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\markboth{ Contributions of A. C. Lazer to mathematical population dynamics }
{ Chris Cosner }
\begin{document}
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\title{\vspace{-1in}\parbox{\linewidth}{\footnotesize\noindent
Nonlinear Differential Equations, \newline
Electron. J. Diff. Eqns., Conf. 05, 2000, pp. 335--352\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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Contributions of Alan C. Lazer to \\ mathematical population dynamics
% 
\thanks{ {\em Mathematics Subject Classifications:}  
92D25, 34D05, 34C25, 35K57, 35K20.  \hfil\break\indent 
{\em Key words:} population dynamics, Lotka-Volterra, periodic-parabolic, 
reaction-diffusion, \hfil\break\indent
competitive systems, nonautonomous systems.
 \hfil\break\indent
\copyright 2000 Southwest Texas State University. 
\hfil\break\indent Published November 2, 2000.  } } 

\date{}
\author{ Chris Cosner }
\maketitle
\begin{abstract} 
This paper is a survey of the contributions that Professor Alan C. Lazer has
made to the mathematical theory of population dynamics. Specific areas
where Professor Lazer has made important contributions include time
periodic population models with diffusion and nonautonomous models for
many competing species.
\end{abstract}

\newtheorem{theorem}{Theorem}[section]


\section{Introduction}

This article will describe some of the contributions that Alan Lazer has
made to mathematical population dynamics. Those contributions include:
\begin{itemize}

\item General and abstract results on competitive systems and on
periodic-parabolic problems

\item Results and methods for nonautonomous systems of ordinary
differential equations, specifically in the context of competition models

\item Various specific results on stability, the existence of traveling
wavefronts, and other problems in the theory of reaction-diffusion
models.
Professor Lazer's papers contributing to the development of
population dynamics include [3-10,14,15,20,23-26].

\end{itemize}

\noindent In addition to his
direct mathematical contributions, Professor Lazer has personally
influenced, inspired, and/or collaborated with many other mathematicians
working in the area. Those include, among others, S. Ahmad, C. Alvarez,
R.S. Cantrell, A. Castro, E.N. Dancer, P. Hess, A. Leung, P.J. McKenna,
F. Montes de Oca, D. Murio, D. Sanchez, and the author of this
survey.  The remainder of the survey is divided into three sections: a
section covering the period from the early 1980's to the early 1990's,
with a focus on models for two competing species with diffusion and/or
periodic time dependence; a section covering the period from the early
1990's to the present, with a focus on models for many competitors with
arbitrary time dependence; and a brief concluding section. Some references
are made to papers that use or build upon Professor Lazer's ideas, but
those are simply examples; there has been no attempt to make a
comprehensive listing of such work.

\section{Eigenvalues, Periodicity, and Pairs of Competing Species}

One of the most basic models in population dynamics is the logistic
equation
$$ \frac{du}{dt}=(a-bu)u \eqno{(2.1)} 
$$
 where $u$ represents a population density (so that only
solutions with $u\geq 0$ are physically meaningful), $a$ represents the
population growth rate at low densities, and $b>0$ represents the
self-regulatory effects of crowding on the population. The logistic
equation always has the nonnegative equilibrium $u=0$, and if $a>0$ it
also has the positive-equilibrium $a/b$. If $a>0$ and $u(0)>0$ then
$u\rightarrow a/b$ as $t\rightarrow \infty $. If $a\leq 0$ and $u(0)\geq
0$ then $u\rightarrow 0$ as $t\rightarrow \infty $. Linearizing
(2.1) around $u=0$ gives $dy/dt=ay$, so $u=0$ is locally stable if $a\leq
0$, asymptotically in  the case $a<0$, and unstable if $a>0$; similarly
linearizing around $a/b$ when $a>0$ yields $dz/dt=-az$, so in that case
$u=a/b$ is locally stable. It is clear from the above discussion that the
sign of $a$ is crucial in determining the behavior of (2.1). The general
ideas of stability, instability, and bifurcation apply to models much more
general than (2.1) but in cases with time dependent coefficients, or
diffusion, or both, we need a criterion that can replace checking the sign
of $a$. The extension of the logistic equation (2.1) and other models to
cases with periodicity and diffusion is important from the applied
viewpoint because many ecological systems are affected by seasonal changes
and most populations are dispersed in space.

\subsection*{Periodic Systems of Ordinary Differential Equations: Floquet
Theory}

If $A(t)$ is an $n\times n$ matrix with continuous $T$-periodic
coefficients, it follows from the results of Floquet theory that the
system
$$ \frac{d\vec{y}}{dt}=A(t)\vec{y} \eqno{(2.2)} 
$$
 has a fundamental matrix $\Phi (t)$ of the form $\Phi (t)=P
(t)\exp (tR)$ where $P(t)$ is $T$-periodic. (If $A$ is a constant
then we may take $\mathbf{P} =I$ and $R=A$.) The characteristic exponents of
the system are the eigenvalues $\{\rho _i\}$ of $R$. (The Floquet
multipliers are $ \{e^{\displaystyle T\rho _i}\}$.) If $\mathop{\rm Re}\rho _i<0$ for
$i=1,\ldots,n$
then the solution $\vec{y} (t)\equiv 0$ is stable, so the characteristic
exponent with the largest real part plays a role analogous to $a$ in
(2.1).

