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+\def\xxpar#1#2{\smallskip\noindent{\bf #1} {\it #2} \smallskip}
+\section{$n$-categories (maybe)}
+\label{sec:ncats}
+\nn{experimental section.  maybe this should be rolled into other sections.
+maybe it should be split off into a separate paper.}
+Before proceeding, we need more appropriate definitions of $n$-categories,
+$A_\infty$ $n$-categories, modules for these, and tensor products of these modules.
+(As is the case throughout this paper, by ``$n$-category" we mean
+a weak $n$-category with strong duality.)
+Consider first ordinary $n$-categories.
+We need a set (or sets) of $k$-morphisms for each $0\le k \le n$.
+We must decide on the ``shape" of the $k$-morphisms.
+Some $n$-category definitions model $k$-morphisms on the standard bihedron (interval, bigon, ...).
+Other definitions have a separate set of 1-morphisms for each interval $[0,l] \sub \r$,
+a separate set of 2-morphisms for each rectangle $[0,l_1]\times [0,l_2] \sub \r^2$,
+and so on.
+(This allows for strict associativity.)
+Still other definitions \nn{need refs for all these; maybe the Leinster book}
+model the $k$-morphisms on more complicated combinatorial polyhedra.
+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
+to a $k$-ball, we have a set of $k$-morphisms
+$\cC(X)$.}
+Given a homeomorphism $f:X\to Y$ between such $k$-manifolds, we want a corresponding
+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
+the category of manifolds homeomorphic to the $k$-ball and
+homeomorphisms to the category of sets and bijections.}
+(Note: We usually omit the subscript $k$.)
+We are being deliberately vague about what flavor of manifolds we are considering.
+They could be unoriented or oriented or Spin or $\mbox{Pin}_\pm$.
+They could be topological or PL or smooth.
+(If smooth, ``homeomorphism" should be read ``diffeomorphism", and we would need
+to be fussier about corners.)
+For each flavor of manifold there is a corresponding flavor of $n$-category.
+We will concentrate of the case of PL unoriented manifolds.
+Next we consider domains and ranges of morphisms (or, as we prefer to say, boundaries
+of morphisms).
+The 0-sphere is unusual among spheres in that it is disconnected.
+Correspondingly, for 1-morphisms it makes sense to distinguish between domain and range.
+For $k>1$ and in the presence of strong duality the domain/range division makes less sense.
+\nn{maybe say more here; rotate disk, Frobenius reciprocity blah blah}
+We prefer to combine the domain and range into a single entity which we call the
+boundary of a morphism.
+Morphisms are modeled on balls, so their boundaries are modeled on spheres:
+\xxpar{Boundaries (domain and range), part 1:}
+{For each $0 \le k \le n-1$, we have a functor $\cC_k$ from
+the category of manifolds homeomorphic to the $k$-sphere and
+homeomorphisms to the category of sets and bijections.}
+(In order to conserve symbols, we use the same symbol $\cC_k$ for both morphisms and boundaries.)
+\xxpar{Boundaries, part 2:}
+{For each $X$ homeomorphic to a $k$-ball, we have a map of sets $\bd: \cC(X)\to \cC(\bd X)$.
+These maps, for various $X$, comprise a natural transformation of functors.}
+(Note that the first ``$\bd$" above is part of the data for the category,
+while the second is the ordinary boundary of manifolds.)
+Given $c\in\cC(\bd(X))$, let $\cC(X; c) = \bd^{-1}(c)$.
+Most of the examples of $n$-categories we are interested in are enriched in the following sense.
+The various sets of $n$-morphisms $\cC(X; c)$, for all $X$ homeomorphic to an $n$-ball and
+all $c\in \cC(\bd X)$, have the structure of an object in some auxiliary category
+(e.g.\ vector spaces, or modules over some ring, or chain complexes),
+and all the structure maps of the $n$-category should be compatible with the auxiliary
+category structure.
