Your search keyword '"Jorge Eduardo Macías-Díaz"' showing total 10 results

1. An Exterior Neumann Boundary-Value Problem for the Div-Curl System and Applications

Author

Briceyda B. Delgado and Jorge Eduardo Macías-Díaz

Subjects

div-curl system, exterior domains, Neumann boundary-value problem, Lamé–Navier equation, maximum principle, harmonic functions, Mathematics, QA1-939

Abstract

We investigate a generalization of the equation curlw→=g→ to an arbitrary number n of dimensions, which is based on the well-known Moisil–Teodorescu differential operator. Explicit solutions are derived for a particular problem in bounded domains of Rn using classical operators from Clifford analysis. In the physically significant case n=3, two explicit solutions to the div-curl system in exterior domains of R3 are obtained following different constructions of hyper-conjugate harmonic pairs. One of the constructions hinges on the use of a radial integral operator introduced recently in the literature. An exterior Neumann boundary-value problem is considered for the div-curl system. That system is conveniently reduced to a Neumann boundary-value problem for the Laplace equation in exterior domains. Some results on its uniqueness and regularity are derived. Finally, some applications to the construction of solutions of the inhomogeneous Lamé–Navier equation in bounded and unbounded domains are discussed.

Published

2021

2. An Efficient Discrete Model to Approximate the Solutions of a Nonlinear Double-Fractional Two-Component Gross–Pitaevskii-Type System

Author

Nuria Reguera, Jorge Eduardo Macías-Díaz, and Adán J. Serna-Reyes

Subjects

Spacetime, Differential equation, Generalization, Continuous modelling, General Mathematics, fractional Bose–Einstein model, fully discrete model, double-fractional system, Fractional calculus, Nonlinear system, stability and convergence analysis, Convergence (routing), Computer Science (miscellaneous), QA1-939, Applied mathematics, Multidimensional systems, Engineering (miscellaneous), Mathematics

Abstract

In this work, we introduce and theoretically analyze a relatively simple numerical algorithm to solve a double-fractional condensate model. The mathematical system is a generalization of the famous Gross–Pitaevskii equation, which is a model consisting of two nonlinear complex-valued diffusive differential equations. The continuous model studied in this manuscript is a multidimensional system that includes Riesz-type spatial fractional derivatives. We prove here the relevant features of the numerical algorithm, and illustrative simulations will be shown to verify the quadratic order of convergence in both the space and time variables.

Published

2021

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

Author

Briceyda B. Delgado and Jorge Eduardo Macías-Díaz

Subjects

Statistics and Probability, Curl (mathematics), QA299.6-433, Vector operator, Generalization, Riemann–Liouville derivative, fractional vector operators, Statistical and Nonlinear Physics, Space (mathematics), Dirac operator, Caputo derivative, Fractional calculus, Divergence, symbols.namesake, Helmholtz decomposition theorem, fractional div-curl systems, symbols, QA1-939, Applied mathematics, Thermodynamics, QC310.15-319, Helmholtz decomposition, Mathematics, Analysis

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.

Published

2021

4. A Mass- and Energy-Conserving Numerical Model for a Fractional Gross–Pitaevskii System in Multiple Dimensions

Author

Jorge Eduardo Macías-Díaz and Adán J. Serna-Reyes

Subjects

Discretization, General Mathematics, conservation of energy, 010103 numerical & computational mathematics, 01 natural sciences, symbols.namesake, stability and convergence analysis, Computer Science (miscellaneous), Riesz space-fractional derivatives, QA1-939, Applied mathematics, 0101 mathematics, Engineering (miscellaneous), Conservation of mass, Mathematics, conservation of mass, Conservation of energy, Partial differential equation, Continuous modelling, linearly implicit model, fractional Gross–Pitaevskii system, 010101 applied mathematics, Bounded function, symbols, Hamiltonian (quantum mechanics), Constant (mathematics)

Abstract

This manuscript studies a double fractional extended p-dimensional coupled Gross–Pitaevskii-type system. This system consists of two parabolic partial differential equations with equal interaction constants, coupling terms, and spatial derivatives of the Riesz type. Associated with the mathematical model, there are energy and non-negative mass functions which are conserved throughout time. Motivated by this fact, we propose a finite-difference discretization of the double fractional Gross–Pitaevskii system which inherits the energy and mass conservation properties. As the continuous model, the mass is a non-negative constant and the solutions are bounded under suitable numerical parameter assumptions. We prove rigorously the existence of solutions for any set of initial conditions. As in the continuous system, the discretization has a discrete Hamiltonian associated. The method is implicit, multi-consistent, stable and quadratically convergent. Finally, we implemented the scheme computationally to confirm the validity of the mass and energy conservation properties, obtaining satisfactory results.