\subsection*{Elliptic Eigenvalues and Diffusion}

The parabolic equation
$$\begin{array}{c} u_t=d\Delta u+ru \quad \mbox{in} \quad \Omega \\[2pt]
\alpha {\displaystyle \frac{\partial u}{\partial \vec{n}}} +\beta u=0
\quad
\mbox{on} \quad
\partial \Omega \,, \end{array} \eqno{(2.3)} 
$$
 where $\Omega \subseteq {\mathbb R}$ is a bounded domain and where
$\alpha ,\beta \geq 0,\; \alpha +\beta >0$, can be solved via separation
of variables to obtain $u={\displaystyle \sum ^\infty _{n=1}}c_ne^{\rho
_nt}\phi _n(x)$ where $\rho _n$ and $\phi _n(x)$ are the $n$th eigenvalue
and eigenfunction respectively for the problem
$$ \begin{array}{c} d\Delta \phi +r\phi =\rho \phi \quad \mbox{in} \quad
\Omega \\[2pt]
 \alpha {\displaystyle \frac{\partial \phi }{\partial \vec{n}
}}+\beta \phi =0 \quad \mbox{on} \quad \partial \Omega\,.
 \end{array} \eqno{(2.4)} 
$$
 The classical variational theory of (2.4) implies that the
eigenvalues $\{\rho _i\}$ are real, with $\rho _1>\rho _2\geq \rho
_3\ldots $. If $\rho _1<0$ then all solutions to (2.3) will approach zero
as $t\rightarrow \infty $; if $\rho _1>0$ at least some will
grow. Furthermore, the eigenfunction $\phi _1(x)$ corresponding to $\rho
_1$ is positive in $\Omega $ and $\rho _1$ is a simple eigenvalue. For
these reasons $\rho _1$ is called the principal eigenvalue for (2.4). More
general elliptic operators may fail to be self-adjoint and thus may admit
complex eigenvalues. However, since second order elliptic operators
satisfy the maximum principle, and typically have compact resolvents on
appropriate function spaces, the Krein-Rutman theorem may be used to show
that the eigenvalue problem
$$ \begin{array}{c} {\displaystyle \sum ^m_{i,j=1}} a_{ij}(x)\phi
_{x_ix_j}+{\displaystyle \sum ^n_{i=1}}b_i(x)\phi _{x_i}+c(x)\phi =\rho
\phi \quad \mbox{in} \quad \Omega \\[2pt]
\alpha (x){\displaystyle
\frac{\partial \phi }{\partial \vec{n}}}+\beta (x)\phi =0 \quad \mbox{on}
\quad \partial \Omega \end{array} \eqno{(2.5)} 
$$
 has a principal eigenvalue $\rho _1$ with positive
eigenfunction $\phi _1$. (This assumes the coefficients of (2.5) and the
boundary of $\Omega $ are reasonably smooth.) It turns out that $\rho
_1>\mathop{\rm Re}\rho _n$ for $n>1$, but that requires additional arguments beyond the
Krein-Rutman theorem. See [11,32] for details.

\subsection*{Principal Eigenvalues of Periodic-Parabolic Operators}

We now can describe one of Alan Lazer's contributions to population
dynamics. Suppose that $\Omega \subseteq {\mathbb R} ^n$ is bounded with smooth
boundary. Let
$$ Lu=u_t-{\displaystyle \sum
^n_{i,j=1}}a_{ij}(x,t)u_{x_ix_j}-{\displaystyle \sum
^n_{i=1}}b_i(x,t)u_{x_i}-c(x,t)u, \eqno{(2.6)} 
$$
 and assume that the coefficients are H\"{o}lder continuous and
$T$-periodic, and that $((a_{ij}))$ is symmetric and uniformly positive
definite. Suppose that $\alpha (x)$ and $\beta (x)$ are nonnegative
H\"{o}lder continuous functions on $\partial \Omega $ with $\alpha +\beta
>0$. 

\begin{theorem}[Lazer, Castro and Lazer {[14,23]}] % Theorem 2.1
There exist a real number $\sigma _1$ and a $T$-periodic function $\phi
_1(x,t)\in C^{2+\alpha ,1+\alpha /2 }(\overline{\Omega } \times {\mathbb R})$
which
is positive on $\Omega \times {\mathbb R}$ such that
$$ \begin{array}{c} L\phi =\sigma _1\phi \quad \mbox{in} \quad \Omega
\times {\mathbb R} \\[2pt]
\alpha (x) {\displaystyle \frac{\partial \phi}{\partial
\vec{n}}} +\beta (x)\phi =0 \quad \mbox{on} \quad \partial \Omega\,.
 \end{array} \eqno{(2.7)} 
$$
\end{theorem}

\noindent {\bf Remarks}: Note that if $L$ and $\phi _1$ were independent
of $t$ then we would have $\sigma _1=-\rho _1$ where $\rho _1$ is the
principal eigenvalue in (2.5). The proof of this theorem is based on the
Krein-Rutman Theorem, as in the nonselfadjoint elliptic case. A key step
involves showing that $(L+K)^{-1}$ exists if $K$ is a large positive
constant; this is accomplished via a result of Kolesov on the existence of
periodic solutions between sub- and super-solutions [22].

Once $\sigma _1$ is available it is possible to use $\phi _1$ to construct
sub- and/or super-solutions to nonlinear problems, apply bifurcation
theory, degree theory, etc., and generally extend much of the theory of
nonlinear elliptic eigenvalue problems. Periodic-parabolic logistic
equations and Lokta-Volterra models are discussed in detail by Hess in
[19].
A typical result is: 

\begin{theorem}[{[19]}] % Theorem 2.2
The $T$-periodic parabolic logistic equation
$$\begin{array}{c} u_t-{\displaystyle \sum
^n_{i,j=1}}a_{ij}(x,t)u_{x_i,x_j}-{\displaystyle \sum
^n_{i=1}}b_i(x,t)u_{x_i} =(c(x,t)-m(x,t)u)u \quad \mbox{in }
\Omega\times(0,\infty ) \\[2pt]
 \alpha (x){\displaystyle \frac{\partial u}{\partial
\vec{n}}}+\beta (x)u=0 \quad  \mbox{on} \quad \partial \Omega \times
(0,\infty ) \end{array} \eqno{(2.8)} 
$$
 has a unique postive $T$-periodic solution $u^*(x,t)$ if and
only if $\sigma _1<0$ in (2.7), where $L$ is the operator in (2.6). (The
coefficients in (2.8) are the same as in (2.6).) If $\sigma _1<0$ then
$u^*$ is globally attracting among positive solutions. If $\sigma _1\geq
0$ then all nonnegative solutions of (2.8) approach zero as $t\rightarrow
\infty $. \end{theorem} 

\noindent {\bf Remarks}: It is clear from Theorem 2.2 that $-\sigma _1$
plays the same role in (2.8) that $a$ plays in (2.1). By combining the use
of the principal eigenvalue of (2.7) with other ideas introduced by
Professor Lazer it is possible to give a comprehensive treatment of
Lotka-Volterra models with diffusion and time periodicity; see for example
[19]. We now turn to some of those other ideas.

