--- a/text/a_inf_blob.tex Wed Jul 07 08:47:50 2010 -0600
+++ b/text/a_inf_blob.tex Wed Jul 07 10:17:30 2010 -0600
@@ -41,9 +41,9 @@
Given a topological $n$-category $C$ and a $n{-}k$-manifold $F$, recall from
Example \ref{ex:blob-complexes-of-balls} that there is an $A_\infty$ $k$-category $\bc_*(F; C)$ defined by
\begin{equation*}
-\bc_*(F; C) = \cB_*(B \times F, C).
+\bc_*(F; C)(B) = \cB_*(F \times B; C).
\end{equation*}
-Now, given a $k$-manifold $Y$, there is a homotopy equivalence between the `old-fashioned'
+Now, given a $k$-manifold $Y$, there is a homotopy equivalence between the ``old-fashioned''
blob complex for $Y \times F$ with coefficients in $C$ and the ``new-fangled"
(i.e.\ homotopy colimit) blob complex for $Y$ with coefficients in $\bc_*(F; C)$:
\begin{align*}
--- a/text/ncat.tex Wed Jul 07 08:47:50 2010 -0600
+++ b/text/ncat.tex Wed Jul 07 10:17:30 2010 -0600
@@ -379,7 +379,6 @@
\[
d: \Delta^{k+m}\to\Delta^k .
\]
-In other words, \nn{each point has a neighborhood blah blah...}
(We thank Kevin Costello for suggesting this approach.)
Note that for each interior point $x\in X$, $\pi\inv(x)$ is an $m$-ball,
@@ -519,7 +518,7 @@
We start with the plain $n$-category case.
-\begin{axiom}[Isotopy invariance in dimension $n$]{\textup{\textbf{[preliminary]}}}
+\begin{axiom}[\textup{\textbf{[preliminary]}} Isotopy invariance in dimension $n$]
Let $X$ be an $n$-ball and $f: X\to X$ be a homeomorphism which restricts
to the identity on $\bd X$ and is isotopic (rel boundary) to the identity.
Then $f$ acts trivially on $\cC(X)$; $f(a) = a$ for all $a\in \cC(X)$.
@@ -593,7 +592,7 @@
The revised axiom is
\addtocounter{axiom}{-1}
-\begin{axiom}{\textup{\textbf{[topological version]}} Extended isotopy invariance in dimension $n$.}
+\begin{axiom}[\textup{\textbf{[topological version]}} Extended isotopy invariance in dimension $n$.]
\label{axiom:extended-isotopies}
Let $X$ be an $n$-ball and $f: X\to X$ be a homeomorphism which restricts
to the identity on $\bd X$ and isotopic (rel boundary) to the identity.
@@ -611,7 +610,7 @@
\addtocounter{axiom}{-1}
-\begin{axiom}{\textup{\textbf{[$A_\infty$ version]}} Families of homeomorphisms act in dimension $n$.}
+\begin{axiom}[\textup{\textbf{[$A_\infty$ version]}} Families of homeomorphisms act in dimension $n$.]
For each $n$-ball $X$ and each $c\in \cl{\cC}(\bd X)$ we have a map of chain complexes
\[
C_*(\Homeo_\bd(X))\ot \cC(X; c) \to \cC(X; c) .
@@ -629,7 +628,7 @@
and we can replace the class of all intervals $J$ with intervals contained in $\r$.
Having chains on the space of collar maps act gives rise to coherence maps involving
weak identities.
-We will not pursue this in this draft of the paper.
+We will not pursue this in detail here.
Note that if we take homology of chain complexes, we turn an $A_\infty$ $n$-category
into a plain $n$-category (enriched over graded groups).
@@ -917,7 +916,7 @@
and we will define $\cl{\cC}(W)$ as a suitable colimit
(or homotopy colimit in the $A_\infty$ case) of this functor.
We'll later give a more explicit description of this colimit.
-In the case that the $n$-category $\cC$ is enriched (e.g. associates vector spaces or chain complexes to $n$-manifolds with boundary data),
+In the case that the $n$-category $\cC$ is enriched (e.g. associates vector spaces or chain complexes to $n$-balls with boundary data),
then the resulting colimit is also enriched, that is, the set associated to $W$ splits into subsets according to boundary data, and each of these subsets has the appropriate structure (e.g. a vector space or chain complex).
Define a {\it permissible decomposition} of $W$ to be a cell decomposition
@@ -975,7 +974,7 @@
$\cS$ and the coproduct and product in Equation \ref{eq:psi-CC} should be replaced by the approriate
operations in $\cS$ (e.g. direct sum and tensor product if $\cS$ is Vect).
-Finally, we construct $\cC(W)$ as the appropriate colimit of $\psi_{\cC;W}$.
+Finally, we construct $\cl{\cC}(W)$ as the appropriate colimit of $\psi_{\cC;W}$.
\begin{defn}[System of fields functor]
\label{def:colim-fields}
@@ -1040,7 +1039,7 @@
$\cC(W)$ is functorial with respect to homeomorphisms of $k$-manifolds. Restricting the $k$-spheres, we have now proved Lemma \ref{lem:spheres}.
-\todo{This next sentence is circular: these maps are an axiom, not a consequence of anything. -S} It is easy to see that
+It is easy to see that
there are well-defined maps $\cC(W)\to\cC(\bd W)$, and that these maps
comprise a natural transformation of functors.
@@ -1342,10 +1341,10 @@
$(B,N) \to (S,T)$ and on each marked $n$-ball $(B,N)$ it consists of all
such maps modulo homotopies fixed on $\bdy B \setminus N$.
This is a module over the fundamental $n$-category $\pi_{\leq n}(S)$ of $S$, from Example \ref{ex:maps-to-a-space}.
+\end{example}
Modifications corresponding to Examples \ref{ex:maps-to-a-space-with-a-fiber} and
\ref{ex:linearized-maps-to-a-space} are also possible, and there is an $A_\infty$ version analogous to
Example \ref{ex:chains-of-maps-to-a-space} given by taking singular chains.
-\end{example}
\subsection{Modules as boundary labels (colimits for decorated manifolds)}
\label{moddecss}