Your search keyword '"Caputo derivative"' showing total 47 results

1. (α+2)-Dimensional fractional evolution equation: group classification, symmetries, reduction and conservation laws.

Author

Hejazi, S. Reza and Naderifard, Azadeh

Subjects

*CAPUTO fractional derivatives, *FRACTIONAL calculus, *LIE algebras, *CONSERVATION laws (Physics), *SYMMETRY

Abstract

A preliminary group classification based on symmetry operators is applied to study invariance properties of the time-fractional $(\alpha +2)$(α+2)-dimensional fractional evolution equation. The concepts of Riemann–Liouville and Caputo fractional derivatives are used in this study. The similarity variables obtained from symmetries and one-dimensional optimal systems of constructed Lie algebras are used in order to find the group-invariant solutions of the equation. Finally conservation laws of the equation are derived via a modified version of Noether’s theorem. [ABSTRACT FROM AUTHOR]

Published

2024

2. Variable‐order Caputo derivative of LC and RC circuits system with numerical analysis.

Author

Naveen, S and Parthiban, V

Subjects

*RC circuits, *INITIAL value problems, *ELECTRIC circuits, *FRACTIONAL calculus, *NUMERICAL analysis

Abstract

Summary In this paper, computational analysis of a Caputo fractional variable‐order system with inductor‐capacitor (LC) and resistor‐capacitor (RC) electrical circuit models is presented. The existence and uniqueness of solutions to the given problem are determined using Schaefer's fixed point theorem and the Banach contraction principle, respectively. The proposed problem's computational consequences are addressed and analyzed using modified Euler and Runge–Kutta fourth‐order techniques. Furthermore, the suggested model compares several orders, including integer, fractional, and variable orders. To demonstrate the utility of the proposed approach, computational simulations are carried out on LC and RC circuit models of various orders. Furthermore, a comparative analysis with previous investigations has been carried. For the given problem, the numerical solution results in high‐precision approximations. [ABSTRACT FROM AUTHOR]

Published

2024

3. Darbo's Fixed-Point Theorem: Establishing Existence and Uniqueness Results for Hybrid Caputo–Hadamard Fractional Sequential Differential Equations.

Author

Yaseen, Muhammad, Mumtaz, Sadia, George, Reny, Hussain, Azhar, and Nabwey, Hossam A.

Subjects

*HYBRID systems, *EXISTENCE theorems, *CAPUTO fractional derivatives, *FIXED point theory, *FRACTIONAL calculus, *FRACTIONAL differential equations, *DIFFERENTIAL equations

Abstract

This work explores the existence and uniqueness criteria for the solution of hybrid Caputo–Hadamard fractional sequential differential equations (HCHFSDEs) by employing Darbo's fixed-point theorem. Fractional differential equations play a pivotal role in modeling complex phenomena in various areas of science and engineering. The hybrid approach considered in this work combines the advantages of both the Caputo and Hadamard fractional derivatives, leading to a more comprehensive and versatile model for describing sequential processes. To address the problem of the existence and uniqueness of solutions for such hybrid fractional sequential differential equations, we turn to Darbo's fixed-point theorem, a powerful mathematical tool that establishes the existence of fixed points for certain types of mappings. By appropriately transforming the differential equation into an equivalent fixed-point formulation, we can exploit the properties of Darbo's theorem to analyze the solutions' existence and uniqueness. The outcomes of this research expand the understanding of HCHFSDEs and contribute to the growing body of knowledge in fractional calculus and fixed-point theory. These findings are expected to have significant implications in various scientific and engineering applications, where sequential processes are prevalent, such as in physics, biology, finance, and control theory. [ABSTRACT FROM AUTHOR]

Published

2024

4. Fractional-Order Sliding Mode Observer for Actuator Fault Estimation in a Quadrotor UAV.

Author

Borja-Jaimes, Vicente, Coronel-Escamilla, Antonio, Escobar-Jiménez, Ricardo Fabricio, Adam-Medina, Manuel, Guerrero-Ramírez, Gerardo Vicente, Sánchez-Coronado, Eduardo Mael, and García-Morales, Jarniel

Subjects

*ACTUATORS

Abstract

In this paper, we present the design of a fractional-order sliding mode observer (FO-SMO) for actuator fault estimation in a quadrotor unmanned aerial vehicle (QUAV) system. Actuator faults can significantly compromise the stability and performance of QUAV systems; therefore, early detection and compensation are crucial. Sliding mode observers (SMOs) have recently demonstrated their accuracy in estimating faults in QUAV systems under matched uncertainties. However, existing SMOs encounter difficulties associated with chattering and sensitivity to initial conditions and noise. These challenges significantly impact the precision of fault estimation and may even render fault estimation impossible depending on the magnitude of the fault. To address these challenges, we propose a new fractional-order SMO structure based on the Caputo derivative definition. To demonstrate the effectiveness of the proposed FO-SMO in overcoming the limitations associated with classical SMOs, we assess the robustness of the FO-SMO under three distinct scenarios. First, we examined its performance in estimating actuator faults under varying initial conditions. Second, we evaluated its ability to handle significant chattering phenomena during fault estimation. Finally, we analyzed its performance in fault estimation under noisy conditions. For comparison purposes, we assess the performance of both observers using the Normalized Root-Mean-Square Error (NRMSE) criterion. The results demonstrate that our approach enables more accurate actuator fault estimation, particularly in scenarios involving chattering phenomena and noise. In contrast, the performance of classical (non-fractional) SMO suffers significantly under these conditions. We concluded that our FO-SMO is more robust to initial conditions, chattering phenomena, and noise than the classical SMO. [ABSTRACT FROM AUTHOR]

Published

2024

5. Approximating fractional calculus operators with general analytic kernel by Stancu variant of modified Bernstein–Kantorovich operators.

Author

Ali Özarslan, Mehmet

Subjects

*FRACTIONAL calculus, *POSITIVE operators, *INTEGRAL operators, *LIPSCHITZ continuity, *LINEAR operators

Abstract

The main aim of this paper is to approximate the fractional calculus (FC) operator with general analytic kernel by using auxiliary newly defined linear positive operators. For this purpose, we introduce the Stancu variant of modified Bernstein–Kantorovich operators and investigate their simultaneous approximation properties. Then we construct new operators by means of these auxiliary operators, and based on the obtained results, we prove the main theorems on the approximation of the general FC operators. We also obtain some quantitative estimates for this approximation in terms of modulus of continuity and Lipschitz class functions. Additionally, we exhibit our approximation results for the well‐known FC operators such as Riemann–Liouville integral, Caputo derivative, Prabhakar integral, and Caputo–Prabhakar derivative. [ABSTRACT FROM AUTHOR]

Published

2024

6. Analysis and simulation of arbitrary order shallow water and Drinfeld–Sokolov–Wilson equations: Natural transform decomposition method.

