interpolation. For this purpose, first we will approximate the time-fractional derivative by Laplace transform method and then by using of cubic B-spline quasi-interpolation, the spatial derivatives are approximated. Moreover, the stability of this method is studied. Finally, European call and put options are priced and we will show that the results are good agreement with the other methods. The main advantage of the resulting scheme is that the algorithm is very simple, so it is very easy to implement.University of TabrizComputational Methods for Differential Equations2345-39828420201101Development of non polynomial spline and New B-spline with application to solution of Klein-Gordon equation794814993310.22034/cmde.2020.27847.1377ENHomaZadvanDepartment of Mathematics and Statistics, Central Tehran Branch, Islamic Azad University, Tehran, Iran.JalilRashidiniaSchool of Mathematics, Iran University of Science and Technol-
ogy, Hengam, Narmak, 168613114 Tehran, Iran.0000-0002-9177-900XJournal Article20180610In this paper we develop a non polynomial cubic spline functions which we called ”TS spline”, based on trigonometric functions. The convergence analysis of this spline is investigated in details. The definition of B-spline basis function for TS spline is extended and ”TS B-spline” is introduced. This paper attempts to develop collocation method based on this B-spline for the numerical solution of the nonlinear Klein-Gordon equation. The convergence analysis of this approach is discussed, the second order of convergence is proved consequently. The proposed method is applied on some test examples and the numerical results are compared with those already available in literature. Observed errors in the solutions show the efficiency and numerical applicability of the proposed method.University of TabrizComputational Methods for Differential Equations2345-39828420201101A denoising PDE model based on isotropic diffusion and total variation models815826993410.22034/cmde.2020.26116.1331ENNedaMohamadiDepartment of Mathematics and statistics, Mashhad Branch, Islamic Azad University, Mashhad, Iran.Ali RezaSoheiliDepartment of Applied Mathematics, Faculty of Mathematical Sciences,
Ferdowsi University of Mashhad, Mashhad, Iran.FaezehToutounianDepartment of Applied Mathematics, Faculty of Mathematical Sciences,
Ferdowsi University of Mashhad, Mashhad, Iran.Journal Article20180225In this paper, a denoising PDE model based on a combination of the isotropic diffusion and total variation models is presented. The new weighted model is able to be adaptive in each region in accordance with the image’s information. The model performs more diffusion in the flat regions of the image, and less diffusion in the edges of the image. The new model has more ability to restore the image in terms of peak signal to noise ratio and visual quality, compared with total variation, isotropic diffusion, and some well-known models. Experimental results show that the model is able to suppress the noise effectively while preserving texture features and edge information well.University of TabrizComputational Methods for Differential Equations2345-39828420201101Approximate analytic compacton solutions of the K(p, p) equation by reduced differential transform method827839994510.22034/cmde.2019.33123.1534ENTurgutAkArmutlu Vocational School,
Yalova University,
77500 Yalova, Turkey.0000-0001-8368-8506SharanjeetDhawanDepartment of Mathematics,
Central University of Haryana,
123029 Haryana, India.Journal Article20190430In the present work, we focus on solutions of K(p, p) equation which are solitons with compact support called compactons. Such a study of compact solitary waves will help us understanding solitons at a deeper level. One of the interesting feature, they govern is quasi elastic collision and gaining the same coherent shape again after scattering. Numerical scheme used to study the compacton solutions of K(p, p) equation is based on reduced differential transform method. Both one dimensional differential transform method and two dimensional reduced differential transform method have been used. Test problems under consideration show the efficient working of the proposed scheme.