Research Article Inverse Problems for the Quadratic Pencil of Rauf Kh. Am
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Hindawi Publishing Corporation
Abstract and Applied Analysis
Volume 2013, Article ID 361989, 10 pages
http://dx.doi.org/10.1155/2013/361989
Research Article
Inverse Problems for the Quadratic Pencil of
the Sturm-Liouville Equations with Impulse
Rauf Kh. AmJrov1 and A. Adiloglu NabJev2
1
2
Department of Mathematics, Faculty of Sciences, Cumhuriyet University, 58140 Sivas, Turkey
Department of Secondary Science and Mathematics Education, Faculty of Education, Cumhuriyet University, 58140 Sivas, Turkey
Correspondence should be addressed to Rauf Kh. AmΔ±rov; emirov@cumhuriyet.edu.tr
Received 22 November 2012; Revised 2 March 2013; Accepted 4 March 2013
Academic Editor: Juan J. Nieto
Copyright © 2013 R. Kh. AmΔ±rov and A. A. NabΔ±ev. This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is
properly cited.
In this study some inverse problems for a boundary value problem generated with a quadratic pencil of Sturm-Liouville equations
with impulse on a finite interval are considered. Some useful integral representations for the linearly independent solutions of a
quadratic pencil of Sturm-Liouville equation have been derived and using these, important spectral properties of the boundary
value problem are investigated; the asymptotic formulas for eigenvalues, eigenfunctions, and normalizing numbers are obtained.
The uniqueness theorems for the inverse problems of reconstruction of the boundary value problem from the Weyl function, from
the spectral data, and from two spectra are proved.
1. Introduction
with the boundary conditions
The theory of inverse problems for differential operators
occupies an important position in the current developments
of the spectral theory of linear operators. Inverse problems
of spectral analysis consist in the recovery of operators
from their spectral data. One takes for the main spectral
data, for instance, one, two, or more spectra, the spectral
function, the spectrum, and the normalizing constants, the
Weyl function. Different statements of inverse problems
are possible depending on the selected spectral data. The
already existing literature on the theory of inverse problems
of spectral analysis is abundant. The most comprehensive
account of the current state of this theory and its applications
can be found in the monographs of Marchenko [1], Levitan
[2], Beals et al. [3], and Yurko [4].
In the present work we consider some inverse problems
for the boundary value problem generated by the differential
equation
πΏ π π¦ := π¦σΈ σΈ + [π2 − 2ππ (π₯) − π (π₯)] π¦ = 0,
π₯ ∈ [0, π) ∪ (π, π]
(1)
π (π¦) := π¦σΈ (0) = 0,
π (π¦) := π¦ (π) = 0
(2)
and with the jump conditions
π¦ (π + 0) = πΌπ¦ (π − 0) ,
π¦σΈ (π + 0) = πΌ−1 π¦σΈ (π − 0) , (3)
where π is the spectral parameter, π(π₯) ∈ π21 [0, π], π(π₯) ∈
πΏ 2 [0, π] are real functions, πΌ is a real number, and πΌ >
0, πΌ =ΜΈ 1, π ∈ (π/2, π). Here we denote by π2π [0, π] the
space of functions π(π₯), π₯ ∈ [0, π], such that the derivatives
π(π) (π₯)(π = 0, π − 1) are absolutely continuous and π(π) (π₯) ∈
πΏ 2 [0, π].
There exist many papers containing a fairly comprehensive analysis of direct and inverse problems of spectral
analysis of the Sturm-Liouville equation
ππ¦ := −π¦σΈ σΈ + π (π₯) π¦ = π2 π¦,
(4)
a special case (π(π₯) ≡ 0) of (1). For instance, inverse problems
for a regular Sturm-Liouville operator with separated boundary conditions have been investigated in [5] (see also [1–4]).
Some versions of inverse problems for (1) which is a
natural generalization of the Sturm-Liouville equation were
2
fully studied in [6–14]. Namely, the inverse problems for
a pencil πΏ π on the half axis and the entire axis were
considered in [6–8], where the scattering data, the spectral function, and the Weyl function, respectively, were
taken for the spectral data. The problem of the recovery
of (1) from the spectra of two boundary value problems
with certain separated boundary conditions was solved in
[9]. The analysis of inverse spectral problems for (1) with
other kinds of separated boundary conditions as well as
with periodic and antiperiodic boundary conditions was
the subject of [10] (see also [11]) where the corresponding results of the monograph [1] were extended to the
case π(π₯) =ΜΈ 0. The inverse periodic problem for the pencil
πΏ π was solved in [12] using another approach. We also
point out the paper [14], in which the uniqueness of the
recovery of the pencil πΏ π from three spectra was investigated.
Boundary value problems with discontinuities inside
the interval often appear in mathematics, physics, and
other fields of natural sciences. The inverse problems of
reconstructing the material properties of a medium from
data collected outside of the medium give solutions to
many important problems in engineering and geosciences.
For example, in electronics, the problem of constructing
parameters of heterogeneous electronic lines is reduced
to a discontinuous inverse problem [15, 16]. The reduced
mathematical model exhibits the boundary value problem
for the equation of type (1) with given spectral information which is described by the desirable amplitude and
phase characteristics. Note that the problem of reconstructing the permittivity and conductivity profiles of a
one-dimensional discontinuous medium is also closed to
the spectral information [17, 18]. Geophysical models for
oscillations of the Earth are also reduced to boundary
value problems with discontinuity in an interior point [19].
Direct and inverse spectral problems for differential operators without discontinuities have been extensively studied
by many authors [20–25]. Some classes of direct and inverse
problems for discontinuous boundary value problems in
various statements have been considered in [18, 26–32] and
other works. Boundary value problems with singularity have
been studied in [33–37], and for further discussion see the
references therein. Note that the inverse spectral problem
for the boundary problem (1)–(3) has never been considered
before.