Author

Ali, Nasir, Zada, Laiq, Nawaz, Rashid, Jamshed, Wasim, Ibrahim, Rabha W., Guedri, Kamel, and Khalifa, Hamiden Abd El-Wahed

Subjects

*SHALLOW-water equations, *DECOMPOSITION method, *WAVE equation, *FRACTIONAL calculus, *DIFFERENTIAL equations, *IMAGE encryption

Abstract

Within the context of fractional calculus, we investigate novel mathematical possibilities. In this context, using the fractional dispersion relations for the fractional wave equation, we explore a class of the generalized fractional wave equation numerically. Some important classes of differential equations in the theory of wave studies are Drinfeld–Sokolov–Wilson and Shallow Water equations. In this effort, the natural transform decomposition technique has been implemented to investigate the explicit result of fractional-order coupled schemes of Drinfeld–Sokolov–Wilson and Shallow Water coupled systems. The proposed method is obtained by coupling the Natural transform with the Adomian decomposition process. The current technique significantly works to find the approximate solution without any discretization or constraining parameter assumptions. The obtained numerical and graphical outcomes by the devised technique are compared with the available exact result to verify the convergence of the method. For mathematical calculations, the Mathematica software package is used. [ABSTRACT FROM AUTHOR]

Published

2024

7. Explicit scheme for solving variable-order time-fractional initial boundary value problems.

Author

Kanwal, Asia, Boulaaras, Salah, Shafqat, Ramsha, Taufeeq, Bilal, and ur Rahman, Mati

Subjects

*BOUNDARY value problems, *INITIAL value problems, *FRACTIONAL calculus, *MATHEMATICAL physics, *FINITE differences, *FOURIER analysis

Abstract

The creation of an explicit finite difference scheme with the express purpose of resolving initial boundary value issues with linear and semi-linear variable-order temporal fractional properties is presented in this study. The rationale behind the utilization of the Caputo derivative in this scheme stems from its known importance in fractional calculus, an area of study that has attracted significant interest in the mathematical sciences and physics. Because of its special capacity to accurately represent physical memory and inheritance, the Caputo derivative is a relevant and appropriate option for representing the fractional features present in the issues this study attempts to address. Moreover, a detailed Fourier analysis of the explicit finite difference scheme's stability is shown, demonstrating its conditional stability. Finally, certain numerical example solutions are reviewed and MATLAB-based graphic presentations are made. [ABSTRACT FROM AUTHOR]

Published

2024

8. Stability analysis of a second-order difference scheme for the time-fractional mixed sub-diffusion and diffusion-wave equation.

Author

Alikhanov, Anatoly A., Asl, Mohammad Shahbazi, and Huang, Chengming

Subjects

*FRACTIONAL calculus, *CAPUTO fractional derivatives, *WAVE equation, *FRACTIONAL integrals, *EQUATIONS, *NUMERICAL analysis

Abstract

This study investigates a class of initial-boundary value problems pertaining to the time-fractional mixed sub-diffusion and diffusion-wave equation (SDDWE). To facilitate the development of a numerical method and analysis, the original problem is transformed into a new integro-differential model which includes the Caputo derivatives and the Riemann-Liouville fractional integrals with orders belonging to (0, 1). By providing an a priori estimate of the exact solution, we have established the continuous dependence on the initial data and uniqueness of the solution for the problem. We propose a second-order method to approximate the fractional Riemann-Liouville integral and employ an L2-type formula to approximate the Caputo derivative. This results in a method with a temporal accuracy of second-order for approximating the considered model. The proof of the unconditional stability of the proposed difference scheme is established. Moreover, we demonstrate the proposed method's potential to construct and analyze a second-order L2-type numerical scheme for a broader class of the time-fractional mixed SDDWEs with multi-term time-fractional derivatives. Numerical results are presented to assess the accuracy of the method and validate the theoretical findings. [ABSTRACT FROM AUTHOR]

Published

2024

9. On collocation-Galerkin method and fractional B-spline functions for a class of stochastic fractional integro-differential equations.

Author

Masti, I. and Sayevand, K.

Subjects

*FRACTIONAL calculus, *FUNCTIONAL equations, *INTEGRAL equations, *CAPUTO fractional derivatives, *FRACTIONAL integrals, *FRACTIONAL differential equations, *INTEGRO-differential equations

Abstract

In recent years, as detailed in several monographs, derivations of the fractional differential equations and fractional integral equations are based on random functional or stochastic equations, with the output that physical interpretation of the resulting fractional derivatives and fractional integrals has been elusive. In many different sciences and problems such as biological systems, environmental quality and natural resources engineering, and so on, stochastic equations and in some cases random functional have appeared. Despite the widespread use of stochastic fractional integro-differential equations (SFIDE), the analytical solution of this equation is not easy and in some cases it is impossible. Therefore, the existence of an efficient and appropriate numerical method can solve this problem. In this study and based on fractional derivative in the Caputo sense, we investigate a class of SFIDE due to Brownian motion by using fractional B-spline basis functions (FB-spline) and with the help of the collocation-Galerkin method as well as the trapezoidal integral law. In other words, a continuous operator problem (here was named as SFIDE) is transformed into a discrete problem by limited sets of basis functions with common assumptions and approximation methods. In the follow-up a system of linear equations is generated, which makes the analysis of the method be efficient. As an important advantage of this combined method is its flexible and easy implementation. Another advantage of the method is its ability to be implemented for different types of linear, non-linear and system of SFIDE, which are discussed in the body of manuscript. An accurate upper bound is obtained and some theorems are established on the stability and convergence analysis. The computational cost is estimated from the sum of the number arithmetic operations and a lower bound for approximation of this equation is formulated. Finally, by examining several examples, the computational performance of the proposed method effectively verifies the applicability and validity of the suggested scheme. [ABSTRACT FROM AUTHOR]

Published

2024

10. A Novel Fractional Multi-Order High-Gain Observer Design to Estimate Temperature in a Heat Exchange Process.

Author

Borja-Jaimes, Vicente, Adam-Medina, Manuel, García-Morales, Jarniel, Cruz-Rojas, Alan, Gil-Velasco, Alfredo, and Coronel-Escamilla, Antonio

Subjects

*HEAT pipes, *FRACTIONAL calculus, *TEMPERATURE

Abstract

In the present manuscript, we design a fractional multi-order high-gain observer to estimate temperature in a double pipe heat exchange process. For comparison purposes and since we want to prove that when using our novel technique, the estimation is more robust than the classical approach, we design a non-fractional high-gain observer, and then we compare the performance of both observers. We consider three scenarios: The first one considers the estimation of the system states by measuring only one output with no noise added on it and under ideal conditions. Second, we add noise to the measured output and then reconstruct the system states, and, third, in addition to the noise, we increase the gain parameter in both observers (non-fractional and fractional) due to the fact that we want to prove that the robustness changes in this parameter. The results showed that, using our approach, the estimated states can be recovered under noise circumstances in the measured output and under parameter change in the observer, contrary to using classical (non-fractional) observers where the states cannot be recovered. In all our tests, we used the normalized root-mean-square, integral square error, and integral absolute error indices, resulting in a better performance for our approach than that obtained using the classical approach. We concluded that our fractional multi-order high-gain observer is more robust to input noise than the classical high-gain observer. [ABSTRACT FROM AUTHOR]

Published

2023

11. Existence, uniqueness, and stability analysis of fractional Langevin equations with anti‐periodic boundary conditions.

