\section{Inductive Limits} \label{section:tvs-inductive} \begin{definition}[Inductive Topology] \label{definition:tvs-inductive} Let $\seqi{E}$ be TVSs over $K \in \RC$, $\seqi{T}$ such that $T_i \in \hom(E_i; E)$ for all $i \in I$, and $E$ be a vector space over $K$, then there exists a topology $\topo$ on $E$ such that: \begin{enumerate} \item $(E, \topo)$ is a TVS over $K$. \item For each $i \in I$, $T_i \in L(E_i; E)$. \item[(U)] For any topology $\mathcal{S}$ on $E$ satisfying (1) and (2), $\mathcal{S} \subset T$. \item For any TVS $F$ and $T \in \hom(E; F)$, $T \in L(E; F)$ if and only if $T \circ T_i \in L(E_i; F)$ for all $i \in I$. \end\{enumerate\} The topology $\topo$ is the \textbf{inductive topology} on $E$ induced by $\seqi{T}$. \end{definition} \begin{proof} (1): Let \[ \mathcal{B} = \bracs{U \subset E|U \text{ radial, circled}, T_i^{-1}(U) \in \cn_{E_i}(0) \forall i \in I} \] To see that $\mathcal{B}$ is a fundamental system of neighbourhoods at $0$ for a vector space topology on $E$, it is sufficient to verify the following and apply \autoref{proposition:tvs-0-neighbourhood-base}. \begin{enumerate} \item[(TVB1)] Every set in $\mathcal{B}$ is radial and circled by definition. \item[(TVB2)] For any $U \in \mathcal{B}$, $U$ is circled, so $\frac{1}{2}U + \frac{1}{2}U \subset U$. Since $\frac{1}{2}U$ is also circled and radial, $\frac{1}{2}U \in \mathcal{B}$. \end{enumerate} Let $\topo$ be the vector space topology such that $\mathcal{B}$ is a fundamental system of neighbourhoods at $0$, then $(E, \topo)$ is a TVS. (2): For each $i \in I$ and $U \in \mathcal{B}$, $T_i^{-1}(U) \in \cn_{E_i}(0)$, so $T_i \in L(E_i; E)$. (U): Let $U \in \cn_{(E, \mathcal{S})}(0)$ be circled and radial, then by (2), $T_i^{-1}(U) \in \cn_{E_i}(0)$ for all $i \in I$. Thus the circled and radial neighbourhoods of $0$ in $(E, \mathcal{S})$ is a subset of $\mathcal{B}$. (4): Let $U \in \cn_F(0)$ be circled and radial and $i \in I$. Since $T \circ E_i \in L(E_i; F)$, $T_i^{-1}(T^{-1}(U)) \in \cn_{E_i}(0)$, so $T^{-1}(U) \in \mathcal{B} \subset \cn_E(0)$. \end{proof} \begin{definition}[Inductive Limit] \label{definition:tvs-inductive-limit} Let $(\seqi{E}, \bracsn{T^i_j| i, j \in I, i \lesssim j})$ be an upward-directed system of TVSs over $K \in \RC$, then there exists $(E, \bracsn{T^i_E}_{i \in I})$ such that: \begin{enumerate} \item $E$ is a TVS over $K$. \item For each $i \in I$, $T^i_E \in L({E_i, E})$. \item For any $i, j \in I$ with $i \lesssim j$, the following diagram commutes: \[ \xymatrix{ E_i \ar@{->}[rd]_{T^i_E} \ar@{->}[r]^{T^i_j} & E_j \ar@{->}[d]^{T^j_E} \\ & E } \] \item[(U)] For any pair $(F, \bracsn{S^i_F}_{i \in I})$ satisfying (1), (2), and (3), there exists a unique $S \in L({E, F})$ such that the following diagram commutes \[ \xymatrix{ E_i \ar@{->}[d]_{T^i_E} \ar@{->}[rd]^{S^i_F} & \\ E \ar@{->}[r]_{S} & F } \] for all $i \in I$. \item For any TVS $F$ and $T \in \hom(E; F)$, $T \in L(E; F)$ if and only if $T \circ T^i_E \in L(E_i; F)$ for all $i \in I$. \end\{enumerate\} The pair $(E, \bracsn{T^i_E}_{i \in I})$ is the \textbf{inductive limit} of $(\seqi{E}, \bracsn{T^i_j| i, j \in I, i \lesssim j})$. \end{definition} \begin{proof} Let $(E, \bracsn{T^i_E}_{i \in I})$ be the direct limit of $(\seqi{E}, \bracsn{T^i_j| i, j \in I, i \lesssim j})$ as vector spaces over $K$ (\autoref{proposition:module-direct-limit}). Equip $E$ with the \hyperref[inductive topology]{definition:tvs-inductive} induced by $\bracsn{T^i_E}_{i \in I}$, then $(E, \bracsn{T^i_E}_{i \in I})$ satisfies (1), (2), and (3). (U): By (U) of \autoref{proposition:module-direct-limit}, there exists a unique $S \in \hom(E; F)$ such that the given diagram commutes. By (4) of \autoref{definition:tvs-inductive}, $S \in L(E; F)$. (5): By (5) of \autoref{definition:tvs-inductive}. \end{proof} \begin{definition}[Strict] \label{definition:lc-inductive-strict} Let $(\seqi{E}, \bracsn{\iota^i_j| i, j \in I, i \lesssim j})$ be an upward-directed system of TVSs over $K \in \RC$, then the system is \textbf{strict} if: \begin{enumerate} \item For each $i, j \in I$ with $i \lesssim j$, $\iota^i_j: E_i \to E_j$ is injective. \item For each $i, j \in I$ with $i \lesssim j$, the topology of $E_i$ is induced by $\iota^i_j$. \end{enumerate} \end{definition}