Your search keyword '"Shah, Rasool"' showing total 34 results

1. On the Solitary Waves and Nonlinear Oscillations to the Fractional Schrödinger–KdV Equation in the Framework of the Caputo Operator.

Author

Noor, Saima, Alotaibi, Badriah M., Shah, Rasool, Ismaeel, Sherif M. E., and El-Tantawy, Samir A.

Subjects

NONLINEAR oscillations, NONLINEAR waves, FRACTIONAL differential equations, CAPUTO fractional derivatives, NONLINEAR Schrodinger equation, OPERATOR equations, EVOLUTION equations, LAPLACIAN operator, SOLITONS

Abstract

The fractional Schrödinger–Korteweg-de Vries (S-KdV) equation is an important mathematical model that incorporates the nonlinear dynamics of the KdV equation with the quantum mechanical effects described by the Schrödinger equation. Motivated by the several applications of the mentioned evolution equation, in this investigation, the Laplace residual power series method (LRPSM) is employed to analyze the fractional S-KdV equation in the framework of the Caputo operator. By incorporating both the Caputo operator and fractional derivatives into the mentioned evolution equation, we can account for memory effects and non-local behavior. The LRPSM is a powerful analytical technique for the solution of fractional differential equations and therefore it is adapted in our current study. In this study, we prove that the combination of the residual power series expansion with the Laplace transform yields precise and efficient solutions. Moreover, we investigate the behavior and properties of the (un)symmetric solutions to the fractional S-KdV equation using extensive numerical simulations and by considering various fractional orders and initial fractional values. The results contribute to the greater comprehension of the interplay between quantum mechanics and nonlinear dynamics in fractional systems and shed light on wave phenomena and symmetry soliton solutions in such equations. In addition, the proposed method successfully solves fractional differential equations with the Caputo operator, providing a valuable computational instrument for the analysis of complex physical systems. Moreover, the obtained results can describe many of the mysteries associated with the mechanism of nonlinear wave propagation in plasma physics. [ABSTRACT FROM AUTHOR]

Published

2023

2. Numerical Investigation of Fractional-Order Fornberg–Whitham Equations in the Framework of Aboodh Transformation.

Author

Noor, Saima, Hammad, Ma'mon Abu, Shah, Rasool, Alrowaily, Albandari W., and El-Tantawy, Samir A.

Subjects

DECOMPOSITION method, PLASMA physics, NONLINEAR equations, DIFFERENTIAL equations, NONLINEAR waves

Abstract

In this investigation, the fractional Fornberg–Whitham equation (FFWE) is solved and analyzed via the variational iteration method (VIM) and Adomian decomposition method (ADM) with the help of the Aboodh transformation (AT). The FFWE is an important model for describing several nonlinear wave propagations in various fields of science and plasma physics. The AT provides a powerful tool for transforming fractional-order differential equations (DEs) into integer-order ones, making them more amenable to analytical solutions. Accordingly, the main objective of this investigation is to demonstrate the effectiveness and accuracy of ADM and VIM in deriving some approximations for the FFWE. Furthermore, we highlight the advantages and potential applications of these methods in solving other fractional-order nonlinear problems in several scientific fields, especially in plasma physics and some engineering problems. [ABSTRACT FROM AUTHOR]

Published

2023

3. Investigating the Impact of Fractional Non-Linearity in the Klein–Fock–Gordon Equation on Quantum Dynamics.

Author

Noor, Saima, Alshehry, Azzh Saad, Aljahdaly, Noufe H., Dutt, Hina M., Khan, Imran, and Shah, Rasool

Subjects

KLEIN-Gordon equation, QUANTUM theory, PARTICLE spin, DIFFERENTIAL equations, POWER series, FREE convection, LAPLACE transformation

Abstract

In this paper, we investigate the fractional-order Klein–Fock–Gordon equations on quantum dynamics using a new iterative method and residual power series method based on the Caputo operator. The fractional-order Klein–Fock–Gordon equation is a generalization of the traditional Klein–Fock–Gordon equation that allows for non-integer orders of differentiation. This equation has been used in the study of quantum dynamics to model the behavior of particles with fractional spin. The Laplace transform is employed to transform the equations into a simpler form, and the resulting equations are then solved using the proposed methods. The accuracy and efficiency of the method are demonstrated through numerical simulations, which show that the method is superior to existing numerical methods in terms of accuracy and computational time. The proposed method is applicable to a wide range of fractional-order differential equations, and it is expected to find applications in various areas of science and engineering. [ABSTRACT FROM AUTHOR]

Published

2023

4. Numerical Analysis of the Fractional-Order Belousov–Zhabotinsky System.

Author

Yasmin, Humaira, Alshehry, Azzh Saad, Khan, Asfandyar, Shah, Rasool, and Nonlaopon, Kamsing

Subjects

NUMERICAL analysis, NONLINEAR differential equations, DECOMPOSITION method, CHEMICAL kinetics, NONLINEAR systems