Author

Shah, Syed Omar, Rizwan, Rizwan, Xia, Yonghui, and Zada, Akbar

Subjects

*LANGEVIN equations, *FRACTIONAL calculus, *NONLINEAR equations, *EXISTENCE theorems, *MATHEMATICAL mappings, *INTEGRAL equations

Abstract

This paper is devoted to studying the system of switched coupled implicit fractional Langevin equations of nonlinear form with anti‐periodic boundary conditions. In the first step, problem's equivalence and the corresponding integral equation by applying fractional calculus tools are established, and a fixed point problem is defined. For mixed monotone mappings, we have used coupled fixed point theorems to achieve the existence and uniqueness of solutions of these equations. In the next step, by using Banach's fixed point theorem, Ulam–Hyers, Ulam–Hyers–Rassias, generalized Ulam–Hyers and generalized Ulam–Hyers–Rassias stabilities of our considered model are discussed. An example is given at the end for the verification of our results. [ABSTRACT FROM AUTHOR]

Published

2023

12. A new fractional derivative operator with generalized cardinal sine kernel: Numerical simulation.

Author

Odibat, Zaid and Baleanu, Dumitru

Subjects

*FRACTIONAL calculus, *FRACTIONAL integrals, *COMPUTER simulation, *DIFFERENTIAL equations, *SINE function, *KERNEL (Mathematics), *INTEGRAL operators, *SINE-Gordon equation

Abstract

In this paper, we proposed a new fractional derivative operator in which the generalized cardinal sine function is used as a non-singular analytic kernel. In addition, we provided the corresponding fractional integral operator. We expressed the new fractional derivative and integral operators as sums in terms of the Riemann–Liouville fractional integral operator. Next, we introduced an efficient extension of the new fractional operator that includes integrable singular kernel to overcome the initialization problem for related differential equations. We also proposed a numerical approach for the numerical simulation of IVPs incorporating the proposed extended fractional derivatives. The proposed fractional operators, the developed relations and the presented numerical method are expected to be employed in the field of fractional calculus. [ABSTRACT FROM AUTHOR]

Published

2023

13. A New Hybrid Optimal Auxiliary Function Method for Approximate Solutions of Non-Linear Fractional Partial Differential Equations.

Author

Ashraf, Rashid, Nawaz, Rashid, Alabdali, Osama, Fewster-Young, Nicholas, Ali, Ali Hasan, Ghanim, Firas, and Alb Lupaş, Alina

Subjects

*FRACTIONAL differential equations, *PARTIAL differential equations, *NONLINEAR differential equations, *CAPUTO fractional derivatives, *NONLINEAR equations, *FRACTIONAL calculus, *HYBRID systems, *POISSON'S equation

Abstract

This study uses the optimal auxiliary function method to approximate solutions for fractional-order non-linear partial differential equations, utilizing Riemann–Liouville's fractional integral and the Caputo derivative. This approach eliminates the need for assumptions about parameter magnitudes, offering a significant advantage. We validate our approach using the time-fractional Cahn–Hilliard, fractional Burgers–Poisson, and Benjamin–Bona–Mahony–Burger equations. Comparative testing shows that our method outperforms new iterative, homotopy perturbation, homotopy analysis, and residual power series methods. These examples highlight our method's effectiveness in obtaining precise solutions for non-linear fractional differential equations, showcasing its superiority in accuracy and consistency. We underscore its potential for revealing elusive exact solutions by demonstrating success across various examples. Our methodology advances fractional differential equation research and equips practitioners with a tool for solving non-linear equations. A key feature is its ability to avoid parameter assumptions, enhancing its applicability to a broader range of problems and expanding the scope of problems addressable using fractional calculus techniques. [ABSTRACT FROM AUTHOR]

Published

2023

14. Effective Modified Fractional Reduced Differential Transform Method for Solving Multi-Term Time-Fractional Wave-Diffusion Equations.

Author

Al-rabtah, Adel and Abuasad, Salah

Subjects

*FRACTIONAL differential equations, *HEAT equation, *EQUATIONS, *FRACTIONAL calculus

Abstract

In this work, we suggest a new method for solving linear multi-term time-fractional wave-diffusion equations, which is named the modified fractional reduced differential transform method (m-FRDTM). The importance of this technique is that it suggests a solution for a multi-term time-fractional equation. Very few techniques have been proposed to solve this type of equation, as will be shown in this paper. To show the effectiveness and efficiency of this proposed method, we introduce two different applications in two-term fractional differential equations. The three-dimensional and two-dimensional plots for different values of the fractional derivative are depicted to compare our results with the exact solutions. [ABSTRACT FROM AUTHOR]

Published

2023

15. Kinetic Behavior and Optimal Control of a Fractional-Order Hepatitis B Model.

Author

Xue, Tingting, Fan, Xiaolin, and Xu, Yan

Subjects

*BASIC reproduction number, *FRACTIONAL differential equations, *OPTIMAL control theory, *HEPATITIS B virus, *EPIDEMICS, *HEPATITIS B, *COMMUNICABLE diseases

Abstract

The fractional-order calculus model is suitable for describing real-world problems that contain non-local effects and have memory genetic effects. Based on the definition of the Caputo derivative, the article proposes a class of fractional hepatitis B epidemic model with a general incidence rate. Firstly, the existence, uniqueness, positivity and boundedness of model solutions, basic reproduction number, equilibrium points, and local stability of equilibrium points are studied employing fractional differential equation theory, stability theory, and infectious disease dynamics theory. Secondly, the fractional necessary optimality conditions for fractional optimal control problems are derived by applying the Pontryagin maximum principle. Finally, the optimization simulation results of fractional optimal control problem are discussed. To control the spread of the hepatitis B virus, three control variables (isolation, treatment, and vaccination) are applied, and the optimal control theory is used to formulate the optimal control strategy. Specifically, by isolating infected and non-infected people, treating patients, and vaccinating susceptible people at the same time, the number of hepatitis B patients can be minimized, the number of recovered people can be increased, and the purpose of ultimately eliminating the transmission of hepatitis B virus can be achieved. [ABSTRACT FROM AUTHOR]

Published

2023

16. Application of the B-spline Galerkin approach for approximating the time-fractional Burger's equation.

Author

AL-saedi, Akeel A. and Rashidinia, Jalil

Subjects

*GALERKIN methods, *BURGERS' equation, *FINITE element method, *FRACTIONAL calculus, *NUMERICAL analysis

Abstract

This paper presents a numerical scheme based on the Galerkin finite element method and cubic B-spline base function with quadratic weight function to approximate the numerical solution of the time-fractional Burger's equation, where the fractional derivative is considered in the Caputo sense. The proposed method is applied to two examples by using the L 2 and L ∞ error norms. The obtained results are compared with a previous existing method to test the accuracy of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

17. Application of the Optimal Homotopy Asymptotic Approach for Solving Two-Point Fuzzy Ordinary Differential Equations of Fractional Order Arising in Physics.