\subsection*{Periodic and Diffusive Lotka-Volterra Models}

Just as the logistic equation is the simplest model for a single
population which accounts for the effects of crowding, Lotka-Volterra
models are the simplest models of density-dependent interactions between
species. If $u_i$ denotes the population density of the $i$th species, the
basic Lotka-Volterra competition model is
$$ {\displaystyle \frac{du_i}{dt}}=(a_i-b_{ii}u_i-b_{ij}u_j)u_i,
\;\; i=1,2, \;\; j\neq i. \eqno{(2.9)} 
$$
 It is easy to see via phase plane analysis that if
$$ a_i>a_jb_{ij}/b_{jj} \quad \mbox{for} \quad i=1,2, \; j\neq i,
\eqno{(2.10)} 
$$
 then there is a unique equilibrium $(u^*_1,u^*_2)$ with both
components positive which is globally attracting among solutions that have
both components positive initially. If (2.10) fails then generally the
model either predicts that one of the competitors always becomes extinct
while the other persists, or that the outcome of the competition depends
on the initial data. Another feature of the system (2.9) is that if
$(u_1,u_2)$ is a solution which is nonnegative in both components then the
change of variables $(v_1,v_2)=(u_1,-u_2)$ converts (2.9) to a cooperative
system. Cooperative systems are well known to be order preserving so if
$(u_1,u_2)$ and $(\tilde{u} _1,\tilde{u} _2)$ are nonnegative solutions to
(2.9) with $u_1(0)\geq \tilde{u} _1(0)$ and $u_2(0)\leq \tilde{u} _2(0)$
then $u_1(t)\geq \tilde{u} _1(t)$ and $u_2(t)\leq \tilde{u} _2(t)$ for all
$t>0$. (See for example [15,19,27,37] for more details.) This order
preserving property extends via the maximum principle to the
Lotka-Volterra model with diffusion
$$ \begin{array}{c} u_{i_t}=d_i\Delta u_i+[a_i-b_{ii}u_i-b_{ij}u_j]u_i
\quad \mbox{in} \quad \Omega \times (0,\infty ),\\[2pt]
\alpha_i{\displaystyle \frac{\partial u_i}{\partial \vec{n}}}+\beta _iu_i=0
\quad
\mbox{on} \quad \partial \Omega , \quad \mbox{for} \quad i=1,2, \;\; j\neq
i\,. \end{array} \eqno{(2.11)} 
$$
 In the case of Neumann conditions in (2.11), solutions to
(2.9) will also be solutions to (2.12). If (2.10) holds, then positive
solutions to (2.9) approach $(u^*_1,u^*_2)$ as $t\rightarrow \infty $. If
$(u_1(x,t),u_2(x,t))$ is a positive solution of (2.11) under Neumann
boundary conditions, then by choosing solutions $(\overline{u}
_1(t),\underline{\mit u}
_2(t))$ and $(\underline{u} _1(t),\overline{u} _2(t))$ of (2.9) such
that
$\underline{u}
_i(0)\leq u_i(x,0)\leq \overline{u} _i(0)$ for $i=1,2$ we can see that
$(u_1,u_2)\rightarrow (u^*_1,u^*_2)$ as $t\rightarrow \infty $ since
$\overline{u} _i(t)\geq u_i(x,t)\geq \underline{u} _i(t)$ and
$\overline{u} _i$,
$\underline{u} _i\rightarrow u^*_i$ as $t\rightarrow \infty $. This
is
essentially the method of contracting rectangles (see [37].) However, in
cases where (2.11) has boundary conditions other than Neumann, or where
the coefficients of (2.9) or (2.11) are allowed to depend on $t$, this
approach fails. By using methods based on sub- and super-solutions, Leung
[28,29] and Pao [31] showed that the model (2.11) with Dirichlet boundary
conditions the system (2.11) has a positive equilibrium if
$$ a_i>d_i\lambda _1+a_jb_{ij}/b_{jj}, \;\; i=1,2, \;\; j\neq
i. \eqno{(2.12)} 
$$
 At around the same time, Gopalsamy [17,18] showed that the
system (2.9) with $a_i=a_i(t)$ $\,T$-periodic has a positive stable
$T$-periodic steady-state provided
$$ \min (a_i)>b_{ij}\max (a_j)/b_{jj}, \;\; i=1,2, \; j\neq
i\,. \eqno{(2.13)} $$

In [14], Professor Lazer and I obtained some stability criteria for
equilibria of (2.11) and showed that if $a_1=a_2=a$ in (2.11) then the
condition (2.12) can be replaced by the conditions $a>d_i\lambda _1,
\; i=1,2$, and $b_{jj}>b_{ij}, \; i=1,2, \; j\neq i$. The most important
idea in that paper, however, was an extension of Gopalsamy's result to the
case of (2.11) with Neumann boundary conditions. Specifically, we showed
that for (2.11) with Neumann boundary conditions and $a_i=a_i(t)$ periodic
in time that under condition (2.13) the solution to (2.9) obtained by
Gopalsamy is also stable for (2.11). A key observation was that although
the periodicity of the system made a simple argument based on contracting
rectangles impossible, it was still possible to construct solutions
$(\overline{u} _1,\underline{u} _2), \; (\underline{u} _1,\overline{u}
_2)$
depending only
on $t$ and having the property $\overline{u} _i(t+T)\leq \overline{u}
_i(t), \; \underline{u} _i(t+T)\geq \underline{u} _i(t)$, even though
$\overline{u} _i(t), \; \underline{u} _i(t)$ were not in general monotone
in $t$. Another way to express the idea would be that although the
original system does not admit contracting rectangles, the period
map (i.e. Poincar\'{e} map) of the system does. I thought that we had just
found an interesting variant on results that were already known in the
autonomous case, but Professor Lazer had the deeper insight that the
methods used in [15] were a special case of something much more general
and abstract.

In the work with C. Alvarez [10], Professor Lazer showed that in the case
of (2.9) where all of the coefficients are $T$-periodic, the system has an
attracting periodic steady state which is globally attracting among
positive solutions provided
$$  \min (a_i)>\max (a_j)\max (b_{ij})/\min (b_{ii}) \quad
i=1,2, \;\; j\neq i\,.  \eqno{(2.14)} 
$$
 Again, the key idea was to look at the Poincar\'{e} map. In this
context Alvarez and Lazer used Floquet theory (and various estimates) to
show that {\it any} periodic solution is locally stable. That observation
made it possible to compute the topological degree at any fixed point of
the period map, so that existence and uniqueness results could be obtained
via degree theory.

\subsection*{Continuing the development}

Continuing to develop the ideas introduced in [10,15], Professor Lazer and
S. Ahmad showed in [3] that for the diffusive system (2.11) with Neumann
boundary conditions and with $a_i, b_{ij}$, and $b_{jj}$ periodic in time
(and possibly varying in space) the condition (2.14) implies the existence
of a coexistence state, while if (2.14) holds for (say) $i=1$ and is
reversed for $i=2$ then $u_2\rightarrow 0$ as $t\rightarrow \infty
$. Again, the key idea was to use something analogous to contracting
rectangles, but for the Poincar\'{e} map.