In what follows we denote the boundary value problem (1)–(3) by πΏ(π, πΌ). In Section 2 we derive some
integral representations for the linearly independent solutions of (1), and using these, we investigate important
spectral properties of the boundary value problem πΏ(π, πΌ).
In Section 3 the asymptotic formulas for eigenvalues,
eigenfunctions, and normalizing numbers of πΏ(π, πΌ) are
obtained. Finally, in Section 4 three inverse problems of
reconstructing the boundary value problem πΏ(πΌ, π) from
the Weyl function, from the spectral data, and from two
spectra are considered and the uniqueness theorems are
proved.
Abstract and Applied Analysis
2. Integral Representations of Solutions and
the Spectral Characteristics
Let π] (π₯, π) (] = 1, 2) be solution of (1) under the initial
condition
π]σΈ (0, π) = ππ€]
π] (0, π) = 1,
(5)
and discontinuity conditions (3), where π€] = (−1)]+1 π.
It is obvious that the functions π] (π₯, π) satisfy the integral
equations
π] (π₯, π)
= π+ (π₯) πππ€] π₯ + π− (π₯) πππ€] (2π−π₯)
+ π+ (π₯) ∫
π
sin π (π₯ − π‘)
{π (π‘)+2ππ (π‘)} π] (π‘, π) ππ‘
π
0
− π− (π₯) ∫
π
sin π (π₯ + π‘ − 2π)
{π (π‘)+2ππ (π‘)} π] (π‘, π) ππ‘
π
0
+∫
π₯
π
sin π (π₯ − π‘)
{π (π‘) + 2ππ (π‘)} π] (π‘, π) ππ‘,
π
(6)
where π± (π₯) = (1/2)(π(π₯) ± (1/π(π₯)) and
1, 0 ≤ π₯ < π
π (π₯) = {
πΌ, π < π₯ ≤ π.
(7)
Using the integral equations (6) and standard successive
approximation methods [7, 9, 11], the following theorem is
proved.
Theorem 1. If π(π₯) ∈ πΏ 2 [−π, π], π(π₯) ∈ π21 [−π, π] (0 < π <
π), then the solution π] (π₯, π) has the form
π₯
π] (π₯, π) = π0] (π₯, π) + ∫ π΄ ] (π₯, π‘) πππ€] π‘ ππ‘,
−π₯
(8)
where
π0] (π₯, π) = π+ (π₯) πππ€] π₯ π
]+ (π₯) + π− (π₯) πππ€] (2π−π₯) π
]− (π₯) ,
π
]± (π₯) = πβπ€] π½
±
(π₯)
,
π½± (π₯) = ∫
π₯
(πβπ)/2
π (π‘) ππ‘,
(9)
and the function π΄ ] (π₯, π‘) satisfies the inequality
π₯
σ΅¨
σ΅¨
∫ σ΅¨σ΅¨σ΅¨π΄ ] (π₯, π‘)σ΅¨σ΅¨σ΅¨ ππ‘ ≤ πππ(π₯) − 1
−π₯
(10)
with
π₯
σ΅¨
σ΅¨
σ΅¨
σ΅¨
π (π₯) = ∫ [(π₯ − π‘) σ΅¨σ΅¨σ΅¨π (π‘)σ΅¨σ΅¨σ΅¨ + 2 σ΅¨σ΅¨σ΅¨π (π‘)σ΅¨σ΅¨σ΅¨] ππ‘,
0
σ΅¨ σ΅¨
π = 2 (πΌ + σ΅¨σ΅¨σ΅¨πΌ− σ΅¨σ΅¨σ΅¨ + 1) ,
+
1
1
πΌ = (πΌ ± ) .
2
πΌ
±
(11)
Abstract and Applied Analysis
3
Let π(π₯, π) be the solution of (1) that satisfies the initial
conditions
σΈ
π (0, π) = 1,
π (0, π) = 0,
(12)
and the jump condition (3).
Then by using Theorem 1, we can formulate the following
assertion.
Theorem 2. Let π(π₯) ∈ πΏ 2 [0, π], π(π₯) ∈ π21 [0, π]. Then
there are the functions π΄(π₯, π‘), π΅(π₯, π‘) whose first order partial
derivatives are summable on [0, π] for each π₯ ∈ [0, π] such that
the representation
π₯
π₯
0
0
π (π₯, π) = π0 (π₯, π)+∫ π΄ (π₯, π‘) cos ππ‘ ππ‘+∫ π΅ (π₯, π‘) sin ππ‘ ππ‘
+ π− (π₯) cos [π (2π − π₯) − π½− (π₯)] .
(14)
π
(πΏ 0 π¦, π¦) = ∫ πΏ 0 π¦π¦ (π₯) ππ₯
0
+
+
+2 ∫ [π΄ (π, π) sin π½ (π)−π΅ (π, π) cos π½ (π)] ππ,
0
π
[π΄ (π₯, π₯) cos π½+ (π₯) + π΅ (π₯, π₯) sin π½+ (π₯)]
ππ₯
σ΅¨σ΅¨π‘=2π−π₯+0
π
σ΅¨
[π΄ (π₯, π‘) cos π½− (π₯) − π΅ (π₯, π‘) sin π½− (π₯)]σ΅¨σ΅¨σ΅¨
σ΅¨σ΅¨π‘=2π−π₯−0
ππ₯
= πΌ− [π (π₯) + π2 (π₯)] ,
σ΅¨
π΄ π‘ (π₯, π‘)σ΅¨σ΅¨σ΅¨π‘=0 = π΅ (π₯, 0) = 0
2
(15)
If one additionally supposes that π(π₯) ∈ π21 [0, π], π(π₯) ∈
π22 [0, π], then the functions π΄(π₯, π‘) and π΅(π₯, π‘) satisfy the
system of partial differential equations
π΅π₯π₯ (π₯, π‘) − π (π₯) π΅ (π₯, π‘) + 2π (π₯) π΄ π‘ (π₯, π‘) = π΅π‘π‘ (π₯, π‘) .