Author

Jameel, Ali Fareed, Jawad Hashim, Dulfikar, Anakira, Nidal, Ababneh, Osama, Qazza, Ahmad, Alomari, Abedel-Karrem, and Al Kalbani, Khamis S.

Subjects

*BOUNDARY value problems, *FRACTIONAL calculus, *NONLINEAR equations, *SET theory, *ORDINARY differential equations, *FRACTIONAL differential equations, *ANALYTICAL solutions, *FUZZY sets

Abstract

This work focuses on solving and analyzing two-point fuzzy boundary value problems in the form of fractional ordinary differential equations (FFOBVPs) using a new version of the approximation analytical approach. FFOBVPs are useful in describing complex scientific phenomena that include heritable characteristics and uncertainty, and obtaining exact or close analytical solutions for these equations can be challenging, especially in the case of nonlinear problems. To address these difficulties, the optimal homotopy asymptotic method (OHAM) was studied and extended in a new form to solve FFOBVPs. The OHAM is known for its ability to solve both linear and nonlinear fractional models and provides a straightforward methodology that uses multiple convergence control parameters to optimally manage the convergence of approximate series solutions. The new form of the OHAM presented in this work incorporates the concepts of fuzzy sets theory and some fractional calculus principles to include fuzzy analysis in the method. The steps of fuzzification and defuzzification are used to transform the fuzzy problem into a crisp problem that can be solved using the OHAM. The method is demonstrated by solving and analyzing linear and nonlinear FFOBVPs at different values of fractional derivatives. The results obtained using the new form of the fuzzy OHAM are analyzed and compared to those found in the literature to demonstrate the method's efficiency and high accuracy in the fuzzy domain. Overall, this work presents a feasible and efficient approach for solving FFOBVPs using a new form of the OHAM with fuzzy analysis. [ABSTRACT FROM AUTHOR]

Published

2023

18. The n-Point Composite Fractional Formula for Approximating Riemann–Liouville Integrator.

Author

Batiha, Iqbal M., Alshorm, Shameseddin, Al-Husban, Abdallah, Saadeh, Rania, Gharib, Gharib, and Momani, Shaher

Subjects

*FRACTIONAL calculus, *DEFINITE integrals, *FRACTIONAL integrals, *INTEGRATORS

Abstract

In this paper, we aim to present a novel n-point composite fractional formula for approximating a Riemann–Liouville fractional integral operator. With the use of the definite fractional integral's definition coupled with the generalized Taylor's formula, a novel three-point central fractional formula is established for approximating a Riemann–Liouville fractional integrator. Such a new formula, which emerges clearly from the symmetrical aspects of the proposed numerical approach, is then further extended to formulate an n-point composite fractional formula for approximating the same operator. Several numerical examples are introduced to validate our findings. [ABSTRACT FROM AUTHOR]

Published

2023

19. Numerical Approximation of a Time-Fractional Modified Equal-Width Wave Model by Using the B-Spline Weighted Residual Method.

Author

AL-saedi, Akeel A. and Rashidinia, Jalil

Subjects

*FRACTIONAL calculus, *MATHEMATICAL models, *FINITE element method

Abstract

Fractional calculus (FC) is an important mathematical tool in modeling many dynamical processes. Therefore, some analytical and numerical methods have been proposed, namely, those based on symmetry and spline schemes. This paper proposed a numerical approach for finding the solution to the time-fractional modified equal-width wave (TFMEW) equation. The fractional derivative is described in the Caputo sense. Indeed, the B-spline Galerkin scheme combined with functions with different weights was employed to discretize TFMEW. The L 2 and L ∞ error norm values and the three invariants I 1 ,   I 2 , and I 3 of the numerical example were calculated and tabulated. A comparison of these errors and invariants was provided to confirm the efficiency and accuracy of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

20. Fractional-Modified Bessel Function of the First Kind of Integer Order.

Author

Martín, Andrés and Estrada, Ernesto

Subjects

*MATHEMATICAL functions, *BESSEL functions, *INTEGERS, *SPECIAL functions, *COSINE function, *INTEGRAL representations

Abstract

The modified Bessel function (MBF) of the first kind is a fundamental special function in mathematics with applications in a large number of areas. When the order of this function is integer, it has an integral representation which includes the exponential of the cosine function. Here, we generalize this MBF to include a fractional parameter, such that the exponential in the previously mentioned integral is replaced by a Mittag–Leffler function. The necessity for this generalization arises from a problem of communication in networks. We find the power series representation of the fractional MBF of the first kind as well as some differential properties. We give some examples of its utility in graph/networks analysis and mention some fundamental open problems for further investigation. [ABSTRACT FROM AUTHOR]

Published

2023

21. Numerical and Analytical Solutions of Space-Time Fractional Partial Differential Equations by Using a New Double Integral Transform Method.

Author

AL-Safi, Mohammed G. S., Abd AL-Hussein., Wurood R., and Fawzi, Rand Muhand

Subjects

*FRACTIONAL differential equations, *PARTIAL differential equations, *FRACTIONAL calculus, *ANALYTICAL solutions, *SPACETIME, *INTEGRAL transforms

Abstract

This work discusses the beginning of fractional calculus and how the Sumudu and Elzaki transforms are applied to fractional derivatives. This approach combines a double Sumudu-Elzaki transform strategy to discover analytic solutions to space-time fractional partial differential equations in Mittag- Leffler functions subject to initial and boundary conditions. Where this method gets closer and closer to the correct answer, and the technique's efficacy is demonstrated using numerical examples performed with Matlab R2015a. [ABSTRACT FROM AUTHOR]

Published

2023

22. Refinable Trapezoidal Method on Riemann–Stieltjes Integral and Caputo Fractional Derivatives for Non-Smooth Functions.