Abstract

This paper presents a new approach for finding analytic solutions to the Belousov–Zhabotinsky system by combining the Adomian decomposition method (ADM) and the homotopy perturbation method (HPM) with the Elzaki transform. The ADM and HPM are both powerful techniques for solving nonlinear differential equations, and their combination allows for a more efficient and accurate solution. The Elzaki transform, on the other hand, is a mathematical tool that transforms the system into a simpler form, making it easier to solve. The proposed method is applied to the Belousov–Zhabotinsky system, which is a well-known model for studying nonlinear chemical reactions. The results show that the combined method is capable of providing accurate analytic solutions to the system. Furthermore, the method is also able to capture the complex behavior of the system, such as the formation of oscillatory patterns. Overall, the proposed method offers a promising approach for solving complex nonlinear differential equations, such as those encountered in the field of chemical kinetics. The combination of ADM, HPM, and the Elzaki transform allows for a more efficient and accurate solution, which can provide valuable insights into the behavior of nonlinear systems. [ABSTRACT FROM AUTHOR]

Published

2023

5. Comparative Analysis of Advection–Dispersion Equations with Atangana–Baleanu Fractional Derivative.

Author

Alshehry, Azzh Saad, Yasmin, Humaira, Ghani, Fazal, Shah, Rasool, and Nonlaopon, Kamsing

Subjects

NONLINEAR equations, DECOMPOSITION method, COMPARATIVE studies, EQUATIONS

Abstract

In this study, we solve the fractional advection–dispersion equation (FADE) by applying the Laplace transform decomposition method (LTDM) and the variational iteration transform method (VITM). The Atangana–Baleanu (AB) sense is used to describe the fractional derivative. This equation is utilized to determine solute transport in groundwater and soils. The FADE is converted into a system of non-linear algebraic equations whose solution leads to the approximate solution for this equation using the techniques presented. The proposed approximate method's convergence is examined. The suggested method's applicability is demonstrated by testing it on several illustrative examples. The series solutions to the specified issues are obtained, and they contain components that converge more quickly to the precise solutions. The actual and estimated results are demonstrated in graphs and tables to be quite similar, demonstrating the usefulness of the proposed strategy. The innovation of the current work is in the application of an effective method that requires less calculation and achieves a greater level of accuracy. Furthermore, the proposed approaches may be implemented to prove their utility in tackling fractional-order problems in science and engineering. [ABSTRACT FROM AUTHOR]

Published

2023

6. An Analytical Approach to Solve the Fractional Benney Equation Using the q-Homotopy Analysis Transform Method.

Author

Shah, Rasool, Alkhezi, Yousuf, and Alhamad, Khaled

Subjects

*NONLINEAR differential equations, *PARTIAL differential equations, *NONLINEAR equations, *EQUATIONS, *ANALYTICAL solutions

Abstract

This paper introduces an analytical approach for solving the Benney equation using the q-homotopy analysis transform method. The Benney equation is a nonlinear partial differential equation that has applications in diverse areas of physics and engineering. The q-homotopy analysis transform method is a numerical technique that has been successfully employed to solve a broad range of nonlinear problems. By utilizing this method, we derive approximate analytical solutions for the Benney equation. The results demonstrate that this method is a powerful and effective tool for obtaining accurate solutions for the equation. The proposed method offers a valuable contribution to the existing literature on the behavior of the Benney equation and provides researchers with a useful tool for solving this equation in various applications. [ABSTRACT FROM AUTHOR]

Published

2023

7. Investigating the Dynamics of Time-Fractional Drinfeld–Sokolov–Wilson System through Analytical Solutions.

Author

Noor, Saima, Alshehry, Azzh Saad, Dutt, Hina M., Nazir, Robina, Khan, Asfandyar, and Shah, Rasool

Subjects

ANALYTICAL solutions, NONLINEAR differential equations, WATER waves, FRACTIONAL differential equations

Abstract

This study addresses a nonlinear fractional Drinfeld–Sokolov–Wilson problem in dispersive water waves, which requires appropriate numerical techniques to obtain an approximative solution. The Adomian decomposition approach, the homotopy perturbation method, and Sumudu transform are combined to tackle the problem. The Caputo manner is used to describe fractional derivative, and He's polynomials and Adomian polynomials are employed to address nonlinearity. By following these approaches, we obtain solutions in the form of convergent series. We verify and demonstrate the effectiveness of our suggested strategies by examining the assumed model in terms of fractional order. We use plots for various fractional orders to represent the physical behavior of the suggested technique solutions, and show a numerical simulation. The results demonstrate that the suggested algorithms are systematic, simple to use, effective, and accurate in analyzing the behavior of coupled nonlinear differential equations of fractional order in related scientific and engineering fields. [ABSTRACT FROM AUTHOR]

Published

2023

8. Application of the q-Homotopy Analysis Transform Method to Fractional-Order Kolmogorov and Rosenau–Hyman Models within the Atangana–Baleanu Operator.

Author

Yasmin, Humaira, Alshehry, Azzh Saad, Saeed, Abdulkafi Mohammed, Shah, Rasool, and Nonlaopon, Kamsing

Subjects

DIFFERENTIAL equations, LINEAR equations

Abstract

The q-homotopy analysis transform method (q-HATM) is a powerful tool for solving differential equations. In this study, we apply the q-HATM to compute the numerical solution of the fractional-order Kolmogorov and Rosenau–Hyman models. Fractional-order models are widely used in physics, engineering, and other fields. However, their numerical solutions are difficult to obtain due to the non-linearity and non-locality of the equations. The q-HATM overcomes these challenges by transforming the equations into a series of linear equations that can be solved numerically. The results show that the q-HATM is an effective and accurate method for solving fractional-order models, and it can be used to study a wide range of phenomena in various fields. [ABSTRACT FROM AUTHOR]

Published

2023

9. On the Solutions of the Fractional-Order Sawada–Kotera–Ito Equation and Modeling Nonlinear Structures in Fluid Mediums.