\subsection*{Abstract Competition Systems and their Implications}

A key idea in the papers [10,14,23] was to look at a periodic system from
the viewpoint of the Poincar\'{e} map. Using the order preserving
properties of models for two competing species then permits the
construction, in some cases, of something analogous to contracting
rectangles for the Poincar\'{e} map. In [20], Professor Lazer and Peter
Hess gave an abstract formulation of this idea in the context of a
discrete dynamical system acting on an ordered Banach space with an
ordering of the sort which is typically preserved by models for two
competitors. (An ordered Banach space is simply a Banach space $E$ with an
ordering defined by a positive cone $P$, which is just a subset of $E$
with the properties that if $x,y\in P$ and $c\in {\mathbb R}$, $c>0$ then
$x+y\in P$ and $cx\in P$. In that setting we write $x\geq y$ if $x-y\in
P$. For a detailed discussion see [11].)

We shall first describe the set-up of [20], make a few key definitions,
and then state the main result of [20] and describe its implications. Let
$E_1$ and $E_2$ be ordered Banach spaces whose orderings are defined by
the positive cones $P_1$ and $P_2$ respectively. Assume that the interiors
of $P_1$ and $P_2$ are nonempty. Define an ordering on $E_1\times E_2$ by
$(x_1,x_2)\leq (y_1,y_2) \Leftrightarrow x_1\leq y_1, \; x_2\geq
y_2$. (This is the type of ordering which is typically preserved by models
of two competitors.) Suppose that $F:E_1\times E_2\rightarrow E_1\times
E_2$ is smooth and order preserving. Iterating $F$ then leads to a
semidynamical system which is a suitable abstraction of the Poincar\'{e}
map. Recall that if $E$ is an ordered Banach space and $a,b\in E$ with
$a\leq b$ then the {\it order interval} $[a,b]$ is the set $\{x\in E:a\leq
x\leq b\}$. Also, recall that $x>y$ means $x\geq y, \; x\neq y$ and that
$x>>y$ means $x-y$ is in the interior of the positive cone. Suppose that
$F(x_1,x_2)=(f_1(x_1,x_2),f_2(x_1,x_2))$. Assume that $F$ satisfies the
following hypotheses:

\begin{description}

\item{(A1)} $F$ maps bounded positive order intervals into compact sets,
i.e. $F$ is order compact.

\item{(A2)} $f_1(0,x_2)=0$ and $f_2(x_1,0)=0$ for all $x_1\in E_1,
\; x_2\in E_2$

\item{(A3)} $0<<f_1(x_1,x_2)<<f_1(x^\prime _1, x^\prime _2),
\;\; 0<<f_2(x^\prime _1,x^\prime _2)<<f_2(x_1,x_2)$ if
\linebreak $0<x_1\leq x^\prime
_1, \;\; 0<x^\prime _2\leq x_2, \;\; (x_1,x_2)\neq (x^\prime _1,x^\prime
_2)$.

\item{(A4)} there exist unique fixed points $\hat{x} _1=f_1(\hat{x} _1,0),
\;\; \hat{x} _2=f_2(0,\hat{x} _2)$, such that $\tau \hat{x} _1<<f_1(\tau
\hat{x} _1,0)<<\hat{x} _1$ for $0<\tau <1, \;\; \hat{x} _1<<f_1(\tau
\hat{x} _1,0)<<\tau \hat{x} _1$ for $\tau >1$, and similarly for $\hat{x}
_2, f_2$

\item{(A5)} the derivatives $D_1f_1$ and $D_2f_2$ satisfy 
$$\displaylines{
D_1f_1(0,\hat{x} _2):P_1-\{0\}\rightarrow \mbox{Int} \quad P_1 \cr
D_2f_2(\hat{x} _1,0):P_2-\{0\}\rightarrow \mbox{Int} \quad P_2
}$$
\end{description}

\noindent {\bf Remarks}: Hypotheses (A1) and (A5) are needed for various
technical reasons; hypotheses (A2)-(A4) capture essential features of
competition models. If $x_1,x_2$ are viewed as population densities,
(A2) says that if one of the populations is initially zero it will remain
zero; (A3) says that increasing the density of either population reduces
the growth rate of both, and (A4) says that each species has a stable
positive equilibrium density when the other is absent.

Assumptions (A1) and (A5) together with the Krein-Rutman theorem imply
that the maps $D_1f_1(0,\hat{x} _2)$ and $D_2f_2(\hat{x} _1,0)$ have
positive principal eigenvalues $\lambda _1$ and $\lambda _2$. \smallskip

\noindent {\bf Definition}: (Lazer and Hess [20]). \quad  The mapping
$F$ is
{\it compressive} if it has an order interval in $\mbox{Int} P_1\times
\mbox{Int} P_2$ which is globally attracting in $(P_1-\{0\})\times
(P_2-\{0\})$. \smallskip

\noindent {\bf Remarks}: If $F$ has a globally attracting fixed point
which is positive in both components then $F$ is compressive. More
generally, if $F$ is compressive then eventually the densities of both
competitors will be bounded away from zero so the competitors will
coexist. A related notion is permanence or uniform persistence, but that
notion does not involve any order preserving properties. For a discussion
of these and other notions of persistence see [16].

We can now state the main abstract result of [20]. 

\begin{theorem} [Lazer and Hess {[20]}] % Theorem 2.3 
The mapping $F$ is
compressive if the principal eigenvalues $\lambda _1$ and $\lambda _2$ of
$$ \begin{array}{c} D_1f_1(0,\hat{x} _2)v_1=\lambda _1v_1 \\[2pt]
D_2f_2(\hat{x} _1,0)v_2=\lambda _2v_2 \end{array} \eqno{(2.15)} 
$$
 are both larger than 1, i.e. $\;\lambda _1,\lambda _2>1$. 
 \end{theorem}
 
\noindent {\bf Discussion}: The mapping $F$ could be taken to be the
Poincar\'{e} map of a periodic
competition model with diffusion. The order preserving properties would
then follow from those for parabolic competition systems, whose order
preserving properties follow from arguments based on the maximum
principle. Parabolic regularity results imply the compactness of $F$ on
various function spaces. In the context where $F$ is the Poincar\'{e} map
for periodic-parabolic competition system, the linearized operators
$D_1f_1(0,\hat{x} _2)$ and $D_2f_2(\hat{x} _1,0)$ will be the Poincar\'{e}
maps for two single linear periodic-parabolic operators. If $L$ is a
periodic-parabolic operator of the form (2.6) and $\sigma _1$ is the
principal eigenvalue in (2.7) then the Poincar\'{e} map defined by
$Mu(x)=v(x,T)$ where $v$ satisfies $Lv=0$ in $\Omega \times(0,T),
\;\; \alpha \partial v/\partial \vec{n} +\beta v=0$ on $\partial \Omega
\times (0,T), \;\; v(x,0)=u(x)$ has the principal eigenvalue $\lambda
=e^{-\sigma _1T}$. Thus, $\lambda $ is in a sense analogous to a Floquet
multiplier while $-\sigma _1$ is analogous to a characteristic exponent.