σ΅¨2
σ΅¨
σ΅¨2
σ΅¨
= ∫ (σ΅¨σ΅¨σ΅¨σ΅¨π¦σΈ (π₯)σ΅¨σ΅¨σ΅¨σ΅¨ + π (π₯) σ΅¨σ΅¨σ΅¨π¦ (π₯)σ΅¨σ΅¨σ΅¨ ) ππ₯.
0
π 0 = (ππ¦0 , π¦0 ) ± √(ππ¦0 , π¦0 ) + (πΏ 0 π¦0 , π¦0 ).
are held.
π΄ π₯π₯ (π₯, π‘) − π (π₯) π΄ (π₯, π‘) − 2π (π₯) π΅π‘ (π₯, π‘) = π΄ π‘π‘ (π₯, π‘) ,
π
(19)
Since condition (17) holds, it follows that (πΏ 0 π¦, π¦) > 0.
Let π 0 be an eigenvalue of the boundary value problem
πΏ(πΌ, π) and π¦0 (π₯) an eigenfunction corresponding to this
eigenvalue and normalized by the condition (π¦0 , π¦0 ) = 1.
By taking the inner product of both sides of the relation
π¦0σΈ σΈ (π₯) + [π20 − 2π 0 π(π₯) − π(π₯)]π¦0 (π₯) = 0 by π¦0 (π₯), we obtain
π20 − 2π 0 (ππ¦0 , π¦0 ) − (πΏ 0 π¦0 , π¦0 ) = 0 and hence
= πΌ+ [π (π₯) + π2 (π₯)] ,
2
Definition 3. A complex number π 0 is called an eigenvalue of
the boundary value problem πΏ(πΌ, π) if (1) with π = π 0 has a
nontrivial solution π¦0 (π₯) satisfying the boundary conditions
(2) and the jump conditions (3). In this case π¦0 (π₯) is called
the eigenfunction of the problem πΏ(πΌ, π) corresponding to the
eigenvalue π 0 . The number of linearly independent solutions
of the problem πΏ(πΌ, π) for a given eigenvalue π 0 is called the
multiplicity of π 0 .
The following lemmas can be proved analogously to the
corresponding assertions in [11].
Proof. We define a linear operator πΏ 0 in the Hilbert space
πΏ 2 [0, π] as follows. The domain π· (πΏ 0 ) consists of all functions π¦(π₯) ∈ π22 [0, π] satisfying the boundary conditions
(2) and the jump conditions (3). For π¦ ∈ π·(πΏ 0 ), we set
πΏ 0 π¦ = −π¦σΈ σΈ + π(π₯)π¦. Integration by part yields
πΌ+ π½+ (π₯) = πΌ+ π₯π (0)
2
(18)
Lemma 4. The eigenvalues of the boundary value problem
πΏ(πΌ, π) are real, nonzero, and simple.
Moreover, the relations
π₯
π¦σΈ (0) π¦ (0) − π¦σΈ (π) π¦ (π) = 0.
(13)
is satisfied, where
π0 (π₯, π) = π+ (π₯) cos [ππ₯ − π½+ (π₯)]
for all π¦(π₯) ∈ π22 [0, π) ∪ (π, π] such that π¦(π₯) =ΜΈ 0 and
(16)
Conversely, if the second order derivatives of functions
π΄(π₯, π‘), π΅(π₯, π‘) are summable on [0, π] for each π₯ ∈ [0, π]
and π΄(π₯, π‘), π΅(π₯, π‘) satisfy equalities (16) and conditions (15),
then the function π(π₯, π) which is defined by (13) is a solution
of (1) satisfying initial conditions (12) and discontinuity
conditions (3).
One here supposes that the function π(π₯) satisfies the
additional condition
π
σ΅¨2
σ΅¨
σ΅¨2
σ΅¨
(17)
∫ {σ΅¨σ΅¨σ΅¨σ΅¨π¦σΈ (π₯)σ΅¨σ΅¨σ΅¨σ΅¨ + π (π₯) σ΅¨σ΅¨σ΅¨π¦ (π₯)σ΅¨σ΅¨σ΅¨ } ππ₯ > 0
0
(19σΈ )
The desired assertion follows from the last relation by
virtue of (πΏ 0 π¦0 , π¦0 ) > 0 with regard to the fact that π(π₯) is
real.
Let us show that π 0 is a simple eigenvalue. Assume that
this is not true. Suppose that π¦1 (π₯) and π¦2 (π₯) are linearly
independent eigenfunctions corresponding to the eigenvalue
π 0 . Then for a given value of π 0 , each solution π¦0 (π₯) of (1)
will be given as linear combination of solutions π¦1 (π₯) and
π¦2 (π₯). Moreover it will satisfy boundary conditions (2) and
discontinuity conditions (3). However, it is impossible.
Lemma 5. The problem (1)–(3) does not have associated
functions.
Proof. Let π¦0 (π₯) be an eigenfunction corresponding to eigenvalue π 0 and normalized by the condition (π¦0 , π¦0 ) = 1 of the
problem (1)–(3). Suppose that π¦1 (π₯) is an associated function
of eigenfunction π¦0 (π₯), that is, the following equalities hold:
π20 π¦0 − 2π 0 π (π₯) π¦0 − πΏ 0 π¦0 = 0,
π20 π¦1 − 2π 0 π (π₯) π¦1 − πΏ 0 π¦1 + 2 (π 0 − π (π₯)) π¦0 = 0.
(20)
4
Abstract and Applied Analysis
If these equations are multiplied by π¦1 (π₯) and π¦0 (π₯),
respectively, as inner product, subtracting them side by side
and taking into our account that operator πΏ 0 is symmetric,
the function π(π₯) and π 0 are real, we get π 0 = (ππ¦0 , π¦0 ). Due
to the condition (6), π 0 = (ππ¦0 , π¦0 ) does not agree with (19σΈ ).
Therefore, the assertion is not true.
