This commit is contained in:
@@ -14,3 +14,4 @@
|
||||
\input{./spaces-of-linear.tex}
|
||||
\input{./tensor.tex}
|
||||
\input{./nuclear.tex}
|
||||
\input{./nuclear-space.tex}
|
||||
|
||||
85
src/fa/lc/nuclear-space.tex
Normal file
85
src/fa/lc/nuclear-space.tex
Normal file
@@ -0,0 +1,85 @@
|
||||
\section{Nuclear Spaces}
|
||||
\label{section:nuclear-space}
|
||||
|
||||
\begin{definition}[Nuclear Space]
|
||||
\label{definition:nuclear-space}
|
||||
Let $E$ be a separated locally convex space over $K \in \RC$, then the following are equivalent:
|
||||
\begin{enumerate}
|
||||
\item There exists a fundamental system of convex and circled neighbourhoods $\fB \subset \cn_E(0)$ such that for each $U \in \fB$, the canonical projection $\pi_U: E \to \wh E_U$ is nuclear.
|
||||
\item For each Banach space $F$ and $T \in L(E; F)$, $T$ is nuclear.
|
||||
\item For each convex and circled neighbourhood $U \in \cn_E(0)$, there exists $V \in \cn_E(0)$ with $V \subset U$ such that the induced map $\wh E_V \to \wh E_U$ is nuclear.
|
||||
\end{enumerate}
|
||||
|
||||
If the above holds, then $E$ is a \textbf{nuclear space}.
|
||||
\end{definition}
|
||||
\begin{proof}
|
||||
(1) $\Rightarrow$ (2): Let $U = T^{-1}(B_F(0, 1))$, then there exists $V \in \fB$ with $V \subset U$. In which case, there exists $\wh T \in L(\wh E_V; F)$ such that the following diagram commutes:
|
||||
\[
|
||||
\xymatrix{
|
||||
E \ar@{->}[r]^{T} \ar@{->}[d]_{\pi_V} & F \\
|
||||
\wh E_V \ar@{->}[ru]_{\wh T} &
|
||||
}
|
||||
\]
|
||||
|
||||
Since $\pi_V \in N(E; \wh E_V)$, $T = \wh T \circ \pi_V$ is nuclear by \autoref{proposition:nuclear-gymnastics}.
|
||||
|
||||
(2) $\Rightarrow$ (3): Let $U \in \cn_E(0)$, then the canonical map $\pi_U: E \to \wh E_U$ is nuclear. Thus there exists an equicontinuous sequence $\seq{\phi_n} \subset E^*$, $\seq{y_n} \subset B_{\wh E_U}(0, 1)$, and $\seq{\lambda_n} \subset K$ such that
|
||||
\begin{enumerate}[label=(\alph*)]
|
||||
\item For each $x \in E$, $\pi_U x = \sum_{n = 1}^\infty \lambda_n y_n \dpn{x, \phi_n}{E}$.
|
||||
\item $\sum_{n \in \natp}|\lambda_n| < \infty$.
|
||||
\end{enumerate}
|
||||
|
||||
Let $V = U \cap \bigcap_{n \in \natp}\phi_n^{-1}(B_K(0, 1))$, then by equicontinuity of $\seq{\phi_n}$, $V \in \cn_E(0)$. Moreover, for each $n \in \natp$, there exists $\wh \phi_n \in \wh E_V^*$ such that the following diagram commutes:
|
||||
\[
|
||||
\xymatrix{
|
||||
E \ar@{->}[r]^{\phi_n} \ar@{->}[d]_{\pi_V} & K \\
|
||||
\wh E_{V} \ar@{->}[ru]_{\widehat \phi_n} &
|
||||
}
|
||||
\]
|
||||
|
||||
As $V \subset \phi_n^{-1}(B_K(0, 1))$, $\normn{\widehat \phi_n}_{\wh E_V^*} \le 1$. Thus the induced map $\widehat \pi_U: \wh E_{V} \to \wh E_U$ takes the form
|
||||
\[
|
||||
\wh \pi_U x = \sum_{n = 1}^\infty \lambda_n y_n \dpn{x, \wh \phi_n}{\wh E_{V}}
|
||||
\]
|
||||
|
||||
with
|
||||
\[
|
||||
\normn{\wh \pi_U}_{N(\wh E_{V}; \wh E_U)} \le \sum_{n \in \natp}|\lambda_n| \cdot \underbrace{\norm{y_n}_{\wh E_U}}_{\le 1} \cdot \underbrace{\normn{\wh \phi_n}_{\wh E_V^*}}_{\le 1} \le \sum_{n \in \natp}|\lambda_n| < \infty
|
||||
\]
|
||||
|
||||
Therefore $\wh \pi_U$ is nuclear.
