# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1248387228 0 # Node ID 9e5716a79abef67cfe82bfd4e89adde4b2ee9b15 # Parent 18611e5661498e16bd2b0e50f436902ae13a065f ... diff -r 18611e566149 -r 9e5716a79abe text/ncat.tex --- a/text/ncat.tex Wed Jul 22 17:37:45 2009 +0000 +++ b/text/ncat.tex Thu Jul 23 22:13:48 2009 +0000 @@ -27,7 +27,8 @@ We will allow our $k$-morphisms to have any shape, so long as it is homeomorphic to a $k$-ball. In other words, -\xxpar{Morphisms (preliminary version):}{For any $k$-manifold $X$ homeomorphic +\xxpar{Morphisms (preliminary version):} +{For any $k$-manifold $X$ homeomorphic to a $k$-ball, we have a set of $k$-morphisms $\cC(X)$.} @@ -35,7 +36,8 @@ bijection of sets $f:\cC(X)\to \cC(Y)$. So we replace the above with -\xxpar{Morphisms:}{For each $0 \le k \le n$, we have a functor $\cC_k$ from +\xxpar{Morphisms:} +{For each $0 \le k \le n$, we have a functor $\cC_k$ from the category of manifolds homeomorphic to the $k$-ball and homeomorphisms to the category of sets and bijections.} @@ -144,14 +146,18 @@ (For $k=n$, see below.)} \xxpar{Strict associativity:} -{The composition (gluing) maps above are strictly associative. -It follows that given a decomposition $B = B_1\cup\cdots\cup B_m$ of a $k$-ball -into small $k$-balls, there is a well-defined -map from an appropriate subset of $\cC(B_1)\times\cdots\times\cC(B_m)$ to $\cC(B)$, +{The composition (gluing) maps above are strictly associative.} + +The above two axioms are equivalent to the following axiom, +which we state in slightly vague form. + +\xxpar{Multi-composition:} +{Given any decomposition $B = B_1\cup\cdots\cup B_m$ of a $k$-ball +into small $k$-balls, there is a +map from an appropriate subset (like a fibered product) +of $\cC(B_1)\times\cdots\times\cC(B_m)$ to $\cC(B)$, and these various $m$-fold composition maps satisfy an -operad-type associativity condition.} - -\nn{above maybe needs some work} +operad-type strict associativity condition.} The next axiom is related to identity morphisms, though that might not be immediately obvious. @@ -306,11 +312,19 @@ modulo the kernel of the evaluation map. Define a product morphism $a\times D$ to be the product of the cell complex of $a$ with $D$, and with the same labeling as $a$. +More generally, start with an $n{+}m$-category $C$ and a closed $m$-manifold $F$. +Define $\cC(X)$, for $\dim(X) < n$, +to be the set of all $C$-labeled sub cell complexes of $X\times F$. +Define $\cC(X; c)$, for $X$ an $n$-ball, +to be the dual Hilbert space $A(X\times F; c)$. \nn{refer elsewhere for details?} \item Variation on the above examples: We could allow $F$ to have boundary and specify boundary conditions on $(\bd X)\times F$, for example product boundary conditions or take the union over all boundary conditions. +\nn{maybe should not emphasize this case, since it's ``better" in some sense +to think of these guys as affording a representation +of the $n{+}1$-category associated to $\bd F$.} \end{itemize} @@ -334,6 +348,65 @@ Next we define [$A_\infty$] $n$-category modules (a.k.a.\ representations, a.k.a.\ actions). +The definition will be very similar to that of $n$-categories. + +Out motivating example comes from an $(m{-}n{+}1)$-dimensional manifold $W$ with boundary +in the context of an $m{+}1$-dimensional TQFT. +Such a $W$ gives rise to a module for the $n$-category associated to $\bd W$. +This will be explained in more detail as we present the axioms. + +Fix an $n$-category $\cC$. + +Define a {\it marked $k$-ball} to be a pair $(B, N)$ homeomorphic to the pair +(standard $k$-ball, northern hemisphere in boundary of standard $k$-ball). +We call $B$ the ball and $N$ the marking. +A homeomorphism between marked $k$-balls is a homeomorphism of balls which +restricts to a homeomorphism of markings. + +\xxpar{Module morphisms} +{For each $0 \le k \le n$, we have a functor $\cM_k$ from +the category of marked $k$-balls and +homeomorphisms to the category of sets and bijections.} + +(As with $n$-categories, we will usually omit the subscript $k$.) + +In our example, let $\cM(B, N) = \cD((B\times \bd W)\cup_{N\times \bd W} (N\times W))$, +where $\cD$ is the fields functor for the TQFT. + +Define the boundary of a marked ball $(B, N)$ to be the pair $(\bd B \setmin N, \bd N)$. +Call such a thing a {marked hemisphere}. + +\xxpar{Module boundaries, part 1:} +{For each $0 \le k \le n-1$, we have a functor $\cM_k$ from +the category of marked hemispheres (of dimension $k$) and +homeomorphisms to the category of sets and bijections.} + +\xxpar{Module boundaries, part 2:} +{For each marked $k$-ball $M$ we have a map of sets $\bd: \cM(M)\to \cM(\bd M)$. +These maps, for various $M$, comprise a natural transformation of functors.} + +Given $c\in\cM(\bd M)$, let $\cM(M; c) = \bd^{-1}(c)$. + +If the $n$-category $\cC$ is enriched over some other category (e.g.\ vector spaces), +then $\cM(M; c)$ should be an object in that category for each marked $n$-ball $M$ +and $c\in \cC(\bd M)$. + +\xxpar{Module domain $+$ range $\to$ boundary:} +{Let $H = M_1 \cup_E M_2$, where $H$ is a marked $k$-hemisphere ($0\le k\le n-1$), +$B_i$ is a marked $k$-ball, and $E = B_1\cap B_2$ is a marked $k{-}1$-hemisphere. +Let $\cM(B_1) \times_{\cM(E)} \cM(B_2)$ denote the fibered product of the +two maps $\bd: \cM(B_i)\to \cM(E)$. +Then (axiom) we have an injective map +\[ + \gl_E : \cM(M_1) \times_{\cM(E)} \cM(M_2) \to \cM(H) +\] +which is natural with respect to the actions of homeomorphisms.} + + + + + + \medskip \hrule @@ -346,7 +419,6 @@ Stuff that remains to be done (either below or in an appendix or in a separate section or in a separate paper): \begin{itemize} -\item modules/representations/actions (need to decide what to call them) \item tensor products \item blob complex is an example of an $A_\infty$ $n$-category \item fundamental $n$-groupoid is an example of an $A_\infty$ $n$-category