1. Introduction
In this paper, the solvability of some inverse problems for the fractional analogue of a parabolic equation with a nonlocal biharmonic operator are studied. The nonlocal biharmonic operator is defined with the help of involutive mappings given in the space . An involutive mapping or an involution S is a mapping that has the property where I is the identity mapping.
As is well known, studies of problems in which, along with solving the equation, it is necessary to find the right side, the coefficient of the equation, or the initial and boundary functions are called inverse problems of mathematical physics. Inverse problems have numerous applications in modern science; they arise in the study of problems in acoustics, astronomy, geophysics, seismology, medical tomography, and other areas (see, for example, [
1,
2] and references therein).
Direct and inverse problems for fractional differential equations with involution were studied in [
3,
4,
5,
6,
7,
8,
9,
10]. In these works, the problems of finding the solution and the right side of the equation in the case of one spatial variable were considered. Inverse problems in the case of two spatial variables for differential equations of fractional order were studied in [
11,
12,
13,
14,
15,
16].
As far as we know, the initial-boundary value problems for partial differential equations of fractional order with operators of the fourth and higher orders have been insufficiently studied. In this direction, we can note works [
17,
18,
19,
20,
21,
22,
23,
24] where, in particular, the inverse problems were also studied.
The problems close to our studies were considered in the work of S. Kerbal et al. [
25]. In this work, for a differential equation of a fractional order with a differential operator of the fourth order in two spatial variables, an initial-boundary value problem is studied, where the boundary conditions in the first variable are specified as Dirichlet-type conditions, and those in the second variable are considered as nonlocal Samarsky–Ionkin-type conditions. Note that the attention of researchers to the study of the problems of the Samarskii–Ionkin type was initiated by the publication of N.I. Ionkin’s papers [
26,
27]. In contrast to classical problems, in this problem, the corresponding spatial differential operator is non-self-adjoint, and, therefore, the system of eigenfunctions is incomplete. Consequently, problems arise in studying the completeness and basis property of such systems. In [
25], this problem was studied for the fourth-order differential operators.
In this paper, we study two types of problems for a fractional-order differential equation with a nonlocal biharmonic operator. In the first problem, boundary conditions of the Dirichlet type are considered, and in the second problem, conditions of the type considered in [
25] are specified.
As we noted above, direct and inverse problems for equations with involutive transformations were mainly studied for the second-order equations with one spatial variable. For high-order equations, in particular for the fourth order, as well as for equations with many space variables, such problems have not been previously studied. Similar problems have been studied only for classical equations, i.e., for equations without involutive transformations. The application of the Fourier method to the solution of such problems leads to the study of spectral questions for high-order differential equations with involutive transformations.
Previously, in [
25], such questions were studied for a fourth-order equation without involution. In our research, unlike [
25], we consider the fourth-order equations with involutive transformations, and we use the completeness of systems of eigenfunctions, as well as systems of eigenfunctions and associated functions for the fourth-order differential operators with involution. Studying the properties of these systems, we use the Fourier method to find solutions to the studied problems.
Let
. Let us introduce the notations
Let
be real numbers. We introduce the operator
where
is a biharmonic operator. If
, then instead of
, we will use the notation
. We will call the operator
(
) a nonlocal biharmonic operator.
Note that the properties and applications of nonlocal elliptic operators
are studied in [
28,
29,
30].
Let us formulate the problems that we will use further. Consider the following problems in the domain .
Problem 1. Find a pair of functions such that the following conditions are satisfied:
- (1)
Functions and are smooth: , , and ;
- (2)
In the domain Ω,
they satisfy the equation - (3)
The following conditions are satisfied
Here, is the derivative of order α in the sense of Caputo, i.e., Problem 2. Find a pair of functions such that the following conditions are satisfied:
- (1)
Functions and are smooth: , , and ;
- (2)
In the domain Ω,
they satisfy the equation - (3)
Conditions (1.2) are satisfied andwhere and are predefined functions.
Note that the boundary conditions of Problem 1 are Dirichlet-type conditions, and some of the boundary conditions of Problem 2 are Samarskii–Ionkin-type conditions. In what follows, we will show that the corresponding spatial differential operator in Problem 1 is self-conjugate, whereas in Problem 2, it is non-self-conjugate. Consequently, the system of eigenfunctions corresponding to Problem 2 is incomplete. Therefore, in Problem 2, in contrast to Problem 1, it is also necessary to study the completeness and basis properties of such systems.
