969 results on '"Caputo derivative"'
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2. Impact of skills development on youth unemployment: A fractional‐order mathematical model.
- Author
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Bansal, Komal and Mathur, Trilok
- Abstract
The global impact of high unemployment rates has significant economic and social consequences. To overcome this, various skill development programs are initiated by governments of developing countries. But the problem of unemployment is still increasing day by day. So, there is a pressing necessity to revise the current policies and models. Therefore, this research proposes a fractional‐order mathematical model that examines the impact of various skill development programs for youths. The proposed model incorporates fractional‐order differential equations to capture the complex dynamics of unemployment. The main objective of this research is to examine the impact of training programs aimed at enhancing the abilities of unemployed individuals, with the ultimate goal of reducing the overall unemployment rate. The reproduction number is calculated using the next‐generation matrix approach, which is crucial for both the existence and stability analysis of the equilibria. When the reproduction number is less than 1, the employment‐free equilibrium is locally and globally asymptotically stable. The employment‐persistence equilibrium point emerges only when the reproduction number exceeds one. We also explore the possibility of transcritical bifurcation and investigate the impact of skill development on the unemployment rate. We conduct numerical simulations to validate our analytical findings, further supporting our qualitative conclusions. These simulations help illustrate the unemployment dynamics and confirm the stability and behavior of the equilibrium points predicted by the mathematical model. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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3. Two efficient techniques for analysis and simulation of time-fractional Tricomi equation.
- Author
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Mohan, Lalit and Prakash, Amit
- Abstract
In this work, the time-fractional Tricomi equation is investigated via two efficient computational techniques. This equation is used to explain the nearly sonic speed gas dynamics phenomenon. The Homotopy perturbation transform technique, which is a combination of Laplace transform and a semi-analytical technique, and Homotopy analysis method are used to solve the time-fractional Tricomi equation. The existence and uniqueness of the solution is analyzed by using two different fixed-point theorems. Finally, the effectiveness of the proposed techniques is illustrated through two test examples by comparing the absolute error of proposed techniques with the existing techniques and the result achieved in this paper benefits (but not limited to) the gas flow dynamics. [ABSTRACT FROM AUTHOR]
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- 2024
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4. The effect of migration on the transmission of HIV/AIDS using a fractional model: Local and global dynamics and numerical simulations.
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Alla Hamou, A., Azroul, E., and L'Kima, S.
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HIV infection transmission , *AIDS , *BASIC reproduction number , *HIV , *COMPUTER simulation , *CAPITAL stock - Abstract
Human immunodeficiency virus (HIV) is a serious disease that threatens and affects capital stock, population composition, and economic growth. This research paper aims to study the mathematical modeling and disease dynamics of HIV/acquired immunodeficiency syndrome (AIDS) with memory effect. We propose two fractional models in the Caputo sense for HIV/AIDS with and without migration. First, we prove the existence and positivity of both models and calculate the basic reproduction number R0$$ {\mathcal{R}}_0 $$ using the next generation method. Then, we study the local and global stability of the obtained equilibria. In addition, numerical simulations are provided for different values of the fractional order ρ$$ \rho $$ using the Adams–Bashforth–Moulton fractional scheme, to verify the theoretical results. Moreover, a sensitivity analysis of the parameters for the model with migration is carried out. [ABSTRACT FROM AUTHOR]
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- 2024
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5. DESIGN AND IMPLEMENTATION OF FUZZY-FRACTIONAL WU–ZHANG SYSTEM USING HE–MOHAND ALGORITHM.
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QAYYUM, MUBASHIR, AHMAD, EFAZA, SOHAIL, MUHAMMAD, SARHAN, NADIA, AWWAD, EMAD MAHROUS, and IQBAL, AMJAD
- Abstract
In recent years, fuzzy and fractional calculus are utilized for simulating complex models with uncertainty and memory effects. This study is focused on fuzzy-fractional modeling of (2+1)-dimensional Wu–Zhang (WZ) system. Caputo-type time-fractional derivative and triangular fuzzy numbers are employed in the model to observe uncertainties in the presence of non-local and memory effects. The extended He–Mohand algorithm is proposed for the solution and analysis of the current model. This approach is based on homotopy perturbation method along with Mohand transformation. Effectiveness of proposed methodology at upper and lower bounds is confirmed through residual errors. The theoretical convergence of proposed algorithm is proved alongside numerical computations. Existence and uniqueness of solution are also theoretically proved in the given paper. Current investigation considers three types of fuzzifications i.e. fuzzified equations, fuzzified conditions, and finally fuzzification in both model and conditions. Different physical aspects of WZ system profiles are analyzed through 2D and 3D illustrations at upper and lower bounds. The obtained results highlight the impact of uncertainty on WZ system in fuzzy-fractional space. Hence, the proposed methodology can be used for other fuzzy-fractional systems for better accuracy with lesser computational cost. [ABSTRACT FROM AUTHOR]
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- 2024
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6. Hyers–Ulam–Rassias stability of fractional delay differential equations with Caputo derivative.
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Benzarouala, Chaimaa and Tunç, Cemil
- Abstract
This paper is devoted to the study of Hyers–Ulam–Rassias (HUR) stability of a nonlinear Caputo fractional delay differential equation (CFrDDE) with multiple variable time delays. We obtain two new theorems with regard to HUR stability of the CFrDDE on bounded and unbounded intervals. The method of the proofs is based on the fixed point approach. The HUR stability results of this paper have indispensable contributions to theory of Ulam stabilities of CFrDDEs and some earlier results in the literature. [ABSTRACT FROM AUTHOR]
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- 2024
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7. Constructing the fractional series solutions for time-fractional K-dV equation using Laplace residual power series technique.