Lemma 6. Eigenfunctions corresponding to different eigenvalues of the problem πΏ(πΌ, π) are orthogonal in the sense of the
equality
(π 1 + π 2 ) (π¦1 , π¦2 ) − 2 (ππ¦1 , π¦2 ) = 0,
(21)
Then we have
β¨π (π₯, π 0 ) , π (π₯, π 0 )β©
=
1 σΈ
[π¦ (π, π 0 ) π (π, π 0 ) − π¦ (π, π 0 ) πσΈ (π, π 0 )]
π1
1
= − π¦ (π, π 0 )
π1
(25)
=0
which is a contradiction.
where (⋅, ⋅) denotes the inner product in πΏ 2 [0, π].
Lemma 7. Let π¦(π₯, π) be a solution of (1) satisfying the
condition (18) and the jump conditions (3). Then π is real and
nonzero and
π
σ΅¨2
σ΅¨
∫ (π − π (π₯)) σ΅¨σ΅¨σ΅¨π¦ (π₯, π)σ΅¨σ΅¨σ΅¨ ππ₯ =ΜΈ 0.
0
(22)
Moreover, the sign of the left-hand side of (22) is similar to the
sign of π.
3. Properties of the Spectrum
In this section we investigate some spectral properties of the
boundary value problem πΏ(πΌ, π).
Let π(π₯, π) be a solution of (1) with the conditions
π(π, π) = 0, πσΈ (π, π) = 1 and the jump conditions (3). It
is clear that function π(π₯, π) is entire in π for each fixed π₯.
Denote Δ(π) = β¨π(π₯, π), π(π₯, π)β©, where β¨π¦, π§β© :=
π¦σΈ π§ − π¦π§σΈ . By virtue of Liouville’s formula, the Wronskian
β¨π(π₯, π), π(π₯, π)β© does not depend on π₯. The function Δ(π)
is called the characteristic function of πΏ(πΌ, π). Obviously, the
function Δ(π) is entire in π and it has at most a countable set
of zeros {π π }.
Lemma 8. The zeros {π π } of the characteristic function Δ(π)
coincide with the eigenvalues of the boundary value problem
πΏ(πΌ, π). The functions π(π₯, π π ) and π(π₯, π π ) are eigenfunctions
corresponding to the eigenvalue π π , and there exists a sequence
{π½π } such that
π (π₯, π n ) = π½π π (π₯, π π ) ,
π½π =ΜΈ 0.
(23)
Proof. Let Δ(π 0 ) = 0. Then by virtue of β¨π(π₯, π 0 ), π(π₯, π 0 )β© =
0, π(π₯, π 0 ) = πΆπ(π₯, π 0 ) for some constant πΆ. Hence π 0 is an
eigenvalue and π(π₯, π 0 ), π(π₯, π 0 ) are eigenfunctions related
to π 0 .
Conversely, let π 0 be an eigenvalue of πΏ(πΌ, π), show that
Δ(π 0 ) = 0. Assuming the converse suppose that Δ(π 0 ) =ΜΈ 0.
In this case the functions π(π₯, π 0 ) and π(π₯, π 0 ) are linearly
independent. Then π¦ (π₯, π 0 ) = π1 π(π₯, π 0 ) + π2 π(π₯, π 0 ) is a
general solution of the problem πΏ(πΌ, π). If π1 =ΜΈ 0, we can write
π (π₯, π 0 ) =
π
1
π¦ (π₯, π 0 ) − 2 π (π₯, π 0 ) .
π1
π1
(24)
Note that we have also proved that for each eigenvalue
there exists only one eigenfunction (up to a multiplicative
constant). Therefore there exists sequence π½π such that
π(π₯, π π ) = π½π π(π₯, π π ).
Let us denote
π
πΌπ := ∫ π2 (π₯, π π ) ππ₯ −
0
1 π
∫ π (π₯) π2 (π₯, π π ) ππ₯.
ππ 0
(26)
The numbers {πΌπ } are called normalized numbers of the
boundary value problem πΏ(πΌ, π).
Μ π ) = −2π π πΌπ π½π holds. Here
Lemma 9. The equality Δ(π
Μ
Δ(π)
= (π/ππ)Δ(π).
Proof. If we differentiate the equalities
− πσΈ σΈ (π₯, π) + [2ππ (π₯) + π (π₯)] π (π₯, π) = π2 π (π₯, π) ,
− πσΈ σΈ (π₯, π) + [2ππ (π₯) + π (π₯)] π (π₯, π) = π2 π (π₯, π)
(27)
with respect to π, we get
− πΜ σΈ σΈ (π₯, π) + [2ππ (π₯) + π (π₯)] πΜ (π₯, π)
= π2 πΜ (π₯, π) + 2 [π − π (π₯)] π (π₯, π) ,
− πΜ σΈ σΈ (π₯, π) + [2ππ (π₯) + π (π₯)] πΜ (π₯, π)
(28)
= π2 πΜ (π₯, π) + 2 [π − π (π₯)] π (π₯, π) .
By virtue of these equalities we have
π
{π (π₯, π) πΜ σΈ (π₯, π) − πσΈ (π₯, π) πΜ (π₯, π)}
ππ₯
= 2 [π − π (π₯)] π (π₯, π) π (π₯, π) ,
π
{πΜ (π₯, π) πσΈ (π₯, π) − πΜ σΈ (π₯, π) π (π₯, π)}
ππ₯
= 2 [π − π (π₯)] π (π₯, π) π (π₯, π) .
(29)
Abstract and Applied Analysis
5
If the last equations are integrated from π₯ to π and from
0 to π₯, respectively, by the discontinuity conditions we obtain
σ΅¨π
(π (π, π) πΜ σΈ (π, π) − πσΈ (π, π) πΜ (π, π))σ΅¨σ΅¨σ΅¨σ΅¨π₯
π
= −2 ∫ (π − π (π)) π (π, π) π (π, π) ππ,
π₯
σ΅¨
lim σ΅¨σ΅¨σ΅¨π₯σΈ
π→∞ σ΅¨ π
(30)
σ΅¨π₯
(πΜ (π, π) π (π, π) − πΜ (π, π) π (π, π))σ΅¨σ΅¨σ΅¨σ΅¨0
σΈ
holds. Now (35) and (36) imply that π΄2 = 1−(1−π2 )sin2 (ππ₯0 +
π) ≤ 1 which is a contradiction. Therefore, (35) has no
multiple roots.
