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Periodic Problem with a Potential Landesman Lazer Condition
Boundary Value Problems volume 2010, Article number: 586971 (2010)
Abstract
We prove the existence of a solution to the periodic nonlinear second-order ordinary differential equation with damping 
, 
, 
. We suppose that 
, the nonlinearity 
satisfies the potential Landesman Lazer condition and prove that a critical point of a corresponding energy functional is a solution to this problem.
1. Introduction
Let us consider the nonlinear problem
where 
, the nonlinearity 
is a Caratheodory function and 
.
To state an existence result to (1.1) Amster [1] assumes that 
is a nondecreasing function (see also [2]). He supposes that the nonlinearity 
satisfies the growth condition 
,
for 
,
, 
where 
is the first eigenvalue of the problem
, 
and there exist 
such that 
An interval 
is centered in 
with the radius 
where 
, 
and 
is a solution to the problem 
with 
.
In [3, 4] authors studied (1.1) with a constant friction term 
and results with repulsive singularities were obtained in [5, 6].
In this paper we present new assumptions, we suppose that the friction term 
has zero mean value
the nonlinearity 
is bounded by a 
function and satisfies the following potential Landesman-Lazer condition (see also [7, 8])
where
, 
, 
and
To obtain our result we use variational approach even if the linearization of the periodic problem (1.1) is a non-self-adjoint operator.
2. Preliminaries
Notation 2.
We will use the classical space 
of functions whose 
th derivative is continuous and the space 
of measurable real-valued functions whose 
th power of the absolute value is Lebesgue integrable. We denote 
the Sobolev space of absolutely continuous functions 
such that 
and 
with the norm 
. By a solution to (1.1) we mean a function 
such that 
is absolutely continuous, 
satisfies the boundary conditions and (1.1) is satisfied a.e. in 
.
We denote 
and we study (1.1) by using variational methods. We investigate the functional 
, which is defined by
where
We say that 
is a critical point of 
, if
We see that every critical point 
of the functional 
satisfies
for all 
.
Now we prove that any critical point of the functional 
is a solution to (1.1) mentioned above.
Lemma 2.1.
Let the condition (1.2) be satisfied. Then any critical point of the functional 
is a solution to (1.1).
Proof.
Setting 
in (2.4) we obtain
We denote
then previous equality (2.5) implies 
and by parts in (2.4) we have
for all 
Hence there exists a constant 
such that
on 
. The condition (1.2) implies 
and from (2.8) we get 
Using 
and differentiating equality (2.8) with respect to 
we obtain
Thus 
is a solution to (1.1).
We say that 
satisfies the Palais-Smale condition (PS) if every sequence 
for which 
is bounded in 
and 
(as 
possesses a convergent subsequence.
To prove the existence of a critical point of the functional 
we use the Saddle Point Theorem which is proved in Rabinowitz [9] (see also [10]).
Theorem 2.2 (Saddle Point Theorem).
Let 
, 
and
. Let 
be a functional such that 
and
(a) there exists a bounded neighborhood 
of
in 
and a constant 
such that 
,
(b) there is a constant 
such that 
,
(c) 
satisfies the Palais-Smale condition (PS).
Then, the functional 
has a critical point in 
.
3. Main Result
We define
Assume that the following potential Landesman-Lazer type condition holds:
We also suppose that there exists a function 
such that
Theorem 3.1.
Under the assumptions (1.2), (3.2), (3.3), problem (1.1) has at least one solution.
Proof.
We verify that the functional 
satisfies assumptions of the Saddle Point Theorem 2.2 on 
, then 
has a critical point 
and due to Lemma 2.1 
is the solution to (1.1).
It is easy to see that 
. Let 
then 
and 
.
In order to check assumption (a), we prove
by contradiction. Then, assume on the contrary there is a sequence of numbers 
such that 
and a constant 
satisfying
From the definition of 
and from (3.5) it follows
We note that from (3.2) it follows there exist constants 
, 
and functions 
such that 
, 
for a.e. 
and for all 
, 
, respectively. We suppose that for this moment 
. Using (3.6) and Fatou's lemma we obtain
a contradiction to (3.2). We proceed for the case 
Then assumption (a) of Theorem 2.2 is verified.
(b) Now we prove that 
is bounded from below on 
. For 
, we have
and assumption (3.3) implies
Hence and due to compact imbedding 
we obtain
Since the function 
is strictly positive equality (3.10) implies that the functional 
is bounded from below.
Using (3.4), (3.10) we see that there exists a bounded neighborhood 
of
in 
, a constant 
such that 
, and there is a constant 
such that 
.
In order to check assumption (c), we show that 
satisfies the Palais-Smale condition. First, we suppose that the sequence 
is unbounded and there exists a constant 
such that
Let 
be an arbitrary sequence bounded in 
. It follows from (3.12) and the Schwarz inequality that
From (3.3) we obtain
Put 
and 
then (3.13), (3.14) imply
Due to compact imbedding 
and (3.15) we have 
in 
, 
. Suppose that 
and set 
in (3.13), we get
Because the nonlinearity 
is bounded (assumption (3.3)) and 
the second integral in previous equality (3.16) converges to zero. Therefore
Now we divide (3.11) by 
. We get
Equalities (3.17), (3.18) imply
Because 
, 
. Using Fatou's lemma and (3.19) we conclude
a contradiction to (3.2). We proceed for the case 
similarly. This implies that the sequence 
is bounded. Then there exists 
such that 
in 
, 
in 
, 
(taking a subsequence if it is necessary). It follows from equality (3.13) that
The strong convergence 
in 
and the assumption (3.3) imply
If we set 
, 
in (3.21) and subtract these equalities, then using (3.22) we have
Hence we obtain the strong convergence 
in 
. This shows that 
satisfies the Palais-Smale condition and the proof of Theorem 3.1 is complete.
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Acknowledgment
This work was supported by Research Plan MSM 4977751301.
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Keywords
- Nonlinear Problem
- Strong Convergence
- Type Condition
- Variational Approach
- Previous Equality