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Yadav, Sanjeev, Vats, Ramesh Kumar, and Rao, Anjali
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POWER series , *ELASTIC wave propagation , *CAPUTO fractional derivatives , *FRACTIONAL powers , *DECOMPOSITION method , *HEAT equation , *LAPLACE transformation - Abstract
In this article, we construct the series solution of the time-fractional Korteveg de Vries (K-dV) equation through a computational approach named as Laplace residual power series (LRPS) that combines the Laplace transform with the residual power series method (RPS). Time-fractional K-dV equation is used to modeled various real life phenomena like propagation of waves in elastic rods, dispersion effects in shallow coastal regions, anomalous diffusion observed in financial markets. The Caputo fractional derivative is used in the formulation of time-fractional K-dV equation. LRPS method is characterized by its rapid convergence and easy finding of the unknown coefficients using the concept of limit at infinity without any perturbation, discretization and linearization. To assess the effectiveness of proposed computational strategy, we perform a comparative analysis among the fractional residual power series method, the Adomian decomposition method, and the RPS method. Additionally, we examine the convergence of the fractional series solution across different α values and assess the solution's behavior as the time domain increased. The efficiency and authenticity of the LRPS method is shown by computing the absolute error, relative error and residual error. This work is supported by 2D and 3D graphical representations made in accordance with Maple and MATLAB. [ABSTRACT FROM AUTHOR]
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- 2024
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8. Distributed Control for Non-Cooperative Systems Governed by Time-Fractional Hyperbolic Operators.
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Serag, Hassan M., Almoneef, Areej A., El-Badawy, Mahmoud, and Hyder, Abd-Allah
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CAPUTO fractional derivatives , *EULER-Lagrange equations , *DYNAMICAL systems - Abstract
This paper studies distributed optimal control for non-cooperative systems involving time-fractional hyperbolic operators. Through the application of the Lax–Milgram theorem, we confirm the existence and uniqueness of weak solutions. Central to our approach is the utilization of the linear quadratic cost functional, which is meticulously crafted to encapsulate the interplay between the system's state and control variables. This functional serves as a pivotal tool in imposing constraints on the dynamic system under consideration, facilitating a nuanced understanding of its controllability. Using the Euler–Lagrange first-order optimality conditions with an adjoint problem defined by means of the right-time fractional derivative in the Caputo sense, we obtain an optimality system for the optimal control. Finally, some examples are analyzed. [ABSTRACT FROM AUTHOR]
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- 2024
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9. A Novel Technique for Solving the Nonlinear Fractional-Order Smoking Model.
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Mohammed Djaouti, Abdelhamid, Khan, Zareen A., Imran Liaqat, Muhammad, and Al-Quran, Ashraf
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POWER series , *SMOKING , *DECOMPOSITION method , *NONLINEAR equations , *BIOLOGICAL systems - Abstract
In the study of biological systems, nonlinear models are commonly employed, although exact solutions are often unattainable. Therefore, it is imperative to develop techniques that offer approximate solutions. This study utilizes the Elzaki residual power series method (ERPSM) to analyze the fractional nonlinear smoking model concerning the Caputo derivative. The outcomes of the proposed technique exhibit good agreement with the Laplace decomposition method, demonstrating that our technique is an excellent alternative to various series solution methods. Our approach utilizes the simple limit principle at zero, making it the easiest way to extract series solutions, while variational iteration, Adomian decomposition, and homotopy perturbation methods require integration. Moreover, our technique is also superior to the residual method by eliminating the need for derivatives, as fractional integration and differentiation are particularly challenging in fractional contexts. Significantly, our technique is simpler than other series solution techniques by not relying on Adomian's and He's polynomials, thereby offering a more efficient way of solving nonlinear problems. [ABSTRACT FROM AUTHOR]
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- 2024
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10. Fractional-Order Sliding Mode Observer for Actuator Fault Estimation in a Quadrotor UAV.
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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
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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]
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- 2024
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11. APPROXIMATE ANALYTICAL SOLUTION OF GENERALIZED FRACTAL EQUAL-WIDTH WAVE EQUATION.
- Author
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Yun QIAO
- Subjects
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WAVE equation , *NONLINEAR differential equations , *CAPUTO fractional derivatives , *ANALYTICAL solutions , *DECOMPOSITION method , *FRACTALS , *PARTIAL differential equations - Abstract
In this paper, a generalized equal width wave equation involving space fractal derivatives and time Caputo fractional derivatives is studied and its approximate analytical solution is presented by the Adomian decomposition method. An example shows that the method is efficient to solve fractal non-linear partial differential equations. [ABSTRACT FROM AUTHOR]
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- 2024
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12. Analysis and numerical simulation of fractional Bloch model arising in magnetic resonance imaging using novel iterative technique.
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Rahul and Prakash, Amit
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MAGNETIC resonance imaging , *NUMERICAL analysis , *INTEGRAL calculus , *BLOCH equations , *COMPUTER simulation - Abstract
The present work investigates Bloch equations arising in magnetic resonance with Caputo and Caputo Fabrizio derivatives. Banach's fixed point approach is used to construct the existence theory for the model's solution. Also, the stability of the solution is established by Ulam–Hyers conditions. A novel 3-step iterative method is used for the considered model's numerical simulation with Caputo and Caputo Fabrizio derivative. This iterative method is formulated by combining Lagrange's interpolation with the fundamental theorem of integral calculus. The proposed method's error estimate is provided. The simulation results are displayed in tabulated and graphical form for distinct values of fractional order. The results demonstrate how the proposed method is accurate and appropriate for analysing fractional Bloch model. Further, this technique can also approximate the solution of other equations arising in engineering physics and quantum fields. [ABSTRACT FROM AUTHOR]
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- 2024
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13. A Quasilinearization Approach for Identification Control Vectors in Fractional-Order Nonlinear Systems.
