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\AtBeginDocument{{\noindent\small {\em 
Electronic Journal of Differential Equations}, 
Vol. 2005(2005), No. 51, pp. 1--6.\newline 
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu
or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu  (login: ftp)}
\thanks{\copyright 2005 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2005/51\hfil Instability of solutions]
{Instability of solutions of certain nonlinear vector differential
equations of third order}
\author[E.  Tun\c{c}\hfil EJDE-2005/51\hfilneg]
{Ercan Tun\c{c}} 

\address{Ercan Tun\c{c} \hfill\break
Faculty of Arts and Sciences\\
Department of Mathematics\\
Gaziosmanpa\c{s}a University\\
 60240, Tokat, Turkey}
\email{ercantunc72@yahoo.com}

\date{}
\thanks{Submitted March 14, 2005. Published May 11, 2005.}
\subjclass{Nonlinear differential equations of third order; \hfill\break\indent 
instability; periodic solution; Lyapunov's method} 
\keywords[2000]{34D20, 34C25, 34A34}

\begin{abstract}
 In this paper, study the system of differential equations
 $$
 \dddot{X}+F(\dot{X})\ddot{X}+G(X)\dot{X} +H(X,\dot{X},\ddot{X})=0\,.
 $$
 We find sufficient conditions for  the zero solution to be unstable,
 and to be the only periodic solution.
\end{abstract}

\maketitle \numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}

\section{Introduction and Statement of Results}

It is well-known that instability and periodic properties for
various third-, fourth-, fifth-, sixth-, seventh- and eighth-order
nonlinear differential equations have been discussed by many
authors. In this connection, we refer the reader to the papers by
Bereketo\u{g}lu \cite{b2,b3,b4,b5}, Ezeilo \cite{e1,e2}, Kipnis
\cite{k1}, Lu \cite{l1}, Reissig \cite{r1}, and Skrapek
\cite{s1,s2},  Tejumola \cite{t1}, Tiryaki \cite{t2,t3,t4},
C.Tun\c{c} and E.Tun\c{c} \cite{t8}, Tun\c{c} \cite{t5,t6,t7,t9}
and the references cited therein. However, according to our
investigation of the relevant literature, in the case $n=1$, the
instability properties of nonlinear differential equations of the
third order have been discussed by discussed by
 Bereketo\u{g}lu \cite{b3}, Lu \cite{l2},
Kipnis \cite{k1} and Skrapek \cite{s2}. Bereketo\u{g}lu \cite{b3},
Kipnis \cite{k1}, and Skrapek \cite{s2} studied the third order
scalar differential equations
\begin{gather*}
\dddot{x}+f(\dot{x})\ddot{x}+g(x)\dot{x}+h(x,\dot{x},\ddot{x})=0, \\
\dddot{x}+p(t)x=0,\\
\dddot{x}+f_{1}(\ddot{x})+f_{2}(\dot{x})+f_{3}(x)+f_{4}(x,\dot{x},\ddot{x})=0\,.
\end{gather*}
We did not find literature  relevant to the instability of
solutions of nonlinear vector differential equations of third
order. This is perhaps due to the difficulty of constructing
proper Lyapunov functions for higher-order nonlinear vector
differential equations. The papers mentioned above are the
motivation for the present work. Our purpose is to obtain
sufficient conditions under which the trivial solution $X=0$  of
vector differential equation
\begin{equation}
\dddot{X}+F(\dot{X})\ddot{X}+G(X)\dot{X}+H(X,\dot{X},\ddot{X})=0
\label{e1.1}
\end{equation}
is unstable, and that the nontrivial solutions of equation
\eqref{e1.1} can not be periodic. It is assumed that $X\in
\mathbb{R}^{n}$, that $F$  and  $G$ are $n\times n$-symmetric
matrix functions; and that $H:\mathbb{R}^{n}\times
\mathbb{R}^{n}\times \mathbb{R}^{n}\to \mathbb{R}^{n}$ with $
H(0,0,0)=0$. Let  $F,G, H$  be continuous, for the uniqueness
theorem to be valid.

