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\markboth{Monotonicity and bounds on Bessel functionsshort}{ Larry Landau }
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\title{\vspace{-1in}\parbox{\linewidth}{\footnotesize\noindent
Mathematical Physics and Quantum Field Theory, \newline
Electronic Journal of Differential Equations, Conf. 04, 2000, pp. 147--154\newline
http://ejde.math.swt.edu or http://ejde.math.unt.edu
\newline ftp  ejde.math.swt.edu or ejde.math.unt.edu (login: ftp)}
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 Monotonicity and bounds on Bessel functions 
\thanks{ {\em Mathematics Subject Classifications:} 33C10.
\hfil\break\indent
{\em Key words:} Bessel function, best uniform bound, 
quantum particle on a lattice.
\hfil\break\indent
\copyright 2000 Southwest Texas State University  and University of
North Texas. \hfil\break\indent
Published July 12, 2000. } }

\date{}
\author{ Larry Landau }
\maketitle
\begin{abstract} 
I survey my recent results on monotonicity with respect to 
order of general Bessel functions, which follow from a new identity and 
lead to  best possible uniform bounds. Application may be made to the 
`spreading of the wave packet' for a free quantum particle on a lattice
and to estimates for perturbative expansions.
\end{abstract}


{\em On my arrival as a graduate student at Berkeley in September 1964, I 
was amused to see a Volkswagen Beetle with Schr\"{o}dinger's equation 
written on it drive past. (I don't recall if it was the time-dependent or 
time-independent equation.)  As I stood in line to enroll, a table off to the 
side with a `Free Speech' banner caught my eye. Soon were to begin the 
student demonstrations which culminated in Vietnam war protests. I managed 
to complete the typing of my thesis in 1969 even as tear gas wafted in 
through the open window. I had asked Eyvind Wichmann if he would supervise 
my Ph.D. studies, and after checking that Emilio Segr\`{e} had given a good 
report on my oral examination, he agreed to take me on. I'd like to thank 
Eyvind for helping to make my stay at Berkeley a successful one.}

\section{Motivation}
The free evolution of a quantum particle is important for understanding the 
``spreading of the wave packet,'' the large time behavior of scattering states,  
the Dyson perturbative expansion (each term of which is expressed in terms 
of the free evolution), and other aspects of the evolution of the quantum 
particle. The free evolution of a quantum particle on a one-dimensional 
lattice is described by Bessel functions of integer order, as reviewed 
below. In higher dimensions, the free evolution is given by products of the 
one-dimensional evolution, and so Bessel functions again describe the 
evolution. A detailed study of the behavior of Bessel functions of integer 
order is therefore necessary if the free evolution on a lattice is to be as 
well understood as in the continuum. 

Computer packages such as Maple yield precise plots of Bessel functions, and 
I carried out computer experiments which yielded a very detailed picture of 
the variation of the Bessel function with respect to order and precise 
bounds on the magnitude of the Bessel function. Rough bounds were no longer 
satisfying when I could see the precise behavior on the computer screen. 
(Of course, computer generated pictures can be misleading and rigorous 
mathematical proof is required.)
Just as a physical theory should give precise agreement with experiment, so 
too one should prove results in precise agreement with computer experiments 
and hence ``best possible.'' 