Author

Yasmin, Humaira, Abu Hammad, Ma'mon, Shah, Rasool, Alotaibi, Badriah M., Ismaeel, Sherif. M. E., and El-Tantawy, Samir A.

Subjects

NONLINEAR equations, SHALLOW-water equations, PARTIAL differential equations, FLUID mechanics, FRACTIONAL differential equations, WATER depth

Abstract

This study investigates the wave solutions of the time-fractional Sawada–Kotera–Ito equation (SKIE) that arise in shallow water and many other fluid mediums by utilizing some of the most flexible and high-precision methods. The SKIE is a nonlinear integrable partial differential equation (PDE) with significant applications in shallow water dynamics and fluid mechanics. However, the traditional numerical methods used for analyzing this equation are often plagued by difficulties in handling the fractional derivatives (FDs), which lead to finding other techniques to overcome these difficulties. To address this challenge, the Adomian decomposition (AD) transform method (ADTM) and homotopy perturbation transform method (HPTM) are employed to obtain exact and numerical solutions for the time-fractional SKIE. The ADTM involves decomposing the fractional equation into a series of polynomials and solving each component iteratively. The HPTM is a modified perturbation method that uses a continuous deformation of a known solution to the desired solution. The results show that both methods can produce accurate and stable solutions for the time-fractional SKIE. In addition, we compare the numerical solutions obtained from both methods and demonstrate the superiority of the HPTM in terms of efficiency and accuracy. The study provides valuable insights into the wave solutions of shallow water dynamics and nonlinear waves in plasma, and has important implications for the study of fractional partial differential equations (FPDEs). In conclusion, the method offers effective and efficient solutions for the time-fractional SKIE and demonstrates their usefulness in solving nonlinear integrable PDEs. [ABSTRACT FROM AUTHOR]

Published

2023

10. A Comparative Analysis of Fractional-Order Fokker–Planck Equation.

Author

Mofarreh, Fatemah, Khan, Asfandyar, Shah, Rasool, and Abdeljabbar, Alrazi

Subjects

FOKKER-Planck equation, PARTIAL differential equations, FRACTIONAL differential equations, ENGINEERING mathematics, COMPARATIVE studies, DYNAMICAL systems

Abstract

The importance of partial differential equations in physics, mathematics and engineering cannot be emphasized enough. Partial differential equations are used to represent physical processes, which are then solved analytically or numerically to examine the dynamical behaviour of the system. The new iterative approach and the Homotopy perturbation method are used in this article to solve the fractional order Fokker–Planck equation numerically. The Caputo sense is used to characterize the fractional derivatives. The suggested approach's accuracy and applicability are demonstrated using illustrations. The proposed method's accuracy is expressed in terms of absolute error. The proposed methods are found to be in good agreement with the exact solution of the problems using graphs and tables. The results acquired using the given approaches are also obtained at various fractional orders of the derivative. It is observed from the graphs and tables that fractional order solutions converge to an integer solution when the fractional orders approach the integer-order of the problems. The tabular and graphical view for the given problems is obtained through Maple. The presented approaches can be applied to existing non-linear fractional partial differential equations due to their accurate, simple and straightforward implementation. [ABSTRACT FROM AUTHOR]

Published

2023

11. Laplace Residual Power Series Method for Solving Three-Dimensional Fractional Helmholtz Equations.

Author

Albalawi, Wedad, Shah, Rasool, Nonlaopon, Kamsing, El-Sherif, Lamiaa S., and El-Tantawy, Samir A.

Subjects

*FRACTIONAL differential equations, *PARTIAL differential equations, *HELMHOLTZ equation, *NONLINEAR equations, *POWER series

Abstract

In the present study, the exact solutions of the fractional three-dimensional (3D) Helmholtz equation (FHE) are obtained using the Laplace residual power series method (LRPSM). The fractional derivative is calculated using the Caputo operator. First, we introduce a novel method that combines the Laplace transform tool and the residual power series approach. We specifically give the specifics of how to apply the suggested approach to solve time-fractional nonlinear equations. Second, we use the FHE to evaluate the method's efficacy and validity. Using 2D and 3D plots of the solutions, the derived and precise solutions are compared, confirming the suggested method's improved accuracy. The results for nonfractional approximate and accurate solutions, as well as fractional approximation solutions for various fractional orders, are indicated in the tables. The relationship between the derived solutions and the actual solutions to each problem is examined, showing that the solution converges to the actual solution as the number of terms in the series solution of the problems increases. Two examples are shown to demonstrate the effectiveness of the suggested approach in solving various categories of fractional partial differential equations. It is evident from the estimated values that the procedure is precise and simple and that it can therefore be further extended to linear and nonlinear issues. [ABSTRACT FROM AUTHOR]

Published

2023

12. Investigation of the Time-Fractional Generalized Burgers–Fisher Equation via Novel Techniques.

Author

Alotaibi, Badriah M., Shah, Rasool, Nonlaopon, Kamsing, Ismaeel, Sherif. M. E., and El-Tantawy, Samir A.

