# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1256682427 0 # Node ID 57291331fd82f7e9315ae33e9504ad6f4413f987 # Parent 62e8cc4799530ac0a160bb5c7df7699724b83405 ... diff -r 62e8cc479953 -r 57291331fd82 text/definitions.tex --- a/text/definitions.tex Tue Oct 27 05:19:10 2009 +0000 +++ b/text/definitions.tex Tue Oct 27 22:27:07 2009 +0000 @@ -277,20 +277,65 @@ \subsection{Constructing a TQFT} -\nn{need to expand this; use $\bc_0/\bc_1$ notation (maybe); also introduce -cylinder categories and gluing formula} +In this subsection we briefly review the construction of a TQFT from a system of fields and local relations. +(For more details, see \cite{kw:tqft}.) + +Let $W$ be an $n{+}1$-manifold. +We can think of the path integral $Z(W)$ as assigning to each +boundary condition $x\in \cC(\bd W)$ a complex number $Z(W)(x)$. +In other words, $Z(W)$ lies in $\c^{\lf(\bd W)}$, the vector space of linear +maps $\lf(\bd W)\to \c$. + +The locality of the TQFT implies that $Z(W)$ in fact lies in a subspace +$Z(\bd W) \sub \c^{\lf(\bd W)}$ defined by local projections. +The linear dual to this subspace, $A(\bd W) = Z(\bd W)^*$, +can be thought of as finite linear combinations of fields modulo local relations. +(In other words, $A(\bd W)$ is a sort of generalized skein module.) +This is the motivation behind the definition of fields and local relations above. -Given a system of fields and local relations, we define the skein space -$A(Y^n; c)$ to be the space of all finite linear combinations of fields on -the $n$-manifold $Y$ modulo local relations. -The Hilbert space $Z(Y; c)$ for the TQFT based on the fields and local relations -is defined to be the dual of $A(Y; c)$. -(See \cite{kw:tqft} or xxxx for details.) +In more detail, let $X$ be an $n$-manifold. +%To harmonize notation with the next section, +%let $\bc_0(X)$ be the vector space of finite linear combinations of fields on $X$, so +%$\bc_0(X) = \lf(X)$. +Define $U(X) \sub \lf(X)$ to be the space of local relations in $\lf(X)$; +$U(X)$ is generated by things of the form $u\bullet r$, where +$u\in U(B)$ for some embedded $n$-ball $B\sub X$ and $r\in \cC(X\setmin B)$. +Define +\[ + A(X) \deq \lf(X) / U(X) . +\] +(The blob complex, defined in the next section, +is in some sense the derived version of $A(X)$.) +If $X$ has boundary we can similarly define $A(X; c)$ for each +boundary condition $c\in\cC(\bd X)$. -\nn{should expand above paragraph} +The above construction can be extended to higher codimensions, assigning +a $k$-category $A(Y)$ to an $n{-}k$-manifold $Y$, for $0 \le k \le n$. +These invariants fit together via actions and gluing formulas. +We describe only the case $k=1$ below. +(The construction of the $n{+}1$-dimensional part of the theory (the path integral) +requires that the starting data (fields and local relations) satisfy additional +conditions. +We do not assume these conditions here, so when we say ``TQFT" we mean a decapitated TQFT +that lacks its $n{+}1$-dimensional part.) -The blob complex is in some sense the derived version of $A(Y; c)$. +Let $Y$ be an $n{-}1$-manifold. +Define a (linear) 1-category $A(Y)$ as follows. +The objects of $A(Y)$ are $\cC(Y)$. +The morphisms from $a$ to $b$ are $A(Y\times I; a, b)$, where $a$ and $b$ label the two boundary components of the cylinder $Y\times I$. +Composition is given by gluing of cylinders. +Let $X$ be an $n$-manifold with boundary and consider the collection of vector spaces +$A(X; \cdot) \deq \{A(X; c)\}$ where $c$ ranges through $\cC(\bd X)$. +This collection of vector spaces affords a representation of the category $A(\bd X)$, where +the action is given by gluing a collar $\bd X\times I$ to $X$. + +Given a splitting $X = X_1 \cup_Y X_2$ of a closed $n$-manifold $X$ along an $n{-}1$-manifold $Y$, +we have left and right actions of $A(Y)$ on $A(X_1; \cdot)$ and $A(X_2; \cdot)$. +The gluing theorem for $n$-manifolds states that there is a natural isomorphism +\[ + A(X) \cong A(X_1; \cdot) \otimes_{A(Y)} A(X_2; \cdot) . +\] \section{The blob complex} diff -r 62e8cc479953 -r 57291331fd82 text/ncat.tex --- a/text/ncat.tex Tue Oct 27 05:19:10 2009 +0000 +++ b/text/ncat.tex Tue Oct 27 22:27:07 2009 +0000 @@ -8,6 +8,9 @@ \nn{experimental section. maybe this should be rolled into other sections. maybe it should be split off into a separate paper.} +\nn{comment somewhere that what we really need is a convenient def of infty case, including tensor products etc. +but while we're at it might as well do plain case too.} + \subsection{Definition of $n$-categories} Before proceeding, we need more appropriate definitions of $n$-categories, @@ -903,6 +906,8 @@ \item define $n{+}1$-cat of $n$-cats (a.k.a.\ $n{+}1$-category of generalized bimodules a.k.a.\ $n{+}1$-category of sphere modules); discuss Morita equivalence \item morphisms of modules; show that it's adjoint to tensor product +(need to define dual module for this) +\item functors \end{itemize} \nn{Some salvaged paragraphs that we might want to work back in:}