Further assuming (34) not to be true let {π₯πσΈ } and {π₯πσΈ σΈ } be
increasing sequences of roots of (35) such that π₯πσΈ =ΜΈ π₯πσΈ σΈ and
σΈ
π₯
= −2 ∫ (π − π (π)) π (π, π) π (π, π) ππ.
0
If we add the last equalities side by side, we get
π [πΜ (π, π) , π (π, π)] + π [π (π, π) , πΜ (π, π)]
(31)
π
= −2 ∫ (π − π (π)) π (π, π) π (π, π) ππ
0
or
π
ΔΜ (π) = −2 ∫ (π − π (π)) π (π, π) π (π, π) ππ.
For π → π π , this yields
π
ΔΜ (π π ) = −2 ∫ (π π − π (π)) π (π, π π ) π (π, π π ) ππ
π
= −2π½π ∫ (π π − π (π)) π2 (π, π π ) ππ
= lim ππσΈ σΈ = π₯0 ,
(38)
lim π σΈ
π→∞ π
= lim π πσΈ σΈ = π¦0 .
(39)
π→∞
π→∞
π΄ cos ππσΈ = cos (π πσΈ + π) .
0
π
(33)
= −2π π π½π [∫ π2 (π, π π ) ππ
π
1
∫ π (π) π2 (π, π π ) ππ]
ππ 0
(40)
Then by virtue of (38) and (39), from (40) we get
π΄ cos π₯0 = cos (π¦0 + π) .
0
(41)
Similarly we can obtain
π΄ cos ππσΈ σΈ = cos (π πσΈ σΈ + π) .
= −2π π π½π πΌπ .
(42)
Further, from (40) and (42), we have
The lemma is proved.
+
lim πσΈ
π→∞ π
Therefore, we can write the equality π΄ cos π₯πσΈ = cos(ππ₯πσΈ + π)
as
0
−
(37)
If we assume that π₯πσΈ = 2ππ π + ππσΈ , where π ∈ N and {ππσΈ } is
a bounded sequence (0 < ππσΈ < 2π), then from (37) we find
that π₯πσΈ σΈ = 2ππ π + ππσΈ σΈ , where {ππσΈ σΈ } is a bounded sequence such
that limπ → ∞ |ππσΈ − ππσΈ σΈ | = 0. It is obvious that ππ₯πσΈ = 2π[πππ ] +
π πσΈ , ππ₯πσΈ σΈ = 2π[πππ ] + π πσΈ σΈ , where π πσΈ = 2π{πππ } + ππσΈ π, π πσΈ σΈ =
2π{πππ }+ππσΈ σΈ π and limπ → ∞ |π πσΈ −π πσΈ σΈ | = 0. Here [⋅] and {⋅} denote
the integer and fractional parts of a real number, respectively.
and {π πσΈ σΈ }
will be
Since sequences {ππσΈ } , {ππσΈ σΈ } , {π πσΈ }
π≥1
π≥1
π≥1
π≥1
bounded, without loss of generality we can assume that these
sequences are convergent. Then let
(32)
0
σ΅¨
− π₯πσΈ σΈ σ΅¨σ΅¨σ΅¨σ΅¨ = 0.
+
−
−
Let Δ 0 (π) = πΌ cos[ππ−π½ (π)]+πΌ cos[π(2π−π)+π½ (π)]
and {π0π } are zeros of Δ 0 (π).
Lemma 10. The roots of the characteristic equation Δ 0 (π) = 0
are separate, that is
σ΅¨
σ΅¨
inf σ΅¨σ΅¨σ΅¨π0 − π0π σ΅¨σ΅¨σ΅¨σ΅¨ = π½ > 0.
π =ΜΈ π σ΅¨ π
+
(34)
−
Proof. Let ππ − π½ (π) = π₯. Then, π(2π − π) + π½ (π) = ππ₯ + π,
where π = (2π − π)/π, π = π½+ (π)((2π − π)/π) + π½− (π). Since
π ∈ (π/2, π), then π ∈ (0, 1). Using these notations we can
rewrite the equation Δ 0 (π) = 0 in the following form:
π΄ cos π₯ = cos (ππ₯ + π) .
(35)
Here π΄ = −(πΌ+ /πΌ− ) which implies that |π΄| > 1. Preliminarily
show that there are no multiple roots of (35). Assuming the
converse we suppose π₯0 to be a multiple root of (35). Then
π΄ sin π₯0 = π sin (ππ₯0 + π)
(36)
π΄ sin
ππσΈ + ππσΈ σΈ
sin
2
ππσΈ − ππσΈ σΈ
2
= sin (
π πσΈ + π πσΈ σΈ
2
+ π) sin
π πσΈ − π πσΈ σΈ
2
.
(43)
Let us write this equality as
π΄ sin
ππσΈ + ππσΈ σΈ
2
= sin (
sin
ππσΈ − ππσΈ σΈ
π πσΈ + π πσΈ σΈ
2
2
+ π) sin
π (ππσΈ − ππσΈ σΈ )
2
(44)
.
Now dividing both sides of equality (44) by (ππσΈ − ππσΈ σΈ )/2 =ΜΈ 0
and taking limit as π → ∞, by virtue of (3) and (39), we
obtain
π΄ sin π₯0 = π sin (π¦0 + π) .
(45)
Finally, from (41) and (45), we conclude that π΄2 = 1 − (1 −
π2 )sin2 (π¦0 + π) ≤ 1 which is a contradiction. Hence roots of
equation Δ 0 (π) = 0 are separate. The lemma is proved.