Recalling that the Bessel function of integer order satisfies
\[
J_{-n}(x)=J_n(-x)=(-1)^nJ_n(x)
\]
we need only consider $n\geq0$ and $x\geq0$. The dependence of $J_n(x)$ on 
the order $n$ is best elucidated by replacing the discrete $n$ with a 
continuous $\nu$. Thus
generalizing from Bessel functions of integer order, we are led to study the 
Bessel function of the first kind $J_\nu(x)$, the second kind $Y_\nu(x)$, 
and the general Bessel function $C_\nu(x)=aJ_\nu(x)+bY_\nu(x)$, for 
$\nu\geq0$ and $x\geq0$.
\subsection*{A Quantum Particle on a Lattice}
A quantum particle on the one-dimensional lattice ${\cal 
L}=\{0,\pm\ell,\pm2\ell,\ldots\}$ has a wave function $\psi(n)$, position 
operator $Q$ and shift operator $U$, where $[Q\psi](n)=n\ell\psi(n)$ and 
$[U\psi](n)=\psi(n-1)$. The finite-difference Laplacian may be expressed in 
terms of the shift operator as
\[
\nabla^2=\frac{U+U^{-1}-2I}{\ell^2}
\]
the free Hamiltonian then being 
\[
H=-\frac{\hbar^2}{2m}\nabla^2\; .
\]
The position operator at time $t$ is
\[
Q(t)=e^{itH/\hbar}Qe^{-itH/\hbar}
\]
and the momentum operator is
\[
P=\left.m\frac{d}{dt}\right\vert_{t=0}Q(t)=\frac{\hbar}{i}\frac{1}{2\ell}[U^
{-1}-U] \; .
\]
It then follows that $P(t)=P$ and 
\begin{equation}\label{enewton}
Q(t)=Q+\frac{t}{m}P\; .
\end{equation}
We'll call equation (\ref{enewton}) {\em Newton's Law}, which has the same 
form as in the continuum. A consequence of Newton's law is that when 
observed on a large space-time scale, the free quantum particle on a lattice 
follows straight line trajectories. (See \cite{l1}, and for additional 
discussion of the large space-time limit \cite{l2}.)
\subsection*{Bessel Functions}
A comparison of the unitary evolution 
\[
e^{-itH/\hbar}=e^{-it\hbar/m\ell^2}e^{t\hbar/2m\ell^2\left[(iU)-(iU)^{-
1}\right]}
\]
with the generating function for Bessel functions
\[
e^{x/2(\rho-1/\rho)}=\sum_{n=-\infty}^\infty\rho^nJ_n(x)
\]
leads to the expression
\[
e^{-itH/\hbar}=e^{-it\hbar/m\ell^2}\sum_{n=-\infty}^\infty 
i^nJ_n\left(t\hbar/m\ell^2\right)U^n \; .
\]
The kernel of the free evolution on the lattice is therefore
\begin{equation}\label{ekern}
K_t(n,k)=e^{-it\hbar/m\ell^2}i^{n-k}J_{n-k}(t\hbar/m\ell^2),
\end{equation}
which may be compared with the kernel in the continuum
\[
K_t(x,y)=\sqrt{\frac{m}{2\pi\hbar it}}e^{im(x-y)^2/2\hbar t}\; .
\]
The $t^{-1/2}$ bound, uniform in $x$, for the continuum kernel must be 
replaced by a $t^{-1/3}$ bound, uniform in $n$, on the lattice.\\
{\bf Remark.} It's amusing that the well-known Bessel function identity
\[
nJ_n(x)=\frac{x}{2}\left[J_{n-1}(x)+J_{n+1}(x)\right]
\]
may be thought of as an expression of Newton's law, as follows by writing 
Newton's law as
\[
e^{-itH/\hbar}Q=(Q-\frac{t}{m}P)e^{-itH/\hbar}
\]
and substituting the kernel (\ref{ekern}).
\section{Method and Results}
Our approach is based on a new Bessel function identity which leads to  
monotonicity properties and in turn to best possible uniform bounds. The 
main ingredients in the derivation of the new identity are the Wronskian
\cite[p.76(1)]{w}
\begin{equation}\label{ejy1}
J_\nu(x)Y_\nu^\prime(x)-Y_\nu(x)J_\nu^\prime(x)=\frac{2}{\pi x}
\end{equation}
where $^\prime$ denotes derivative with respect to the argument $x$,
and the Nicholson integral (this one actually proved by Watson) 
\cite[p.444(2)]{w} relating derivatives with respect to the order $\nu$:
\begin{equation}\label{ejy2}
J_\nu(x)\frac{\partial Y_\nu(x)}{\partial\nu}(x)-
Y_\nu(x)\frac{\partial J_\nu(x)}{\partial\nu}(x)=-\frac{4}{\pi}A_\nu(x)
\end{equation}
where
\[
A_\nu(x)=\int_0^\infty K_0(2x\sinh\,t)e^{-2\nu t}\,dt
\]
and $K_0$ is the modified Bessel function of the second kind of order $0$, 
where in general:
\[
K_\nu(x)=\int_0^\infty e^{-x\cosh\,u}\cosh\,\nu u\,du\; .
\]
The identity concerns the derivative with respect to order of the function 
\[
f_\nu(x)=F(x)C_\nu(x)
\]
