On the Approximate Solution of Partial Integro-Differential Equations Using the Pseudospectral Method Based on Chebyshev Cardinal Functions

In this paper, we apply the pseudospectral method based on the Chebyshev cardinal function to solve the parabolic partial integro-differential equations (PIDEs). Since these equations play a key role in mathematics, physics, and engineering, finding an appropriate solution is important. We use an efficient method to solve PIDEs, especially for the integral part. Unlike when using Chebyshev functions, when using Chebyshev cardinal functions it is no longer necessary to integrate to find expansion coefficients of a given function. This reduces the computation. The convergence analysis is investigated and some numerical examples guarantee our theoretical results. We compare the presented method with others. The results confirm the efficiency and accuracy of the method.

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Hybrid Bernstein Block-Pulse Functions Method for Second Kind Integral Equations with Convergence Analysis

Abstract and Applied Analysis ◽

10.1155/2014/623763 ◽

2014 ◽

Vol 2014 ◽

pp. 1-8 ◽

Cited By ~ 7

Author(s):

Mohsen Alipour ◽

Dumitru Baleanu ◽

Fereshteh Babaei

Keyword(s):

Integral Equation ◽

Approximate Solution ◽

Convergence Analysis ◽

Bernstein Polynomials ◽

Linear Equations ◽

The Other ◽

New Combination ◽

System Of Linear Equations ◽

Numerical Examples ◽

Block Pulse Functions

We introduce a new combination of Bernstein polynomials (BPs) and Block-Pulse functions (BPFs) on the interval [0, 1]. These functions are suitable for finding an approximate solution of the second kind integral equation. We call this method Hybrid Bernstein Block-Pulse Functions Method (HBBPFM). This method is very simple such that an integral equation is reduced to a system of linear equations. On the other hand, convergence analysis for this method is discussed. The method is computationally very simple and attractive so that numerical examples illustrate the efficiency and accuracy of this method.

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A Friendly Iterative Technique for Solving Nonlinear Integro-Differential and Systems of Nonlinear Integro-Differential Equations

International Journal of Computational Methods ◽

10.1142/s0219876218500160 ◽

2018 ◽

Vol 15 (03) ◽

pp. 1850016 ◽

Cited By ~ 3

Author(s):

A. A. Hemeda

Keyword(s):

Approximate Solution ◽

Differential Operator ◽

Differential Equations ◽

The Other ◽

Iterative Technique ◽

Restrictive Assumption ◽

Numerical Examples ◽

Linear And Nonlinear ◽

Computational Procedures ◽

Adomian’S Polynomials

In this work, a simple new iterative technique based on the integral operator, the inverse of the differential operator in the problem under consideration, is introduced to solve nonlinear integro-differential and systems of nonlinear integro-differential equations (IDEs). The introduced technique is simpler and shorter in its computational procedures and time than the other methods. In addition, it does not require discretization, linearization or any restrictive assumption of any form in providing analytical or approximate solution to linear and nonlinear equations. Also, this technique does not require calculating Adomian’s polynomials, Lagrange’s multiplier values or equating the terms of equal powers of the impeding parameter which need more computational procedures and time. These advantages make it reliable and its efficiency is demonstrated with numerical examples.

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Improved Convergence Analysis of Gauss-Newton-Secant Method for Solving Nonlinear Least Squares Problems

Mathematics ◽

10.3390/math7010099 ◽

2019 ◽

Vol 7 (1) ◽

pp. 99 ◽

Cited By ~ 1

Author(s):

Ioannis Argyros ◽

Stepan Shakhno ◽

Yurii Shunkin

Keyword(s):

Least Squares ◽

Convergence Analysis ◽

Difference Method ◽

Divided Difference ◽

Nonlinear Least Squares ◽

Convergence Order ◽

Least Squares Problems ◽

Convergence Radius ◽

Numerical Examples ◽

Theoretical Results

We study an iterative differential-difference method for solving nonlinear least squares problems, which uses, instead of the Jacobian, the sum of derivative of differentiable parts of operator and divided difference of nondifferentiable parts. Moreover, we introduce a method that uses the derivative of differentiable parts instead of the Jacobian. Results that establish the conditions of convergence, radius and the convergence order of the proposed methods in earlier work are presented. The numerical examples illustrate the theoretical results.