6
Abstract and Applied Analysis
Denote
On the other hand, since
σ΅¨ σ΅¨ π½
Γπ = {π : |π| = σ΅¨σ΅¨σ΅¨σ΅¨π0π σ΅¨σ΅¨σ΅¨σ΅¨ + } ,
2
σ΅¨
σ΅¨
πΊπΏ := {π : σ΅¨σ΅¨σ΅¨σ΅¨π − π0π σ΅¨σ΅¨σ΅¨σ΅¨ ≥ πΏ}
π = 0, 1, . . . ,
(46)
Δ 0 (π)
= πΌ+ cos (ππ − π½+ (π)) + πΌ− cos (π (2π − π) + π½− (π)) ,
(πΏ > 0) ,
Δ 0 (π0π + ππ ) = ΔΜ π (π0π ) ππ + π (ππ ) ,
where πΏ is sufficiently small positive number (πΏ βͺ π½/2).
π σ³¨→ ∞,
(51)
Lemma 11. For sufficiently large values of π, one has
σ΅¨σ΅¨
σ΅¨ πΆ | Im π|π
,
σ΅¨σ΅¨Δ (π) − Δ π (π)σ΅¨σ΅¨σ΅¨ < πΏ π
2
π ∈ Γπ .
(47)
Proof. As it is shown in [38], |Δ π (π)| ≥ πΆπΏ π| Im π|π for all π ∈
πΊπΏ , where πΆπΏ > 0 is some constant. On the other hand, since
(50) takes the form of
π
ΔΜ 0 (π0π ) ππ + ∫ π΄ (π, π‘) cos (π0π + ππ ) π‘ ππ‘
0
π
lim π−| Im π|π (Δ (π) − Δ π (π))
+ ∫ π΅ (π, π‘) sin (π0π + ππ ) π‘ ππ‘ + π (ππ ) = 0,
|π| → ∞
0
π σ³¨→ ∞.
(52)
π
Μ (π, π‘) cos ππ‘ ππ‘
= lim π−| Im π|π (∫ π΄
|π| → ∞
0
(48)
π
Μ (π, π‘) sin ππ‘ ππ‘)
+∫ π΅
0
=0
It is easy to see that the function Δ 0 (π) is type of “Sine” [39],
so there exists πΎπΏ > 0 such that |ΔΜ π (π0π )| ≥ πΎπΏ > 0 is satisfied
for all π. We also have
for sufficiently large values of π (see [1]) we get (47). The
lemma is proved.
Lemma 12. The problem πΏ(πΌ, π) has countable set of eigenvalues. If one denotes by π 1 , π 2 , . . . the positive eigenvalues
arranged in increasing order and by π −1 , π −2 , . . . the negative
eigenvalues arranged in decreasing order, then eigenvalues of
the problem πΏ(πΌ, π) have the asymptotic behavior
π π = π0π +
ππ πΏπ
+ ,
π0π π0π
π σ³¨→ ±∞,
(49)
where πΏπ ∈ π2 and ππ is a bounded sequence, π0π = π +
(1/π)π½+ (π) + βπ , supπ |βπ | < ∞.
Proof. According to Lemma 11, if π is a sufficiently large
natural number and π ∈ Γπ , we have |Δ π (π)| ≥ πΆπΏ π| Im π|π >
(πΆπΏ /2)π| Im π|π > |Δ(π) − Δ π (π)|. Applying Rouche’s theorem
we conclude that for sufficiently large π inside the contour
Γπ the functions Δ π (π) and Δ π (π) + {Δ(π) − Δ π (π)} = Δ(π)
have the same number of zeros counting their multiplicities.
That is, there are exactly (π + 1) zeros π 0 , π 1 , . . . , π π . in
Γπ . Analogously, it is shown by Rouche’s theorem that, for
sufficiently large values of π, the function Δ(π) has a unique
zero inside each circle |π − π0π | < πΏ. Since πΏ > 0 is arbitrary,
it follows that π π = π0π + ππ , where limπ → ∞ ππ = 0. Further
according to Δ(π π ) = 0, we have
π0π = π +
ππ =
1
{ [πΌ+ sin (π0π π − π½1 (π))
Μ
2Δπ (π0π ) π0π
+ πΌ− sin (π0π (2π − π) + π½2 (π))]
π
× ∫ (π (π₯) + π2 (π₯)) ππ₯
0
− [πΌ+ cos (π0π π − π½1 (π))
+ πΌ− cos (π0π (2π − π) + π½2 (π))]
× (π (π) − π (0)) }
+
π
1
[∫
π΅π‘σΈ (π, π‘) cos π0π π‘ ππ‘
ΔΜ π (π0π ) π0π 0
π
− ∫ π΄σΈ π‘ (π, π‘) sin π0π π‘ ππ‘]
π
0
+∫
0
π΅ (π, π‘) sin (π0π
0
(50)
+ ππ ) π‘ ππ‘ = 0.
(53)
where supπ |βπ | ≤ π for some constant π > 0 [40] (see
also [41]). Further, substituting (53) into (52) after certain
transformations [1, page 67], we reach ππ ∈ π2 . We can obtain
more precisely
Δ 0 (π0π + ππ ) + ∫ π΄ (π, π‘) cos (π0π + ππ ) π‘ ππ‘
π
1 +
π½ (π) + βπ ,
π
+
π (ππ )
,
π0π
π σ³¨→ ∞.
(54)
Abstract and Applied Analysis
7
π
π
Since ∫0 π΅π‘σΈ (π, π‘) cos π0π π‘ ππ‘ ∈ π2 , ∫0 π΄σΈ π‘ (π, π‘) sin π0π π‘ ππ‘ ∈
π2 , we have
ππ =
− [π΅ (π₯, 2π − π₯ + 0) − π΅ (π₯, 2π − π₯ − 0)] cos π π (2π − π₯)
1
{ [πΌ+ sin (π0π π − π½1 (π))
Μ
2Δπ (π0π ) π0π
+πΌ
−
sin (π0π
=
(2π − π) + π½2 (π))]
π
(55)
− [πΌ
+
cos (π0π π
× (π (π) − π (0)) } +
by using the asymptotic formula (49) for π π .
