1. Introduction
Fractional differential equations become another necessary tool in solving real-life problems in different research areas such as mathematical biology, engineering, mechanics, and physics; for example, see the monographs [
1,
2,
3,
4,
5,
6,
7,
8,
9]. Boundary value problems of fractional differential equations and inclusions represent an important class of applied analysis. Most researchers have studied fractional differential equations by taking Caputo or Riemann–Liouville derivative. Engineers and scientists have developed some new models that involve fractional differential equations for which the Riemann–Liouville derivative is not considered appropriate. Therefore, certain modifications were introduced to avoid the difficulties and some new-type fractional order derivative operators were introduced in the literature by Hadamard, Erdelyi–Kober, Katugampola, and others. A generalization of derivatives of both Riemann–Liouville and Caputo was given by R. Hilfer in [
10] and is known as the Hilfer fractional derivative of order
and a type
, which can be reduced to the Riemann–Liouville and Caputo fractional derivatives when
and
, respectively. Such a derivative interpolates between the Riemann–Liouville and Caputo derivative. Fractional differential equations involving Hilfer derivative have many applications; see [
11,
12,
13,
14,
15,
16] and references cited therein.
This survey is devoted to articles published by the author and his collaborators and concern some recent existence and uniqueness results for various classes of boundary value problems for Hilfer fractional differential equations and inclusions of fractional order in supplemented with different kinds of nonlocal boundary conditions.
The rest of this survey is organized as follows. In
Section 2, we introduce some notations and definitions of fractional calculus and multivalued analysis. In the subsequent sections, we present existence and uniqueness results for boundary value problems for Hilfer,
-Hilfer fractional, and sequential fractional differential equations and inclusions with a variety of nonlocal boundary conditions, such as multipoint, integral, integral multipoint, integro-multipoint, integro-multistrip-multipoint and Riemann–Stieltjes integral multistrip. We also present existence and uniqueness results for coupled systems of Hilfer and
-Hilfer types and Hilfer-Hadamard fractional and sequential fractional differential equations. Note that our goal here is a more complete and comprehensive review, and as such, the choice is made to include as many results as possible to illustrate the progress on the matter. Any proofs (that are rather long) are omitted, for this matter, and the reader is referred to the relative article accordingly.
Let us describe briefly the used methods to obtain our results. In each problem, we first present an auxiliary result concerning a linear variant of the corresponding boundary value problem that is very useful to transform the studied problem into a fixed point problem. A variety of fixed point theorems are then used to establish the existence and uniqueness results. For the single-valued case, the fixed point theorems of Banach, Boyd and Wong, Krasnoselskii, Sadovskii, Isaia and the Leray–Schauder nonlinear alternative were used, while in the multivalued case, the fixed point theorems of Bohnenblust–Karlin, Martelli, Covitz–Nadler and the Leray-Schauder nonlinear alternative for multivalued maps maps were used. For the multivalued case, we present existence results for both cases, convex-valued (upper semicontinuous case), and nonconvex-valued (Lipschitz case) multifunctions. To obtain the existence and uniqueness results for fractional coupled systems, Banach’s contraction mapping principle and the Leray-Schauder alternative are used. In each theorem, we indicate the used fixed point theorem.
2. Preliminaries
In this section, we introduce some notations and definitions of fractional calculus and multivalued analysis.
2.1. Fractional Calculus
Let
denote the Banach space of all continuous functions from
to
endowed with the norm defined by
. It is obvious that the product space
is Banach space with the norm
is the
n-times absolutely continuous functions defined as
Definition 1. The Riemann–Liouville fractional integral of order of a continuous function is defined byprovided the right-hand side exists on . Definition 2. The Riemann–Liouville fractional derivative of order of a continuous function u is defined bywhere , denotes the integer part of real number α, provided the right-hand side is pointwise defined on . Definition 3. The Caputo fractional derivative of order of a continuous function u is defined asprovided the right-hand side is pointwise defined on . In [
10] (see also [
11]), another new definition of the fractional derivative, known as the generalized Riemann–Liouville fractional derivative, was suggested; it is defined as
Definition 4. The generalized Riemann–Liouville fractional derivative or Hilfer fractional derivative of order α and parameter β of a function u is defined bywhere , , , . Remark 1. In the above definition, type β allows to interpolate continuously between the classical Riemann–Liouville fractional derivative and the Caputo fractional derivative. When , the Hilfer fractional derivative corresponds to the Riemann–Liouville fractional derivativewhile when , the Hilfer fractional derivative corresponds to the Caputo fractional derivative In the following, we recall some notations and results from -Hilfer fractional derivatives.
Definition 5 ([
2]).
Let , be a finite or infinite interval of the half-axis and . In addition, let be a positive increasing function on , which has a continuous derivative on . The ψ-Riemann–Liouville fractional integral of a function f with respect to another function ψ on is defined bywhere represents the Gamma function. Definition 6 ([
2]).
Let and , . The Riemann–Liouville derivatives of a function f with respect to another function ψ of order α correspondent to the Riemann–Liouville is defined bywhere , represents the integer part of the real number α. This is the greatest integer n such that Definition 7 ([
17]).
Let with , is the interval such that and two functions such that ψ is increasing, and for all . The ψ-Hilfer fractional derivative of a function f of order α and type is defined bywhere , represents the integer part of the real number α with . Some preliminaries from the Hilfer–Hadamard fractional derivative are presented next.
Definition 8 (Hadamard fractional integral [
2]).
The Hadamard fractional integral of order for a function is defined asprovided the integral exists, where . Definition 9 (Hadamard fractional derivative [
2]).
The Hadamard fractional derivative of order applied to the function is defined aswhere and denotes the integer part of the real number α. The Hilfer–Hadamard fractional derivative may be viewed as interpolating the Hadamard fractional derivative. Indeed, for , this derivative reduces to the Hadamard fractional derivative.
Definition 10 (Hilfer–Hadamard fractional derivative [
18]).
Let and , . The Hilfer–Hadamard fractional derivative of order α and type β of f is defined aswhere and are the Hadamard fractional integral and derivative defined by (1) and (2), respectively. 2.2. Multivalued Analysis
For a normed space , we define: Y is bounded and closed}; is bounded, closed and convex} and
For the basic concepts of multivalued analysis, we refer to [
19,
20].
A multivalued map has a fixed point if there is such that
Definition 11. A multivalued map is said to be Carathéodory if:
- (i)
is measurable for each;
- (ii)
is upper semicontinuous for almost all
Furthermore, a Carathéodory function F is calledCarathéodory if:
- (iii)
for each,
there existssuch thatfor allwithand for a.e.
7. Coupled Systems of Hilfer Fractional Differential Equations with Nonlocal Fractional Integral Boundary Conditions
A new class of coupled systems of Hilfer-type fractional differential equations with nonlocal integral boundary conditions was introduced in [
32] by considering the following coupled system
where
and
are the Hilfer fractional derivatives of orders
,
,
, and parameters
,
, respectively,
, and
,
are the Riemann–Liouville fractional integrals of order
and
, respectively, the points
,
,
are continuous functions, and
,
,
,
are given real constants.
The following lemma deals with a linear variant of the problem (
40).
Lemma 11. Let , , , , , , , , , , , and Then, the systemis equivalent to the following integral equationsand In view of Lemma 11, we define two operators
by
where
and
where
For computational convenience, we set