Your search keyword '"Awadalla P"' showing total 13 results

1. Post-Pandemic Sector-Based Investment Model Using Generalized Liouville–Caputo Type

Author

Muath Awadalla, Muthaiah Subramanian, Prakash Madheshwaran, and Kinda Abuasbeh

Subjects

investment mathematical model, pandemic circumstances, Euler technique, generalized Liouville-Caputo, existence, Ulam—Hyers stability, Mathematics, QA1-939

Abstract

In this article, Euler’s technique was employed to solve the novel post-pandemic sector-based investment mathematical model. The solution was established within the framework of the new generalized Caputo-type fractional derivative for the system under consideration that serves as an example of the investment model. The mathematical investment model consists of a system of four fractional-order nonlinear differential equations of the generalized Liouville–Caputo type. Moreover, the existence and uniqueness of solutions for the above fractional order model under pandemic situations were investigated using the well-known Schauder and Banach fixed-point theorem technique. The stability analysis in the context of Ulam—Hyers and generalized Ulam—Hyers criteria was also discussed. Using the investment model under consideration, a new analysis was conducted. Figures that depict the behavior of the classes of the projected model were used to discuss the obtained results. The demonstrated results of the employed technique are extremely emphatic and simple to apply to the system of non-linear equations. When a generalized Liouville–Caputo fractional derivative parameter (ρ) is changed, the results are asymmetric. The current work can attest to the novel generalized Caputo-type fractional operator’s suitability for use in mathematical epidemiology and real-world problems towards the future pandemic circumstances.

Published

2023

2. A Method for Solving Time-Fractional Initial Boundary Value Problems of Variable Order

Author

Kinda Abuasbeh, Asia Kanwal, Ramsha Shafqat, Bilal Taufeeq, Muna A. Almulla, and Muath Awadalla

Subjects

Caputo derivative, fractional calculus, finite difference, fractional-order, initial boundary value problems, stability analysis, Mathematics, QA1-939

Abstract

Various scholars have lately employed a wide range of strategies to resolve specific types of symmetrical fractional differential equations. This paper introduces a new implicit finite difference method with variable-order time-fractional Caputo derivative to solve semi-linear initial boundary value problems. Despite its extensive use in other areas, fractional calculus has only recently been applied to physics. This paper aims to find a solution for the fractional diffusion equation using an implicit finite difference scheme, and the results are displayed graphically using MATLAB and the Fourier technique to assess stability. The findings show the unconditional stability of the implicit time-fractional finite difference method. This method employs a variable-order fractional derivative of time, enabling greater flexibility and the ability to tackle more complicated problems.

Published

2023

3. Mild Solutions for the Time-Fractional Navier-Stokes Equations with MHD Effects

Author

Kinda Abuasbeh, Ramsha Shafqat, Azmat Ullah Khan Niazi, and Muath Awadalla

Subjects

Navier-Stokes equations, Caputo fractional derivative, Mittag-Leffler functions, mild solutions, regularity, Mathematics, QA1-939

Abstract

Recently, various techniques and methods have been employed by mathematicians to solve specific types of fractional differential equations (FDEs) with symmetric properties. The study focuses on Navier-Stokes equations (NSEs) that involve MHD effects with time-fractional derivatives (FDs). The (NSEs) with time-FDs of order β∈(0,1) are investigated. To facilitate anomalous diffusion in fractal media, mild solutions and Mittag-Leffler functions are used. In Hδ,r, the existence, and uniqueness of local and global mild solutions are proved, as well as the symmetric structure created. Moderate local solutions are provided in Jr. Moreover, the regularity and existence of classical solutions to the equations in Jr. are established and presented.

Published

2023

4. Analysis of the Mathematical Modelling of COVID-19 by Using Mild Solution with Delay Caputo Operator

Author

Kinda Abuasbeh, Ramsha Shafqat, Ammar Alsinai, and Muath Awadalla

Subjects

COVID-19, fractional epidemic model, Caputo operator, existence and uniqueness, numerical simulations, Mathematics, QA1-939

Abstract

This work investigates a mathematical fractional-order model that depicts the Caputo growth of a new coronavirus (COVID-19). We studied the existence and uniqueness of the linked solution using the fixed point theory method. Using the Laplace Adomian decomposition method (LADM), we explored the precise solution of our model and obtained results that are stated in terms of infinite series. Numerical data were then used to demonstrate the use of the new derivative and the symmetric structure that we created. When compared to the traditional order derivatives, our results under the new hypothesis show that the innovative coronavirus model performs better.