πΏπ
,
π0π
4. Inverse Problems
where πΏπ ∈ π2 . Hence we obtain
π π = π0π +
ππ πΏπ
+ ,
π0π π0π
(56)
where
1
{ [πΌ+ sin (π0π π − π½+ (π))
Μ
2Δπ (π0π )
+ πΌ− sin (π0π (2π − π) + π½− (π))]
π
× ∫ (π (π₯) + π2 (π₯)) ππ₯
0
− [πΌ
+
cos (π0π π
(57)
− π½ (π))
Μ , π = 0, ±1, ±2, . . ., then π = πΜ, πΌ = πΌ
Μ,
Lemma 15. If π π = π
π
that is, the sequence {π π } uniquely determines numbers π and
πΌ.
× (π (π) − π (0)) }
is a bounded sequence. The proof is completed.
Lemma 13. Normalizing numbers πΌπ of the problem πΏ(πΌ, π)
are positive and the formula
π
π
π
2
2
+ 1π
[(πΌ+ ) + (πΌ− ) ] + 11
2
π0π
π
(58)
holds, where π11 = −(πΌπ/2)π(0), π1π ∈ π2 .
Proof. The formula (58) can be easily obtained from the
equalities
π΄ (π₯, π₯) sin π π π₯ − π΅ (π₯, π₯) cos π π π₯
πΌ+
=
{ (π (π₯) − π (0)) cos (π π π₯ − π½+ (π₯))
2
π₯
+ ∫ (π (π‘) + π2 (π‘)) ππ‘ sin (π π π₯ − π½+ (π₯))} ,
0
Together with πΏ(πΌ, π), we consider the boundary value probΜ π) of the same form but with different coefficients
lem πΏ(πΌ,
Μ, πΌ
Μ , πΜ). It is assumed in what follows that if a certain
(Μπ, π
symbol πΎ denotes an object related to the problem πΏ(πΌ, π),
then πΎΜ will denote the corresponding object related to the
Μ π).
problem πΏ(πΌ,
In the present section, we investigate some inverse spectral problem of the reconstruction of a boundary value problem πΏ(πΌ, π) of type (1)–(4) from its spectral characteristics.
Namely, we consider the inverse problems of reconstruction of the boundary value problem πΏ(πΌ, π) from the Weyl
function, from the spectral data {π π , πΌπ }π≥0 , and from two
spectra {π π , ππ }π≥0 and prove that the following two lemmas
can be easily obtained from asymptotic behavior (49) of the
eigenvalues π π .
Μ , π = 0, ±1, ±2, . . ., then π½+ (π) =
Lemma 14. If π π = π
π
+
−
Μ (π), π½− (π) = π½
Μ (π), that is, the sequence {π } uniquely
π½
π
determines π½± (π).
+
+ πΌ− cos (π0π (2π − π) + π½− (π))]
πΌπ =
(59)
− π½1 (π))
+ πΌ− cos (π0π (2π − π) + π½2 (π))]
ππ =
π₯
πΌ−
{∫ (π (π‘) + π2 (π‘)) ππ‘ sin (π π (2π − π₯) + π½− (π₯))
2
0
− (π (π₯) − π (0)) cos (π π (2π − π₯) + π½− (π₯)) }
× ∫ (π (π₯) + π2 (π₯)) ππ₯
0
[π΄ (π₯, 2π − π₯ + 0) − π΄ (π₯, 2π − π₯ − 0)] sin π π (2π − π₯)
Let Φ(π₯, π) be the solution of (1) under the conditions
π(Φ) = 1, π(Φ) = 0 and under the jump conditions (3). One
sets π(π) := Φ(0, π). The functions Φ(π₯, π) and π(π) are
called the Weyl solution and Weyl function for the boundary
value problem πΏ(πΌ, π), respectively. Using the solution π(π₯, π)
defined in the previous sections one has
Φ (π₯, π) = −
π (π₯, π)
= π (π₯, π) + π (π) π (π₯, π) ,
Δ (π)
π (0, π)
π (π) = −
,
Δ (π)
(60)
where π(π₯, π) is a solution of (1) satisfying the conditions
π(π, π) = 0, πσΈ (π, π) = −1, and the jump conditions (3), and
π(π₯, π) is defined from the equality
π (π₯, π) = π (0, π) π (π₯, π) − Δ (π) π (π₯, π) .
(61)
8
Abstract and Applied Analysis
Note that, by virtue of equalities β¨π(π₯, π), π(π₯, π)β© ≡ 1 and
(60), one has
β¨Φ (π₯, π) , π (π₯, π)β© ≡ 1,
β¨π (π₯, π) , π (π₯, π)β© ≡ −Δ (π)
for π₯ =ΜΈ π.
(62)
The following theorem shows that the Weyl function
uniquely determines the potentials and the coefficients of the
boundary value problem πΏ(πΌ, π).
Μ
Μ π). Thus,
Theorem 16. If π(π) = π(π),
then πΏ(πΌ, π) = πΏ(πΌ,
the boundary value problem πΏ(πΌ, π) is uniquely defined by the
Weyl function.
Proof. Since
π(]) (π₯, π) = π (|π|]−1 exp (|Im π| (π − π₯))) ,
|Δ (π)| ≥ πΆπΏ exp (|Im π| π) ,
ΜπΏ ,
π∈πΊ
(63)
ΜπΏ , πΆπΏ < 0, ] = 0, 1,
π∈πΊ
(64)
it is easy to observe that
σ΅¨σ΅¨ (])
σ΅¨
σ΅¨σ΅¨Φ (π₯, π)σ΅¨σ΅¨σ΅¨ ≤ πΆπΏ |π|]−1 exp (− |Im π| π₯) ,
σ΅¨
σ΅¨
π ∈ πΊπΏ .