|
||||
|
||||
(3) $\Rightarrow$ (1): Let $U \in \cn_E(0)$ be convex and circled, then there exists a convex circled neighbourhood $V \in \cn_E(0)$ such that the induced map $\wh \pi_U: \wh E_V \to \wh E_U$ is nuclear. In which case, the canonical map $\pi_U: E \to \wh E_U$ is the composition of $\pi_V$ and $\wh \pi_U$. Thus $\pi_U: E \to \wh E_U$ is nuclear by \autoref{proposition:nuclear-gymnastics}.
|
||||
\end{proof}
|
||||
|
||||
\begin{theorem}
|
||||
\label{theorem:nuclear-lp}
|
||||
Let $E$ be a nuclear space over $K \in \RC$, $U \in \cn_E(0)$, and $p \in [1, \infty]$, then there exists $V \in \cn_E(0)$ with $V \subset U$ such that $\wh E_V$ is isomorphic to a subspace of $l^p(\natp; K)$ with equal norms.
|
||||
\end{theorem}
|
||||
\begin{proof}[Proof, {{\cite[III.7.3]{SchaeferWolff}}}. ]
|
||||
Assume without loss of generality that $U$ is convex and circled, and the canonical projection $\pi_U: E \to \wh E_U$ is nuclear. In which case, there exists an equicontinuous sequence $\seq{\phi_n} \subset E^*$, $\seq{y_n} \subset B_{\wh E_U}(0, 1)$, and $\seq{\lambda_n} \subset K$ such that
|
||||
\begin{enumerate}[label=(\alph*)]
|
||||
\item For each $x \in E$, $\pi_U x = \sum_{n = 1}^\infty \lambda_n y_n \dpn{x, \phi_n}{E}$.
|
||||
\item $\sum_{n \in \natp}|\lambda_n| < \infty$.
|
||||
\end{enumerate}
|
||||
|
||||
By rescaling, further assume without loss of generality that $\sum_{n \in \natp}|\lambda_n| = 1$ and $\lambda_n > 0$ for all $n \in \natp$. Under the convention that $1/\infty = 0$, define
|
||||
\[
|
||||
T: E \to l^p(\natp; K) \quad (Tx)_n = \lambda_n^{1/p}\dpn{x, \phi_n}{E}
|
||||
\]
|
||||
|
||||
then for each $x \in E$, $\norm{Tx}_{l^p(\natp; K)} \le \norm{\pi_U x}_{\wh E_U}$, so $T$ is continuous.
|
||||
|
||||
|
||||
On the other hand,
|
||||
\[
|
||||
\normn{\pi_U x}_{\wh E_U} = \norm{\sum_{n = 1}^\infty \lambda_n y_n \dpn{x, \phi_n}{E}}_{\wh E_U} \le \sum_{n = 1}^\infty \lambda_n |\dpn{x, \phi_n}{E}|
|
||||
\]
|
||||
|
||||
Let $q \in [1, \infty]$ be the Hölder conjugate of $p$. By \hyperref[Hölder's inequality]{theorem:holder} applied to $\bracsn{\lambda_n^{1/p}\dpn{x, \phi_n}{E}}_1^\infty$ and $\bracsn{\lambda_n^{1/q}}_1^\infty$, $\normn{\pi_U x}_{\wh E_U} \le \norm{Tx}_{l^p(\natp; K)}$.
|
||||
|
||||
Finally, let $V = T^{-1}(B_{l^p(\natp; K)})$, then $V \subset U$, and $\wh E_V$ is isomorphic to $\ol{T(E)}$, with equal norms.
|
||||
\end{proof}
|
||||
|
||||
|
||||
|
||||
Reference in New Issue
Block a user