where $C_\nu(x)=aJ_\nu(x)+bY_\nu(x)$ and $a$ and $b$ are real constants 
(independent of $\nu$ and $x$), and $F(x)$ is a differentiable function of 
$x$. The analysis \cite{l3} proceeds by introducing also the function
\[
g_\nu(x)=F(x)D_\nu(x)
\]
where
\[
D_\nu(x)=cJ_\nu(x)+dY_\nu(x)
\]
and $\gamma\doteq ad-bc\neq0$. A straightforward computation using 
(\ref{ejy1}) and (\ref{ejy2}) yields
\begin{eqnarray}
\left[\frac{g_\nu(x)}{f_\nu(x)}\right]^\prime&=&\frac{2\gamma F^2}{\pi 
xf_\nu^2}\label{egf1}\\
\frac{\partial}{\partial\nu}\left[\frac{g_\nu(x)}{f_\nu(x)}\right]&=&-
\frac{4\gamma F^2A_\nu}{\pi f_\nu^2}\label{egf2}
\end{eqnarray}
Now setting the derivative of (\ref{egf1}) with respect to $\nu$ equal to 
the derivative of (\ref{egf2}) with respect to $x$ gives \cite{l3}
\begin{equation}\label{ederf}
\fbox{\begin{minipage}{3in}
\[
\frac{\partial 
f_\nu}{\partial\nu}=x\left[\frac{(F^2A_\nu)^\prime}{F^2}f_\nu-2A_\nu 
f_\nu^\prime\right]\; .
\]
~
\end{minipage}}
\end{equation}
This is the new identity which leads to monotonicity and then to best 
possible uniform bounds. Notice that it expresses a derivative with respect 
to order $\nu$ (which is in general difficult to analyze) in terms of 
derivatives with respect to argument $x$ (which are easier to deal with). 
The main advantage of (\ref{ederf}) becomes apparent at a stationary point 
of $f_\nu$, where $f_\nu^\prime(x)=0$, and hence
\[
\frac{\partial 
f_\nu}{\partial\nu}=x\frac{\left[F^2A_\nu\right]^\prime}{F^2}f_\nu \; .
\]
Multiplying through by $f_\nu$ then yields
\begin{equation}\label{ederg}
\fbox{\begin{minipage}{3in}
\[
\frac{\partial 
f_\nu^2}{\partial\nu}=2x\frac{f_\nu^2}{F^2}\left[F^2A_\nu\right]^\prime \; .
\]
~
\end{minipage}}
\end{equation}
Notice that the sign of the right-hand-side of (\ref{ederg}) is the same as 
the sign of $[F^2A_\nu]^\prime$. (Recall that we are taking $x\geq0$ and 
$\nu\geq0$.) Thus {\em the magnitude of $f_\nu$ at a stationary point is 
increasing or decreasing in $\nu$ depending on whether $F^2A_\nu$ is 
increasing or decreasing in $x$ at the stationary point}.
\subsection*{Case 1: $F(x)=1$}
Here $f_\nu(x)=C_\nu(x)$, the general Bessel function. According to equation 
(\ref{ederg}) we need to consider $A_\nu^\prime$. But as is easily seen, 
$K_0(x)$ decreases monotonically in $x$ and hence $A_\nu(x)$ decreases monotonically 
in $x$. Indeed, $A_\nu^\prime(x)<0$ for all positive $x$. We conclude that 
{\em the magnitude of $C_\nu(x)$ is decreasing in $\nu$ at all its positive 
stationary points}. In the case of $J_\nu(x)$, its value at the first 
stationary point is equal to $\sup_x\vert J_\nu(x)\vert$, which therefore 
decreases monotonically in $\nu$.
\subsection*{Case 2: $F(x)=x^{1/2}$}
Here $f_\nu(x)=x^{1/2}C_\nu(x)$. According to equation (\ref{ederg}) we need 
to consider $[xA_\nu(x)]^\prime$. Now by a change in the variable of 
integration we may express $xA_\nu(x)$ as
\begin{equation}\label{exa}
xA_\nu(x)=\int_0^\infty K_0(2x\sinh(y/x))e^{-2\nu y/x}dy \; .
\end{equation}
Since $2\nu y/x$ and $x\sinh(y/x)$ decrease with $x$, it follows that the 
integrand (\ref{exa}) increases and thus $xA_\nu(x)$ is increasing in $x$. 
Indeed $[xA_\nu(x)]^\prime>0$ for all positive $x$. We conclude that {\em 
the magnitude of $x^{1/2}C_\nu(x)$ in increasing in $\nu$ at all its 
positive stationary points}. 
\subsection*{Case 3: $F(x)=x^\alpha$, $0<\alpha<1/2$}
Here $f_\nu(x)=x^\alpha C_\nu(x)$. According to equation (\ref{ederg}) we 
need to consider $[x^{2\alpha}A_\nu(x)]^\prime$. An analysis \cite{l3} of 
$x^{2\alpha}A_\nu(x)$ shows that it tends to $0$ as $x\rightarrow0$ and 
$\infty$, and has a unique stationary point at $x=x_\nu$, which is the 
location of its maximum. The point $x_\nu$ increases with $\nu$ \cite{l3}. 
The magnitude of  $x^\alpha C_\nu(x)$ at a stationary point $x=X_\nu$ is 
increasing in $\nu$ if $X_\nu<x_\nu$ and decreasing in $\nu$ if 
$X_\nu>x_\nu$. 