Published

2021

5. An Economic Model for OECD Economies with Truncated M-Derivatives: Exact Solutions and Simulations

Author

L. A. Quezada-Téllez, Jorge Eduardo Macías-Díaz, Guillermo Fernández-Anaya, Dominique Brun-Battistini, and Benjamín Nuñez-Zavala

Subjects

General Mathematics, Depreciation, Convergence (economics), Function (mathematics), 01 natural sciences, Solow growth model, truncated M-derivative, 010305 fluids & plasmas, 010101 applied mathematics, Inada conditions, Economy, fractional operators, Capital (economics), 0103 physical sciences, Computer Science (miscellaneous), Per capita, Economics, QA1-939, Economic model, 0101 mathematics, Divergence (statistics), Engineering (miscellaneous), Mathematics

Abstract

This article proposes two conformal Solow models (with and without migration), accompanied by simulations for six Organisation for Economic Co-operation and Development economies. The models are proposed by employing suitable Inada conditions on the Cobb–Douglas function and making use of the truncated M-derivative for the Mittag–Leffler function. In the exact solutions derived in this manuscript, two new parameters play an important role in the convergence towards, or the divergence from, the steady state of capital and per capita product. The economical dynamics of these nations are influenced by the intensity of the capital and labor factors, as well as the level of depreciation, the labor force rate and the level of saving.

Published

2021

6. A Convergent Three-Step Numerical Method to Solve a Double-Fractional Two-Component Bose–Einstein Condensate

Author

Adán J. Serna-Reyes, Jorge Eduardo Macías-Díaz, and Nuria Reguera

Subjects

General Mathematics, 01 natural sciences, Dirichlet distribution, double-fractional system, 010305 fluids & plasmas, law.invention, symbols.namesake, law, 0103 physical sciences, Computer Science (miscellaneous), QA1-939, Applied mathematics, 0101 mathematics, Engineering (miscellaneous), Mathematics, numerically efficient scheme, Partial differential equation, two-component Bose–Einstein condensate, Spacetime, Numerical analysis, Finite difference, Fractional calculus, 010101 applied mathematics, Nonlinear system, symbols, Bose–Einstein condensate

Abstract

This manuscript introduces a discrete technique to estimate the solution of a double-fractional two-component Bose–Einstein condensate. The system consists of two coupled nonlinear parabolic partial differential equations whose solutions are two complex functions, and the spatial fractional derivatives are interpreted in the Riesz sense. Initial and homogeneous Dirichlet boundary data are imposed on a multidimensional spatial domain. To approximate the solutions, we employ a finite difference methodology. We rigorously establish the existence of numerical solutions along with the main numerical properties. Concretely, we show that the scheme is consistent in both space and time as well as stable and convergent. Numerical simulations in the one-dimensional scenario are presented in order to show the performance of the scheme. For the sake of convenience, A MATLAB code of the numerical model is provided in the appendix at the end of this work.

Published

2021

7. A Numerical Schemefor the Probability Density of the First Hitting Time for Some Random Processes

Author

Jorge Eduardo Macías-Díaz

Subjects

Physics and Astronomy (miscellaneous), Stochastic modelling, General Mathematics, theoretical analysis, Monotonic function, Probability density function, 010103 numerical & computational mathematics, probability distribution function of the first hitting time, 01 natural sciences, Stability (probability), advection–diffusion problem, Computer Science (miscellaneous), Applied mathematics, 0101 mathematics, Mathematics, Stochastic process, lcsh:Mathematics, moving boundary problem, Boundary problem, Hitting time, implicit finite-difference model, lcsh:QA1-939, 010101 applied mathematics, Chemistry (miscellaneous), spatially symmetric discrete model, Random variable

Abstract

Departing from a general stochastic model for a moving boundary problem, we consider the density function of probability for the first passing time. It is well known that the distribution of this random variable satisfies a problem ruled by an advection&ndash, diffusion system for which very few solutions are known in exact form. The model considers also a deterministic source, and the coefficients of this equation are functions with sufficient regularity. A numerical scheme is designed to estimate the solutions of the initial-boundary-value problem. We prove rigorously that the numerical model is capable of preserving the main characteristics of the solutions of the stochastic model, that is, positivity, boundedness and monotonicity. The scheme has spatial symmetry, and it is theoretically analyzed for consistency, stability and convergence. Some numerical simulations are carried out in this work to assess the capability of the discrete model to preserve the main structural features of the solutions of the model. Moreover, a numerical study confirms the efficiency of the scheme, in agreement with the mathematical results obtained in this work.