- Author
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Koleva, Miglena N. and Vulkov, Lubin G.
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NONLINEAR systems , *VECTOR control , *QUASILINEARIZATION , *ORDINARY differential equations , *NONLINEAR differential equations , *TIKHONOV regularization - Abstract
This paper is concerned with solving the problem of identifying the control vector problem for a fractional multi-order system of nonlinear ordinary differential equations (ODEs). We describe a quasilinearization approach, based on minimization of a quadratic functional, to compute the values of the unknown parameter vector. Numerical algorithm combining the method with appropriate fractional derivative approximation on graded mesh is applied to SIS and SEIR problems to illustrate the efficiency and accuracy. Tikhonov regularization is implemented to improve the convergence. Results from computations, both with noisy-free and noisy data, are provided and discussed. Simulations with real data are also performed. [ABSTRACT FROM AUTHOR]
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- 2024
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14. A new application of fractional glucose-insulin model and numerical solutions.
- Author
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ÖZTÜRK, Zafer, BİLGİL, Halis, and SORGUN, Sezer
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EULER method , *BLOOD sugar , *SMALL intestine , *MATHEMATICAL models , *INSULIN , *GLUCOSE , *DIABETES - Abstract
Along with the developing technology, obesity and diabetes are increasing rapidly among people. The identification of diabetes diseases, modeling, predicting their behavior, conducting simulations, studying control and treatment methods using mathematical methods has become of great importance. In this paper, we have obtained numerical solutions by considering the glucose-insulin fractional model. This model consists of three compartments: the blood glucose concentration (G), the blood insulin concentration (I) and the ready-to-absorb glucose concentration (D) in the small intestine. The fractional derivative is used in the sense of Caputo. By performing mathematical analyzes for the Glucose-Insulin fractional mathematical model, numerical results were obtained with the help of the Euler method and graphs were drawn. [ABSTRACT FROM AUTHOR]
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- 2024
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15. On the separation of solutions to fractional differential equations of order α ∈ (1,2).
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Chaudhary, Renu, Diethelm, Kai, and Hashemishahraki, Safoura
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EQUATIONS - Abstract
Given the Caputo-type fractional differential equation D α y (t) = f (t , y (t)) with α ∈ (1 , 2) , we consider two distinct solutions y 1 , y 2 ∈ C [ 0 , T ] to this equation subject to different sets of initial conditions. In this framework, we discuss nontrivial upper and lower bounds for the difference | y 1 (t) − y 2 (t) | for t ∈ [ 0 , T ]. The main emphasis is on describing how such bounds are related to the differences of the associated initial values. [ABSTRACT FROM AUTHOR]
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- 2024
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16. A Study on Fractional SIR Epidemic Model with Vital Dynamics and Variable Population Size using the Residual Power Series Method.
- Author
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Meena, Rakesh Kumar and Kumar, Sushil
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POPULATION dynamics , *POWER series , *FRACTIONAL powers , *GLOBAL analysis (Mathematics) , *EPIDEMICS , *POPULATION density - Abstract
In this paper, we develop an integer and fractional-order susceptible, infectious, and recovery (SIR) epidemic model based on vital dynamics, i.e., birth, death, immigration, and variable population size, including infection and recovery rates. We investigate the stability analysis for the fractional SIR model on the disease-free and endemic equilibrium points. The existence and uniqueness conditions of solutions for a stable model are also discussed. The residual power series (RPS) approach is used to get the semi-analytical solutions of the proposed model in the form of convergent fractional power series. The convergence analysis of the RPS method is also discussed. Numerical results demonstrate the effect of distinct fractional orders α ∈ (0, 1] on the population density. The obtained results are exciting and may be beneficial for medical experts to control the epidemic disease. [ABSTRACT FROM AUTHOR]
- Published
- 2024
17. Analysing the conduction of heat in porous medium via Caputo fractional operator with Sumudu transform.
- Author
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Mohan, Lalit and Prakash, Amit
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HEAT conduction , *POROUS materials , *HEAT equation , *NONEQUILIBRIUM thermodynamics , *CRYSTALS , *FREE convection - Abstract
In this article, we analyse the fractional Cattaneo heat equation for studying the conduction of heat in porous medium. This equation is also used in studying extended irreversible thermodynamics, material, plasma, cosmological model, computational biology, and diffusion theory in crystalline solids. The Sumudu adomian decomposition technique, which is combination of Sumudu transform and a numerical technique, is applied for getting numerical solution. The existence and uniqueness is analysed by using the fixed point theorem and the highest error of the designed technique is also analysed. Finally, the accuracy of the designed numerical method is presented by solving two examples and the findings are compared with the existing method. [ABSTRACT FROM AUTHOR]
- Published
- 2024
18. Analysis of coupled system of q‐fractional Langevin differential equations with q‐fractional integral conditions.
- Author
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Zhang, Keyu, Khalid, Khansa Hina, Zada, Akbar, Popa, Ioan‐Lucian, Xu, Jiafa, and Kallekh, Afef
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DIFFERENTIAL equations , *LANGEVIN equations , *INTEGRAL equations , *NONLINEAR functional analysis , *FUNCTIONAL analysis - Abstract
In this dissertation, we study the coupled system of q$$ q $$‐fractional Langevin differential equations involving q$$ q $$‐Caputo derivative having q$$ q $$‐fractional integral conditions. With the help of some adequate conditions, we investigate the uniqueness and existence of mild solution of the aforementioned system. We also analyze various kinds of Ulam's stability. Banach fixed point theorem and Leray–Schauder of cone type are used to illustrate the existence and uniqueness results. We also used non‐linear functional analysis methods to explore variety of stability types. An example is provided to clearly demonstrate our theoretical outcomes. [ABSTRACT FROM AUTHOR]
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- 2024
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19. Numerical simulation of nonlinear fractional delay differential equations with Mittag-Leffler kernels.