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Dependence Analysis of the Solutions on the Parameters of Fractional Delay Differential Equations

Advances in Applied Mathematics and Mechanics ◽

10.4208/aamm.10-m1045 ◽

2011 ◽

Vol 3 (5) ◽

pp. 586-597 ◽

Cited By ~ 3

Author(s):

Shuiping Yang ◽

Aiguo Xiao ◽

Xinyuan Pan

Keyword(s):

Differential Equations ◽

Delay Differential Equations ◽

Initial Function ◽

Hand Function ◽

Dependence Analysis ◽

Numerical Examples ◽

Fractional Delay ◽

Delay Differential ◽

Fractional Delay Differential Equations ◽

Theoretical Results

AbstractIn this paper, we investigate the dependence of the solutions on the parameters (order, initial function, right-hand function) of fractional delay differential equations (FDDEs) with the Caputo fractional derivative. Some results including an estimate of the solutions of FDDEs are given respectively. Theoretical results are verified by some numerical examples.

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Application of Rational Second Kind Chebyshev Functions for System of Integrodifferential Equations on Semi-Infinite Intervals

Journal of Applied Mathematics ◽

10.1155/2012/803503 ◽

2012 ◽

Vol 2012 ◽

pp. 1-11 ◽

Cited By ~ 2

Author(s):

M. Tavassoli Kajani ◽

S. Vahdati ◽

Zulkifly Abbas ◽

Mohammad Maleki

Keyword(s):

Approximate Solution ◽

Differential Equations ◽

Galerkin Method ◽

High Accuracy ◽

Integrodifferential Equations ◽

Expansion Test ◽

Infinite Intervals ◽

System Of Integrodifferential Equations ◽

Rational Chebyshev ◽

Chebyshev Functions

Rational Chebyshev bases and Galerkin method are used to obtain the approximate solution of a system of high-order integro-differential equations on the interval [0,∞). This method is based on replacement of the unknown functions by their truncated series of rational Chebyshev expansion. Test examples are considered to show the high accuracy, simplicity, and efficiency of this method.

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Convergence Analysis of the Spectral Methods for Weakly Singular Volterra Integro-Differential Equations with Smooth Solutions

Advances in Applied Mathematics and Mechanics ◽

10.4208/aamm.10-m1055 ◽

2012 ◽

Vol 4 (1) ◽

pp. 1-20 ◽

Cited By ~ 35

Author(s):

Yunxia Wei ◽

Yanping Chen

Keyword(s):

Differential Equations ◽

Spectral Methods ◽

Approximate Solutions ◽

Smooth Solutions ◽

Weakly Singular Kernel ◽

Numerical Examples ◽

Weakly Singular ◽

Rigorous Error ◽

Derivatives Of ◽

Theoretical Results

AbstractThe theory of a class of spectral methods is extended to Volterra integro-differential equations which contain a weakly singular kernel (t - s)->* with 0< μ <1. In this work, we consider the case when the underlying solutions of weakly singular Volterra integro-differential equations are sufficiently smooth. We provide a rigorous error analysis for the spectral methods, which shows that both the errors of approximate solutions and the errors of approximate derivatives of the solutions decay exponentially inL°°-norm and weightedL2-norm. The numerical examples are given to illustrate the theoretical results.