Author

Karnan, Gopalakrishnan and Yen, Chien-Chang

Subjects

*FRACTIONAL calculus, *FRACTIONAL differential equations, *FRACTIONAL integrals, *DIFFERENTIABLE functions, *CONTINUOUS functions

Abstract

The Caputo fractional α -derivative, 0 < α < 1 , for non-smooth functions with 1 + α regularity is calculated by numerical computation. Let I be an interval and D α (I) be the set of all functions f (x) which satisfy f (x) = f (c) + f ′ (c) (x − a) + g c (x) (x − c) | (x − c) | α , where x , c ∈ I and g c (x) is a continuous function for each c. We first extend the trapezoidal method on the set D α (I) and rewrite the integrand of the Caputo fractional integral as a product of two differentiable functions. In this approach, the non-smooth function and the singular kernel could have the same impact. The trapezoidal method using the Riemann–Stieltjes integral (TRSI) depends on the regularity of the two functions in the integrand. Numerical simulations demonstrated that the order of accuracy cannot be increased as the number of zones increases using the uniform discretization. However, for a fixed coarsest grid discretization, a refinable mesh approach was employed; the corresponding results show that the order of accuracy is k α , where k is a refinable scale. Meanwhile, the application of the product of two differentiable functions can also be applied to some Riemann–Liouville fractional differential equations. Finally, the stable numerical scheme is shown. [ABSTRACT FROM AUTHOR]

Published

2023

23. A linear Galerkin numerical method for a quasilinear subdiffusion equation.

Author

Płociniczak, Łukasz

Subjects

*GALERKIN methods, *FRACTIONAL calculus, *CAPUTO fractional derivatives, *EQUATIONS, *NONLINEAR functions

Abstract

We couple the L1 discretization for the Caputo derivative in time with the spectral Galerkin method in space to devise a scheme that solves quasilinear subdiffusion equations. Both the diffusivity and the source are allowed to be nonlinear functions of the solution. We prove the stability and convergence of the method with spectral accuracy in space. The temporal order depends on the regularity of the solution in time. Furthermore, we support our results with numerical simulations that utilize parallelism for spatial discretization. Moreover, as a side result, we find exact asymptotic values of the error constants along with their remainders for discretizations of the Caputo derivative and fractional integrals. These constants are the smallest possible, which improves previously established results from the literature. [ABSTRACT FROM AUTHOR]

Published

2023

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

Author

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

Subjects

*BOUNDARY value problems, *INITIAL value problems, *FINITE differences, *FRACTIONAL differential equations, *FRACTIONAL calculus, *FINITE difference method, *HEAT equation

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. [ABSTRACT FROM AUTHOR]

Published

2023

25. An analytic and numerical study for two classes of differential equations of fractional order involving Caputo and Khalil derivatives.

Author

Rakah, Mahdi, Anber, Ahmed, Dahmani, Zoubir, and Jebril, Iqbal

Subjects

*MATHEMATICAL research, *DIFFERENTIAL equations, *FRACTIONAL calculus, *CAPUTO fractional derivatives, *KORTEWEG-de Vries equation

Abstract

In this paper, we study new classes of differential equations of fractional order. The first considered problem involves the derivative of Caputo, while the second one involves conformable Khalil derivative. For the first class, we prove an existence and uniqueness result, then, we discuss an example to show the applicability of the result. For the second one, we apply the exp-function method to find new traveling wave solutions for a generalised conformable fractional partial differential equation, then some examples on Ostrovsky and KdV equations are given to illustrate the efficiency and accuracy of the method. Some graphs are plotted and discussed to show more the importance of the obtained results. [ABSTRACT FROM AUTHOR]

Published

2023

26. A Study on Numerical Algorithms for Differential Equations in Two Cases q-Calculus and (p,q)-Calculus.

Author

Ahmadkhanlu, A., Khoshvaghti, L., and Rezapour, Sh.

Subjects

*DIFFERENTIAL equations, *MALLIAVIN calculus, *NUMERICAL calculations, *FRACTIONAL calculus, *ALGORITHMS, *FRACTIONAL differential equations

Abstract

We investigate the existence and uniqueness of the solution and also the rate of convergence of a numerical method for a fractional differential equation in both q-calculus and (p; q)-calculus versions. We use the Banach and Schauder fixed point theorems in this study. We provide two examples, one by definition of the q-derivative and the other by (p; q)-derivative. We compare the rate of convergence of the numerical method. We like to clear some facts on (p; q)-calculus. The data from our numerical calculations show well that q-calculus works better than (p; q)-calculus in each case. [ABSTRACT FROM AUTHOR]

Published

2023

27. Time-Delay Fractional Variable Order Adaptive Synchronization and Anti-Synchronization between Chen and Lorenz Chaotic Systems Using Fractional Order PID Control.

Author

Padron, Joel Perez, Perez, Jose P., Diaz, Jose Javier Perez, and Astengo-Noguez, Carlos

Subjects

*CAPUTO fractional derivatives, *FRACTIONAL calculus, *SYNCHRONIZATION, *CHAOS synchronization, *PROBLEM solving, *SYSTEMS theory

Abstract

In this research work, time-delay adaptive synchronization and adaptive anti-synchronization of chaotic fractional order systems are analyzed via the Caputo fractional derivative, and the prob-lem of synchronization and anti-synchronization of chaotic systems of variable fractional order is solved by using the fractional order PID control law, the adaptive laws of variable-order frac-tional calculus, and a control law deduced from Lyapunov's theory extended to systems of time-delay variable-order fractional calculus. In this research work, two important problems are solved in the control area: The first problem is described in which deals with syn-chro-nization of chaotic systems of adaptive fractional order with time delay, this problem is solved by using the fractional order PID control law and adaptative laws. The second problem is de-scribed in which deals with anti-synchronization of chaotic systems of adaptive frac-tional order with time delay, and this problem is solved by using the fractional order PID con-trol law and adaptative laws. [ABSTRACT FROM AUTHOR]

Published

2023

28. Convergence analysis of the fractional decomposition method with applications to time‐fractional biological population models.

Author

Obeidat, Nazek A. and Bentil, Daniel E.

Subjects

*DECOMPOSITION method, *BIOLOGICAL models, *FRACTIONAL differential equations, *PARTIAL differential equations, *NONLINEAR equations

Abstract

In this study, we present convergence analysis along with an error estimate for time‐fractional biological population equation in terms of the Caputo derivative using a new technique called the fractional decomposition method (FDM). Further, we present exact solutions to four test problems of nonlinear time‐fractional biological population models to show the accuracy and efficiency of the FDM. This method based on constructing series solutions in a form of rapidly convergent series with easily computable components and without the need of linearization, discretization and perturbations. The results prove that the FDM is very effective and simple for solving fractional partial differential equations in multi‐dimensional spaces, special cases of which we have described in this paper. [ABSTRACT FROM AUTHOR]

Published

2023

29. Modified Three-Point Fractional Formulas with Richardson Extrapolation.

Author

Batiha, Iqbal M., Alshorm, Shameseddin, Ouannas, Adel, Momani, Shaher, Ababneh, Osama Y., and Albdareen, Meaad

Subjects

*EXTRAPOLATION, *FRACTIONAL calculus, *VALUES (Ethics)