Subjects

*MATHEMATICAL physics, *DECOMPOSITION method, *GAS dynamics, *FLUID mechanics, *PLASMA physics, *ADVECTION-diffusion equations

Abstract

Numerous applied mathematics and physical applications, such as the simulation of financial mathematics, gas dynamics, nonlinear phenomena in plasma physics, fluid mechanics, and ocean engineering, utilize the time-fractional generalized Burgers–Fisher equation (TF-GBFE). This equation describes the concept of dissipation and illustrates how reaction systems can be coordinated with advection. To examine and analyze the present evolution equation (TF-GBFE), the modified forms of the Adomian decomposition method (ADM) and homotopy perturbation method (HPM) with Yang transform are utilized. When the results are achieved, they are connected to exact solutions of the σ = 1 order and even for different values of σ to verify the technique's validity. The results are represented as two- and three-dimensional graphs. Additionally, the study of the precise and suggested technique solutions shows that the suggested techniques are very accurate. [ABSTRACT FROM AUTHOR]

Published

2023

13. Analysis and Numerical Simulation of System of Fractional Partial Differential Equations with Non-Singular Kernel Operators.

Author

Alesemi, Meshari, Shahrani, Jameelah S. Al, Iqbal, Naveed, Shah, Rasool, and Nonlaopon, Kamsing

Subjects

PARTIAL differential equations, FRACTIONAL differential equations, NUMERICAL analysis, SIMULATION methods & models, DECOMPOSITION method

Abstract

The exact solution to fractional-order partial differential equations is usually quite difficult to achieve. Semi-analytical or numerical methods are thought to be suitable options for dealing with such complex problems. To elaborate on this concept, we used the decomposition method along with natural transformation to discover the solution to a system of fractional-order partial differential equations. Using certain examples, the efficacy of the proposed technique is demonstrated. The exact and approximate solutions were shown to be in close contact in the graphical representation of the obtained results. We also examine whether the proposed method can achieve a quick convergence with a minimal number of calculations. The present approaches are also used to calculate solutions in various fractional orders. It has been proven that fractional-order solutions converge to integer-order solutions to problems. The current technique can be modified for various fractional-order problems due to its simple and straightforward implementation. [ABSTRACT FROM AUTHOR]

Published

2023

14. Investigation of Fractional Nonlinear Regularized Long-Wave Models via Novel Techniques.

Author

Naeem, Muhammad, Yasmin, Humaira, Shah, Rasool, Shah, Nehad Ali, and Nonlaopon, Kamsing

Subjects

NONLINEAR differential equations, FRACTIONAL differential equations, DECOMPOSITION method, INFINITE series (Mathematics), PLASMA waves, SHALLOW-water equations, WAVE equation, MATHEMATICAL regularization

Abstract

The main goal of the current work is to develop numerical approaches that use the Yang transform, the homotopy perturbation method (HPM), and the Adomian decomposition method to analyze the fractional model of the regularized long-wave equation. The shallow-water waves and ion-acoustic waves in plasma are both explained by the regularized long-wave equation. The first method combines the Yang transform with the homotopy perturbation method and He's polynomials. In contrast, the second method combines the Yang transform with the Adomian polynomials and the decomposition method. The Caputo sense is applied to the fractional derivatives. The strategy's effectiveness is shown by providing a variety of fractional and integer-order graphs and tables. To confirm the validity of each result, the technique was substituted into the equation. The described methods can be used to find the solutions to these kinds of equations as infinite series, and when these series are in closed form, they give the precise solution. The results support the claim that this approach is simple, strong, and efficient for obtaining exact solutions for nonlinear fractional differential equations. The method is a strong contender to contribute to the existing literature. [ABSTRACT FROM AUTHOR]

Published

2023

15. On the Solution of Fractional Biswas–Milovic Model via Analytical Method.

Author

Sunthrayuth, Pongsakorn, Naeem, Muhammad, Shah, Nehad Ali, Shah, Rasool, and Chung, Jae Dong

Subjects

MATHEMATICAL models, INTEGRATED software, INFINITE series (Mathematics), COMPUTER simulation, POLYNOMIALS, EQUATIONS

Abstract

Through the use of a unique approach, we study the fractional Biswas–Milovic model with Kerr and parabolic law nonlinearities in this paper. The Caputo approach is used to take the fractional derivative. The method employed here is the homotopy perturbation transform method (HPTM), which combines the homotopy perturbation method (HPM) and Yang transform (YT). The HPTM combines the homotopy perturbation method, He's polynomials, and the Yang transform. He's polynomial is a wonderful tool for dealing with nonlinear terms. To confirm the validity of each result, the technique was substituted into the equation. The described techniques can be used to find the solutions to these kinds of equations as infinite series, and when these series are in closed form, they give a precise solution. Graphs are used to show the derived numerical results. The maple software package is used to carry out the numerical simulation work. The results of this research are highly positive and demonstrate how effective the suggested method is for mathematical modeling of natural occurrences. [ABSTRACT FROM AUTHOR]

Published

2023

16. A Comparative Study of Fractional Partial Differential Equations with the Help of Yang Transform.

Author

Naeem, Muhammad, Yasmin, Humaira, Shah, Rasool, Shah, Nehad Ali, and Chung, Jae Dong

Subjects

FRACTIONAL differential equations, NUMERICAL solutions to differential equations, FRACTIONAL calculus, DECOMPOSITION method, APPLIED sciences, COMPARATIVE studies