The most important case is $\alpha=1/3$ and $C_\nu=J_\nu$, so 
$f_\nu(x)=x^{1/3}J_\nu(x)$. We first locate the maximum of $x^{1/3}J_\nu(x)$ 
at its first stationary point $x=X_\nu$, using a Sturm comparison argument. 
If we could show that $X_\nu>x_\nu$ for all $\nu$, we could conclude that 
$\sup_x\vert x^{1/3}J_\nu(x)$ decreases in $\nu$ and hence is bounded by its 
value at $\nu=0$, which is $c=0.7857\cdots$ (which would therefore be the 
best possible constant in such a bound):
\begin{equation}\label{ebound}
\vert J_\nu(x)\vert\leq c\vert x\vert^{-1/3}\; .
\end{equation}
However, we do not show $X_\nu>x_\nu$ for all $\nu$, but nevertheless we are 
able to prove (\ref{ebound}) by a combination of monotonicity for $\nu\leq3$ 
and a bound for $\nu\geq3$. Thus we prove (\ref{ebound}) in two steps:
\begin{description}
\item[Step 1.]For $0\leq\nu\leq3$, we prove (\ref{ebound}) by showing 
$X_\nu>x_\nu$ for $0\leq\nu\leq3$. This is shown by computing the values 
(given in table~\ref{tab1}) of $X_\nu$ and $x_\nu$ for $\nu=0,0.5,1,2$ and 
$3$, and using the fact that both $x_\nu$ and $X_\nu$ are increasing in 
$\nu$. (For the increase in $X_\nu$ see \cite{m},\cite{is}, or \cite{hm}. 
Note that $X_\nu$ is a root of the equation 
$\frac13J_\nu(x)+xJ_\nu^\prime(x)=0$. The general qualitative behavior with 
respect to order $\nu$, including monotonicity and multiplicity, of all the 
positive roots of $\alpha J_\nu(x)+xJ_\nu^\prime(x)=0$ for all real $\alpha$ 
and $\nu$, is derived in \cite{l4}.)