The results of this work are presented in the following order. In
Section 2, the properties of some biorthogonal systems related to the spectral issues of Problem 2 are described. In
Section 3, the known properties of the Mittag-Leffler type function, as well as a solution to a one-dimensional differential equation of a fractional order are considered.
Section 4 is devoted to the study of the first inverse problem, where the main theorems on the existence and uniqueness of the solution to the studied problem are given.
Section 5 presents the main theorem on the existence and uniqueness of a solution to Inverse Problem 2. The conclusion is presented in
Section 6.
4. Uniqueness and Existence of a Solution to Problem 1
Let
. Use the notation
. From equality (
1) and conditions (
3) and (
4), it follows that the system
are eigenfunctions of the problem
The corresponding eigenvalues are .
As for the function
, the equalities
are satisfied, then for
, we obtain
where
Note that for
, the equalities are valid:
In the case
, we obtain
, and hence,
Further, we will assume that
for all
. From equality (
22) and conditions (
20) and (
21), it follows that
and
are eigenfunctions and eigenvalues of the spectral problem
with boundary conditions (
20) and (
21).
Applying the operator
to equality (
26), and taking into account Equation (
1), we have
Moreover, from the boundary conditions (
2), we obtain
where
Thus, for the coefficients
,
, we obtain the following boundary value problem
As we have already noted, the general solution to Equation (
27) has the form
where
are arbitrary constants. Taking into account that
and using property (
18) of the function
for the coefficients
we obtain the representation
Then, from the boundary conditions (
28), we have
From equality (
18), it follows
Substituting the obtained value of into (
30), we obtain the final form of the functions
Note that formulas (
30) and (
31) were obtained under the assumption that a solution to Problem 1 exists. Moreover, if conditions (
2) in Problem 1 are homogeneous, i.e.,
and
, then
. Hence, for almost all
, the condition
is satisfied. Then, due to completeness of the system
, the equality
holds for almost all
. By the condition of the problem,
, and therefore,
. Similarly, we obtain
. Hence, the solution to Problem 1 is unique. Let us formulate the main assertion for Problem 1.
Theorem 1. Let the coefficients in Problem 1 be such that the conditions are satisfied, and for the functions and , the conditions are satisfied:
- (1)
- (2)
- (3)
Then, the solution to Problem 1 exists, is unique, and is represented as a series Proof. By its construction, the sum of the series (
32) and (
33) formally satisfies all the conditions of Problem 1. We only have to investigate the smoothness of the sum of these series. Let us show that
. Acting by the operator
on (
32) and taking into account formula (
22), we have
Let us use the notation
. As
, then there is
, such that
. Then, taking into account
, we obtain
Thus, the series
is a majorant, and convergence of the series (
34) reduces to the study of convergence of the series (
36). Using the conditions imposed on the function
for the coefficients
, we obtain
Thus, the equality is valid:
Similarly, we obtain the equalities
Let us study the convergence of the series
To do this, we first examine the convergence of the series
Taking into account (
37), applying the Cauchy–Schwarz and Bessel inequalities, we obtain
Hence, we conclude that the series
converges. Using conditions (
38), we similarly prove the convergence of the series
Then, from equality (
39), using the Cauchy–Schwarz and Bessel inequalities, we obtain
i.e., the series
converges. Hence, the series (
40) also converges. Taking into account the conditions imposed on
in a similar way, we prove the convergence of the series
Then, according to the Weierstrass theorem, the series (
34) converges absolutely and uniformly in the domain
and its sum is a continuous function in this domain. Similarly, it is proved that
Obviously, under the condition of the theorem, the series (
32) converges and
Further, we will prove that
From (
33), taking into account that
, we obtain
Hence, we obtain that the series (
36) is also a majorant for the series (
33), whose convergence, under the conditions of the theorem, was proved above. Thus, series (
33) converges absolutely and uniformly in the domain
, i.e.,
The theorem is proved. □
5. Uniqueness and Existence of a Solution to Problem 2
In this section, we will study Problem 2. We will seek the solution to the problem in the form of series
Here, are unknown functions, and are unknown constants.