Equation \eqref{e1.1} represents  a systems of real-valued
third-order differential equations of the form
\begin{gather*}
\dddot{x_{i}}+\sum_{k=1}^{n}f_{ik}(\dot{x_{1}},\dot{x_{2}},\dots ,
\dot{x_{n}})\ddot{x_{k}}+\sum_{k=1}^{n}g_{ik}(x_{1},x_{2},\dots
,x_{n})
\dot{x_{k}} \\
+h_{i}(x_{1},x_{2},\dots ,x;\dot{x_{1}},\dot{x_{2}},\dots ,\overset{.%
}{x_{n}};\ddot{x_{1}},\ddot{x_{2}},\dots ,\ddot{x_{n}})=0,
\end{gather*}
($i=1,2,\dots ,n$). Let $J_{F}(\dot{X})$ and $J_{G}(X)$ denote the
Jacobian matrices corresponding to $F(\dot{X})$  and $G(X)$
respectively, that is,
\begin{equation*}
J_{F}(\dot{X})=\frac{\partial f_{i}}{\partial \dot{x}_{j}},\quad
J_{G}(X)=\frac{\partial g_{i}}{\partial x_{j}} \quad
(i,j=1,2,\dots, n),
\end{equation*}
where $(x_{1},x_{2},\dots ,x_{n}),(\dot{x_{1}},\dot{x_{2}},\dots ,
\dot{x_{n}}),(f_{1},f_{2},\dots ,f_{n})$ and $(g_{1},g_{2},\dots
,g_{n})$ are components of $X$, $\dot{X}$, $F$ and $G$,
respectively. It will be assumed that the Jacobian matrices $
J_{F}(\dot{X})$, $J_{G}(X)$  exist and are continuous.

Given any $X,Y$  in $ \mathbb{R}^{n}$. The symbol $\langle
X,Y\rangle $ will denote the usual scalar product in
$\mathbb{R}^{n}$, that is, $\langle X,Y\rangle
=\sum_{i=1}^{n}x_{i}y_{i}$; thus $\langle X,X\rangle =\| X\|
^{2}$.  The matrix $A$  is said to be negative-definite, when
$\langle AX,X\rangle <0$  for all non-zero $X$  in
$\mathbb{R}^{n}$. $\lambda _{i}(A)$ $(i=1,2,\dots ,n)$ will denote
the eigenvalues of the $n\times n$  matrix $A$.

We will use the following differential system which is equivalent
to the equation \eqref{e1.1}:
\begin{equation}
\begin{gathered}
\dot{X}=Y,\dot{Y}=Z, \\
\dot{Z}=-F(Y)Z-G(X)Y-H(X,Y,Z)\,.
\end{gathered}
\label{e1.2}
\end{equation}
Which is obtained as usual by setting $\dot{X}=Y,\ddot{X}=Z$ in
\eqref{e1.1}.

It should be noted that the Lyapunov's second (or direct) method,
(see \cite{l3}), is used to verify the results established here.
This method requires the construction of an appropriate Lyapunov
function for the equation under study. Namely, this function and
its total time derivative satisfy some fundamental inequalities.

\section{The main result}

We establish the following statements:

\begin{theorem} \label{thm1}
Let the functions $F,G,H$ be as defined above, , and assume the
following conditions are fulfilled:
\begin{itemize}
\item[(i)] $\lambda _{i}(F(Y))\leq 0$,  for all  $X,Y\in
\mathbb{R}^{n}$

\item[(ii)] $\sum_{i=1}^{n}x_{i}h_{i}(X,Y,Z)>0$
for all $X,Y,Z\in \mathbb{R}^{n}$, where
\[
H(X,Y,Z)=(h_{1}(X,Y,Z),h_{2}(X,Y,Z),\dots ,h_{n}(X,Y,Z)).
\]
\end{itemize}
Then the trivial solution $X=0$ of  the system \eqref{e1.2} is
unstable.
\end{theorem}

\begin{theorem} \label{thm2}
Under the assumptions of Theorem \ref{thm1}, equation \eqref{e1.2}
has no periodic solution other than $X=0$.
\end{theorem}

We need the following algebraic result.

\begin{lemma} \label{lem1}
Let $A$ be a real symmetric $n\times n$-matrix and $a'\geq \lambda
_{i}(A)\geq a>0$ ($i=1,2,\dots ,n$), where $a',a$ are constants.
Then
\begin{gather*}
a'\langle X,X\rangle \geq \langle AX,X\rangle \geq a\langle
X,X\rangle,
\\
(a')^{2}\langle X,X\rangle \geq \langle AX,AX\rangle \geq
a^{2}\langle X,X\rangle .
\end{gather*}
\end{lemma}

For the proof of this lemma, see \cite{t7}.

