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\AtBeginDocument{{\noindent\small
Sixth Mississippi State Conference on Differential Equations and 
Computational Simulations,
{\em Electronic Journal of Differential Equations},
Conference 15 (2007),  pp. 159--162.\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 2007 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document} \setcounter{page}{159}
\title[\hfilneg EJDE-2006/Conf/15\hfil Error estimates for asymptotic solutions]
{Error estimates for asymptotic solutions of dynamic equations 
on time scales}

\author[G. Hovhannisyan\hfil EJDE/Conf/15 \hfilneg]
{Gro Hovhannisyan}  % in alphabetical order

\address{Gro R. Hovhannisyan \newline
Kent State University, Stark Campus \\
6000 Frank Ave. NW,
Canton, OH 44720-7599, USA}
\email{ghovhannisyan@stark.kent.edu}

\thanks{Published February 28, 2007.}
\subjclass[2000]{39A10}
\keywords{Time scale; asymptotic representation; error estimates;
   \hfill\break\indent  second order differential equation; first order system }

\begin{abstract}
 We establish error estimates for first-order linear systems of equations
 and linear second-order dynamic equations on time scales by using
 calculus on a time scales \cite{a1,b3,b4} and Birkhoff-Levinson's 
 method of asymptotic solutions \cite{b2,l1,h2,h3}.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{remark}[theorem]{Remark}
\newtheorem{example}[theorem]{Example}

\section{Results}

Asymptotic behavior of solutions of dynamic equations and systems on 
time scales was investigated in  \cite{b4}. 
In this paper we establish error estimates of such asymptotic 
representations, which may be applied to the investigation
of stability of dynamic equations (see f.e. \cite{h3}).

Consider the system of ordinary differential equations on time scales
\begin{equation}\label{e1}
a^{\Delta}(t)=A(t)a(t),\quad t>T,
\end{equation}
where $a^{\Delta}$ is delta (Hilger) derivative, $a(t)$ is a n-vector function, 
and $A(t)$ is a $n\times n$ matrix function from $ C_{rd}(T,\infty)$ 
(definition of rd-continuous functions see in \cite{b3}).
A time scale is an arbitrary nonempty closed subset of the real numbers.
Let $\mathbb{T}$ be a time scale. For $t\in\mathbb{T}$ we define the forward 
jump operator $\sigma:\mathbb{T}\to\mathbb{T}$ by
$$
\sigma(t)=\inf\{s\in \mathbb{T}:s>t\}.
$$
The graininess function $\mu:\mathbb{T}\to[0,\infty]$ is defined by
$$
\mu(t)=\sigma(t)-t.
$$
We assume that $\sup\mathbb{T}=\infty$.

Suppose we can find the exact solutions of the auxiliary system
\begin{equation}\label{e2}
\psi^{\Delta}(t)=A_1(t)\psi(t),\quad t>T,
\end{equation}
with the matrix function $A_1(t)\in C_{rd}(T,\infty)$ close to the 
matrix function A(t), which means that condition
\eqref{e5} below is satisfied. Let $\Psi(t)$ be the fundamental
matrix of the system \eqref{e2}. 
Then the solutions of \eqref{e1} can be represented in the form
\begin{equation}\label{e3}
a(t)=\Psi(t)(C+\varepsilon(t)),
\end{equation}
where  $a(t),\varepsilon(t), C $ are the vector columns.
We can consider \eqref{e3} as a definition of the error vector 
function $\varepsilon(t)$. 
Denote
\begin{equation}\label{e4}
H(t)\equiv\left(1+\mu(t)\Psi^{-1}(t)\Psi^{\Delta}(t)\right)^{-1}\Psi^{-1}(t)
\left(A(t)\Psi(t)-\Psi^{\Delta}(t)\right).
\end{equation}

\begin{theorem} \label{thm1}
Assume there exist an invertible and differentiable matrix 
function $\Psi(t)\in C_{rd}(T,\infty)$ such that  
$1+\mu(t)\Psi^{-1}(t)\Psi^{\Delta}(t)$ is invertible and
\begin{equation}\label{e5}
\int_t^{\infty}\Big(\lim_{m\searrow\mu(s)}\frac{\log(1+m\|H(s)\|)}{m}
\Delta s\Big)<\infty.
\end{equation}
Then every solution of \eqref{e1} can be represented in form \eqref{e3}
 and the error function $\varepsilon(t)$ can be estimated as
\begin{equation}\label{e6}
\|\varepsilon(t)\|\le \|C\|\left(-1+e_{\|H\|}(\infty,t)\right),
\end{equation}
where $\|.\|$ is the Euclidean vector (or matrix) norm:
 $\|C\|=\sqrt{C_1^2+\dots +C_n^2}$,
and  expression in \eqref{e5} usually is used to define the exponential 
function on time scales (see \cite{a1,b3}):
\begin{equation}\label{e7}
e_{\|H\|}(\infty,t)=\exp{\left(\int_t^{\infty}\lim_{m\searrow\mu(s)}
\frac{\log(1+m\|H(s)\|)}{m}\Delta s\right)}.
\end{equation}
\end{theorem}

\begin{remark} \label{rmk1} \rm
Comparing with the similar result from \cite{b4} advantage of Theorem 
\ref{thm1} 
is that it not only proves that error vector function approaches 
to zero as $t$ approaches to infinity, but
inequality \eqref{e6} also estimates the speed of that approach to zero.