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Odibat, Zaid and Baleanu, Dumitru
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FRACTIONAL differential equations , *DELAY differential equations , *NUMERICAL solutions to nonlinear differential equations , *COMPUTER simulation - Abstract
This study is concerned with finding numerical solutions of nonlinear delay differential equations involving extended Mittag-Leffler fractional derivatives of the Caputo-type. The main benefit of the used extension is to address the complexity resulting from the limitations of using fractional derivatives with non-singular Mittag-Leffler kernels. We discussed the existence and uniqueness of solutions for the studied delay models. Next, we modified an Adams-type method to numerically solve fractional delay differential equations combined with Mittag-Leffler kernels. A new type of solution belonging to the L 1 space is presented for the studied models using the proposed scheme. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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20. Optimal spectral Galerkin approximation for time and space fractional reaction-diffusion equations.
- Author
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Hendy, A.S., Qiao, L., Aldraiweesh, A., and Zaky, M.A.
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RIESZ spaces , *REACTION-diffusion equations , *LAPLACIAN operator , *SPACETIME - Abstract
A one-dimensional space-time fractional reaction-diffusion problem is considered. We present a complete theory for the solution of the time-space fractional reaction-diffusion model, including existence and uniqueness in the case of using the spectral representation of the fractional Laplacian operator. An optimal error estimate is presented for the Galerkin spectral approximation of the problem under consideration. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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21. Approximating fractional calculus operators with general analytic kernel by Stancu variant of modified Bernstein–Kantorovich operators.
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Ali Özarslan, Mehmet
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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
- Full Text
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22. A homotopy-based computational scheme for two-dimensional fractional cable equation.
- Author
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Kumar, C. V. Darshan, Prakasha, D. G., Veeresha, P., and Kapoor, Mamta
- Abstract
In this paper, we examine the time-dependent two-dimensional cable equation of fractional order in terms of the Caputo fractional derivative. This cable equation plays a vital role in diverse areas of electrophysiology and modeling neuronal dynamics. This paper conveys a precise semi-analytical method called the
q -homotopy analysis transform method to solve the fractional cable equation. The proposed method is based on the conjunction of theq -homotopy analysis method and Laplace transform. We explained the uniqueness of the solution produced by the suggested method with the help of Banach’s fixed-point theory. The results obtained through the considered method are in the form of a series solution, and they converge rapidly. The obtained outcomes were in good agreement with the exact solution and are discussed through the 3D plots and graphs that express the physical representation of the considered equation. It shows that the proposed technique used here is reliable, well-organized and effective in analyzing the considered non-homogeneous fractional differential equations arising in various branches of science and engineering. [ABSTRACT FROM AUTHOR]- Published
- 2024
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23. Qualitative analysis of variable‐order fractional differential equations with constant delay.
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Naveen, S. and Parthiban, V.
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FRACTIONAL differential equations , *DELAY differential equations - Abstract
This paper presents the computational analysis of fractional differential equations of variable‐order delay systems. To the proposed problem, the existence of solutions is derived using Arzela‐Ascoli theorem, and the Banach fixed point theorem is used for uniqueness results. To investigate and address the computational solutions, Adams‐Bashforth‐Moulton technique is established. To demonstrate the method's efficiency, computational simulations of chaotic behaviors in several one‐dimensional delayed systems with distinct variable orders are employed. The numerical solution of the proposed problem gives high precision approximations. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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24. A shifted Chebyshev operational matrix method for pantograph‐type nonlinear fractional differential equations.
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Yang, Changqing and Lv, Xiaoguang
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NONLINEAR differential equations , *CAPUTO fractional derivatives , *DIFFERENTIAL equations , *CHEBYSHEV polynomials , *CHEBYSHEV approximation , *FRACTIONAL differential equations - Abstract
In this study, we investigate and analyze an approximation of the Chebyshev polynomials for pantograph‐type fractional‐order differential equations. First, we construct the operational matrices of pantograph and Caputo fractional derivatives using Chebyshev interpolation. Then, the obtained matrices are utilized to approximate the fractional derivative. We also provide a detailed convergence analysis in terms of the weighted square norm. Finally, we describe and discuss the results of three numerical experiments conducted to confirm the applicability and accuracy of the computational scheme. [ABSTRACT FROM AUTHOR]
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- 2024
- Full Text
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25. Explicit scheme for solving variable-order time-fractional initial boundary value problems.
- Author
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Kanwal, Asia, Boulaaras, Salah, Shafqat, Ramsha, Taufeeq, Bilal, and ur Rahman, Mati
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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
- Full Text
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26. New Results on (r , k , μ) -Riemann–Liouville Fractional Operators in Complex Domain with Applications.
- Author
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Tayyah, Adel Salim and Atshan, Waggas Galib
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ORDINARY differential equations , *GENERALIZED integrals , *WAVE equation , *STAR-like functions , *INTEGRAL operators - Abstract
This paper introduces fractional operators in the complex domain as generalizations for the Srivastava–Owa operators. Some properties for the above operators are also provided. We discuss the convexity and starlikeness of the generalized Libera integral operator. A condition for the convexity and starlikeness of the solutions of fractional differential equations is provided. Finally, a fractional differential equation is converted into an ordinary differential equation by wave transformation; illustrative examples are provided to clarify the solution within the complex domain. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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27. An implicit scheme for time-fractional coupled generalized Burgers' equation.
