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Inverse problems for a class of degenerate evolution equations with Riemann – Liouville derivative

  • Vladimir E. Fedorov EMAIL logo and Roman R. Nazhimov
Published/Copyright: May 11, 2019
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Fractional Calculus and Applied Analysis
From the journal Fractional Calculus and Applied Analysis Volume 22 Issue 2

Abstract

Unique solvability and well-posedness issues are studied for linear inverse problems with a constant unknown parameter to fractional order differential equations with Riemann – Liouvlle derivative in Banach spaces. Firstly, well-posedness criteria for the inverse problem with the Cauchy type initial conditions to the differential equation in a Banach space that solved with respect to the fractional derivative is obtained. This result is applied to search of sufficient conditions for the unique solution existence of the inverse problem for equation with linear degenerate operator at the Riemann – Liouville fractional derivative. It is shown that the presence of the matching conditions for the data of the problem excludes the possibility of the well-posedness consideration for the degenerate inverse problem with the Cauchy type condition. But for the inverse problem with the Showalter – Sidorov type conditions it is found the criteria of the well-posedness. Abstract results are used to the search of conditions of the unique solvability for an inverse problem to a class of partial differential equations of time-fractional order with polynomials of elliptic differential operators with respect to the spatial variables.

MSC 2010: Primary 35R30; Secondary 34G10; 35R11; 34A08
Key Words and Phrases: fractional Riemann – Liouville derivative; inverse problem; degenerate evolution equation; (L, p)-bounded operator

Acknowledgements

This paper has been partially supported by Act 211 of Government of the Russian Federation, contract 02.A03.21.0011, and by Ministry of Education and Science of the Russian Federation, task No 1.6462.2017/BCh.

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Received: 2018-03-26
Published Online: 2019-05-11
Published in Print: 2019-04-24

© 2019 Diogenes Co., Sofia

Articles in the same Issue

  1. Frontmatter
  2. Editorial Note
  3. FCAA related news, events and books (FCAA–Volume 22–2–2019)
  4. Discussion Paper
  5. The flaw in the conformable calculus: It is conformable because it is not fractional
  6. The failure of certain fractional calculus operators in two physical models
  7. Research Paper
  8. Inverse problems for a class of degenerate evolution equations with Riemann – Liouville derivative
  9. On Riesz derivative
  10. A note on fractional powers of strongly positive operators and their applications
  11. Semi-fractional diffusion equations
  12. Extremum principle for the Hadamard derivatives and its application to nonlinear fractional partial differential equations
  13. Well-posedness of fractional degenerate differential equations in Banach spaces
  14. Structure factors for generalized grey Browinian motion
  15. Linear stationary fractional differential equations
  16. Perfect control for right-invertible Grünwald-Letnikov plants – an innovative approach to practical implementation
  17. On fractional differential inclusions with Nonlocal boundary conditions
  18. On solutions of linear fractional differential equations and systems thereof
  19. Existence of mild solution of a class of nonlocal fractional order differential equation with not instantaneous impulses
  20. A CAD-based algorithm for solving stable parameter region of fractional-order systems with structured perturbations
  21. On representation and interpretation of Fractional calculus and fractional order systems
https://doi.org/10.1515/fca-2019-0018
Keywords for this article
fractional Riemann – Liouville derivative; inverse problem; degenerate evolution equation; (L, p)-bounded operator

Articles in the same Issue

  1. Frontmatter
  2. Editorial Note
  3. FCAA related news, events and books (FCAA–Volume 22–2–2019)
  4. Discussion Paper
  5. The flaw in the conformable calculus: It is conformable because it is not fractional
  6. The failure of certain fractional calculus operators in two physical models
  7. Research Paper
  8. Inverse problems for a class of degenerate evolution equations with Riemann – Liouville derivative
  9. On Riesz derivative
  10. A note on fractional powers of strongly positive operators and their applications
  11. Semi-fractional diffusion equations
  12. Extremum principle for the Hadamard derivatives and its application to nonlinear fractional partial differential equations
  13. Well-posedness of fractional degenerate differential equations in Banach spaces
  14. Structure factors for generalized grey Browinian motion
  15. Linear stationary fractional differential equations
  16. Perfect control for right-invertible Grünwald-Letnikov plants – an innovative approach to practical implementation
  17. On fractional differential inclusions with Nonlocal boundary conditions
  18. On solutions of linear fractional differential equations and systems thereof
  19. Existence of mild solution of a class of nonlocal fractional order differential equation with not instantaneous impulses
  20. A CAD-based algorithm for solving stable parameter region of fractional-order systems with structured perturbations
  21. On representation and interpretation of Fractional calculus and fractional order systems
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