Abstract

In applied sciences and engineering, partial differential equations (PDE) of integer and non-integer order play a crucial role. It can be challenging to determine these equations' exact solutions. As a result, developing numerical approaches to obtain precise numerical solutions to these kinds of differential equations takes time. The homotopy perturbation transform method (HPTM) and Yang transform decomposition method (YTDM) are the subjects of several recent findings that we describe. These techniques work well for fractional calculus applications. We also examine fractional differential equations' precise and approximative solutions. The Caputo derivative is employed because it enables the inclusion of traditional initial and boundary conditions in the formulation of the issue. This has major implications for complicated problems. The paper lists the important characteristics of the YTDM and HPTM. Our research has numerous applications in the disciplines of science and engineering and might be seen as a substitute for current methods. [ABSTRACT FROM AUTHOR]

Published

2023

17. An Efficient Analytical Method for Analyzing the Nonlinear Fractional Klein–Fock–Gordon Equations.

Author

Alyousef, Haifa A., Shah, Rasool, Nonlaopon, Kamsing, El-Sherif, Lamiaa S., and El-Tantawy, Samir A.

Subjects

*KLEIN-Gordon equation, *ACCOUNTING methods

Abstract

The purpose of this article is to solve a nonlinear fractional Klein–Fock–Gordon equation that involves a recently created non-singular kernel fractional derivative by Caputo–Fabrizio. Motivated by some physical applications related to the fractional Klein–Fock–Gordon equation, we focus our study on this equation and some phenomena rated to it. The findings are crucial and essential for explaining a variety of physical processes. In order to find satisfactory approximations to the offered problems, this work takes into account a modern methodology and fractional operator in this context. We first take the Yang transform of the Caputo–Fabrizio fractional derivative and then implement it to solve fractional Klein–Fock–Gordon equations. We will consider three cases of the nonlinear fractional Klein–Fock–Gordon equation to ensure the applicability and effectiveness of the suggested technique. In order to determine an approximate solution to the fractional Klein–Fock–Gordon equation in the fast convergent series form, we can use the fractional homotopy perturbation transform approach. The numerical simulation is provided to demonstrate the effectiveness and dependability of the suggested method. Furthermore, several fractional orders will be used to describe the behavior of the given solutions. The results achieved demonstrate the high efficiency, ease of use, and applicability of this strategy for resolving other nonlinear issues. [ABSTRACT FROM AUTHOR]

Published

2022

18. Numerical Simulations of the Fractional Systems of Volterra Integral Equations within the Chebyshev Pseudo-Spectral Method.

Author

Sunthrayuth, Pongsakorn, Naeem, Muhammad, Shah, Nehad Ali, Shah, Rasool, and Chung, Jae Dong

Subjects

VOLTERRA equations, NONLINEAR equations, SIMULATION methods & models, COMPUTER simulation, CHEBYSHEV systems

Abstract

In this article, we find the solutions to fractional Volterra-type integral equation nonlinear systems through a Chebyshev pseudo-spectral method (CPM). The fractional derivative is described in the Caputo manner. The suggested method's accuracy and reliability are confirmed by the results. The proposed method is implemented for solving various nonlinear systems; the results we obtained were compared with the exact solution and other method solutions. The graphical representation and tables show that our method's error quickly converges as compared to other methods. By comparing the proposed method's solution with the actual solution and other methods, we can confirm that CPM is more accurate and closer to the exact solution. We display the pointwise solution in the tables, which verifies the proposed method's accuracy at each point and aids in a better comprehension of the suggested approach. Moreover, the results of using the suggested method at different fractional orders are examined, showing that when a value moves from a fractional order to an integer order, the result is closer to the precise solution. Furthermore, the proposed technique for handling fractional-order linear and non-linear physical problems in science and engineering is straightforward to implement. [ABSTRACT FROM AUTHOR]

Published

2022

19. Evaluation of Fractional-Order Pantograph Delay Differential Equation via Modified Laguerre Wavelet Method.

Author

Alderremy, Aisha Abdullah, Shah, Rasool, Shah, Nehad Ali, Aly, Shaban, and Nonlaopon, Kamsing

Subjects

*PANTOGRAPH, *NONLINEAR differential equations, *DELAY differential equations, *NUMERICAL analysis, *WAVELET transforms, *WAVELETS (Mathematics)

Abstract

Wavelet transforms or wavelet analysis represent a recently created mathematical tool for assistance in resolving various issues. Wavelets can also be used in numerical analysis. In this study, we solve pantograph delay differential equations using the Modified Laguerre Wavelet method (MLWM), an effective numerical technique. Fractional derivatives are defined using the Caputo operator. The convergence of the suggested strategy is carefully examined. The suggested strategy is straightforward, effective, and simple in comparison with previous approaches. Specific examples are provided to demonstrate the current scenario's reliability and accuracy. Compared with other methodologies, our results show a higher accuracy level. With the aid of tables and graphs, we demonstrate the effectiveness of the proposed approach by comparing results of the actual and suggested methods and demonstrating their strong agreement. For better understanding of the proposed method, we show the pointwise solution in the tables provided which confirm the accuracy at each point of the proposed method. Additionally, the results of employing the suggested method to various fractional-orders are compared, which demonstrates that when a value shifts from fractional-order to integer-order, the result approaches the exact solution. Owing to its novelty and scientific significance, the suggested technique can also be used to solve additional nonlinear delay differential equations of fractional-order. [ABSTRACT FROM AUTHOR]