The key hypothesis of Theorem 2.3 is that the principal eigenvalues
$\lambda _1,\lambda _2$ of (2.15) are both larger than 1. The eigenvalue
problem $D_1f_1(0,\hat{x} _2)v_1=\lambda _1v_1$ corresponds to the
linearization of $f_1$ around the equilibrium $(0,\hat{x} _2)$. The
condition $\lambda _1>1$ implies that a population satisfying
$x_1(t+1)=Df_1(0,\hat{x} _2)x_1(t)$ would grow exponentially. The
condition $\lambda _2>1$ has an analogous interpretation. Together, they
essentially mean that the density of either species will increase if that
species is introduced at a low density when the other species is already
established. Thus, Theorem 2.3 is a rigorous version of the notion that
mutual invasibility implies coexistence.

As a concrete application of Theorem 2.3, consider the system
$$ \begin{array}{c} L_iu_i=[a_i(x,t)-b_{ij}(x,t)u_i-b_{ij}(x,t)u_j]u_i
\quad \mbox{in} \quad \Omega \times (0,\infty ) \\[2pt]
\alpha_i(x){\displaystyle \frac{\partial u_i}{\partial \vec{n}}}+\beta
_i(x)u_i=0 \quad {\rm on} \quad \partial \Omega \times (0,\infty ),
\;\; i=1,2,\;\; j\neq i\,. \end{array} \eqno{(2.16)} 
$$
 where $L_i$ is as in (2.6) and the coefficients
$a_i,b_{ii},b_{ij}$ are H\"{o}lder continuous in both variables and
$T$-periodic in $t$. Suppose that the principal eigenvalues of the
problems
$$\displaylines{
(L_i-a_i)\psi =\sigma \psi \quad \mbox{in} \quad \Omega
\times (0,\infty ), \cr
\alpha _i{\displaystyle \frac{\partial \psi
}{\partial \vec{n}}} +\beta _i\psi =0 \quad \mbox{on} \quad \partial \Omega
\times (0,\infty ), \cr
\psi \;\;\;\; T-\mbox{periodic} 
} $$
 for $i=1,2$ are both negative so that the logistic equations
obtained by setting $u_j=0$ in (2.16) both have single species
steady-state solutions by Theorem 2.2. Denote those solutions by $u^*_i,
\; i=1,2$; then $(u^*_1,0)$ and $(0,u^*_2)$ are steady-state solutions for
(2.16). To apply Theorem 2.3 we would use, for example, $\hat{x}
_1=(u^*_1(x,0),0), \hat{x} _2=(0,\hat{u} ^*_2(x,0))$ and take $F$ to be
the Poincar\'{e} map for (2.16). It is reasonably straightforward to
verify that Theorem 2.3 applies in this situation; see the discussion in
[19] or [20]. By theorem 2.3, the system (2.16) is compressive if the
principal eigenvalues of
$$ \begin{array}{l} (L_i-a_i+b_{ij}u^*_j)\psi =\sigma \psi \quad \mbox{in}
\quad \Omega \times (0,\infty ) \\ \\ \alpha _i{\displaystyle
\frac{\partial \psi }{\partial \vec{n} }}+\beta _i\psi =0 \quad \mbox{on}
\quad \partial \Omega \times (0,\infty ) \\ \\ \psi
\;\;\;\; T-\mbox{periodic}
\end{array} \eqno{(2.17)} 
$$
 are both negative for $i=1,2, \;\;j\neq i$. (This result can be
set
in $[C^{2+\alpha }(\overline{\Omega })]^2$ or $[W^{2,p}(\Omega )]^2$,
among other possible function spaces.) The condition that the principal
eigenvalues be negative in (2.17) for $i=1,2$ generalizes most of the
previous conditions for the existence of a steady-state of (2.16) which is
positive in both components. For example, systems with constant
coefficients are periodic with every period $T$, and for such systems the
condition (2.12) implies the negativity of the eigenvalues in (2.17) via
simple estimates of the eigenvalues. However, condition (2.12) is less
sharp than the requirement of negativity of the eigenvalues in
(2.17). Various other previous results, including those of [3], can be
recovered, improved, or unified by applications of Theorem 2.3; see
[19,20] for detailed discussions.

\subsection*{Related Ideas and Applications of Periodic-Parabolic
Eigenvalues}

Theorem 2.3 gives a good criterion for coexistence in competition models,
but there are other problems in population dynamics and other analytic
approaches where the existence of principal eigenvalues for
periodic-parabolic operators plays a crucial role. Many techniques of
nonlinear analysis, such as degree theory and bifurcation theory, depend
on a knowledge of the eigenvalues of linearized operators. Constructions
of sub- and supersolutions often involve eigenfunctions. Some of these
ideas are discussed in [13,19]. For systems such as predator-prey models
which do not have simple order-preserving properties, the notion of
compressivity must often be replaced with that of permanence, i.e. uniform
persistence plus dissipativity. A semidynamical system on an ordered
Banach space is permanent if there is a bounded subset of the interior of
the positive cone which is also uniformly bounded away from the boundary
of the positive cone and which is globally attracting positive
trajectories of the system. (See [21] for a discussion.) A key point in
establishing permanence is to show that steady-states with one or more
species absent are unstable in the sense that if they are perturbed by
adding one of the missing species at low densities then the population
of density of that introduced species will increase. To
apply the idea of permanence to a periodic-parabolic model, the first step
is to convert the time-dependent problem into a semidynamical system by
writing it as a skew-product flow (see [35]) and establish that it is
dissipative; the second step is to analyze the stability of
steady-states; and the final step is to apply an appropriate abstract
result to conclude that the system is indeed permanent. Eigenvalues and
eigenfunctions are used in the stability analysis; see for example
[12]. (A comparison of the ideas of compressivity, permanence, and
practical persistence is given in [16].)

