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The Existence and Uniqueness of Solution of Duffing Equations with Non-
Perturbation Functional at Nonresonance
Boundary Value Problems volume 2008, Article number: 859461 (2008)
Abstract
This paper deals with a boundary value problem for Duffing equation. The existence of unique solution for the problem is studied by using the minimax theorem due to Huang Wenhua. The existence and uniqueness result was presented under a generalized nonresonance condition.
1. Introduction
In recent years, many authors are greatly attached to investigation for the existence and uniqueness of solution of Duffing equations, for example, [1–11], and so forth. Some authors ([8, 11, 12], etc.) proved the existence and uniqueness of solution of Duffing equations under 
perturbation functions and other conditions at nonresonance by employing minimax theorems. In 1986, Tersian investigated the equation 
using a minimax theorem proved by himself and reaped a result of generalized solution [13]. In 2005, Huang and Shen generalized the minimax theorem of Tersian in [13]. Using the generalized minimax theorem, Huang and Shen proved a theorem of existence and uniqueness of solution for the equation 
[14] under the weaker conditions than those in [13].
Stimulated by the works in [13, 14], in the present paper, we investigate the solutions of the boundary value problems of Duffing equations with non-
perturbation functions at nonresonance using the minimax theorem proved by Huang in [15].
2. Preliminaries
Let 
be a real Hilbert space with inner product 
and norm 
, respectively, 
and 
be two orthogonal closed subspaces of 
such that 
. Let 
denote the projections from 
to 
and from 
to 
, respectively. The following theorem will be employed to prove our main theorem.
Theorem 2.1 (see [15]).
Let 
be a real Hilbert space, let 
and 
be orthogonal closed vector subspace of 
such that 
, let 
be an everywhere defined functional with Gâteaux derivative, 
everywhere defined and hemicontinuous. Suppose that there exist two continuous functions 
satisfying
for 
, 
, 
, 
, 
, 
. Then, the following hold:
(a)
has a unique critical point 
such that 
;
(b)
.
It is easy to prove the following corollary of the above theorem.
Corollary 2.2.
Let 
be a real Hilbert space, let 
and 
be orthogonal closed vector subspace of 
such that 
, and let 
be an everywhere defined functional with second Gâteaux differential. Suppose that there exist two continuous functions 
satisfying
for 
, 
, 
, 
, 
, 
, 
. Then, the following hold:
(a)
has a unique critical point 
such that 
;
(b)
.
Proof.
We note that 
is a second Gâteaux differentiable functional, the mean-value theorem ensures that there exists 
such that 
. Therefore, for 
, 
, 
, 
, 
, 
, we have
The conclusion of the corollary follows immediately from Theorem 2.1.
3. The Main Theorems
Consider the boundary value problem
where 
, 
is a potential Carathéodory function, 
is a given function in 
.
Let 
, then (3.1) may be written in the form of
where 
. Clearly, 
is a potential Carathéodory function, and if 
is a solution of (3.2), then 
will be a solution of (3.1).
It is well known that 
is a Hilbert space with inner product:
and norm 
, respectively. The system of trigonometrical functions,
is a system of orthonormal functions in 
. Each 
can be written as the Fourier series
Define the linear operator 
,
Denote
Clearly, 
is a self-adjoint operator, and 
is a Hilbert space for the inner product:
, the norm induced by this inner product is
Note that 
is not a space.
Since 
in (3.1), and hence 
in (3.2), is a potential Carathéodory function, there exists a function 
such that
and hence
and the mapping 
, and hence 
, generates a Nemytskii operator 
by
and hence
Define the functional 
by
where 
satisfies (3.10) and 
is in (3.1). We have
It is easy to see that
where 
. Clearly, 
is a critical point of 
if and only if 
is a solution of the equation 
and hence a solution of (3.2) and thus 
is a solution of (3.1).
Now, we suppose that there exists a real-bounded mapping 
such that
For 
, let
Since
equation (3.17) is equivalent to
Suppose that for 
,
and for 
, define
which is equivalent to
Since 
is a self-adjoint operator, it possesses spectral resolution
with a right continuous spectral family 
; and we let
for all 
with 
. Then, the operator 
has the spectral resolution:
where 
is an identity operator.
Define 
and 
by
By (3.21), we have
and hence
We need to prove a lemma before presenting our main theorem.
Lemma 3.1.
Suppose that 
in (3.2) satisfies (3.20), 
commutes with the linear operator 
and satisfies (3.21), 
is a continuous function defined in (3.22). Then, for 
Proof.
For 
, let
Note that 
commutes with the linear operator 
and
By (3.22),
Now, we show our main theorem dealing with (3.1).
Theorem 3.2.
Let 
be a potential Carathéodory function satisfying (3.17). Suppose that 
commutes with the linear operator 
and satisfies
and the continuous function 
defined by (3.23) satisfies the conditions
Then, (3.1) has a unique solution 
such that
where 
is a functional defined in (3.14) and 
.
Proof.
For 
, by Lemma 3.1, we have
Employing Theorem 2.1, we can know that there exists a unique 
such that 
, where 
is a solution of (3.2) and this means that (3.1) has a unique solution 
such that
where 
is a functional defined in (3.14) and 
.
If the perturbation function 
in (3.10) is a second Gâteaux differential, (3.17), (3.34), and (3.23) become
respectively. By (3.30) in Lemma 3.1, we have
where 
.
We then have the following corollary of Theorem 3.2.
Corollary 3.3.
Let 
be a potential Carathéodory function with first Gâteaux derivative 
satisfying (3.39) and (3.40) and 
commutes with the linear operator 
. If the continuous function 
defined by (3.41) satisfies (3.35), then (3.1) has a unique solution 
and
where 
is a functional defined in (3.14) and 
.
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The corresponding author is grateful to the referees for their helpful and valuable comments.
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Ting, Z., Wenhua, H. The Existence and Uniqueness of Solution of Duffing Equations with Non-
Perturbation Functional at Nonresonance.
Bound Value Probl 2008, 859461 (2008). https://doi.org/10.1155/2008/859461
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DOI: https://doi.org/10.1155/2008/859461