Housekeeping.
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src/fa/interpolation/complex.tex
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src/fa/interpolation/complex.tex
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\section{The Complex Interpolation Method}
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\label{section:complex-interpolation}
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\begin{definition}[Compatible Couple]
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\label{definition:compactible-couple}
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Let $E_0, E_1, \mathcal{U}$ be topological vector spaces over $K \in \RC$ and $\iota_0 \in L(E_0; \mathcal{U})$ and $\iota_1 \in L(E_1; \mathcal{U})$ be continuous injections. Under the identification that $E_0$ and $E_1$ are subspaces of $\mathcal{U}$, the pair $(E_0, E_1)$ forms a \textbf{compatible couple} of topological vector spaces.
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Let $E_0, E_1$ be topological vector spaces over $K \in \RC$, $\mathcal{U}$ be a separated topological vector space over $K$, and $\iota_0 \in L(E_0; \mathcal{U})$ and $\iota_1 \in L(E_1; \mathcal{U})$ be continuous injections. Under the identification that $E_0$ and $E_1$ are subspaces of $\mathcal{U}$, the pair $(E_0, E_1)$ forms a \textbf{compatible couple} of topological vector spaces.
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\end{definition}
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\begin{remark}
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@@ -59,14 +59,14 @@
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\normn{x - \sum_{n = 1}^Nx_n}_{E_0 + E_1} \le \sum_{n > N}\norm{y_n}_{E_0} + \sum_{n > N}\norm{z_n}_{E_1} \le 2\sum_{n > N}\norm{x_n}_{E_0 + E_1} \to 0
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\]
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as $N \to \infty$. Therefore $E_0 + E_1$ is also a Banach space.
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as $N \to \infty$. By \autoref{lemma:banach-criterion}, $E_0 + E_1$ is also a Banach space.
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\end{proof}
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\begin{definition}[Category of Compatible Couples]
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\label{definition:compatible-category}
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Let $\catc$ be a subcategory of normed spaces over $K \in \RC$ and $(E_0, E_1)$ be a compatible couple, then $E_0 E_1$ are a \textbf{compatible couple in $\catc$} if $E_0, E_1, E_0 \cap E_1, E_0 + E_1 \in \catc$.
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Let $(E_0, E_1)$ and $(F_0, F_1)$ be compatible couples in $\catc$ and $T \in L(E_0 + E_1, F_0 + F_1)$, then $T$ is a \textbf{morphism of compatible couples} if $T|_{E_0} \in \text{Mor}_{\catc}(E_0; F_0)$ and $T|_{E_1} \in \text{Mor}(E_1; F_1)$.
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Let $(E_0, E_1)$ and $(F_0, F_1)$ be compatible couples in $\catc$ and $T \in L(E_0 + E_1, F_0 + F_1)$, then $T$ is a \textbf{morphism of compatible couples} if $T|_{E_0} \in \text{Mor}_{\catc}(E_0; F_0)$ and $T|_{E_1} \in \text{Mor}_{\catc}(E_1; F_1)$.
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The collection $\catc_1$ of all compatible couples in $\catc$ equipped with the above definition of morphisms is the \textbf{category of compatible couples} in $\catc$.
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\end{definition}
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@@ -111,12 +111,6 @@
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\end{definition}
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\textit{"This is how things appeared in 1965. Fifteen years later, it was found that the number
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of interpolation methods at our disposal is not large."} — \cite[Page vi, Footnote 3]{brudnyi1991interpolation}.
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\item[(SN2)] For any $x \in E$ and $\lambda \in K$, $\norm{\lambda x}_E = \abs{\lambda} \norm{x}_E$.
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\item[(SN3)] For any $x, y \in E$, $\norm{x + y}_E \le \norm{x}_E + \norm{y}_E$.
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\end{enumerate}
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In which case, the pair $(E, \norm{\cdot}_E)$ is a \textbf{normed vector space} over $K$.
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\end{definition}
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\begin{definition}[Banach Space]
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\label{definition:banach-space}
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Let $E$ be a normed vector space over $K \in \RC$, then $E$ is a \textbf{Banach space} if it is complete.
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\end{definition}
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\begin{lemma}
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\label{lemma:banach-criterion}
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Let $E$ be a normed vector space, then the following are equivalent:
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\begin{enumerate}
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\item $E$ is a Banach space.
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\item For each $\seq{x_n} \subset E$ with $\sum_{n \in \natp}\norm{x_n}_E < \infty$, there exists $x \in E$ such that $x = \sum_{n = 1}^\infty x_n$.
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\end{enumerate}
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\end{lemma}
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\begin{proof}
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(2) $\Rightarrow$ (1): Let $\seq{x_n} \subset E$ be a Cauchy sequence, then there exists a subsequence $\seq{n_k}$ such that $\norm{x_{n_{k+1}} - x_{n_{k}}}_E < 2^{-k}$ for all $k \in \natp$. For each $k \in \natp$, let $y_k = x_{n_{k+1}} - x_{n_{k}}$, then there exists $y \in E$ such that $y = \sum_{k = 1}^\infty y_k$. Let $\eps > 0$, then there exists $K \in \natp$ such that:
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\begin{enumerate}[label=(\alph*)]
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\item $\norm{y - \sum_{k = 1}^{K-1} y_k}_E < \eps$.
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\item For each $n \ge n_K$, $\norm{x_n - x_{n_K}}_E < \eps$.
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\end{enumerate}
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In which case, for every $n \ge n_K$,
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\begin{align*}
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\norm{x_n - (y + x_{n_1})}_E &< \norm{x_{n_K} - (y + x_{n_1})}_E + \eps \\
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&= \norm{y - \sum_{k = 1}^{K-1} (x_{n_{k+1}} - x_{n_{k}})}_E + \eps \\
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&= \norm{y - \sum_{k = 1}^{K-1} y_k}_E + \epsilon < 2\eps
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\end{align*}
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Therefore $x_n \to y + x_{n_1}$ as $n \to \infty$.
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\end{proof}
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\begin{proposition}
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\label{proposition:norm-criterion}
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Let $E$ be a separated TVS over $K \in \RC$, then the following are equivalent:
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