Published

2023

5. Analysis of Controllability of Fractional Functional Random Integroevolution Equations with Delay

Author

Kinda Abuasbeh, Ramsha Shafqat, Ammar Alsinai, and Muath Awadalla

Subjects

random fixed point, state dependent delay, controllability, functional differential equation, mild solution, finite delay, Mathematics, QA1-939

Abstract

Various scholars have lately employed a wide range of strategies to resolve two specific types of symmetrical fractional differential equations. The evolution of a number of real-world systems in the physical and biological sciences exhibits impulsive dynamical features that can be represented via impulsive differential equations. In this paper, we explore some existence and controllability theories for the Caputo order q∈(1,2) of delay- and random-effect-affected fractional functional integroevolution equations (FFIEEs). In order to prove that random solutions exist, we must prove a random fixed point theorem using a stochastic domain and the mild solution. Then we demonstrate that our solutions are controllable. At the end, applications and example is illustrated which indicates the applicability of this manuscript.

Published

2023

6. A Novel Three-Step Numerical Solver for Physical Models under Fractal Behavior

Author

Muath Awadalla, Sania Qureshi, Amanullah Soomro, and Kinda Abuasbeh

Subjects

convergence analysis, fractals, efficiency index, symmetric twisting of polynomiographs, Newton’s method, Mathematics, QA1-939

Abstract

In this paper, we suggest an iterative method for solving nonlinear equations that can be used in the physical sciences. This response is broken down into three parts. Our methodology is inspired by both the standard Taylor’s method and an earlier Halley’s method. Three evaluations of the given function and two evaluations of its first derivative are all that are needed for each iteration with this method. Because of this, the unique methodology can complete its goal far more quickly than many of the other methods currently in use. We looked at several additional practical research models, including population growth, blood rheology, and neurophysiology. Polynomiographs can be used to show the convergence zones of certain polynomials with complex values. Polynomiographs are produced as a byproduct, and these end up having an appealing look and being artistically engaging. The twisting of polynomiographs is symmetric when the parameters are all real and asymmetric when some of the parameters are imaginary.

Published

2023

7. Existence of Global and Local Mild Solution for the Fractional Navier–Stokes Equations

Author

Muath Awadalla, Azhar Hussain, Farva Hafeez, and Kinda Abuasbeh

Subjects

Navier–Stokes equations, Caputo fractional derivatives, mild solutions, regularity, Mathematics, QA1-939

Abstract

Navier–Stokes equations (NS-equations) are applied extensively for the study of various waves phenomena where the symmetries are involved. In this paper, we discuss the NS-equations with the time-fractional derivative of order β∈(0,1). In fractional media, these equations can be utilized to recreate anomalous diffusion equations which can be used to construct symmetries. We examine the initial value problem involving the symmetric Stokes operator and gravitational force utilizing the Caputo fractional derivative. Additionally, we demonstrate the global and local mild solutions in Hα,p. We also demonstrate the regularity of classical solutions in such circumstances. An example is presented to demonstrate the reliability of our findings.

Published

2023

8. Entropy Generation for MHD Peristaltic Transport of Non-Newtonian Fluid in a Horizontal Symmetric Divergent Channel

Author

Kinda Abuasbeh, Bilal Ahmed, Azmat Ullah Khan Niazi, and Muath Awadalla

Subjects

peristaltic flow, Ree–Eyring fluid, entropy generation, magnetic field, Mathematics, QA1-939

Abstract

The analysis in view is proposed to investigate the impacts of entropy in the peristaltically flown Ree–Eyring fluid under the stress of a normally imposed uniform magnetic field in a non-uniform symmetric channel of varying thickness. The administering equations of the present flow problem are switched into the non-dimensional form and then reduced by the availing of long wavelengths and creeping flow regime restrictions. The analytical treatment for the developed problem is performed to attain closed-form solutions which are further displayed as graphs of velocity, pressure, temperature, and entropy distribution. The trapping phenomenon has also been an area of our current examination. The role of relevant pronounced parameters such as the Brinkmann number, Hartmann number, and Ree–Eyring parameter for throwing vivid impacts are also concerned. It has been inferred that both the Brinkmann number and Ree–Eyring parameter with rising values inflate temperature and entropy profiles. The velocity profile shows the symmetric nature due to the horizontally assumed symmetric channel of varying thickness. The circulation of streamlines and bolus formations is visibly reduced in response to the increasing Hartmann number.

