Inverse problem for $2b$-order differential equation with a time-fractional derivative

Authors

  • A.O. Lopushansky University of Rzeszow, 1 Prof. St. Pigonia str., 35-310, Rzeszow, Poland https://orcid.org/0000-0002-1448-964X
  • H.P. Lopushanska Ivan Franko Lviv National University, 1 Universytetska str., 79000, Lviv, Ukraine
https://doi.org/10.15330/cmp.11.1.107-118

Keywords:

distribution, fractional derivative, inverse problem, Green vector-function
Published online: 2019-06-30

Abstract

We study the inverse problem for a differential equation of order $2b$ with the Riemann-Liouville fractional derivative of order $\beta\in (0,1)$ in time and given Schwartz type distributions in the right-hand sides of the equation and the initial condition. The problem is to find the pair of functions $(u, g)$: a generalized solution $u$ to the Cauchy problem for such equation and the time dependent multiplier $g$ in the right-hand side of the equation. As an additional condition, we use an analog of the integral condition $$(u(\cdot,t),\varphi_0(\cdot))=F(t), \;\;\; t\in [0,T],$$ where the symbol $(u(\cdot,t),\varphi_0(\cdot))$ stands for the value of an unknown distribution $u$ on the given test function $\varphi_0$ for every $t\in [0,T]$, $F$ is a given continuous function.

We prove a theorem for the existence and uniqueness of a generalized solution of the Cauchy problem, obtain its representation using the Green's vector-function. The proof of the theorem is based on the properties of conjugate Green's operators of the Cauchy problem on spaces of the Schwartz type test functions and on the structure of the Schwartz type distributions.

We establish sufficient conditions for a unique solvability of the inverse problem and find a representation of anunknown function $g$ by means of a solution of a certain Volterra integral equation of the second kind with an integrable kernel.

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How to Cite
(1)
Lopushansky, A.; Lopushanska, H. Inverse Problem for $2b$-Order Differential Equation With a Time-Fractional Derivative. Carpathian Math. Publ. 2019, 11, 107-118.