\subsection*{Preliminaries}
The proof of Theorem \ref{thm1} is based on the instability
criterion created by Krasovskiii \cite{k2}. According to these
criteria it is necessary to show that there exists a continuously
differentiable function $V(X,Y,Z)$ which has the following there
properties:
\begin{itemize}
\item[(P1)] In every neighbourhood of $(0,0,0)$ there exists a point
$(\xi ,\eta ,\zeta )$ such that $V(\xi ,\eta ,\zeta )>0$,

\item[(P2)] The time derivative $\frac{d}{dt}V(X,Y,Z)$ along solution
path of \eqref{e1.2} is positive-semidefinite,

\item[(P3)] The only solution $(X(t),Y(t),Z(t))$ of \eqref{e1.2} which
satisfies
\begin{equation*}
\dot{V}(X(t),Y(t),Z(t))=0\quad (t\geq 0)
\end{equation*}
is the trivial solution $(0,0,0)$.
\end{itemize}
Since the zero solution of \eqref{e1.2} is isolated, the existence
of a function $V$ with the properties (P1), (P2), (P3) is
sufficient for the instability of the trivial solution of
\eqref{e1.2}.

\subsection*{Proof of the Theorem \ref{thm1}}
Consider the continuously differentiable function
\begin{equation}
V(X,Y,Z)= -\int_{0}^{1}\langle F(\sigma Y)Y,X\rangle d\sigma
-\int_{0}^{1}\langle \sigma G(\sigma X)X,X\rangle d\sigma
 -\langle X,Z\rangle +\frac{1}{2}\langle Y,Y\rangle ,
\label{e2.1}
\end{equation}
which also plays an essential role in the proof of Theorem
\ref{thm2}. It is clear that
\begin{equation*}
V(0,\varepsilon ,0)=\frac{1}{2}\langle \varepsilon,\varepsilon
\rangle =\frac{1}{2}\| \varepsilon \| ^{2}>0
\end{equation*}
for all arbitrary $\varepsilon \in \mathbb{R}^{n}$ , $\varepsilon
\neq 0$. So, in every neighbourhood of $ (0,0,0)$ there exists a
point $(\xi ,\eta ,\zeta )$ such that $V(\xi ,\eta ,\zeta )>0$ for
all $\xi ,\eta $ and $\zeta $ in $\mathbb{R}^{n}$. Hence $V$  has
the property (P1).

Now let
\begin{equation*}
(X,Y,Z)=(X(t),Y(t),Z(t))
\end{equation*}
be any solution of \eqref{e1.2}. An elementary differentiation
from \eqref{e1.2} and \eqref{e2.1} yields
\begin{equation}
\begin{aligned}
\dot{V}(t)&=\frac{d}{dt}V(X(t),Y(t),Z(t)) \\
& =-\frac{d}{dt}\int_{0}^{1}\langle F(\sigma Y)Y,X\rangle d\sigma
-\frac{d}{dt}\int_{0}^{1}\langle \sigma G(\sigma X)X,X\rangle
d\sigma
\\
&\quad -\langle Y,Z\rangle +\langle X,F(Y)Z\rangle +\langle
X,G(X)Y\rangle +\langle X,H(X,Y,Z)\rangle +\langle Y,Z\rangle\,.
\end{aligned}
\label{e2.2}
\end{equation}
Note that
\begin{equation}
\begin{aligned}
&\frac{d}{dt}\int_{0}^{1}\sigma \langle G(\sigma
X)X,X\rangle d\sigma \\
& =\int_{0}^{1}\langle \sigma G(\sigma X)Y,X\rangle d\sigma
 +\int_{0}^{1}\sigma ^{2}\langle J_{G}(\sigma X)XY,X\rangle d\sigma
 +\int_{0}^{1}\sigma \langle G(\sigma X)X,Y\rangle d\sigma \\
& =\int_{0}^{1}\langle \sigma G(\sigma X)Y,X\rangle d\sigma
+\int_{0}^{1}\sigma \frac{\partial }{\partial \sigma }
\langle \sigma G(\sigma X)Y,X\rangle d\sigma \\
& =\sigma ^{2}\langle G(\sigma X)Y,X\rangle \big|_0^1 = \langle
G(X)Y,X\rangle .
\end{aligned}
\label{e2.3}
\end{equation}
and
\begin{equation}
\begin{aligned}
&\frac{d}{dt}\int_{0}^{1}\langle F(\sigma Y)Y,X\rangle d\sigma \\
&=\frac{d}{dt}\int_{0}^{1}\langle F(\sigma Y)X,Y\rangle d\sigma \\
&=\int_{0}^{1}\langle F(\sigma Y)X,Z\rangle d\sigma
 +\int_{0}^{1}\sigma \langle J_{F}(\sigma Y)XZ,Y\rangle d\sigma
 +\int_{0}^{1}\langle F(\sigma Y)Y,Y\rangle d\sigma \\
& =\int_{0}^{1}\langle F(\sigma Y)X,Z\rangle d\sigma
+\int_{0}^{1}\sigma \frac{\partial }{\partial \sigma }\langle
F(\sigma Y)X,Z\rangle d\sigma
 +\int_{0}^{1}\langle F(\sigma Y)Y,Y\rangle d\sigma \\
& =\sigma \langle F(\sigma Y)X,Z\rangle \big|_0^1
+\int_{0}^{1}\langle F(\sigma Y)Y,Y\rangle d\sigma \\
& =\langle F(Y)X,Z\rangle +\int_{0}^{1}\langle F(\sigma
Y)Y,Y\rangle d\sigma .
\end{aligned} \label{e2.4}
\end{equation}
 Using estimates \eqref{e2.3} and \eqref{e2.4} in \eqref{e2.2}, we
obtain
\begin{equation*}
\dot{V}=-\int_{0}^{1}\langle F(\sigma Y)Y,Y\rangle d\sigma
+\langle X,H(X,Y,Z)\rangle .
\end{equation*}
 From (i) and (ii), $\dot{V}(t)\geq 0$  for all $X,Y,Z$.
Therefore, $\dot{V}(t)$ is positive-semidefinite so that the
property (P2) holds.