\section{Systems with Many Competitors}

\subsection*{Persistence and Convergence in Nonautonomous Systems: Uniform
Conditions}

If the competition model (2.9) is extended to include $N$ competing
species, the resulting system is
$$  \frac{du_i}{dt}=\Big[ a_i(t)-{\displaystyle \sum
^N_{j=1}}b_{ij}(t)u_j\Big] u_i, \;\;i=1,\ldots ,N. \eqno{(3.1)} 
$$
 (The coefficients are always assumed to be bounded, continous,
and nonnegative.) If the coefficients $a_i$ and $b_{ii}$ are bounded below
by positive constants then the natural extension of condition (2.14) to
the $N$-species case is
$$ \inf a_i > {\displaystyle \sum ^N_{\stackrel{j=1}{j\neq i}}} (\sup
b_{ij})(\sup
a_j)/\inf (b_{jj}), \;\; i=1\ldots N. \eqno{(3.2)} 
$$
 A somewhat weaker condition is
$$ \inf a_i\geq {\displaystyle \sum ^N_{\stackrel{j=1}{j\neq i}}} (\sup
b_{ij})\sup (a_j/b_{jj}), \;\; i=1,\ldots N. \eqno{(3.3)} 
$$
 In [5], Professor Lazer and S. Ahmad proved 

\begin{theorem} % Theorem 3.1
 If the coefficients $a_i, b_{ii}$ are bounded
below by positive constants and (3.3) holds, then (3.1) has a unique
solution $\vec{u} _*(t)$ such that
$$ 0<{\displaystyle \inf _{t\in {\mathbb R} }}u_{*i}(t)\leq {\displaystyle \sup
_{t\in {\mathbb R}}}u_{*i} (t)<\infty , \eqno{(3.4)} 
$$
 and if $\vec{u}$ is any solution to (3.1) with $u_i(t_0)>0,
\; i=1,\ldots ,N$, for some $t_0$, then
$$ |\vec{u} _*(t)-\vec{u} (t)|\rightarrow 0 \quad \mbox{as} \quad
t\rightarrow \infty . \eqno{(3.5)} 
$$ 
\end{theorem}

\noindent {\bf Remarks}: The corresponding result for the periodic case
under condition (3.2) was treated by Alvarez and Tineo [38]; the
almost-periodic case with $N=2$ by Ahmad [1]. This line of research was
initiated by Gopalsamy [17,18], but his results required additional
conditions. Theorem 3.1 is significant in part because it allows general
time dependence. Many abstract results on persistence are set in the
context of autonomous systems whose forward orbits are
precompact;  (see
[21]). Even if a time dependent system is rewritten as an autonomous
system by casting it as a skew product flow (see [35]), the forward orbits
will not be precompact unless the time dependence is almost periodic. Thus
Theorem 3.1 applies to systems where the abstract results discussed in
[21] fail.

Condition (3.2) is an inequality between uniform bounds on coefficients of
(3.1). Condition (3.3) is weaker than (3.2) because in (3.3) the quotient
of uniform bounds, $\sup a_j/\inf b_{jj}$, is replaced by the uniform
bound on the quotient $\sup (a_j/b_{jj})$. It is natural to ask whether
the condition can be weakened further, perhaps to a condition imposing
only a single uniform bound on some combination of coefficients of (3.1),
or perhaps to some type of pointwise or average condition. It turns
out that some such extensions are possible, but the issue is quite
delicate. Suppose that in (3.1) we have $a_i,b_{ii}>0$ and ${\displaystyle
\sup _{{\mathbb R}}} (a_i/b_{ii})<\infty $ for $i=1,\ldots ,N$ but do not
assume that $\inf a_i>0$ or that $\inf b_{ii}>0$. Suppose further that
$$  \inf _{{\mathbb R} }\Bigg( {\displaystyle
\frac{a_i-{\sum ^N_{\stackrel{j=1}{j\neq i}}}b_{ij}\sup
(a_j/b_{jj})}{b_{ii}}}\Bigg) >0 \eqno{(3.6)} 
$$
 and
$$ \int ^\infty _0 b_{ii}(t)dt =\infty \eqno{(3.7)} 
$$
 for $i=1,\ldots ,N$. \smallskip

\begin{theorem} [Lazer and Ahmad {[5]}] %Theorem 3.2 
 If (3.6) and (3.7) hold then any solution $\vec{u} (t) $ with $u_i(t_0)>0$ 
 for $i=1,\ldots ,N$ satisfies
$$ 0<{\displaystyle \inf _{t>t_0}}u_i(t)<{\displaystyle \sup
_{t>t_0}} \;u_i(t)<\infty . \eqno{(3.8)} 
$$
 Furthermore, (3.1) has a solution $\vec{u} _*(t)$ satisfying
(3.4). \end{theorem} 

\noindent {\bf Remarks}: The solution $\vec{u} _*(t)$ may not be unique
and thus the convergence property (3.5) may fail. A counterexample for the
case $N=6$ has been given by Redheffer [33,34]. Whether (3.6) and
(3.7) imply uniqueness of $\vec{u} _*(t)$ and the convergence in (3.5) for
$N\leq 5$ appears to be an open question. Other results related to those
of [5] are also discussed in [33,34].

If solutions to (3.1) need not converge to a unique steady state $\vec{u}
_*(t)$, what can be said about their asymptotic behavior? In general,
competition systems can have arbitrarily complicated dynamics; see
[36]. The conclusion (3.8) implies a version of strong persistence, so
that species which are present initially will not become extinct, but that
does not imply convergence. The answer is given in the following result:


 \begin{theorem}[Lazer and Ahmad {[8]}] % Theorem 3.3
Suppose that $a_i,b_{ii}>0$ and \linebreak $\sup (a_i/b_{ii} )<\infty $
for
$i=1,\ldots ,N$, and that (3.6) and (3.7) are satisfied. For $A\subseteq
([0,\infty ))^N\subseteq {\mathbb R} ^N$ define $U(t,t_0,A)=\{ \vec{u}
(t):\vec{u} (t_0)\in A$, $\vec{u} \quad \mbox{satisfies} \quad
\mbox(3.1)\}
$. If $A\subseteq ((0,\infty ))^N$ is a bounded measurable set then $\mu
(U(t,t_0,A))\rightarrow 0$ as $t\rightarrow \infty $, where $\mu $ denotes
$N$-dimensional Lebesgue measure. 
\end{theorem}

\noindent {\bf Remarks}: Theorem 3.3 implies that although conditions
(3.6) and (3.7) do not necessarily imply that solutions to (3.1) converge
to a unique globally bounded solution, trajectories must converge in some
generalized sense, because the system (3.1) takes sets of arbitrarily
large
finite measure and ``squeezes'' the measure toward zero as $t\rightarrow
\infty $.