+Note that this auxiliary structure is only in dimension $n$;
+$\cC(Y; c)$ is just a plain set if $\dim(Y) < n$.
+\medskip
+\nn{At the moment I'm a little confused about orientations, and more specifically
+about the role of orientation-reversing maps of boundaries when gluing oriented manifolds.
+Tentatively, I think we need to redefine the oriented boundary of an oriented $n$-manifold.
+Instead of an ordinary oriented $(n-1)$-manifold via the inward (or outward) normal
+first (or last) convention, perhaps it is better to define the boundary to be an $(n-1)$-manifold
+equipped with an orientation of its once-stabilized tangent bundle.
+Similarly, in dimension $n-k$ we would have manifolds equipped with an orientation of
+their $k$ times stabilized tangent bundles.
+For the moment just stick with unoriented manifolds.}
+\medskip
+We have just argued that the boundary of a morphism has no preferred splitting into
+domain and range, but the converse meets with our approval.
+That is, given compatible domain and range, we should be able to combine them into
+the full boundary of a morphism:
+\xxpar{Domain $+$ range $\to$ boundary:}
+{Let $S = B_1 \cup_E B_2$, where $S$ is homeomorphic to a $k$-sphere ($0\le k\le n-1$),
+$B_i$ is homeomorphic to a $k$-ball, and $E = B_1\cap B_2$ is homeomorphic to  a $k{-}1$-sphere.
+Let $\cC(B_1) \times_{\cC(E)} \cC(B_2)$ denote the fibered product of the
+two maps $\bd: \cC(B_i)\to \cC(E)$.
+Then (axiom) we have an injective map
+\[
+	\gl_E : \cC(B_1) \times_{\cC(E)} \cC(B_2) \to \cC(S)
+\]
+which is natural with respect to the actions of homeomorphisms.}
+Note that we insist on injectivity above.
+Let $\cC(S)_E$ denote the image of $\gl_E$.
+We have ``restriction" maps $\cC(S)_E \to \cC(B_i)$, which can be thought of as
+domain and range maps, relative to the choice of splitting $S = B_1 \cup_E B_2$.
+If $B$ is homeomorphic to a $k$-ball and $E \sub \bd B$ splits $\bd B$ into two $k{-}1$-balls
+as above, then we define $\cC(B)_E = \bd^{-1}(\cC(\bd B)_E)$.
+Next we consider composition of morphisms.
+For $n$-categories which lack strong duality, one usually considers
+$k$ different types of composition of $k$-morphisms, each associated to a different direction.
+(For example, vertical and horizontal composition of 2-morphisms.)
+In the presence of strong duality, these $k$ distinct compositions are subsumed into
+one general type of composition which can be in any ``direction".
+\xxpar{Composition:}
+{Let $B = B_1 \cup_Y B_2$, where $B$, $B_1$ and $B_2$ are homeomorphic to $k$-balls ($0\le k\le n$)
+and $Y = B_1\cap B_2$ is homeomorphic to a $k{-}1$-ball.
+Let $E = \bd Y$, which is homeomorphic to a $k{-}2$-sphere.
+Note that each of $B$, $B_1$ and $B_2$ has its boundary split into two $k{-}1$-balls by $E$.
+We have restriction (domain or range) maps $\cC(B_i)_E \to \cC(Y)$.
+Let $\cC(B_1)_E \times_{\cC(Y)} \cC(B_2)_E$ denote the fibered product of these two maps.
+Then (axiom) we have a map
+\[
+	\gl_Y : \cC(B_1)_E \times_{\cC(Y)} \cC(B_2)_E \to \cC(B)_E
+\]
+which is natural with respect to the actions of homeomorphisms, and also compatible with restrictions
+to the intersection of the boundaries of $B$ and $B_i$.
+If $k < n$ we require that $\gl_Y$ is injective.
+(For $k=n$, see below.)}

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