# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1266721676 0 # Node ID aa7c033bacfa94880d04e87fa88331d5120ef841 # Parent 0127f415fb6540663ccab748a6349d2c37cda71e ... diff -r 0127f415fb65 -r aa7c033bacfa text/ncat.tex --- a/text/ncat.tex Sun Feb 21 02:23:30 2010 +0000 +++ b/text/ncat.tex Sun Feb 21 03:07:56 2010 +0000 @@ -1136,8 +1136,44 @@ \medskip +Part of the structure of an $n$-cat 0-sphere module is captured my saying it is +a collection $\cD^{ab}$ of $n{-}1$-categories, indexed by pairs $(a, b)$ of objects (0-morphisms) +of $\cA$ and $\cB$. +Let $J$ be some standard 0-marked 1-ball (i.e.\ an interval with a marked point in its interior). +Given a $j$-ball $X$, $0\le j\le n-1$, we define +\[ + \cD(X) \deq \cM(X\times J) . +\] +The product is pinched over the boundary of $J$. +$\cD$ breaks into ``blocks" according to the restrictions to the pinched points of $X\times J$ +(see Figure xxxx). +These restrictions are 0-morphisms $(a, b)$ of $\cA$ and $\cB$. +More generally, consider an interval with interior marked points, and with the complements +of these points labeled by $n$-categories $\cA_i$ ($0\le i\le l$) and the marked points labeled +by $\cA_i$-$\cA_{i+1}$ bimodules $\cM_i$. +(See Figure xxxx.) +To this data we can apply to coend construction as in Subsection \ref{moddecss} above +to obtain an $\cA_0$-$\cA_l$ bimodule and, forgetfully, an $n{-}1$-category. +This amounts to a definition of taking tensor products of bimodules over $n$-categories. +We could also similarly mark and label a circle, obtaining an $n{-}1$-category +associated to the marked and labeled circle. +(See Figure xxxx.) +If the circle is divided into two intervals, we can think of this $n{-}1$-category +as the 2-ended tensor product of the two bimodules associated to the two intervals. + +\medskip + +Next we define $n$-category 1-sphere modules. +These are just representations of (modules for) $n{-}1$-categories associated to marked and labeled +circles (1-spheres) which we just introduced. + +Equivalently, we can define 1-sphere modules in terms of 1-marked $k$-balls, $2\le k\le n$. +Fix a marked (and labeled) circle $S$. +Let $C(S)$ denote the cone of $S$, a marked 2-ball (Figure xxxx). +\nn{I need to make up my mind whether marked things are always labeled too.} +A 1-marked $k$-ball is anything homeomorphic to $B^j \times C(S)$, $0\le j\le n-2$. \medskip \hrule