Using Lemma 1 for the coefficients
,
,
from (
41) and (
42), we obtain the following representations
Then, using Equation (
5) and Lemma 5 of the function
for the coefficients
, we obtain
In addition, from the conditions (
2), it follows that
Thus, for the function
, we obtain the problem
where
Similarly, from Equation (
5) and Lemma 5 for the coefficients
, we obtain
when
Further, using Equation (
5) and Lemma 5 for the function
, as in the case for the coefficients
, we obtain
where
.
As follows from (
15) and (
16), the solution to Equation (
45) that satisfies the first condition from (
46) is written as
Hence, taking into account
and formula (
18), we have
To find the coefficient
, we use the second condition from (
46). From this condition it follows that
Hence, we find
Substituting the obtained values of
into the expressions for
, we obtain
Similarly, from (
47) and (
48), we find
and
. The corresponding solution has the form
Consider Equation (
49). The solution to the equation satisfying the second boundary condition from (
50) is
Taking into account that
and formula (
18), we simplify the last expression
To find the coefficient
, we use the second condition from (
50). We have
Substituting
into the expression for
we obtain
Further, using the first formula from equality (
18), we represent the coefficients
and
from equalities (
51)–(
56) as
where
Thus, the solutions to the problem have the form (
41) and (
42), where the functions
and coefficients
are determined, respectively, by formulas (
57)–(
62).
Let us formulate the main assertion regarding Problem 2.
Theorem 2. Let coefficients and in Problem 2 be such that and functions and satisfy the conditions
- (1)
- (2)
- (3)
- (4)
Then, a solution to Problem 2 exists and is unique.
Proof. The existence of a solution to the problem. Since system (
8) forms the Riesz basis in the space
, the functions
and
can be represented in the form (
41) and (
42), where the coefficients
and functions
are determined, respectively, by Formulas (
57)–(
62).
By construction, the functions
and
satisfy Equation (
5) and conditions (
6) and (
7). Let us show that
. Taking into account Lemma 4, acting by the operator
on (
41), we have
Further, taking into account the following inequalities
we obtain
Now, let us estimate the functions
,
, and
. From (
57), we obtain
Hence, taking into account the estimate (
17) and the complete monotonicity of the Mittag-Leffler function, as well as the fact that
,
, we obtain
Similarly, from (
59), we obtain
Now, we will estimate
. From (
61), we obtain
Taking into account formulas (
17) and (
18), we estimate
hence,
Then, (
64) takes the form
Hence, we obtain that the series
is a majorant, and the convergence of the series (
63) reduces to the study of the convergence of the series (
68).
Let us show the convergence of the series
Integrating by parts the integral in the representation of the coefficients
, taking into account the conditions imposed on
, we easily obtain the equality
Similarly, taking into account the conditions imposed on
, we obtain
Further, taking into account the relationship (
70) and (
71), and using the Cauchy–Schwarz and Bessel inequalities, we have
i.e., the considered series converges. Let us prove the convergence of the series
For coefficients
and
, we obtain
Similarly, for
and
, we obtain
Further, taking into account the relation (
73)–(
79) and using the Cauchy–Schwarz and Bessel inequality, we obtain
i.e., the considered series converges.
The convergence of the remaining series is proved similarly. Hence, the series (
68) majorizing the functional series (
63) converges. Then, according to the Weierstrass theorem, the series (
63) converges absolutely and uniformly in the domain
, and its sum is a continuous function in this domain. It is proved similarly that
, and the condition
follows from Equation (
5) and from the fact that
.
Uniqueness of the solution. Suppose the opposite. Let Problem 2 have two different solutions
,
and
Then, it is easy to check that
satisfies the Equation (
5), conditions (
6) and (
7), and
We will show that problems (
5)–(
7) and (
79) have only a trivial solution. Let
be a solution of this problem. Taking into account that
,
, and Lemma 2, from the equalities (
45), (
46), (
51), and (
54), we obtain
Then, from (
61)–(
66), it follows that
Using these values in equalities (
43) and (
44), we obtain that the functions
and
are orthogonal to system (
9), which is complete and forms a basis in
. Hence, almost everywhere, the equalities
in
and
in
are correct. Since
and
, we conclude that
and
, respectively, in the domains
and
, i.e.,
and
. The theorem is proved. □