- Author
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Vigo-Aguiar, J., Chawla, Reetika, Kumar, Devendra, and Mazumdar, Tapas
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BURGERS' equation , *HAMBURGERS , *NONLINEAR equations , *QUASILINEARIZATION - Abstract
This article presents an efficient implicit spline-based numerical technique to solve the time-fractional generalized coupled Burgers' equation. The time-fractional derivative is considered in the Caputo sense. The time discretization of the fractional derivative is discussed using the quadrature formula. The quasilinearization process is used to linearize this non-linear problem. In this work, the formulation of the numerical scheme is broadly discussed using cubic B-spline functions. The stability of the proposed method is proved theoretically through Von-Neumann analysis. The reliability and efficiency are demonstrated by numerical experiments that validate theoretical results via tables and plots. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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28. Existence and stability of a q-Caputo fractional jerk differential equation having anti-periodic boundary conditions.
- Author
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Khalid, Khansa Hina, Zada, Akbar, Popa, Ioan-Lucian, and Samei, Mohammad Esmael
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MATHEMATICAL analysis , *FRACTIONAL differential equations , *DIFFERENTIAL equations - Abstract
In this work, we analyze a q-fractional jerk problem having anti-periodic boundary conditions. The focus is on investigating whether a unique solution exists and remains stable under specific conditions. To prove the uniqueness of the solution, we employ a Banach fixed point theorem and a mathematical tool for establishing the presence of distinct fixed points. To demonstrate the availability of a solution, we utilize Leray–Schauder's alternative, a method commonly employed in mathematical analysis. Furthermore, we examine and introduce different kinds of stability concepts for the given problem. In conclusion, we present several examples to illustrate and validate the outcomes of our study. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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29. A novel technique to study the solutions of time fractional nonlinear smoking epidemic model.
- Author
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Pavani, K. and Raghavendar, K.
- Subjects
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DECOMPOSITION method , *SMOKING , *EPIDEMICS , *ANALYTICAL solutions , *SENSITIVITY analysis - Abstract
The primary goal of the current work is to use a novel technique known as the natural transform decomposition method to approximate an analytical solution for the fractional smoking epidemic model. In the proposed method, fractional derivatives are considered in the Caputo, Caputo–Fabrizio, and Atangana–Baleanu–Caputo senses. An epidemic model is proposed to explain the dynamics of drug use among adults. Smoking is a serious issue everywhere in the world. Notwithstanding the overwhelming evidence against smoking, it is nonetheless a harmful habit that is widespread and accepted in society. The considered nonlinear mathematical model has been successfully used to explain how smoking has changed among people and its effects on public health in a community. The two states of being endemic and disease-free, which are when the disease dies out or persists in a population, have been compared using sensitivity analysis. The proposed technique has been used to solve the model, which consists of five compartmental agents representing various smokers identified, such as potential smokers V, occasional smokers G, smokers T, temporarily quitters O, and permanently quitters W. The results of the suggested method are contrasted with those of existing numerical methods. Finally, some numerical findings that illustrate the tables and figures are shown. The outcomes show that the proposed method is efficient and effective. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
30. Fuzzy Fractional Caputo Derivative of Susceptible-Infectious- Removed Epidemic Model for Childhood Diseases.
- Author
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Subramanian, Suganya, Kumaran, Agilan, Ravichandran, Srilekha, Venugopal, Parthiban, Dhahri, Slim, and Ramasamy, Kavikumar
- Subjects
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CAPUTO fractional derivatives , *JUVENILE diseases , *FRACTIONAL differential equations , *LAPLACE transformation , *EPIDEMICS - Abstract
In this work, the susceptible-infectious-removed (SIR) dynamics are considered in relation to the effects on the health system. With the help of the Caputo derivative fractional-order method, the SIR epidemic model for childhood diseases is designed. Subsequenly, a set of sufficient conditions ensuring the existence and uniqueness of the addressed model by choosing proper fuzzy approximation methods. In particular, the fuzzy Laplace method along with the Adomian decomposition transform were employed to better understand the dynamical structures of childhood diseases. This leads to the development of an efficient methodology for solving fuzzy fractional differential equations using Laplace transforms and their inverses, specifically with the Caputo sense derivative. This innovative approach facilitates the numerical resolution of the problem and numerical simulations are executed for considering parameter values. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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31. Stability analysis of a second-order difference scheme for the time-fractional mixed sub-diffusion and diffusion-wave equation.
- Author
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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
- Full Text
- View/download PDF
32. Series and closed form solution of Caputo time-fractional wave and heat problems with the variable coefficients by a novel approach.
- Author
-
Liaqat, Muhammad Imran, Akgül, Ali, and Bayram, Mustafa
- Subjects
- *
POWER series , *FRACTIONAL powers , *DIFFERENTIAL equations , *DECOMPOSITION method , *NONLINEAR equations , *EULER-Lagrange equations , *PHYSIOLOGICAL effects of heat - Abstract
The mathematical efficiency of fractional-order differential equations in modeling real systems has been established. The first-order and second-order time derivatives are substituted in integer-order problems by a fractional derivative of order 0 < ω ≤ 1 , resulting in time-fractional heat and wave problems with variable coefficients. In this research, we analyze fractional-order wave and heat problems with variable coefficients within the framework of a Caputo derivative (CD) using the Elzaki residual power series method (ERPSM), which is a coupling of the residual power series method (RPSM) and the Elzaki transform (E-T). It relies on a novel form of fractional power series (FPS), which provides a convergent series as a solution. The accuracy and convergence rates have been proven by the relative, absolute, and recurrence error analyses, demonstrating the validity of the recommended approach. By employing the simple limit principle at zero, the ERPSM excels at calculating the coefficients of terms in a FPS, but other well-known approaches such as Adomian decomposition, variational iteration, and homotopy perturbation need integration, while the RPSM needs the derivative, both of which are challenging in fractional contexts. ERPSM is also more effective than various series solution methods due to the avoidance of Adomian's and He's polynomials to solve nonlinear problems. The results obtained using the ERPSM show excellent agreement with the natural transform decomposition method and homotopy analysis transform method, demonstrating that the ERPSM is an effective approach for obtaining the approximate and closed-form solutions of fractional models. We established that our approach for fractional models is accurate and straightforward and researcher can use this approach to solve various problems. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
33. Solution of the fractional Liouville equation by using Riemann–Liouville and Caputo derivatives in statistical mechanics.
