Search engine for discovering works of Art, research articles, and books related to Art and Culture
Javascript must be enabled to continue!
New Modified Adomian Decomposition Recursion Schemes for Solving Certain Types of Nonlinear Fractional Two-Point Boundary Value Problems
View through CrossRef
We apply new modified recursion schemes obtained by the Adomian decomposition method (ADM) to analytically solve specific types of two-point boundary value problems for nonlinear fractional order ordinary and partial differential equations. The new modified recursion schemes, which sometimes utilize the technique of Duan’s convergence parameter, are derived using the Duan-Rach modified ADM. The Duan-Rach modified ADM employs all of the given boundary conditions to compute the remaining unknown constants of integration, which are then embedded in the integral solution form before constructing recursion schemes for the solution components. New modified recursion schemes obtained by the method are generated in order to analytically solve nonlinear fractional order boundary value problems with a variety of two-point boundary conditions such as Robin and separated boundary conditions. Some numerical examples of such problems are demonstrated graphically. In addition, the maximal errors (MEn) or the error remainder functions (ERn(x)) of each problem are calculated.
Title: New Modified Adomian Decomposition Recursion Schemes for Solving Certain Types of Nonlinear Fractional Two-Point Boundary Value Problems
Description:
We apply new modified recursion schemes obtained by the Adomian decomposition method (ADM) to analytically solve specific types of two-point boundary value problems for nonlinear fractional order ordinary and partial differential equations.
The new modified recursion schemes, which sometimes utilize the technique of Duan’s convergence parameter, are derived using the Duan-Rach modified ADM.
The Duan-Rach modified ADM employs all of the given boundary conditions to compute the remaining unknown constants of integration, which are then embedded in the integral solution form before constructing recursion schemes for the solution components.
New modified recursion schemes obtained by the method are generated in order to analytically solve nonlinear fractional order boundary value problems with a variety of two-point boundary conditions such as Robin and separated boundary conditions.
Some numerical examples of such problems are demonstrated graphically.
In addition, the maximal errors (MEn) or the error remainder functions (ERn(x)) of each problem are calculated.
Related Results
Solving Undamped and Damped Fractional Oscillators via Integral Rohit Transform
Solving Undamped and Damped Fractional Oscillators via Integral Rohit Transform
Background: The dynamics of fractional oscillators are generally described by fractional differential equations, which include the fractional derivative of the Caputo or Riemann-Li...
Natural Transform Method with Modified ADM for Nonlinear Time Fractional PDEs with Proportional Delay
Natural Transform Method with Modified ADM for Nonlinear Time Fractional PDEs with Proportional Delay
Abstract
This paper presents a practical approach for solving nonlinear partial differential equations with both time fractional and proportional delay. These equat...
An Efficient Analytical Technique, for The Solution of Fractional-Order Telegraph Equations
An Efficient Analytical Technique, for The Solution of Fractional-Order Telegraph Equations
In the present article, fractional-order telegraph equations are solved by using the Laplace-Adomian decomposition method. The Caputo operator is used to define the fractional deri...
Numerical resolution of Emden's equation using Adomian polynomials
Numerical resolution of Emden's equation using Adomian polynomials
PurposeIn this paper the authors aim to show the advantages of using the decomposition method introduced by Adomian to solve Emden's equation, a classical non‐linear equation that ...
On α-Fractional Bregman Divergence to study α-Fractional Minty’s Lemma
On α-Fractional Bregman Divergence to study α-Fractional Minty’s Lemma
In this paper fractional variational inequality problems (FVIP) and dual fractional variational inequality problems (DFVIP), Fractional minimization problems are defined with the h...
Nonlinear optimal control for robotic exoskeletons with electropneumatic actuators
Nonlinear optimal control for robotic exoskeletons with electropneumatic actuators
Purpose
To provide high torques needed to move a robot’s links, electric actuators are followed by a transmission system with a high transmission rate. For instance, gear ratios of...
Tarig Projected Differential Transform Method to solve fractional nonlinear partial differential equations
Tarig Projected Differential Transform Method to solve fractional nonlinear partial differential equations
Recent advancement in the field of nonlinear analysis and fractional calculus help to address the rising challenges in the solution of nonlinear fractional partial differential equ...
A generalized integral transform and Adomian decomposition scheme for solving the nonlinear fractional Kuramoto–Sivashinsky equation
A generalized integral transform and Adomian decomposition scheme for solving the nonlinear fractional Kuramoto–Sivashinsky equation
In this work, we approximate the NTFK-S equation, a model that describes a number of chemical and physical phenomena, including hydrodynamics, reaction-diffusion systems, and long ...