Published

2022

20. Fractional View Analysis of Emden-Fowler Equations with the Help of Analytical Method.

Author

Botmart, Thongchai, Naeem, Muhammad, Shah, Rasool, and Iqbal, Naveed

Subjects

DECOMPOSITION method, EQUATIONS, MATHEMATICAL models

Abstract

This work aims at a new semi-analytical technique called the Adomian decomposition method for the analysis of time-fractional Emden–Fowler equations. The Laplace transformation and the iterative method are implemented to obtain the result of the given models. The suggested technique has the edge over other methods, as it does not need extra materials and calculations. The presented technique validity is demonstrated by examining four mathematical models. Due to the straightforward implementation, the proposed method can solve other non-linear fractional order problems. [ABSTRACT FROM AUTHOR]

Published

2022

21. Fractional View Analysis of Fornberg–Whitham Equations by Using Elzaki Transform.

Author

Haroon, Faisal, Mukhtar, Safyan, and Shah, Rasool

Subjects

DECOMPOSITION method, EQUATIONS, ANALYTICAL solutions

Abstract

We present analytical solutions of the Fornberg–Whitham equations with the aid of two well-known methods: Adomian decomposition transform and variational iteration transform involving fractional-order derivatives with the Atangana–Baleanu–Caputo derivative. The Elzaki transformation is used in the Atangana–Baleanu–Caputo derivative to find the solution to the Fornberg–Whitham equations. Using certain exemplary situations, the proposed method's viability is assessed. Comparative analysis for both integer and fractional-order results is established. For validation, the solutions of the suggested methods are compared with the actual results available in the literature. Two examples are considered to check the accuracy and effectiveness of the proposed techniques. [ABSTRACT FROM AUTHOR]

Published

2022

22. Fractional Series Solution Construction for Nonlinear Fractional Reaction-Diffusion Brusselator Model Utilizing Laplace Residual Power Series.

Author

Alderremy, Aisha Abdullah, Shah, Rasool, Iqbal, Naveed, Aly, Shaban, and Nonlaopon, Kamsing

Subjects

*POWER series, *PARTIAL differential equations, *FRACTIONAL differential equations, *LAPLACE transformation, *APPLIED sciences

Abstract

This article investigates different nonlinear systems of fractional partial differential equations analytically using an attractive modified method known as the Laplace residual power series technique. Based on a combination of the Laplace transformation and the residual power series technique, we achieve analytic and approximation results in rapid convergent series form by employing the notion of the limit, with less time and effort than the residual power series method. Three challenges are evaluated and simulated to validate the suggested method's practicability, efficiency, and simplicity. The analysis of the acquired findings demonstrates that the method mentioned above is simple, accurate, and appropriate for investigating the solutions to nonlinear applied sciences models. [ABSTRACT FROM AUTHOR]

Published

2022

23. Fractional-View Analysis of Fokker-Planck Equations by ZZ Transform with Mittag-Leffler Kernel.

Author

Saad Alshehry, Azzh, Imran, Muhammad, Shah, Rasool, and Weera, Wajaree

Subjects

FOKKER-Planck equation, DECOMPOSITION method, PHENOMENOLOGICAL theory (Physics), ANALYTICAL solutions, MATHEMATICAL models

Abstract

This work combines a ZZ transformation with the Adomian decomposition method to solve the fractional-order Fokker-Planck equations. The fractional derivative is represented in the Atangana-Baleanu derivative. It is looked at with graphs that show that the accurate and estimated results are close to each other, indicating that the method works. Fractional-order solutions are the most in line with the dynamics of the targeted problems, and they provide an endless number of options for an optimal mathematical model solution for a particular physical phenomenon. This analytical approach produces a series type result that quickly converges to actual answers. The acquired outcomes suggest that the novel analytical solution method is simple to use and very successful at assessing complicated equations that occur in related research and engineering fields. [ABSTRACT FROM AUTHOR]

Published

2022

24. A Semi-Analytical Method to Investigate Fractional-Order Gas Dynamics Equations by Shehu Transform.

Author

Shah, Rasool, Saad Alshehry, Azzh, and Weera, Wajaree

Subjects

*GAS dynamics, *EQUATIONS, *PROBLEM solving, *NONLINEAR equations

Abstract

This work aims at a new semi-analytical method called the variational iteration transformation method for solving nonlinear homogeneous and nonhomogeneous fractional-order gas dynamics equations. The Shehu transformation and the iterative technique are applied to solve the suggested problems. The proposed method has an advantage over existing approaches because it does not require additional materials or computations. Four problems are used to test the authenticity of the proposed method. Using the suggested method, the solution proves to be more accurate. The proposed method can be implemented to solve many nonlinear fractional order problems because it has a straightforward implementation. [ABSTRACT FROM AUTHOR]

Published

2022

25. Fractional View Analysis of Kuramoto–Sivashinsky Equations with Non-Singular Kernel Operators.

Author

Saad Alshehry, Azzh, Imran, Muhammad, Khan, Adnan, Shah, Rasool, and Weera, Wajaree

Subjects

DECOMPOSITION method, EQUATIONS, PHENOMENOLOGICAL theory (Physics), ANALYTICAL solutions, SCIENTIFIC models

Abstract

In this article, we investigate the nonlinear model describing the various physical and chemical phenomena named the Kuramoto–Sivashinsky equation. We implemented the natural decomposition method, a novel technique, mixed with the Caputo–Fabrizio (CF) and Atangana–Baleanu deriavatives in Caputo manner (ABC) fractional derivatives for obtaining the approximate analytical solution of the fractional Kuramoto–Sivashinsky equation (FKS). The proposed method gives a series form solution which converges quickly towards the exact solution. To show the accuracy of the proposed method, we examine three different cases. We presented proposed method results by means of graphs and tables to ensure proposed method validity. Further, the behavior of the achieved results for the fractional order is also presented. The results we obtain by implementing the proposed method shows that our technique is extremely efficient and simple to investigate the behaviour of nonlinear models found in science and technology. [ABSTRACT FROM AUTHOR]

Published

2022

26. Analysis of the Fractional-Order Local Poisson Equation in Fractal Porous Media.

Author

Alqhtani, Manal, Saad, Khaled M., Shah, Rasool, Weera, Wajaree, and Hamanah, Waleed M.