Then for $0\leq\nu\leq0.5$,
\[
x_\nu\leq x_{0.5}<X_0\leq X_\nu \; .
\]
A similar argument works for the other intervals, finally giving 
$x_\nu<X_\nu$ for all $\nu$ in the interval $[0,3]$.

\begin{table}[h,b]
\begin{center}
\begin{tabular}{l|l|l}
$\nu$&$x_\nu$&$X_\nu$\\ \hline
0&0.1726&0.7837\\
0.5&0.5918&1.4569\\
1&1.0595&2.0694\\
2&2.0336&3.2315\\
3&3.0231&4.3540\\
\end{tabular}
\caption{Values of $x_\nu$ (the location of the maximum of $A_\nu(x)$) and 
$X_\nu$ (the location of the maximum of $\vert 
x^{1/3}J_\nu(x)\vert$).}\label{tab1}
\end{center}
\end{table}
\item[Step 2.]
For $\nu\geq3$, we prove (\ref{ebound}) by the bound:
\begin{equation}\label{ebound3}
\sup_x\vert x^{1/3}J_\nu(x)\vert=X_\nu^{1/3}J_\nu(X_\nu)
=\left[\frac{X_\nu}{\nu}\right]^{1/3}\nu^{1/3}J_\nu(X_\nu)
\leq\left[\frac{X_3}{3}\right]^{1/3}b
\end{equation}
This bound uses two facts:
\begin{itemize}
\item the decrease in $\nu$ of $X_\nu/\nu$ (\cite{is} and \cite{hm}, see 
also \cite{l4}) 
\item the bound
\begin{equation}\label{ebound2}
\nu^{1/3}\sup_x\vert J_\nu(x)\vert<b
\end{equation}
where $b=0.6748\cdots$ is the best possible such constant. 
This bound is proved in \cite{l3} using a Sturm comparison argument, which 
shows that $\nu^{1/3}\sup_x\vert J_\nu(x)\vert$ strictly increases to $b$.
\end{itemize}
Substituting values into the right-hand-side of (\ref{ebound3}) gives 
$0.7641\cdots$, which is less than $c$. Hence (\ref{ebound}) is proved for 
$\nu\geq3$.
\end{description}
\section{Summary}
\begin{enumerate}
\item The magnitude of the general Bessel function $C_\nu(x)$ of order $\nu$ 
is decreasing in $\nu$ at all its positive stationary points. It follows 
that $\sup_x\vert J_\nu(x)\vert$ is decreasing in $\nu$.
\item The magnitude of $x^{1/2}C_\nu(x)$ is increasing in $\nu$ at all its 
positive stationary points.
\item $\nu^{1/3}\sup_x\vert J_\nu(x)\vert$ is increasing in $\nu$ to the 
value $b$, yielding the bound, uniform in the argument $x$, 
\[
\vert J_\nu(x)\vert<\frac{b}{\nu^{1/3}} 
\]
which is best possible in the exponent $1/3$ and constant $b=0.6748\cdots$.
\item The bound, uniform in the order $\nu$,
\[
\vert J_\nu(x)\vert\leq\frac{c}{x^{1/3}}
\]
is best possible in the exponent $1/3$ and constant $c=0.7857\cdots$.
\end{enumerate}
\begin{thebibliography}{abc}
\bibitem{hm} M.\,H\'{a}\v{c}ik and E.\,Michal\'{i}kov\'{a}, {\em Pr\'{a}ce a 
\v{S}t\'{u}die Vysokej \v{S}koly Dopravy A Spojov v \v{Z}iline} (1989) 7-13.
\bibitem{is} E.\,K.\,Ifantis and P.\,D.\,Siafarikas, {\em Zeitschrift 
f\"{u}r Analysis und ihre Anwendungen} {\bf 7} No.2 (1988), 185-192.
\bibitem{l1} L.\,J.\,Landau, {\em J.\,Statist.\,Phys.} {\bf 77}, No. 1-2 
(1994), 259-310.
\bibitem{l2} L.\,J.\,Landau, {\em Annals of Physics} {\bf 246}, No. 1 
(1996), 190-227.
\bibitem{l3} L.\,J.\,Landau, Bessel Functions: Monotonicity and Bounds, {\em 
J.\,London Math. Society}, to appear.
\bibitem{l4} L.\,J.\,Landau, Ratios of Bessel Functions and Roots of $\alpha 
J_\nu(x)+xJ_\nu^\prime(x)=0$, to be published.
\bibitem{m} M.E.\,Muldoon, {\em Arch. Math. (Brno)} {\bf 1} (1982), 23-34.
\bibitem{w} G.\,N.\,Watson, {\em A Treatise on the Theory of Bessel 
Functions} (Cambridge University Press, 1996).
\end{thebibliography}

\noindent{\sc Larry Landau }\\
 Mathematics Department, King's College London\\
 Strand, London WC2R 2LS, UK\\
email: {\tt larry.landau@kcl.ac.uk}
\end{document}