\subsection*{Persistence and Extinction in Nonautonomous Systems: Average
Conditions}

The conditions (3.6) and (3.7) are weaker than (3.2), essentially because
they do not require uniform lower bounds on the coefficients $a_i$ and
$b_{ii}$ in (3.1). However, (3.6) imposes a uniform lower bound on a
combination of coefficients of (3.1). A different sort of generalization
would replace uniform conditions with some type of average
conditions. Suppose that $g(t)$ is a bounded continuous function on
${\mathbb R}$. The average of $g(t)$ on the interval $t_1,t_2$ is
$$ A[g,t_1,t_2]={\displaystyle \frac{1}{t_2-t_1}}\int ^{t_2}_{t_1}
g(s) ds. 
$$
 The upper and lower averages of $g$ on ${\mathbb R}$ are defined
(respectively) as
$$ M[g]={\displaystyle \limsup _{s\rightarrow \infty }}
\{A[g,t_1,t_2]:t_2-t_1>s\} 
$$
 and
$$ m[g]={\displaystyle \liminf _{s\rightarrow \infty }}
\{A[g,t_1,t_2]:t_2-t_1>s\}. \eqno{(3.10)} 
$$
 (If $g(t)$ is periodic or even almost periodic then $m[g]=M[g]$
and $g$ has an average on ${\mathbb R}$.) Suppose that the coefficients $a_i$
and $b_{ii}$ in (3.1) are uniformly bounded below by positive
constants. The condition analogous to (3.2) is then
$$ m[a_i]\geq {\displaystyle \sum ^N_{\stackrel{j=1}{j\neq i}}}\left(
{\displaystyle \sup _{{\mathbb R}}} \;b_{ij}\right) M[a_j]/\left(
{\displaystyle
\inf _{{\mathbb R}}}\;b_{jj}\right) , \quad i=1,\ldots ,N. \eqno{(3.11)} 
$$
 {\bf Theorem 3.4}: (Lazer and Ahmad [9]): \quad  If
(3.11) holds then
for any solution of (3.1) with $u_i(t_0)>0$ for $i=1,\ldots ,N$,
(3.8) holds. If $\vec{u} $ and $\vec{v} $ are two componentwise positive
solutions of (3.1), ${\displaystyle \lim _{t\rightarrow \infty }}|\vec{u}
(t)-\vec{v} (t)|=0$. \smallskip

\noindent {\bf Remarks:} Recall that (3.8) is a version of strong
persistence. In this case the convergence result is stronger than in
Theorem 3.3. The upper and lower averages satisfy ${\displaystyle \inf
_{{\mathbb R}}}(g)\leq m[g]\leq M[g]\leq {\displaystyle \sup _{{\mathbb R}}} (g)$,
so (3.2) implies (3.11). Theorem 3.4 is important because it gives a
criterion for persistence even if populations experience occasional
significant declines in their growth rates. Many populations are subject
to serious but temporary declines in population growth rates because of
sporadic events such as epidemics, periods of unfavorable weather, etc.,
so persistence results which can accomodate such phenomena are highly
desirable for the study of natural systems.

It is of interest to know when populations can be expected to persist, but
it is also important to be able to decide when a species faces
extinction. In the case of two competitors and constant coefficients in
(3.1), the second competitor will be forced to extinction by the first
competitor (i.e. competitive exclusion will occur) if
$a_1>b_{12}a_2/b_{22}$ and $a_2<b_{21}a_1/b_{11}$. This result was
extended to the nonautonomous case under the condition $\inf a_1>(\sup
b_{12})(\sup a_2)/\inf (b_{22})$, $\; \sup a_2<(\inf b_{21})(\inf
a_1)/\sup (b_{11})$ by S. Ahmad [2]. In collaboration with
Ahmad, Professor
Lazer extended these results to criteria for the extinction of the $N$th
species (and the persistence of all other species) in models for $N$
species. They treated the autonomous case in [6] and the specific
nonautonomous case where the growth rates $a_i$ depend on $t$ but the
other coefficients of (3.1) do not in [7]. Since the results of [7] imply
those of [6],only they will be presented here. The first condition which
is required is that the upper and lower averages (as defined in (3.9) and
(3.10)) are equal for each of the coefficients $a_i$, so that each
coefficient $a_i$ has an average which is equal to $M[a_i]$. The second
condition is that the first $N-1$ inequalities in (3.2) are satisfied,
i.e. (3.2) holds for $i=1,\ldots ,N-1$. That condition implies the system
of $N-1$ linear equations
$$ M[a_i]={\displaystyle \sum ^{N-1}_{j=1}} b_{ij}x_j, \; i=1,\ldots ,N-1
\eqno{(3.12)} 
$$
 has a unique componentwise positive solution $x_i=\xi _i,
\; i=1\ldots N-1$. (See [7].) \smallskip


\begin{theorem}[Lazer and Ahmad {[7]}] % Theorem 3.5
Suppose that the
coefficients $a_i$ all have averages $M[a_i]$ and that the first $N-1$
inequalities of (3.2) are satisfied. Let $(\xi _1,\ldots ,\xi _{N-1})$ be
the unique componentwise positive solution to (3.12).
\begin{description}

\item{i)} If
$$ M[a_N]<{\displaystyle \sum ^{N-1}_{j=1}}b_{Nj}\xi _j \eqno{(3.13)} 
$$
 then for any solution of (3.1) with componentwise positive
initial data, $u_N(t)\rightarrow 0$ as $t\rightarrow \infty $.

\item{ii)} If
$$ M[a_N]>{\displaystyle \sum ^{N-1}_{j=1}}b_{Nj}\xi _j \eqno{(3.14)} 
$$
 and $\vec{u}$ is a solution to (3.1) which is componentwise
positive at $t=t_0$, then ${\displaystyle \inf _{t>t_0}}u_i(t)>0$ for
$i=1,\ldots ,N$.

\item{iii)} If
$$ M[a_N]={\displaystyle \sum ^{N-1}_{j=1}} b_{N_j}\xi _j 
$$
 then for any componentwise positive solution to (3.1),
${\displaystyle \liminf _{t\rightarrow \infty }}\;u_N(t)=0$.
\end{description}

\end{theorem}

\noindent {\bf Remarks:} Theorem 3.5 implies that if the first $N-1$
inequalities of (3.2) hold then (3.15) is necessary and sufficient for the
conclusion that for solutions that are componentwise positive at $t=t_0,
\;\; {\displaystyle \inf _{t>t_0}} u_i(t)>0$ for $i=1,\ldots ,N$. It is
also shown in [7] that if the only coefficients of (3.1) which vary in
time
are \linebreak $a_i,i=1,\ldots ,N$, and the first $N-1$ inequalities in
(3.2) are
satisfied, and (3.13) holds, the (3.1) has a unique solution $\vec{u}
_*(t)=(u_{1*}(t),\ldots ,u_{N-1*}(t),0)$ satisfying $0<{\displaystyle \inf
_{{\mathbb R}}}\;u_{i*}(t)\leq {\displaystyle \sup _{{\mathbb R}}}\;u_{i*}(t)<\infty
$,
and $\vec{u} _*(t)$ is globally asymptotically stable in the sense that
${\displaystyle \lim _{t\rightarrow \infty }}|\vec{u} _*(t)-\vec{u}
(t)|=0$ for any componentwise positive solution $\vec{u} (t)$. Some
related results on extinction have been obtained by Montes de Oca and
Zeeman [30], and conclusions about extinction in diffusive Lotka-Volterra
models can be obtained via the methods of [13]. However, there has been
much less research on conditions for extinction than on conditions for
persistence, so the work contained in and inspired by [6,7] constitutes
one important contribution to the literature.