>From the estimate \eqref{e6} it follows also that the error vector 
function $\varepsilon(t)$ is small when
 $\int_t^{\infty}\lim_{m\searrow\mu(s)}\frac{\log(1+m\|H(s)\|)}{m}\Delta s$ 
 is small.
\end{remark}


\begin{proof}[Proof of Theorem \ref{thm1}]
Let $a(t)$ be a solution of \eqref{e1}. The substitution 
$a(t)=\Psi(t)u(t)$ transforms \eqref{e1} into
\[
 u^{\Delta}=H(t)u(t),\quad t>T,
\]
where $H$ is defined by \eqref{e4}. By integration we get
\begin{equation}\label{e8}
u(t)=C-\int_t^bH(s)u(s)\Delta s,\quad t<s<b,
\end{equation}
where the constant vector C is chosen as in \eqref{e3}.
Estimating $u(t)$
\[
\|u(t)\|\le\|C\|+\int_t^b\|H(s)\|\cdot\|u(s)\|\Delta s,
\]
and applying Gronwall's lemma (see \cite{b3}) we have
\begin{equation}\label{e9}
\|u(t)\|\le \|C\|e_{\|H\|}(b,t).
\end{equation}
 From representation \eqref{e3} and expression \eqref{e7}, we have
\[
\varepsilon(t)=\Psi^{-1}(t)a(t)-C=u(t)-C=-\int_t^bH(s)u(s)\Delta s.
\]
Then using \eqref{e9} we obtain
\begin{align*}
\|\varepsilon(t)\|&\le \int_t^b\|H(s)u(s)\|\Delta s\\
&\le\|C\|\int_t^b\|H(s)\|\cdot e_{\|H\|}(b,s)\\
&=\|C\|\left[-1+e_{\|H\|}(b,t)\right]\\
&\le\|C\|\left[-1+e_{\|H\|}(\infty,t)\right].
\end{align*}
Note that from \eqref{e5}, it  follows that
\[
\lim_{t\to\infty}\left[-1+e_{\|H\|}(\infty,t)\right]
=\lim_{t\to\infty}
\Big[-1+\exp{\int_t^{\infty}\lim_{m\searrow \mu(s)}
\frac{\log(1+m\|H(s)\|)}{m}\Delta s}\Big]=0.
\]
\end{proof}

Consider the second-order dynamic equation on time scales
\begin{equation}\label{e10}
L[x(t)]=x^{\Delta\Delta}+p(t)x^{\Delta}(t)+q(t)x(t)=0,
\quad t>t_0>0,\; t\in\mathbb{T}.
\end{equation}
>From the functions $\varphi_{1,2}(t)\in C_{rd}^2(T,\infty)$ 
let us construct auxiliary matrix-functions
\begin{equation}\label{e11}
\begin{gathered}
\Phi(t)=\begin{pmatrix}  \varphi_1(t) & \varphi_2(t)\\
\varphi_1^{\Delta}(t) & \varphi_2^{\Delta}(t)\end{pmatrix},\quad
H(t)=(1+\mu(t)\Phi^{-1}(t)\Phi^{\Delta}(t))^{-1}B(t),
\\
 B(t)=\begin{pmatrix} B_{21}(t) & B_{22}(t)\\
-B_{11}(t) & -B_{12}(t)\end{pmatrix},
\quad B_{kj}(t)\equiv\frac{\varphi_{k}(t)L[\varphi_{j}(t)]}{
W(\varphi_1,\varphi_2)}, \quad j=1,2.
\end{gathered}
\end{equation}

\begin{theorem}\label{thm2}
Let $\varphi_{1,2}(t)\in C_{rd}^2(T,\infty)$ be complex-valued functions
such that
\begin{equation}\label{e12}
\int_T^{\infty}\Big(\lim_{m\searrow\mu(s)}\frac{
\log\left(1+m\|\left(1+m\Phi^{-1}(t)\Phi^{\Delta}(t)\right)^{-1}
B(t)\|\right)}{m}\Big)\Delta t <\infty,
\quad k,j=1,2,
\end{equation}
where $\|.\|$ is Euclidean matrix norm.
Then for arbitrary constants $C_1$,$C_2$ there exist solution of
\eqref{e1} that can be written in the form
\begin{gather}
x(t)=\left[C_1+\varepsilon_1(t)\right]\varphi_1(t)+\left[C_2+\varepsilon_2(t)\right]
\varphi_2(t), \label{e13} \\
x^{\Delta}(t)=\left[C_1+\varepsilon_1(t)\right]\varphi_1^{\Delta}(t)+\left[C_2
+\varepsilon_2(t)\right]\varphi_2^{\Delta}(t). \label{e14}
\end{gather}
The error vector-function $\varepsilon(t)=(\varepsilon_1(t),\varepsilon_2(t))$ is estimated as
\begin{equation}\label{e15}
\|\varepsilon(t)\|\le \|C\|\big(-1 +e_{\|H(t)\|}(\infty,t)\big),
\end{equation}
where $C=(C_1,C_2)$ is an arbitrary constant vector, 
and the matrix function $H(t)$ is defined in \eqref{e11}.
\end{theorem}