Abstract

In this paper, we introduce new three-point fractional formulas which represent three generalizations for the well-known classical three-point formulas; central, forward and backward formulas. This has enabled us to study the function's behavior according to different fractional-order values of α numerically. Accordingly, we then introduce a new methodology for Richardson extrapolation depending on the fractional central formula in order to obtain a high accuracy for the gained approximations. We compare the efficiency of the proposed methods by using tables and figures to show their reliability. [ABSTRACT FROM AUTHOR]

Published

2022

30. Fuzzy fractional generalized Bagley–Torvik equation with fuzzy Caputo gH-differentiability.

Author

Muhammad, Ghulam and Akram, Muhammad

Subjects

*NEWTONIAN fluids, *ANALYTICAL solutions, *EQUATIONS, *PROBLEM solving, *FRACTIONAL calculus

Abstract

The fractional generalized Bagley–Torvik equation (FGB-TE) is a mathematical description of the motion of an immersed plate in a Newtonian fluid. The analytical study of the FGB-TE with uncertain initial conditions and two independent fractional orders is usually complex and difficult. Therefore, it is necessary to develop a proper and effective technique to solve the fuzzy fractional generalized Bagley–Torvik equation (FFGB-TE) analytically. This paper presents the analytical fuzzy solution of the FFGB-TEs based on the concept of the fuzzy Caputo generalized Hukuhara differentiability (g H -differentiability) using the fuzzy Laplace transform (FLT) technique. The closed-form solution of FFGB-TEs is presented for both the homogeneous and non-homogeneous cases in terms of the Mittag-Leffler function (MLF) involving double series. Several significant results are introduced and proven with true reasoning. We illustrate our proposed analytical approach with the help of several demonstrative examples. To enhance the novelty of the proposed work, we solved the FFGB-TE as an application of the motion of an immersed plate and visualized their graphs to support the theoretical results. • Analytical solutions of fuzzy fractional Bagley-Torvik equation are investigated. • The potential solutions are extracted using fuzzy Caputo g H -differentiability. • Closed-form solutions of proposed scheme are presented using Mittag-Leffler function. • Several significant results are presented using the proposed analytical approach. • The real-world problem is solved as an application of the proposed study. [ABSTRACT FROM AUTHOR]

Published

2024

31. Solutions of Initial Value Problems with Non-Singular, Caputo Type and Riemann-Liouville Type, Integro-Differential Operators.

Author

Angstmann, Christopher N., Burney, Stuart-James M., Henry, Bruce I., and Jacobs, Byron A.

Subjects

*INITIAL value problems, *INTEGRO-differential equations, *FRACTIONAL calculus

Abstract

Motivated by the recent interest in generalized fractional order operators and their applications, we consider some classes of integro-differential initial value problems based on derivatives of the Riemann–Liouville and Caputo form, but with non-singular kernels. We show that, in general, the solutions to these initial value problems possess discontinuities at the origin. We also show how these initial value problems can be re-formulated to provide solutions that are continuous at the origin but this imposes further constraints on the system. Consideration of the intrinsic discontinuities, or constraints, in these initial value problems is important if they are to be employed in mathematical modelling applications. [ABSTRACT FROM AUTHOR]

Published

2022

32. Axisymmetric Fractional Diffusion with Mass Absorption in a Circle under Time-Harmonic Impact.

Author

Povstenko, Yuriy and Kyrylych, Tamara

Subjects

*KLEIN-Gordon equation, *HEAT equation, *INTEGRAL transforms, *ABSORPTION, *NUMERICAL calculations, *MASS transfer

Abstract

The axisymmetric time-fractional diffusion equation with mass absorption is studied in a circle under the time-harmonic Dirichlet boundary condition. The Caputo derivative of the order 0 < α ≤ 2 is used. The investigated equation can be considered as the time-fractional generalization of the bioheat equation and the Klein–Gordon equation. Different formulations of the problem for integer values of the time-derivatives α = 1 and α = 2 are also discussed. The integral transform technique is employed. The outcomes of numerical calculations are illustrated graphically for different values of the parameters. [ABSTRACT FROM AUTHOR]

Published

2022

33. A Hilbert Space Approach to Fractional Differential Equations.

Author

Diethelm, Kai, Kitzing, Konrad, Picard, Rainer, Siegmund, Stefan, Trostorff, Sascha, and Waurick, Marcus

Subjects

*FRACTIONAL differential equations, *HILBERT space, *INTERPOLATION spaces, *NONLINEAR differential equations, *FRACTIONAL calculus

Abstract

We study fractional differential equations of Riemann–Liouville and Caputo type in Hilbert spaces. Using exponentially weighted spaces of functions defined on R , we define fractional operators by means of a functional calculus using the Fourier transform. Main tools are extrapolation- and interpolation spaces. Main results are the existence and uniqueness of solutions and the causality of solution operators for non-linear fractional differential equations. [ABSTRACT FROM AUTHOR]

Published

2022

34. Memory responses in a three-dimensional thermo-viscoelastic medium.

Author

Sur, Abhik

Subjects

*THERMOELASTICITY, *TRANSIENTS (Dynamics), *FRACTIONAL calculus, *KERNEL functions, *HEAT transfer

Abstract

Due to the shortcomings of power law distributions in the heat transfer laws of fractional calculus, some other forms of derivatives with few other kernel functions have been proposed. This literature survey focuses on the mathematical model of thermo-viscoelasticity which investigates the transient phenomena in a three-dimensional thermoelastic medium in the context of two-temperature Kelvin–Voigt three-phase-lag model of generalized thermoelasticity, defined in integral form on a slipping interval incorporating the memory-dependent heat transport law. The bounding plane is subjected to a time-dependent thermal loading and is free of tractions. Incorporating normal mode as a tool, the problem has been solved analytically in terms of normal modes and the physical fields have been depicted graphically for a copper-like material. According to the graphical representations corresponding to the numerical results, conclusions about the new theory is constructed. Excellent predictive capability is demonstrated due to the presence of memory-dependent derivative, effect of delay time and viscosity also. [ABSTRACT FROM AUTHOR]

Published

2022

35. Approximate Solution for High Order Fractional Integro-Differential Equations Via an Optimum Parameter Method.

Author

Agheli, B., Darzi, R., and Dabbaghian, A.

