Startseite New Results from Old Investigation: A Note on Fractional M-Dimensional Differential Operators. The Fractional Laplacian
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New Results from Old Investigation: A Note on Fractional M-Dimensional Differential Operators. The Fractional Laplacian

  • Humberto Prado EMAIL logo , Margarita Rivero , Juan J. Trujillo und M. Pilar Velasco
Veröffentlicht/Copyright: 13. März 2015
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Fractional Calculus and Applied Analysis
Aus der Zeitschrift Fractional Calculus and Applied Analysis Band 18 Heft 2

Abstract

The non local fractional Laplacian plays a relevant role when modeling the dynamics of many processes through complex media. From 1933 to 1949, within the framework of potential theory, the Hungarian mathematician Marcel Riesz discovered the well known Riesz potential operators, a generalization of the Riemann-Liouville fractional integral to dimension higher than one. The scope of this note is to highlight that in the above mentioned works, Riesz also gave the necessary tools to introduce several new definitions of the generalized coupled fractional Laplacian which can be applied to much wider domains of functions than those given in the literature, which are based in both the theory of fractional power of operators or in certain hyper-singular integrals. Moreover, we will introduce the corresponding fractional hyperbolic differential operator also called fractional Lorentzian Laplacian.

Keywords : n-dimensional fractional operators; fractional Laplacian; fractional Lorentzian Laplacian; Riesz potencial operators; fractional spatial derivatives; Riemann-Liouville operators

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Received: 2014-7-31
Published Online: 2015-3-13
Published in Print: 2015-4-1

© 2015 Diogenes Co., Sofia

Artikel in diesem Heft

  1. Contents
  2. Fcaa Related News, Events and Books (Fcaa–Volume 18–2–2015)
  3. New Results from Old Investigation: A Note on Fractional M-Dimensional Differential Operators. The Fractional Laplacian
  4. Pollutant Reduction of a Turbocharged Diesel Engine Using a Decentralized Mimo Crone Controller
  5. Experimental Implications of Bochner-Levy-Riesz Diffusion
  6. Fractional Diffusion on Bounded Domains
  7. On a System of Fractional Differential Equations with Coupled Integral Boundary Conditions
  8. A Numerical Approach for Fractional Order Riccati Differential Equation Using B-Spline Operational Matrix
  9. Solving Fractional Delay Differential Equations: A New Approach
  10. Formal Consistency Versus Actual Convergence Rates of Difference Schemes for Fractional-Derivative Boundary Value Problems
  11. Asymptotic Stability Of Dynamic Equations With Two Fractional Terms: Continuous Versus Discrete Case
  12. Analysis of Natural and Artificial Phenomena Using Signal Processing and Fractional Calculus
  13. Fractional Approach for Estimating Sap Velocity in Trees
  14. Fractional Calculus: Quo Vadimus? (Where are we Going?)
https://doi.org/10.1515/fca-2015-0020
Schlagwörter für diesen Artikel
n-dimensional fractional operators; fractional Laplacian; fractional Lorentzian Laplacian; Riesz potencial operators; fractional spatial derivatives; Riemann-Liouville operators

Artikel in diesem Heft

  1. Contents
  2. Fcaa Related News, Events and Books (Fcaa–Volume 18–2–2015)
  3. New Results from Old Investigation: A Note on Fractional M-Dimensional Differential Operators. The Fractional Laplacian
  4. Pollutant Reduction of a Turbocharged Diesel Engine Using a Decentralized Mimo Crone Controller
  5. Experimental Implications of Bochner-Levy-Riesz Diffusion
  6. Fractional Diffusion on Bounded Domains
  7. On a System of Fractional Differential Equations with Coupled Integral Boundary Conditions
  8. A Numerical Approach for Fractional Order Riccati Differential Equation Using B-Spline Operational Matrix
  9. Solving Fractional Delay Differential Equations: A New Approach
  10. Formal Consistency Versus Actual Convergence Rates of Difference Schemes for Fractional-Derivative Boundary Value Problems
  11. Asymptotic Stability Of Dynamic Equations With Two Fractional Terms: Continuous Versus Discrete Case
  12. Analysis of Natural and Artificial Phenomena Using Signal Processing and Fractional Calculus
  13. Fractional Approach for Estimating Sap Velocity in Trees
  14. Fractional Calculus: Quo Vadimus? (Where are we Going?)
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