\begin{proof} Rewrite equation \eqref{e10} in form \eqref{e1}:
\begin{equation}\label{e16}
a^{\Delta}(t)=A(t)a(t),
\end{equation}
where
\[
a(t)=\begin{pmatrix} x(t)\\
x^{\Delta}(t)\end{pmatrix},\quad 
A(t)=\begin{pmatrix}0 & 1\\
  -q(t)& -p(t)\end{pmatrix}.
\]
By substitution
\begin{equation}\label{e17}
a(t)=\Phi(t)w(t),
\end{equation}
in \eqref{e16} we get
\begin{equation}\label{e18}
w^{\Delta}=H(t)w(t),
\end{equation}
 where $H(t)$ defined by \eqref{e11}.
To apply Theorem \ref{thm1} to system \eqref{e16} we choose 
$A(t)=H(t)$ and $A_1\equiv 0$. Then the identity matrix is 
fundamental solution of \eqref{e2}, so conditions \eqref{e5}
 turns to \eqref{e12}.
>From Theorem \ref{thm1} we have
\[
w(t)=C+\varepsilon(t),\quad \hbox{or}  
\quad a(t)=\Phi(t)w(t)=\Phi(t)(C+\varepsilon(t)).
\]
Representations \eqref{e13},\eqref{e14} and estimates \eqref{e15} 
follow from Theorem \ref{thm1}.
\end{proof}

\begin{example} \rm
For solutions of the equation
$$
x^{\Delta\Delta}(t)+\big(\gamma^2+\frac{1}{t^2}\big)x(t)=0,\quad t>t_0,
$$
we get representations \eqref{e13}, \eqref{e14}, where
$$
\varphi_1= \cos_{\gamma}(t,t_0),\quad \varphi_2= \sin_{\gamma}(t,t_0)
$$
are trigonometric functions on time scales \cite{b3}.
By direct calculations
$H=O(t^{-2})$ as $t\to\infty$, and
$$
|\varepsilon_j(t)|\le \|C\|\Big[-1 
+\exp\Big(\int_t^{\infty}\lim_{m\searrow\mu(s)}
\frac{\log\left(1+C_1 m s^{-2}\right)}{m}\Delta s\Big)\Big],
\quad j=1,2.
$$
\end{example}

\subsection*{Acknowledgments}
The author wants  to thank the anonymous referee for his/her
comments that helped improving the original paper.


\begin{thebibliography}{00}

\bibitem{a1} R. Aulbach and S. Hilger. 
\emph{Linear dynamic processes with inhomogeneous time scales.} 
In Non-linear Dynamics and Quantum Dynamical systems. 
Academie Verlag, Berlin, 1990.

\bibitem{b1} Z. Benzaid and D. A. Lutz. 
\emph{Asymptotic representation of solutions of
perturbed systems of linear difference equations.} 
Studies in Applied Mathematics, 1987, 77, 195-221.

\bibitem{b2} J. D. Birkhoff 
\emph{Quantum mechanics and asymptotic series.} 
Bull. Amer. Math., Soc. 32 1933, 681-700

\bibitem{b3} M. Bohner, A. Peterson. 
\emph{Dynamic equations on time scales: An Introduction with Applications.} 
Birkhauser, Boston, 2001.

\bibitem{b4} M. Bohner, D. A. Lutz. 
\emph{Asymptotic behavior of Dynamic Equations on Time Scales.} 
J. Differ. Equations Appl, 2001, 7 (1): 21-50.

\bibitem{l1} N. Levinson 
\emph{The asymptotic nature of solutions of linear systems of differential 
equations.} Duke Math. J., 1948, 15, 111-126.

\bibitem{h1} W.A. Harris and D.A. Lutz. 
\emph{A unified theory of asymptotic integration.} 
J. Math. Anal. Appl., 1977, 57 (3), 571-586.

\bibitem{h2} G. Hovhannisyan. 
\emph{Estimates for error functions of asymptotic solutions of ordinary 
linear differential equations}. Izv. NAN Armenii, Matematika, 
[English translation: Journal of Contemporary Math. Analysis -
 (Armenian Academy of Sciences) 1996, v. 31, no.1, 9-28.

\bibitem{h3}G. Hovhannisyan.  
\emph{Asymptotic stability for second-order differential equations 
with complex coefficients} Electron. J. Diff. Eqns., Vol. 2004 (2004), 
No. 85, 1-20.

\end{thebibliography}

\end{document}