Again by (i) and (ii) it is clear that
\begin{equation*}
\dot{V}(X(t),Y(t),Z(t))=0 \quad (t\geq 0)
\end{equation*}
implies  $X=0$  for all $t\geq 0$. So by \eqref{e1.2}, we have
\begin{equation*}
Y\equiv \dot{X}=0,\quad Z\equiv \dot{Y}=0,\quad \dot{Z}=0\quad
\text{for all }t\geq 0.
\end{equation*}
Thus $\dot{V}(x,y,z)=0$ $(t\geq 0)$ implies
\begin{equation*}
(X(t),Y(t),Z(t))=(0,0,0)\quad \text{for all }t\geq 0,
\end{equation*}
which proves the property (P3).

Hence, the function $V$ has the Krasovskii's properties (P1)-(P3),
which completes the proof of Theorem \ref{thm1}.

\subsection*{Proof of Theorem \ref{thm2}}
To prove the theorem it is sufficient to show that every
$\omega$-periodic solution $(X(t),Y(t),Z(t))$ of \eqref{e1.2},
that is $(X(t),Y(t),Z(t))=(X(t+\omega ),Y(t+\omega ),Z(t+\omega
))$, satisfies
\begin{equation}
(X(t),Y(t),Z(t))=(0,0,0)\quad \text{for all }t.  \label{e2.5}
\end{equation}
To verify \eqref{e2.5}, again we employ the function $V(X,Y,Z)$
which is defined by \eqref{e2.1}. Let $(X_{1},Y_{1},Z_{1})\equiv
(X_{1}(t),Y_{1}(t),Z_{1}(t))$ be an arbitrary $\omega $-periodic
solution of \eqref{e1.2} and consider the function $V(t)\equiv
V(X_{1}(t),Y_{1}(t),Z_{1}(t))$ corresponding to this solution.
Differentiating $V(t)$, we have
\begin{equation}
\dot{V}(t)=-\int_{0}^{1}\langle F(\sigma Y_{1})Y_{1},Y_{1}\rangle
d\sigma +\langle X_{1},H(X_{1},Y_{1},Z_{1})\rangle .  \label{e2.6}
\end{equation}
By (i) and (ii),
\begin{equation}
\dot{V}(t)\geq 0  \label{e2.7}
\end{equation}
for all $t$ which implies $V(t)$ is monotone in $t$. Since $V(t)$
is monotone and periodic, it must be constant. Therefore,
\begin{equation}
\dot{V}(t)=0\text{  for all }t.  \label{e2.8}
\end{equation}
Considering \eqref{e2.6} and \eqref{e2.8} together, and then using
(i) and (ii) we obtain
\begin{equation}
X_{1}=0\quad \text{for all }t.  \label{e2.9}
\end{equation}
Because of $\dot{X_{1}}=Y_{1}$ and $\dot{Y_{1}}=Z_{1}$,
\eqref{e2.9} in turn implies that
\begin{equation}
\dot{X_{1}}=Y_{1}=Z_{1}=\dot{Z_{1}}=0\quad \text{for all }t.
\label{e2.10}
\end{equation}
Hence, we get
\begin{equation*}
(X_{1}(t),Y_{1}(t),Z_{1}(t))=(0,0,0)\text{for all }t
\end{equation*}
which completes the proof.


\subsection*{Remark} Our results give
$n$-dimensional extensions for the results established in
\cite{b3}.

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\end{document}