Subjects

*FRACTIONAL differential equations, *HOMOTOPY theory, *STOCHASTIC convergence, *FRACTIONAL calculus, *PERTURBATION theory

Abstract

The most significant objective of this article is the adoption of a method with a free parameter known as "The Optimum Asymptotic Homotopy Method" which has been utilized in order to obtain solutions for integral differential equations of high-order non integer derivative. The process in this method is more favorable than "Homotopy Perturbation Method" as it has a more rapid convergence compared to the mentioned method or even the similar methods. Another advantage of this method is that the convergence rate is recognized as control area. It is worth mentioning that Caputo derivative is adopted in this article. A number of instances are provided to better understand the method and its level of efficiency compared to other same methods. [ABSTRACT FROM AUTHOR]

Published

2021

36. A Semi-analytical Solutions of Fractional Riccati Differential Equation via Singular and Non-singular Operators.

Author

Agheli, B. and Firozja, M. Adabitabar

Subjects

*FRACTIONAL differential equations, *OPERATOR theory, *FRACTIONAL calculus, *ITERATIVE methods (Mathematics), *INTEGRALS

Abstract

In this paper, we investigate the solution of the Riccati differential equations of fractional order (FRDEs) involving Caputo derivative (CD), Caputo-Fabrizio derivative (CFD) or Atangana-Baleanu derivative (ABD) using a semi-analytical iterative approach. Temimi and Ansari introduced this method and called it TAM. The linearization of the method involves splitting the problem into a linear and nonlinear part. While this approach is a semi-analytical iterative technique, there is a significant amount of analytical work where the computational times of integrals are needed to be carried out numerically. The novelty and the motivation behind this paper is the comparison of the time used in minutes which is given for three derivatives: CD, CFD and ABD. Meanwhile, the comparison of the approximate solutions with CD, CFD and ABD are presented. With the help of the software Mathematica, the computational results have been obtained. [ABSTRACT FROM AUTHOR]

Published

2021

37. Solution method for the time‐fractional hyperbolic heat equation.

Author

Dassios, Ioannis and Font, Francesc

Subjects

*BOUNDARY value problems, *CAPUTO fractional derivatives, *SEPARATION of variables, *FOURIER series, *FRACTIONAL calculus, *HEAT equation, *ANALYTICAL solutions

Abstract

In this article, we propose a method to solve the time‐fractional hyperbolic heat equation. We first formulate a boundary value problem for the standard hyperbolic heat equation in a finite domain and provide an analytical solution by means of separation of variables and Fourier series. Then, we consider the same boundary value problem for the fractional hyperbolic heat equation. The fractional problem is solved using three different definitions of the fractional derivative: the Caputo fractional derivative and two recently defined alternative versions of this derivative, the Caputo–Fabrizio and the Atangana–Baleanu. A closed form of the solution is provided for each case. Finally, we compare the solutions of the fractional and the standard problem and show numerically that the solution of the standard hyperbolic heat equation can be retrieved from the solution of the fractional equation in the limit γ→2, where γ represents the exponent of the fractional derivative. [ABSTRACT FROM AUTHOR]

Published

2021

38. New problem of sequential differential equations with nonlocal conditions.

Author

Bekkouche, Z. and Dahmani, Z.

Subjects

*DIFFERENTIAL equations, *FRACTIONAL calculus, *CAPUTO fractional derivatives, *NONLINEAR differential equations, *FRACTIONAL integrals

Abstract

In this paper, we study a nonlinear differential equation of Lane Emden type. The considered problem, with its nonlocal conditions, involves Caputo fractional derivative and Riemann-Liouville integral in its nonlinearities. We investigate the existence and uniqueness of solution for our problem. Then, we study the Ulam-Hyers stability of its solutions. [ABSTRACT FROM AUTHOR]

Published

2021

39. On the General Solutions of Some Non-Homogeneous Div-Curl Systems with Riemann-Liouville and Caputo Fractional Derivatives.

Author

Delgado, Briceyda B. and Macías-Díaz, Jorge E.

Subjects

*FRACTIONAL calculus, *DIRAC equation, *PARTIAL differential equations, *WAVE equation, *CAPUTO fractional derivatives

Abstract

In this work, we investigate analytically the solutions of a nonlinear div-curl system with fractional derivatives of the Riemann-Liouville or Caputo types. To this end, the fractional-order vector operators of divergence, curl and gradient are identified as components of the fractional Dirac operator in quaternionic form. As one of the most important results of this manuscript, we derive general solutions of some non-homogeneous div-curl systems that consider the presence of fractional-order derivatives of the Riemann-Liouville or Caputo types. A fractional analogous to the Teodorescu transform is presented in this work, and we employ some properties of its component operators, developed in this work to establish a generalization of the Helmholtz decomposition theorem in fractional space. Additionally, right inverses of the fractional-order curl, divergence and gradient vector operators are obtained using Riemann-Liouville and Caputo fractional operators. Finally, some consequences of these results are provided as applications at the end of this work. [ABSTRACT FROM AUTHOR]

Published

2021

40. Spline Collocation for Multi-Term Fractional Integro-Differential Equations with Weakly Singular Kernels.

Author

Pedas, Arvet and Vikerpuur, Mikk

Subjects

*CAPUTO fractional derivatives, *FRACTIONAL calculus, *KERNEL (Mathematics), *KERNEL functions, *REPRODUCING kernel (Mathematics)

Abstract

We consider general linear multi-term Caputo fractional integro-differential equations with weakly singular kernels subject to local or non-local boundary conditions. Using an integral equation reformulation of the proposed problem, we first study the existence, uniqueness and regularity of the exact solution. Based on the obtained regularity properties and spline collocation techniques, the numerical solution of the problem is discussed. Optimal global convergence estimates are derived and a superconvergence result for a special choice of grid and collocation parameters is given. A numerical illustration is also presented. [ABSTRACT FROM AUTHOR]

Published

2021

41. Caputo derivative applied to very short time photovoltaic power forecasting.

Author

Lauria, Davide, Mottola, Fabio, and Proto, Daniela

Subjects

*REAL-time control, *FORECASTING, *FRACTIONAL calculus, *INDEPENDENT system operators, *STATISTICAL power analysis, *MOVING average process

Abstract

• PV power intra-hour forecasting is dealt with. • A novel method is proposed based on fractional calculus, more specifically the Caputo derivative has been used. • The use of Caputo derivative allows considering information on the trend of the forecasting variable. • The prediction tool allows to provide a closed form for the predictor which is particularly suitable for online applications. • A sensitivity analysis shows that the inclusion of information on the trend of the forecasting variable in recent past could lead to accurate results. Intra-hour photovoltaic power forecasting provides essential information for real time optimal control of microgrids. At this purpose, a critical issue is the selection of the forecasting method. The choice of a forecasting method depends on many factors such as the availability of historical data, the time horizon, the lag period, and the time available for the forecast. Persistence based methods are particularly tailored for real time forecasting which require fast information and are typically a good trade-off choice when dealing with real time operation of microgrids. Their accuracy, however, could be not satisfactory in some cases such as when it appears critical to consider the trend of the power output in the last few minutes rather than only the last measured value. Derivatives help reach this goal, but fractional derivatives seem to be a more accurate choice in order to take into account the history of the variable to be forecasted as they are a promising tool for describing memory phenomena. In this paper, a novel intra-hour forecasting method is proposed based on the Caputo derivative. Numerical applications are carried out to show the efficacy of the proposed approach. Also, the accuracy of the proposed approach is tested through comparison with three models namely, persistence, derivative-persistence and auto regressive moving average models. The strength of the proposed forecasting tool is strictly related to its low computational burden without compromising accuracy. This makes of it an interesting means for real time grid operation strategies and can be of interest for the grid operators especially in vision of the changes distribution grids are witnessing with the transition to the smart grid paradigm. [ABSTRACT FROM AUTHOR]