\subsection*{Traveling Wavefronts in Diffusion Models}

One of the more interesting and important properties of reaction-diffusion
equations and systems is that they may support traveling wave
solutions; see for example [37]. A traveling wave solution is simply a
solution $\vec{u} (x,t)=\vec{u} (x+ct)$ which propagates a fixed profile
at a fixed speed. To find traveling wave solutions one typically
substitues $\vec{u} =\vec{\theta } (x+ct)$ into the reaction-difussion
system and obtains a system of ordinary differential equations for
$\vec{\theta } $ with $c$ appearing as a parameter. If that system of
ordinary differential equations has the right sort of solutions, those
solutions yield traveling waves when $x+ct$ is used as the independent
variable. For a single reaction-diffusion equation, the system of ordinary
differential equations which determined the traveling waves consists of
only two equations, so solutions leading to traveling waves can often be
constructed by keeping track of how the phase plane for the system changes
as the wavespeed parameter $c$ is varied. For reaction-diffusion systems
with two or more equations matters typically become much more
delicate. Construction of traveling waves for systems may require a
careful analysis of a higher dimensional phase space or may require the
use of sophisticated methods such as the Conley index. It is remarkable
that Professor Lazer and S. Ahmad [4] were able to give an elementary
construction for travelling wavefronts in a class of systems which include
some diffusive Lotka-Volterra models with many competitors. The specific
systems that were treated in [4] are of the form
$$ {\displaystyle \frac{\partial u_i}{\partial t}}=d_i{\displaystyle
\frac{\partial ^2u_i}{\partial x^2}}+u_if_i(\vec{u} ), \;\; i=1,\ldots
,N. \eqno{(3.15)} 
$$
 {\bf Theorem 3.6} (Lazer and Ahmad [4]) \quad 
Suppose that the functions $f_i$ in (3.15) are locally Lipschitz. Suppose
that the system (3.15) admits a spatially constant equilibrium $\vec{a}
=(a_1,\ldots ,a_N)$ (so that $f_i(\vec{a} )=0, \;\; i=1\ldots N$) such
that
$$ f_i(\vec{0} )\geq f_i(\vec{u} )>0 \quad \mbox{if} \quad 0\leq u_i\leq
a_i \quad \mbox{for} \quad i=1\ldots N, \; \vec{u} \not\equiv
\vec{a}. \eqno{(3.16)} 
$$
 Let $r_i=f_i(0)$. If
$$ c^2>4r_id_i \eqno{(3.17)} 
$$
 then (3.15) has a wavefront solution $\vec{u} =\vec{\theta
}(x+ct)$ of speed $c$ with $\vec{\theta }(s)\rightarrow \vec{0} $ as
$s\rightarrow \infty $, $\; \vec{\theta }(s)\rightarrow \vec{a} $ as
$s\rightarrow -\infty $. 

\noindent {\bf Sketch of Proof}:
A traveling wave solution satisfies the system
$$ d_i\theta ^{\prime \prime }_i=-c\theta ^\prime _i-\theta
_if_i(\vec{\theta }), \;\; i=1\ldots N. \eqno{(3.18)} 
$$
 The hypothesis (3.17) implies that there exist numbers $\mu _i$
so that $\mu ^2_i-(c/d_i)\mu _i+(r_i/d_i)<0$. The proof proceeds as
follows:

\begin{description}

\item{1)} Show that the set $0<\theta _i<a_i, \; -\mu _i\theta _i<\theta
^\prime _i<0$ is positively invariant in the phase space of (3.18) via
differential inequalities.

\item{2)} Show that the bounds in 1) imply that $\theta _i(s),\theta
^\prime _i(s)\rightarrow 0$ as $s\rightarrow \infty $ (multiply (3.18) by
$\theta ^\prime _i$ and integrate).

\item{3)} Choose a sequence $\vec{\theta }^*_m=(\theta ^*_{im},\ldots
,\theta ^*_{Nm})$ of functions satisfying (3.18) such that $\theta
^*_{im}(0)=a_i, \; \theta ^{*\prime }_{im} (0)=-\epsilon _m$, where
$\epsilon _m \rightarrow 0$ as $m\rightarrow \infty $. Choose $\tau _m$
such that $\theta ^*_{im}(\tau _m)\geq a_i/2$ for each $i$ and $\theta
^*_{jm}(\tau _m)=a_j/2$ for some $j$. Show that $\tau _m\rightarrow \infty
$ as $m\rightarrow \infty $ by using the continuous dependence of
solutions on initial data.

\item{4)} Let $\theta _{im}(s)=\theta ^*_{im}(s+\tau _m)$ and show that
$\vec{\theta }_m(s)\rightarrow \vec{\theta }(s)$ for a subsequence of
$\{\theta _m\}$ by arguments based on continuous dependence on initial
data and compactness.

\end{description}

\noindent {\bf Remarks}: All of the steps in the analysis are elementary.

\section{Conclusions}
The results and ideas described in the earlier sections of this article
show the scope and depth of Professor Lazer's contributions to
mathematical propulation dynamics. His work has introduced fundamental new
results, methods, and ideas into the study of time dependent population
models, among other areas. For applied purposes it is important to be able
to treat time dependent population models, because natural populations are
very often influenced by factors which vary in time. Those factors include
daily and seasonal variations, in things such as temperature and light
which are at least approximately periodic, but they also include factors
such as rainfall which are less regular and predictable. Thus, both
periodic and nonperiodic variations are important to consider. Another
important feature of much of Professor Lazer's work is that he has often
been able to obtain deep results via relatively elementary methods. This
feature makes his work accessible to a wide range of scientists. Finally,
Professor Lazer has inspired many collaborators, students, colleagues, and
other mathematical acquaintances. A few of those have been mentioned here
by name, but many others have not. Through his own work and his influence
on others, Professor Lazer's contributions to mathematical population
dynamics have permanently changed that subject.


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}\end{thebibliography}

\noindent{\sc Chris Cosner} \\
Department of Mathematics \\
University of Miami \\
Coral Gables, FL  33124 \\
e-mail: gcc@cs.miami.edu

\end{document}