Published

2020

8. Analysis of Structure-Preserving Discrete Models for Predator-Prey Systems with Anomalous Diffusion

Author

Joel Alba-Pérez and Jorge Eduardo Macías-Díaz

Subjects

Generality, Work (thermodynamics), Partial differential equation, Anomalous diffusion, Computer science, Continuous modelling, General Mathematics, 010102 general mathematics, Structure (category theory), structure-preserving methods, 01 natural sciences, 010101 applied mathematics, Population model, Bounded function, Riesz space-fractional diffusion, nonlinear population models, Computer Science (miscellaneous), Quantitative Biology::Populations and Evolution, Applied mathematics, systems of parabolic partial differential equations, stability and convergence analyses, 0101 mathematics, Engineering (miscellaneous)

Abstract

In this work, we investigate numerically a system of partial differential equations that describes the interactions between populations of predators and preys. The system considers the effects of anomalous diffusion and generalized Michaelis&ndash, Menten-type reactions. For the sake of generality, we consider an extended form of that system in various spatial dimensions and propose two finite-difference methods to approximate its solutions. Both methodologies are presented in alternative forms to facilitate their analyses and computer implementations. We show that both schemes are structure-preserving techniques, in the sense that they can keep the positive and bounded character of the computational approximations. This is in agreement with the relevant solutions of the original population model. Moreover, we prove rigorously that the schemes are consistent discretizations of the generalized continuous model and that they are stable and convergent. The methodologies were implemented efficiently using MATLAB. Some computer simulations are provided for illustration purposes. In particular, we use our schemes in the investigation of complex patterns in some two- and three-dimensional predator&ndash, prey systems with anomalous diffusion.

Published

2019

9. Analysis and Nonstandard Numerical Design of a Discrete Three-Dimensional Hepatitis B Epidemic Model

Author

Muhammad Rafiq, Nauman Ahmed, and Jorge Eduardo Macías-Díaz

Subjects

0303 health sciences, Work (thermodynamics), Computer science, splitting methods, General Mathematics, Stability (learning theory), hepatitis B epidemic dynamics, 010103 numerical & computational mathematics, 01 natural sciences, 03 medical and health sciences, Nonlinear system, Numerical design, Consistency (statistics), Convergence (routing), Computer Science (miscellaneous), Quantitative Biology::Populations and Evolution, Applied mathematics, 0101 mathematics, nonstandard finite-difference method, Epidemic model, Engineering (miscellaneous), stability and bifurcation analyses, Bifurcation, 030304 developmental biology

Abstract

In this work, we numerically investigate a three-dimensional nonlinear reaction-diffusion susceptible-infected-recovered hepatitis B epidemic model. To that end, the stability and bifurcation analyses of the mathematical model are rigorously discussed using the Routh&ndash, Hurwitz condition. Numerically, an efficient structure-preserving nonstandard finite-difference time-splitting method is proposed to approximate the solutions of the hepatitis B model. The dynamical consistency of the splitting method is verified mathematically and graphically. Moreover, we perform a mathematical study of the stability of the proposed scheme. The properties of consistency, stability and convergence of our technique are thoroughly analyzed in this work. Some comparisons are provided against existing standard techniques in order to validate the efficacy of our scheme. Our computational results show a superior performance of the present approach when compared against existing methods available in the literature.

Published

2019

10. Numerically Efficient Methods for Variational Fractional Wave Equations: An Explicit Four-Step Scheme

Author

Jorge Eduardo Macías-Díaz

Subjects

Anomalous diffusion, Continuous modelling, General Mathematics, Numerical analysis, variational fractional wave equation, analyses of stability and convergence, 010103 numerical & computational mathematics, Wave equation, 01 natural sciences, Fractional calculus, 010101 applied mathematics, Discrete system, Rate of convergence, Riesz space-fractional diffusion, Computer Science (miscellaneous), Dissipative system, Applied mathematics, variational finite-difference scheme, 0101 mathematics, Engineering (miscellaneous), Mathematics

Abstract

In this work, we investigate numerically a one-dimensional wave equation in generalized form. The system considers the presence of constant damping and functional anomalous diffusion of the Riesz type. Reaction terms are also considered, in such way that the mathematical model can be presented in variational form when damping is not present. As opposed to previous efforts available in the literature, the reaction terms are not only functions of the solution. Instead, we consider the presence of smooth functions that depend on fractional derivatives of the solution function. Using a finite-difference approach, we propose a numerical scheme to approximate the solutions of the fractional wave equation. Along with this integrator, we propose discrete forms of the local and the total energy operators. In a first stage, we show rigorously that the energy properties of the continuous system are mimicked by our discrete methodology. In particular, we prove that the discrete system is dissipative (respectively, conservative) when damping is present (respectively, absent), in agreement with the continuous model. The theoretical numerical analysis of this system is more complicated in light of the presence of the functional form of the anomalous diffusion. To solve this problem, some novel technical lemmas are proved and used to establish the stability and the quadratic convergence of the scheme. Finally, we provide some computer simulations to show the capability of the scheme to conserve/dissipate the energy. Various fractional problems with functional forms of the anomalous diffusion of the solution are considered to that effect.

Published

2019