Published

2022

42. Fractional telegraph equation under moving time-harmonic impact.

Author

Povstenko, Yuriy and Ostoja-Starzewski, Martin

Subjects

*TELEGRAPH & telegraphy, *DOPPLER effect, *HEAT equation, *INTEGRAL transforms, *FOURIER series, *EQUATIONS

Abstract

• The time-fractional telegraph equation with moving time-harmonic source is considered on a real line. • Two characteristic versions of this equation: the "wave-type" with the second and Caputo fractional time-derivatives as well as the "heat-type" with the first and Caputo fractional time-derivatives are investigated. • The solution to the "wave-type" equation contains wave fronts and describes the Doppler effect contrary to the solution for the "heat-type" equation. • For the time-fractional telegraph equation it is impossible to consider the quasi-steady-state corresponding to the solution being a product of a function of the spatial coordinate and the time-harmonic term. • The derived solutions can be successfully used when the source term can be expanded into a Fourier series. The time-fractional telegraph equation with moving time-harmonic source is considered on a real line. We investigate two characteristic versions of this equation: the "wave-type" with the second and Caputo fractional time-derivatives as well as the "heat-type" with the first and Caputo fractional time-derivatives. In both cases the order of fractional derivative 1 < α < 2. For the time-fractional telegraph equation it is impossible to consider the quasi-steady-state corresponding to the solution being a product of a function of the spatial coordinate and the time-harmonic term. The considered problem is solved using the integral transforms technique. The solution to the "wave-type" equation contains wave fronts and describes the Doppler effect contrary to the solution for the "heat-type" equation. Numerical results are illustrated graphically for different values of nondimensional parameters. [ABSTRACT FROM AUTHOR]

Published

2022

43. An External Circular Crack in an Infinite Solid under Axisymmetric Heat Flux Loading in the Framework of Fractional Thermoelasticity.

Author

Povstenko, Yuriy, Kyrylych, Tamara, Woźna-Szcześniak, Bożena, Kawa, Renata, and Yatsko, Andrzej

Subjects

*HEAT flux, *HEATING load, *HEAT conduction, *HEAT equation, *SURFACE cracks, *THERMAL stresses, *THERMOELASTICITY

Abstract

In a real solid there are different types of defects. During sudden cooling, near cracks, there can appear high thermal stresses. In this paper, the time-fractional heat conduction equation is studied in an infinite space with an external circular crack with the interior radius R in the case of axial symmetry. The surfaces of a crack are exposed to the constant heat flux loading in a circular ring R < r < ρ . The stress intensity factor is calculated as a function of the order of time-derivative, time, and the size of a circular ring and is presented graphically. [ABSTRACT FROM AUTHOR]

Published

2022

44. A Novel Analytical Approach for the Solution of Fractional-Order Diffusion-Wave Equations.

Author

Mustafa, Saima, Hajira, Khan, Hassan, Shah, Rasool, and Masood, Saadia

Subjects

*WAVE equation, *BOUNDARY value problems, *NUMERICAL analysis, *CAPUTO fractional derivatives, *FRACTIONAL calculus

Abstract

In the present note, a new modification of the Adomian decomposition method is developed for the solution of fractional-order diffusion-wave equations with initial and boundary value Problems. The derivatives are described in the Caputo sense. The generalized formulation of the present technique is discussed to provide an easy way of understanding. In this context, some numerical examples of fractional-order diffusion-wave equations are solved by the suggested technique. It is investigated that the solution of fractional-order diffusion-wave equations can easily be handled by using the present technique. Moreover, a graphical representation was made for the solution of three illustrative examples. The solution-graphs are presented for integer and fractional order problems. It was found that the derived and exact results are in good agreement of integer-order problems. The convergence of fractional-order solution is the focus point of the present research work. The discussed technique is considered to be the best tool for the solution of fractional-order initial-boundary value problems in science and engineering. [ABSTRACT FROM AUTHOR]

Published

2021

45. Solving a Higher-Dimensional Time-Fractional Diffusion Equation via the Fractional Reduced Differential Transform Method.

Author

Abuasad, Salah, Alshammari, Saleh, Al-rabtah, Adil, and Hashim, Ishak

Subjects

*HEAT equation, *DIFFERENTIAL equations, *CAPUTO fractional derivatives, *FRACTIONAL calculus, *NUMERICAL analysis

Abstract

In this study, exact and approximate solutions of higher-dimensional time-fractional diffusion equations were obtained using a relatively new method, the fractional reduced differential transform method (FRDTM). The exact solutions can be found with the benefit of a special function, and we applied Caputo fractional derivatives in this method. The numerical results and graphical representations specified that the proposed method is very effective for solving fractional diffusion equations in higher dimensions. [ABSTRACT FROM AUTHOR]

Published

2021

46. On a discrete composition of the fractional integral and Caputo derivative.

Author

Płociniczak, Łukasz

Subjects

*FRACTIONAL calculus, *CAPUTO fractional derivatives, *INTEGRAL functions, *NUMERICAL analysis, *FRACTIONAL integrals

Abstract

We prove a discrete analogue for the composition of the fractional integral and Caputo derivative. This result is relevant in numerical analysis of fractional PDEs when one discretizes the Caputo derivative with the so-called L1 scheme. The proof is based on asymptotic evaluation of the discrete sums with the use of the Euler–Maclaurin summation formula. • The discrete version of the composition mimics the continuous case. • The remainder involves the fractional integral and the derivative of the function. • The remainder with a step h decays to zero at a rate h min (a l p h a , 1 − a l p h a) . [ABSTRACT FROM AUTHOR]

Published

2022

47. A new nonlinear duffing system with sequential fractional derivatives.

Author

Bezziou, Mohamed, Jebril, Iqbal, and Dahmani, Zoubir

Subjects

*FRACTIONAL calculus, *NONLINEAR systems, *CAPUTO fractional derivatives, *DUFFING equations, *INTEGRAL representations

Abstract

By considering the Caputo fractional derivative and Riemann-Liouville integral, in the present work, we are concerned with a nonlinear sequential fractional differential system of Duffing oscillator type. The considered system has neither the commutativity nor the semi group properties, since the sum of the two orders of derivatives, of the left hand side of the problem, are outside the interval [0,1]. With the absence of these two properties, we have to find other arguments to obtain the integral representation of the problem, to be able thereafter to present the other main results. Then, using the contraction mapping principle and Scheafer theorem, two main theorems on the uniqueness and existence of solutions are proved. Finally, some examples are given to illustrate the proposed main results. [ABSTRACT FROM AUTHOR]

Published

2021