- Author
-
Korichi, Z., Souigat, A., Bekhouche, R., and Meftah, M. T.
- Subjects
- *
IDEAL gases , *STATISTICAL mechanics , *BURGERS' equation , *EQUATIONS - Abstract
We solve the fractional Liouville equation by using Riemann–Liouville and Caputo derivatives for systems exhibiting noninteger power laws in their Hamiltonians. Based on the fractional Liouville equation, we calculate the density function (DF) of a classical ideal gas. If the Riemann–Liouville derivative is used, the DF is a function depending on both the momentum and the coordinate , but if the derivative in the Caputo sense is used, the DF is a constant independent of and . We also study a gas consisting of fractional oscillators in one-dimensional space and obtain that the DF of the system depends on the type of the derivative. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
34. An Efficient Cubic B-Spline Technique for Solving the Time Fractional Coupled Viscous Burgers Equation.
- Author
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Ghafoor, Usama, Abbas, Muhammad, Akram, Tayyaba, El-Shewy, Emad K., Abdelrahman, Mahmoud A. E., and Abdo, Noura F.
- Subjects
- *
BURGERS' equation , *WATER depth , *SHOCK waves , *QUASILINEARIZATION , *FINITE differences - Abstract
The second order Burger's equation model is used to study the turbulent fluids, suspensions, shock waves, and the propagation of shallow water waves. In the present research, we investigate a numerical solution to the time fractional coupled-Burgers equation (TFCBE) using Crank–Nicolson and the cubic B-spline (CBS) approaches. The time derivative is addressed using Caputo's formula, while the CBS technique with the help of a θ -weighted scheme is utilized to discretize the first- and second-order spatial derivatives. The quasi-linearization technique is used to linearize the non-linear terms. The suggested scheme demonstrates unconditionally stable. Some numerical tests are utilized to evaluate the accuracy and feasibility of the current technique. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
35. On nonlinear Sobolev equation with the Caputo fractional operator and exponential nonlinearity.
- Author
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Duy Binh, Ho, Dinh Huy, Nguyen, Tuan Nguyen, Anh, and Huu Can, Nguyen
- Subjects
- *
NONLINEAR equations , *BLOWING up (Algebraic geometry) , *BANACH spaces , *EXPONENTIAL functions , *LAPLACIAN operator , *INITIAL value problems - Abstract
The initial value problem for the Caputo type time‐fractional Sobolev equation with a nonlinear exponential source function is investigated in this work. We establish the existence and uniqueness of mild solutions corresponding to two different initial data assumptions. We derive global results of a unique mild solution with small initial data using some Sobolev/Sobolev‐Orlicz embeddings, a weighted Banach space, and the fixed point theorem. In the absence of any smallness assumptions, the Cauchy iteration method demonstrates that the mild solution blows up at a finite time or exists globally in time. Finally, we consider some illustrated examples to test the results obtained in theory. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
36. Exploring the interplay between memory effects and vesicle dynamics: A five‐dimensional analysis using rigid sphere models and mapping techniques.
- Author
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Azroul, E., Diki, G., and Guedda, M.
- Subjects
- *
BILAYER lipid membranes , *ERYTHROCYTES , *MEMORY , *FRACTIONAL differential equations - Abstract
The memory effect in vesicle dynamics refers to the persistence of shape changes in lipid vesicles, a type of lipid bilayer membrane that mimics some features of real cells, particularly red blood cells (RBCs). To study this effect, a fractional rigid sphere model in five dimensions has been investigated, which maps the dynamics of a vesicle using the Caputo operator. This model provides new insights into the mechanisms behind the memory effect as well as the emergence of two other motions, namely, tank‐treading with underdamped and tank‐treading with overdamped vesicle oscillations, in addition to the tank‐treading mode where the vesicle rotates about its axis while maintaining a constant shape. Overall, this work represents a significant advance in our understanding of vesicle dynamics and has important implications for understanding the behavior of RBCs. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
37. Stability and numerical analysis of fractional BBM-Burger equation and fractional diffusion-wave equation with Caputo derivative.
- Author
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Mohan, Lalit and Prakash, Amit
- Subjects
- *
NUMERICAL analysis , *LAPLACE transformation , *GRAVITY waves , *ROOT-mean-squares , *SOUND waves , *THEORY of wave motion - Abstract
This paper gives a highly efficient technique to analyse the fractional BBM-Burger equation and fractional Diffusion-Wave equation. These equations are used to model various real-life phenomena like acoustic gravity waves, diffusion theory, anomalous diffusive systems, and wave propagation phenomena. A modified technique, which is the combination of the Homotopy perturbation method and Laplace transform, is used for getting the numerical solution. The Lyapunov function is used to investigate asymptotic stability, and the maximum absolute error for the proposed technique is also examined. The efficiency of the proposed technique is shown by computing the root mean square (RMS), L 2 , and L ∞ errors and comparing the results with the other techniques. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
38. investigating nonlinear fractional systems: reproducing kernel Hilbert space method.
- Author
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Attia, Nourhane, Akgül, Ali, and Alqahtani, Rubayyi T.