Published

2023

9. Existence and Ulam–Hyers Stability Results for a System of Coupled Generalized Liouville–Caputo Fractional Langevin Equations with Multipoint Boundary Conditions

Author

Muath Awadalla, Muthaiah Subramanian, and Kinda Abuasbeh

Subjects

coupled system, Langevin equations, generalized fractional integrals, generalized fractional derivatives, stability, existence, Mathematics, QA1-939

Abstract

We study the existence and uniqueness of solutions for coupled Langevin differential equations of fractional order with multipoint boundary conditions involving generalized Liouville–Caputo fractional derivatives. Furthermore, we discuss Ulam–Hyers stability in the context of the problem at hand. The results are shown with examples. Results are asymmetric when a generalized Liouville–Caputo fractional derivative (ρ) parameter is changed.

Published

2023

10. On a System of Coupled Langevin Equations in the Frame of Generalized Liouville–Caputo Fractional Derivatives

Author

Hassan J. Al Salman, Muath Awadalla, Muthaiah Subramanian, and Kinda Abuasbeh

Subjects

coupled system, Langevin equations, Katugampola integrals, generalized Liouville–Caputo derivatives, stability, existence, Mathematics, QA1-939

Abstract

We investigate the existence and uniqueness results for coupled Langevin differential equations of fractional order with Katugampola integral boundary conditions involving generalized Liouville–Caputo fractional derivatives. Furthermore, we discuss Ulam–Hyers stability in the context of the problem at hand. The results are shown with examples. Results are asymmetric when a generalised Liouville–Caputo fractional derivative (ρ) parameter is changed. With its novel results, this paper makes a significant contribution to the relevant literature.

Published

2023

11. Applicability of Mönch’s Fixed Point Theorem on a System of (k, ψ)-Hilfer Type Fractional Differential Equations

Author

Emad Fadhal, Kinda Abuasbeh, Murugesan Manigandan, and Muath Awadalla

Subjects

generalized Hilfer derivative, existence, mixed boundary conditions, Ulam–Hyers stability, Mathematics, QA1-939

Abstract

In this article, we study a system of Hilfer (k,ψ)-fractional differential equations, subject to nonlocal boundary conditions involving Hilfer (k,ψ)-derivatives and (k,ψ)-integrals. The results for the mentioned system are established by using Mönch’s fixed point theorem, then the Ulam–Hyers technique is used to verify the stability of the solution for the proposed system. In general, symmetry and fractional differential equations are related to each other. When a generalized Hilfer fractional derivative is modified, asymmetric results are obtained. This study concludes with an applied example illustrating the existence results obtained by Mönch’s theorem.

Published

2022

12. Extraction of Exact Solutions of Higher Order Sasa-Satsuma Equation in the Sense of Beta Derivative

Author

Emad Fadhal, Arzu Akbulut, Melike Kaplan, Muath Awadalla, and Kinda Abuasbeh

Subjects

beta derivative, sasa satsuma equation, wave transformations, exact solutions, Mathematics, QA1-939

Abstract

Nearly every area of mathematics, natural, social, and engineering now includes research into finding exact answers to nonlinear fractional differential equations (NFDES). In order to discover the exact solutions to the higher order Sasa-Satsuma equation in the sense of the beta derivative, the paper will discuss the modified simple equation (MSE) and exponential rational function (ERF) approaches. In general, symmetry and travelling wave solutions of the Sasa-Satsuma equation have a common correlation with each other, thus we reduce equations from wave transformations to ordinary differential equations with the help of Lie symmetries. Actually, we can say that wave moves are symmetrical. The considered procedures are effective, accurate, simple, and straightforward to compute. In order to highlight the physical characteristics of the solutions, we also provide 2D and 3D plots of the results.

Published

2022

13. On the Generalized Liouville–Caputo Type Fractional Differential Equations Supplemented with Katugampola Integral Boundary Conditions

Author

Muath Awadalla, Muthaiah Subramanian, Kinda Abuasbeh, and Murugesan Manigandan

Subjects

generalized fractional derivatives, generalized fractional integrals, coupled system, existence, fixed point, Mathematics, QA1-939

Abstract

In this study, we examine the existence and Hyers–Ulam stability of a coupled system of generalized Liouville–Caputo fractional order differential equations with integral boundary conditions and a connection to Katugampola integrals. In the first and third theorems, the Leray–Schauder alternative and Krasnoselskii’s fixed point theorem are used to demonstrate the existence of a solution. The Banach fixed point theorem’s concept of contraction mapping is used in the second theorem to emphasise the analysis of uniqueness, and the results for Hyers–Ulam stability are established in the next theorem. We establish the stability of Ulam–Hyers using conventional functional analysis. Finally, examples are used to support the results. When a generalized Liouville–Caputo (ρ) parameter is modified, asymmetric results are obtained. This study presents novel results that significantly contribute to the literature on this topic.

Published

2022