(65)
Let us define the matrix π(π₯, π) = [πππ (π₯, π)]π,π=1,2 , where
σΈ
Μ (π₯, π) − Φ(π−1) (π₯, π) π
Μ σΈ (π₯, π) ,
ππ1 (π₯, π) = π(π−1) (π₯, π) Φ
Μ (π₯, π) .
Μ σΈ (π₯, π) − π(π−1) (π₯, π) Φ
ππ2 (π₯, π) = Φ(π−1) (π₯, π) π
(66)
Μ (π₯, π) + π12 (π₯, π) Φ
Μ σΈ (π₯, π) .
Φ (π₯, π) = π11 (π₯, π) Φ
(67)
According to (60) and (65), for each fixed π₯, the functions
πππ (π₯, π) are meromorphic in π with poles at points π π and
Μ . Denote πΊβ = πΊ ∩ πΊ
ΜπΏ . By virtue of (65), (66), and
π
π
πΏ
πΏ
π(]) (π₯, π) = π (|π|] exp (|Im π| π₯)) ,
π ∈ πΊπΏβ ,
(68)
σ΅¨
σ΅¨σ΅¨
σ΅¨σ΅¨π11 (π₯, π)σ΅¨σ΅¨σ΅¨ ≤ πΆπΏ ,
π ∈ πΊπΏβ . (69)
Μ
It follows from (60) and (66) that if π(π) ≡ π(π),
then for
each fixed π₯ the functions π1π (π₯, π) are entire in π. Together
with (69) this yields π12 (π₯, π) ≡ 0, π12 (π₯, π) ≡ π΄(π₯). Now
using (67), we obtain
Μ (π₯, π) ,
π (π₯, π) ≡ π΄ (π₯) π
Μ (π₯, π) .
Φ (π₯, π) ≡ π΄ (π₯) Φ
(70)
Therefore, for |π| → ∞, arg π ∈ [π, π − π] (π > 0), we have
1
π
π (π₯, π) = exp (−π (ππ₯ − π½1 (π₯))) (1 + π ( )) ,
2
π
Finally, taking into account the relations β¨Φ(π₯, π), π(π₯, π)β© ≡
Μ + , π΄(π₯) ≡ 1, that is, π(π₯, π) ≡
1 and (65), we have πΌ+ = πΌ
Μ
Μ (π₯, π), Φ(π₯, π) ≡ Φ(π₯, π) for all π₯ and π. Consequently,
π
Μ π). The theorem is proved.
πΏ(πΌ, π) = πΏ(πΌ,
The following two theorems show that two spectra and
spectral data also uniquely determine the potentials and the
coefficients of the boundary value problem πΏ(πΌ, π).
Μ ,π = π
Μ π , π = 0, ±1, ±2, . . ., then
Theorem 17. If π π = π
π
π
Μ π).
πΏ(πΌ, π) = πΏ(πΌ,
Proof. It is obvious that characteristic functions Δ(π) and
π(0, π) are uniquely determined by the sequences {π2π } and
Μ , π =
{ππ2 } (π = 0, ±1, ±2, . . .), respectively. If π π = π
π
π
Μ
Μ (0, π).
Μ π , π = 0, ±1, ±2, . . ., then Δ(π) ≡ Δ(π),
π(0, π) ≡ π
π
Μ
It follows from (60) that π(π) ≡ π(π).
Therefore, applying
Μ π). The proof is
Theorem 16, we conclude that πΏ(πΌ, π) = πΏ(πΌ,
completed.
Μ ,πΌ = πΌ
Μ π , π = 0, ±1, ±2, . . ., then
Theorem 18. If π π = π
π
π
Μ
πΏ(πΌ, π) = πΏ(πΌ, π), that is, spectral data {π π , πΌπ } uniquely
determines the problem πΏ(πΌ, π).
π
π
0
0
Δ (π) = Δ 0 (π) + ∫ π΄ (π, π) cos ππ‘ ππ‘ + ∫ π΅ (π, π) sin ππ‘ ππ‘
(73)
Μ π ), π(π₯, π π ) = π½π π(π₯, π π ), we
and equalities 2π π π½π πΌπ = −Δ(π
have
π (0, π π )
π½
1
=− π =
.
Re π π (π) = −
(74)
Μ
Μ
π=π π
Δ (π π )
Δ (π π ) 2π π πΌπ
Since the Weyl function π(π) is regular for π ∈ Γπ , applying
the Rouche theorem, we conclude that
we get
σ΅¨σ΅¨
σ΅¨
−1
σ΅¨σ΅¨π12 (π₯, π)σ΅¨σ΅¨σ΅¨ ≤ πΆπΏ |π| ,
|π| σ³¨→ ∞, arg π ∈ [π, π − π] .
(72)
Proof. It is obvious that the Weyl function π(π) is meromorphic with simple poles at points π2π . Using the expression
Then we have
Μ (π₯, π) + π12 (π₯, π) π
Μ σΈ (π₯, π) ,
π (π₯, π) = π11 (π₯, π) π
where π = 1 for π₯ < π and π = πΌ+ for π₯ > π. Similarly, one
can calculate
1
Φ (π₯, π) = (πππ)−1 exp (π (ππ₯ − π½1 (π₯))) (1 + π ( )) ,
π
π (π) =
π (π)
1
ππ,
∫
2ππ Γπ π − π
π ∈ int Γπ .
(75)
Taking (60) and (63) into account, we arrive at |π(π)| ≤
πΆπΏ |π|−1 , π ∈ πΊπΏ . Therefore
π (π) = lim
1
π → ∞ 2ππ
∫
Γπ1
π (π)
ππ,
π−π
(76)
where Γπ1 = {π : |π| = |π0π |}, π = 0, ±1, ±2, . . .. Hence, by the
residue theorem, we have
∞
(71)
1
.
π=−∞ 2π π πΌπ (π − π π )
π (π) = ∑
(77)
Abstract and Applied Analysis
Μ
Finally, from the equality π(π) ≡ π(π),
applying TheoΜ
rem 16, we conclude that πΏ(πΌ, π) = πΏ(πΌ, π). The theorem is
proved.
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