- Subjects
- *
NONLINEAR systems , *FRACTIONAL differential equations , *DECOMPOSITION method , *ORDINARY differential equations , *HILBERT space - Abstract
The reproducing kernel Hilbert space method (RK-HS method) is used in this research for solving some important nonlinear systems of fractional ordinary differential equations, such as the fractional Susceptible-Infected-Recovered (SIR) model. Nonlinear systems are widely used across various disciplines, including medicine, biology, technology, and numerous other fields. To evaluate the RK-HS method's accuracy and applicability, we compare its numerical solutions with those obtained via Hermite interpolation, the Adomian decomposition method, and the residual power series method. To further support the reliability of the RK-HS method, the convergence analysis is discussed. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
39. An analytical approach for the fractional-order Hepatitis B model using new operator.
- Author
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Ghosh, Surath
- Subjects
- *
HEPATITIS B , *HEPATITIS , *INTEGERS - Abstract
In this work, the main goal is to implement Homotopy perturbation transform method (HPTM) involving Katugampola fractional operator. As an example, a fractional order Hepatitis model is considered to analyze the solutions. At first, the integer order model is converted to fractional order model in Caputo sense. Then, the new operator Katugampola fractional derivative is used to present the model. The new such kind of operator is illustrated in Caputo sense. HPTM is described to get the solution of the proposed model using the new kind of operator. Also, there are some analyses about the new kind of operator to prove the efficiency of the operator. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
40. Fractional Optimal Control Model and Bifurcation Analysis of Human Syncytial Respiratory Virus Transmission Dynamics.
- Author
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Awadalla, Muath, Alahmadi, Jihan, Cheneke, Kumama Regassa, and Qureshi, Sania
- Subjects
- *
INFECTIOUS disease transmission , *RESPIRATORY syncytial virus , *BASIC reproduction number , *BEHAVIORAL assessment , *HAMILTON'S principle function - Abstract
In this paper, the Caputo-based fractional derivative optimal control model is looked at to learn more about how the human respiratory syncytial virus (RSV) spreads. Model solution properties such as boundedness and non-negativity are checked and found to be true. The fundamental reproduction number is calculated by using the next-generation matrix's spectral radius. The fractional optimal control model includes the control functions of vaccination and treatment to illustrate the impact of these interventions on the dynamics of virus transmission. In addition, the order of the derivative in the fractional optimal control problem indicates that encouraging vaccination and treatment early on can slow the spread of RSV. The overall analysis and the simulated behavior of the fractional optimum control model are in good agreement, and this is due in large part to the use of the MATLAB platform. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
41. Collocation-based numerical simulation of fractional order Allen–Cahn equation.
- Author
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Choudhary, Renu and Kumar, Devendra
- Subjects
- *
FINITE differences , *COMPUTER simulation , *NUMERICAL analysis , *EQUATIONS , *COLLOCATION methods - Abstract
This article looks for a reliable numerical technique to solve the Allen–Cahn equation using the Caputo time-fractional derivative. The fractional derivative semi-discretization approach using finite differences of the second order is shown first. The cubic B-spline collocation method is used to get a full discretization. We prove the conditional stability and convergence of the suggested approach. The technique's effectiveness is demonstrated with numerical examples using two test problems. Numerical analysis confirms the approach's efficiency and the method's continued correctness. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
42. On collocation-Galerkin method and fractional B-spline functions for a class of stochastic fractional integro-differential equations.
- Author
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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
- Full Text
- View/download PDF
43. A finite difference method on quasi-uniform grids for the fractional boundary-layer Blasius flow.
- Author
-
Jannelli, Alessandra
- Subjects
- *
FINITE difference method , *BOUNDARY value problems , *FINITE differences , *SEISMIC waves , *NONLINEAR boundary value problems - Abstract
In this paper, we propose a fractional formulation, in terms of the Caputo derivative, of the Blasius flow described by a non-linear two-point fractional boundary value problem on a semi-infinite interval. We develop a finite difference method on quasi-uniform grids, based on a suitable modification of the classical L1 approximation formula and show the consistency, the stability and the convergence. The numerical results confirm the theoretical ones. Comparisons with some recently proposed results are carried out to validate the accuracy of the obtained numerical results, and to show the efficiency and the reliability of the proposed numerical method. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
44. A fractional modeling approach for the transmission dynamics of measles with double-dose vaccination.
- Author
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Farhan, Muhammad, Shah, Zahir, Jan, Rashid, Islam, Saeed, Alshehri, Mansoor H., and Ling, Zhi
- Abstract
AbstractMeasles, a member of the Paramyxoviridae family and the Morbillivirus genus, is an infectious disease caused by the measles virus that is extremely contagious and can be prevented through vaccination. When a person with the measles coughs or sneezes, the virus is disseminated by respiratory droplets. Normally, the appearance of measles symptoms takes 10–14 d following viral exposure. Conjunctivitis, a high temperature, a cough, a runny nose, and a distinctive rash are some of the symptoms. Despite the measles vaccination being available, it is still widespread worldwide. To eradicate measles, the Reproduction Number (i.e. R0<1) must remain less than unity. This study examines a
SEIVR compartmental model in the caputo sense using a double dose of vaccine to simulate the measles outbreak. The reproduction number R0 and model properties are both thoroughly examined. Both the local and global stabilities of the proposed model are determined for R0 less and greater than 1. To achieve the model’s global stability, the Lyapunov function is used while the existence and uniqueness of the proposed model are demonstrated In addition to the calculated and fitted biological parameters, the forward sensitivity indices for R0 are also obtained. Simulations of the proposed fractional order (FO) caputo model are performed in order to analyse their graphical representations and the significance of FO derivatives to illustrate how our theoretical findings have an impact. The graphical results show that the measles outbreak is reduced by increasing vaccine dosage rates. [ABSTRACT FROM AUTHOR]- Published
- 2023
- Full Text
- View/download PDF
45. Strong Stationarity for Optimal Control Problems with Non-smooth Integral Equation Constraints: Application to a Continuous DNN.