Subjects

ELLIPTIC differential equations, FRACTAL analysis, POISSON'S equation, POROUS materials, PARTIAL differential equations, FRACTIONAL differential equations, COMPUTATIONAL electromagnetics

Abstract

This paper investigates the fractional local Poisson equation using the homotopy perturbation transformation method. The Poisson equation discusses the potential area due to a provided charge with the possibility of area identified, and one can then determine the electrostatic or gravitational area in the fractal domain. Elliptic partial differential equations are frequently used in the modeling of electromagnetic mechanisms. The Poisson equation is investigated in this work in the context of a fractional local derivative. To deal with the fractional local Poisson equation, some illustrative problems are discussed. The solution shows the well-organized and straightforward nature of the homotopy perturbation transformation method to handle partial differential equations having fractional derivatives in the presence of a fractional local derivative. The solutions obtained by the defined methods reveal that the proposed system is simple to apply, and the computational cost is very reliable. The result of the fractional local Poisson equation yields attractive outcomes, and the Poisson equation with a fractional local derivative yields improved physical consequences. [ABSTRACT FROM AUTHOR]

Published

2022

27. The Numerical Investigation of a Fractional-Order Multi-Dimensional Model of Navier–Stokes Equation via Novel Techniques.

Author

Mukhtar, Safyan, Shah, Rasool, and Noor, Saima

Subjects

*NAVIER-Stokes equations, *DECOMPOSITION method

Abstract

In this study, numerical results of a fractional-order multi-dimensional model of the Navier–Stokes equations will be achieved via adoption of two analytical methods, i.e., the Adomian decomposition transform method and the q-Homotopy analysis transform method. The Caputo–Fabrizio operator will be used to define the fractional derivative. The proposed methods will be implemented to provide the series form results of the given models. The series form results of proposed techniques will be validated with the exact results available in the literature. The proposed techniques will be investigated to be efficient, straightforward, and reliable for application to many other scientific and engineering problems. [ABSTRACT FROM AUTHOR]

Published

2022

28. A Comparative Analysis of Fractional-Order Kaup–Kupershmidt Equation within Different Operators.

Author

Shah, Nehad Ali, Hamed, Yasser S., Abualnaja, Khadijah M., Chung, Jae-Dong, Shah, Rasool, and Khan, Adnan

Subjects

GRAVITY waves, CAPILLARY waves, DECOMPOSITION method, COMPARATIVE studies, NONLINEAR waves

Abstract

In this paper, we find the solution of the fractional-order Kaup–Kupershmidt (KK) equation by implementing the natural decomposition method with the aid of two different fractional derivatives, namely the Atangana–Baleanu derivative in Caputo manner (ABC) and Caputo–Fabrizio (CF). When investigating capillary gravity waves and nonlinear dispersive waves, the KK equation is extremely important. To demonstrate the accuracy and efficiency of the proposed technique, we study the nonlinear fractional KK equation in three distinct cases. The results are given in the form of a series, which converges quickly. The numerical simulations are presented through tables to illustrate the validity of the suggested technique. Numerical simulations in terms of absolute error are performed to ensure that the proposed methodologies are trustworthy and accurate. The resulting solutions are graphically shown to ensure the applicability and validity of the algorithms under consideration. The results that we obtain confirm that the proposed method is the best tool for handling any nonlinear problems arising in science and technology. [ABSTRACT FROM AUTHOR]

Published

2022

29. Analytical Investigation of Fractional-Order Korteweg–De-Vries-Type Equations under Atangana–Baleanu–Caputo Operator: Modeling Nonlinear Waves in a Plasma and Fluid.

Author

Shah, Nehad Ali, Alyousef, Haifa A., El-Tantawy, Samir A., Shah, Rasool, and Chung, Jae Dong

Subjects

PLASMA waves, NONLINEAR waves, WAVES (Fluid mechanics), NONLINEAR operators, EQUATIONS

Abstract

This article applies the homotopy perturbation transform technique to analyze fractional-order nonlinear fifth-order Korteweg–de-Vries-type (KdV-type)/Kawahara-type equations. This method combines the Zain Ul Abadin Zafar-transform (ZZ-T) and the homotopy perturbation technique (HPT) to show the validation and efficiency of this technique to investigate three examples. It is also shown that the fractional and integer-order solutions have closed contact with the exact result. The suggested technique is found to be reliable, efficient, and straightforward to use for many related models of engineering and several branches of science, such as modeling nonlinear waves in different plasma models. [ABSTRACT FROM AUTHOR]

Published

2022

30. Numerical Investigation of Fractional-Order Swift–Hohenberg Equations via a Novel Transform.

Author

Nonlaopon, Kamsing, Alsharif, Abdullah M., Zidan, Ahmed M., Khan, Adnan, Hamed, Yasser S., and Shah, Rasool