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A New Scheme for Solving Multiorder Fractional Differential Equations Based on Müntz–Legendre Wavelets

Complexity ◽

10.1155/2021/9915551 ◽

2021 ◽

Vol 2021 ◽

pp. 1-9

Author(s):

Haifa Bin Jebreen ◽

Fairouz Tchier

Keyword(s):

Differential Equations ◽

Fractional Differential Equations ◽

Operational Matrix ◽

Pseudospectral Method ◽

Algebraic Equations ◽

Legendre Wavelets ◽

Derivative Operator ◽

Numerical Examples ◽

Linear Algebraic Equations ◽

Fractional Differential

In this study, we apply the pseudospectral method based on Müntz–Legendre wavelets to solve the multiorder fractional differential equations with Caputo fractional derivative. Using the operational matrix for the Caputo derivative operator and applying the Chebyshev and Legendre zeros, the problem is reduced to a system of linear algebraic equations. We illustrate the reliability, efficiency, and accuracy of the method by some numerical examples. We also compare the proposed method with others and show that the proposed method gives better results.

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Convergence analysis for a fast class of multi-step Chebyshev-Halley-type methods under weak conditions

Open Journal of Mathematical Sciences ◽

10.30538/oms2021.0143 ◽

2021 ◽

Vol 4 (1) ◽

pp. 34-43

Author(s):

Samundra Regmi ◽

◽

Ioannis K. Argyros ◽

Santhosh George ◽

◽

...

Keyword(s):

Banach Space ◽

Convergence Analysis ◽

Computational Cost ◽

Convergence Domain ◽

Convergence Region ◽

Type Method ◽

Precise Information ◽

Numerical Examples ◽

Lipschitz Constants ◽

Theoretical Results

In this study a convergence analysis for a fast multi-step Chebyshe-Halley-type method for solving nonlinear equations involving Banach space valued operator is presented. We introduce a more precise convergence region containing the iterates leading to tighter Lipschitz constants and functions. This way advantages are obtained in both the local as well as the semi-local convergence case under the same computational cost such as: extended convergence domain, tighter error bounds on the distances involved and a more precise information on the location of the solution. The new technique can be used to extend the applicability of other iterative methods. The numerical examples further validate the theoretical results.

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Spectral-Collocation Methods for Fractional Pantograph Delay-Integrodifferential Equations

Advances in Mathematical Physics ◽

10.1155/2013/821327 ◽

2013 ◽

Vol 2013 ◽

pp. 1-14 ◽

Cited By ~ 20

Author(s):

Yin Yang ◽

Yunqing Huang

Keyword(s):

Approximate Solution ◽

Error Analysis ◽

Fractional Derivative ◽

Integrodifferential Equations ◽

Collocation Methods ◽

Volterra Type ◽

Numerical Examples ◽

Rigorous Error ◽

Spectral Collocation Methods ◽

Theoretical Results

We propose and analyze a spectral Jacobi-collocation approximation for fractional order integrodifferential equations of Volterra type with pantograph delay. The fractional derivative is described in the Caputo sense. We provide a rigorous error analysis for the collocation method, which shows that the error of approximate solution decays exponentially inL∞norm and weightedL2-norm. The numerical examples are given to illustrate the theoretical results.

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A computational method for time fractional partial integro-differential equations

Journal of Applied Analysis ◽

10.1515/jaa-2020-2013 ◽

2020 ◽

Vol 26 (2) ◽

pp. 315-323

Author(s):

M. Mojahedfar ◽

Abolfazl Tari ◽

S. Shahmorad

Keyword(s):

Approximate Solution ◽

Differential Equations ◽

Error Estimation ◽

Initial Conditions ◽

Computational Method ◽

Operational Matrices ◽

Algebraic Equations ◽

Numerical Examples

AbstractIn this paper, a class of time fractional partial integro-differential equations (FPIDEs) with initial conditions is studied. Some operational matrices are used to reduce a FPIDE problem to a system of algebraic equations with special properties. The resulted system is solved to give an approximate solution to the problem. Error estimation is also discussed for the approximate solution. Finally, some numerical examples are given to show the accuracy of the proposed method.

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