- Author
-
Antil, Harbir, Betz, Livia, and Wachsmuth, Daniel
- Abstract
Motivated by the residual type neural networks (ResNet), this paper studies optimal control problems constrained by a non-smooth integral equation associated to a fractional differential equation. Such non-smooth equations, for instance, arise in the continuous representation of fractional deep neural networks (DNNs). Here the underlying non-differentiable function is the ReLU or max function. The control enters in a nonlinear and multiplicative manner and we additionally impose control constraints. Because of the presence of the non-differentiable mapping, the application of standard adjoint calculus is excluded. We derive strong stationary conditions by relying on the limited differentiability properties of the non-smooth map. While traditional approaches smoothen the non-differentiable function, no such smoothness is retained in our final strong stationarity system. Thus, this work also closes a gap which currently exists in continuous neural networks with ReLU type activation function. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
46. 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
- Full Text
- View/download PDF
47. A novel robust fractional-time anisotropic diffusion for multi-frame image super-resolution.
- Author
-
Ben-loghfyry, Anouar and Hakim, Abdelilah
- Abstract
In this paper, we propose an image multi-frame Super Resolution (SR) method based on fractional-time Caputo derivative combined with Weickert-type diffusion process idea. We provide the existence and uniqueness results with a detailed discretization using the finite difference scheme. Our approach is based on anisotropic diffusion behavior with coherence enhancing diffusion tensor together with the fractional-time derivative to benefit from its memory effect potential and to control the smoothing process near strong edges and flat regions while avoiding tiny corners destruction. The experimental results confirm the effectiveness of fractional-time derivative and the robustness of the proposed Partial Differential Equation (PDE) compared with some competitive super-resolution methods. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
48. Unique solutions, stability and travelling waves for some generalized fractional differential problems.
- Author
-
Rakah, Mahdi, Gouari, Yazid, Ibrahim, Rabha W., Dahmani, Zoubir, and Kahtan, Hasan
- Subjects
- *
DUFFING equations , *SINE-Gordon equation , *MATHEMATICAL models , *TRAVELING exhibitions , *INFINITE series (Mathematics) , *ENGINEERING systems - Abstract
The type of symmetry exhibited by a travelling wave can have important implications for its behaviour and properties, such as its polarization, dispersion, and interactions with other waves or boundaries. The fractional differential Duffing problem refers to the mathematical modelling of nonlinear, damped oscillations of a system with fractional derivatives. It is a generalization of the classical Duffing equation, which describes the behaviour of a nonlinear, damped oscillator (the equation becomes symmetric under time-reversal). The fractional derivatives allow for a more accurate description of the system's memory and hereditary properties. The solution of the fractional Duffing equation can provide insight into the complex dynamic behaviour of various physical, biological, and engineering systems. We are concerned with studying a new differential Duffing fractional problem. It involves some sequential Caputo derivatives with an infinite series of Riemann-Liouville integrals and some other functions. We begin by proving a first existence and uniqueness result, then we discuss two types of stability for the obtained uniqueness result. An illustrative examples is given to show the applicability of the result. We are also concerned with applying the Tanh method to obtain new classes of travelling wave solutions for three important classes of (Khalil) fractional conformable problems; the generalized equation of Duffing, the Landau-Ginzburg-Higgs equation and the Sine-Gordon one. Some numerical simulations are plotted and a conclusion is given at the end. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
49. A fractional-order model for computer viruses and some solution associated with residual power series method.
- Author
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Al-Jarrah, A., Alquran, M., Freihat, A., Al-Omari, S., and Nonlaopon, K.
- Subjects
- *
COMPUTER viruses , *COMPUTER simulation , *CAPUTO fractional derivatives , *EPIDEMIOLOGICAL models , *RUNGE-Kutta formulas , *POWER series , *SMART devices - Abstract
Awareness of virus spreading is an important issue for building various defence strategies and protecting personal computers, smart devices, network devices, etc. In this research work, we develop epidemiological models to address this problem and introduce certain modified epidemiological fractional SAIR model, where we consider the fractional derivative in Caputo sense. We utilize the residual power series method to construct approximate solutions for the governing system. To show the efficiency and suitability of the proposed technique, we introduce a comparative between the obtained solutions and those solutions that are constructed using the fourth-order Runge-Kutta method. We derive some numerical results by considering specific values for the parameters in the governing model, and then we depict some of these results into two and three dimensions. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
50. An Approximate Analytic Solution for the Multidimensional Fractional-Order Time and Space Burger Equation Based on Caputo-Katugampola Derivative.
- Author
-
Sawangtong, Wannika, Ikot, Akpan N., and Sawangtong, Panumart
- Abstract
The Burger equation has been widely used to study nonlinear acoustic plane waves in gas-filled tubes, waves in shallow water, and shock waves in gas. Recently, a more comprehensive version of the equation, known as the fractional-order Burger equation, has emerged. However, finding a closed-form for approximate analytic solution using analytical methods for this type of equation is challenging. This paper focuses on researching the multidimensional fractional-order time and space Burger equation based on the Caputo-Katugampola derivative. An approximate analytic solution is obtained using the generalized Laplace homotopy perturbation method. The coefficients of the approximate analytic solution have a recurrence relation similar to the Catalan number in number theory, and the closed form of the approximate analytic solution can be obtained using number theory knowledge. It is worth noting that the Caputo-Katugampola derivative can be reduced to the Caputo derivative, and hence, the closed form for the approximate analytic solution of the multidimensional fractional-order time and space Burger equation based on the Caputo derivative is also obtained. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
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