Subjects

CONVECTIVE flow, DECOMPOSITION method, PARTIAL differential equations, LIQUID surfaces, EQUATIONS, WIENER processes

Abstract

In this paper, the Elzaki transform decomposition method is implemented to solve the time-fractional Swift–Hohenberg equations. The presented model is related to the temperature and thermal convection of fluid dynamics, which can also be used to explain the formation process in liquid surfaces bounded along a horizontally well-conducting boundary. In the Caputo manner, the fractional derivative is described. The suggested method is easy to implement and needs a small number of calculations. The validity of the presented method is confirmed from the numerical examples. Illustrative figures are used to derive and verify the supporting analytical schemes for fractional-order of the proposed problems. It has been confirmed that the proposed method can be easily extended for the solution of other linear and non-linear fractional-order partial differential equations. [ABSTRACT FROM AUTHOR]

Published

2021

31. A Novel Analytical View of Time-Fractional Korteweg-De Vries Equations via a New Integral Transform.

Author

Rashid, Saima, Khalid, Aasma, Sultana, Sobia, Hammouch, Zakia, Shah, Rasool, and Alsharif, Abdullah M.

Subjects

KORTEWEG-de Vries equation, DECOMPOSITION method, NONLINEAR waves, INTEGRAL transforms, CAPUTO fractional derivatives, NONLINEAR equations

Abstract

We put into practice relatively new analytical techniques, the Shehu decomposition method and the Shehu iterative transform method, for solving the nonlinear fractional coupled Korteweg-de Vries (KdV) equation. The KdV equation has been developed to represent a broad spectrum of physics behaviors of the evolution and association of nonlinear waves. Approximate-analytical solutions are presented in the form of a series with simple and straightforward components, and some aspects show an appropriate dependence on the values of the fractional-order derivatives that are, in a certain sense, symmetric. The fractional derivative is proposed in the Caputo sense. The uniqueness and convergence analysis is carried out. To comprehend the analytical procedure of both methods, three test examples are provided for the analytical results of the time-fractional KdV equation. Additionally, the efficiency of the mentioned procedures and the reduction in calculations provide broader applicability. It is also illustrated that the findings of the current methodology are in close harmony with the exact solutions. It is worth mentioning that the proposed methods are powerful and are some of the best procedures to tackle nonlinear fractional PDEs. [ABSTRACT FROM AUTHOR]

Published

2021

32. A New Analysis of Fractional-Order Equal-Width Equations via Novel Techniques.

Author

Naeem, Muhammad, Zidan, Ahmed M., Nonlaopon, Kamsing, Syam, Muhammad I., Al-Zhour, Zeyad, Shah, Rasool, and Awrejcewicz, Jan

Subjects

MAGNETOHYDRODYNAMIC waves, LOW temperature plasmas, PLASMA waves, EQUATIONS

Abstract

In this paper, the new iterative transform method and the homotopy perturbation transform method was used to solve fractional-order Equal-Width equations with the help of Caputo-Fabrizio. This method combines the Laplace transform with the new iterative transform method and the homotopy perturbation method. The approximate results are calculated in the series form with easily computable components. The fractional Equal-Width equations play an essential role in describe hydromagnetic waves in cold plasma. Our object is to study the nonlinear behaviour of the plasma system and highlight the critical points. The techniques are very reliable, effective, and efficient, which can solve a wide range of problems arising in engineering and sciences. [ABSTRACT FROM AUTHOR]

Published

2021

33. The Comparative Study for Solving Fractional-Order Fornberg–Whitham Equation via ρ -Laplace Transform.

Author

Sunthrayuth, Pongsakorn, Zidan, Ahmed M., Yao, Shao-Wen, Shah, Rasool, and Inc, Mustafa

Subjects

COMPARATIVE studies, EQUATIONS, PARTIAL differential equations

Abstract

In this article, we also introduced two well-known computational techniques for solving the time-fractional Fornberg–Whitham equations. The methods suggested are the modified form of the variational iteration and Adomian decomposition techniques by ρ -Laplace. Furthermore, an illustrative scheme is introduced to verify the accuracy of the available methods. The graphical representation of the exact and derived results is presented to show the suggested approaches reliability. The comparative solution analysis via graphs also represented the higher reliability and accuracy of the current techniques. [ABSTRACT FROM AUTHOR]

Published

2021

34. Laplace Adomian Decomposition Method for Multi Dimensional Time Fractional Model of Navier-Stokes Equation.

Author

Mahmood, Shahid, Shah, Rasool, khan, Hassan, and Arif, Muhammad

Subjects

*LAPLACE transformation, *DECOMPOSITION method, *NAVIER-Stokes equations, *CAPUTO fractional derivatives, *APPROXIMATION theory

Abstract

In this research paper, a hybrid method called Laplace Adomian Decomposition Method (LADM) is used for the analytical solution of the system of time fractional Navier-Stokes equation. The solution of this system can be obtained with the help of Maple software, which provide LADM algorithm for the given problem. Moreover, the results of the proposed method are compared with the exact solution of the problems, which has confirmed, that as the terms of the series increases the approximate solutions are convergent to the exact solution of each problem. The accuracy of the method is examined with help of some examples. The LADM, results have shown that, the proposed method has higher rate of convergence as compare to ADM and HPM. [ABSTRACT FROM AUTHOR]

Published

2019