# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1255649385 0 # Node ID a5e863658e7433b5d5671222ffcb7e321e3f57ec # Parent d4e6bf589ebea753947ad463cb00b1ceae49b9c2 ... diff -r d4e6bf589ebe -r a5e863658e74 text/a_inf_blob.tex --- a/text/a_inf_blob.tex Tue Oct 13 21:32:06 2009 +0000 +++ b/text/a_inf_blob.tex Thu Oct 15 23:29:45 2009 +0000 @@ -20,7 +20,7 @@ Let $\cF$ be the $A_\infty$ $k$-category which assigns to a $k$-ball $X$ the old-fashioned blob complex $\bc_*(X\times F)$. -\begin{thm} +\begin{thm} \label{product_thm} The old-fashioned blob complex $\bc_*^C(Y\times F)$ is homotopy equivalent to the new-fangled blob complex $\bc_*^\cF(Y)$. \end{thm} @@ -28,14 +28,20 @@ \begin{proof} We will use the concrete description of the colimit from Subsection \ref{ss:ncat_fields}. -First we define a map from $\bc_*^\cF(Y)$ to $\bc_*^C(Y\times F)$. +First we define a map +\[ + \psi: \bc_*^\cF(Y) \to \bc_*^C(Y\times F) . +\] In filtration degree 0 we just glue together the various blob diagrams on $X\times F$ (where $X$ is a component of a permissible decomposition of $Y$) to get a blob diagram on $Y\times F$. In filtration degrees 1 and higher we define the map to be zero. It is easy to check that this is a chain map. -Next we define a map from $\phi: \bc_*^C(Y\times F) \to \bc_*^\cF(Y)$. +Next we define a map +\[ + \phi: \bc_*^C(Y\times F) \to \bc_*^\cF(Y) . +\] Actually, we will define it on the homotopy equivalent subcomplex $\cS_* \sub \bc_*^C(Y\times F)$ generated by blob diagrams which are small with respect to some open cover @@ -56,7 +62,7 @@ We will define $\phi$ using a variant of the method of acyclic models. Let $a\in \cS_m$ be a blob diagram on $Y\times F$. For $m$ sufficiently small there exists a decomposition $K$ of $Y$ into $k$-balls such that the -codimension 1 cells of $K\times F$ miss the blobs of $a$, and more generally such that $a$ is splittable along $K\times F$. +codimension 1 cells of $K\times F$ miss the blobs of $a$, and more generally such that $a$ is splittable along (the codimension-1 part of) $K\times F$. Let $D(a)$ denote the subcomplex of $\bc_*^\cF(Y)$ generated by all $(a, \bar{K})$ such that each $K_i$ has the aforementioned splittable property (see Subsection \ref{ss:ncat_fields}). @@ -109,7 +115,6 @@ \nn{need to also require that $KLM$ antirefines to $KM$, etc.} Then we have a filtration degree 2 chain, as shown in Figure \ref{zzz5}, which does the trick. (Each small triangle in Figure \ref{zzz5} can be filled with a filtration degree 2 chain.) -For example, .... \begin{figure}[!ht] \begin{equation*} @@ -119,16 +124,48 @@ \label{zzz5} \end{figure} +Continuing in this way we see that $D(a)$ is acyclic. \end{proof} +We are now in a position to apply the method of acyclic models to get a map +$\phi:\cS_* \to \bc_*^\cF(Y)$. +This map is defined in sufficiently low degrees, sends a blob diagram $a$ to $D(a)$, +and is well-defined up to (iterated) homotopy. -\nn{....} +The subcomplex $\cS_* \subset \bc_*^C(Y\times F)$ depends on choice of cover of $Y\times F$. +If we refine that cover, we get a complex $\cS'_* \subset \cS_*$ +and a map $\phi':\cS'_* \to \bc_*^\cF(Y)$. +$\phi'$ is defined only on homological degrees below some bound, but this bound is higher than +the corresponding bound for $\phi$. +We must show that $\phi$ and $\phi'$ agree, up to homotopy, +on the intersection of the subcomplexes on which they are defined. +This is clear, since the acyclic subcomplexes $D(a)$ above used in the definition of +$\phi$ and $\phi'$ do not depend on the choice of cover. + +\nn{need to say (and justify) that we now have a map $\phi$ indep of choice of cover} + +We now show that $\phi\circ\psi$ and $\psi\circ\phi$ are homotopic to the identity. + +$\psi\circ\phi$ is the identity. $\phi$ takes a blob diagram $a$ and chops it into pieces +according to some decomposition $K$ of $Y$. +$\psi$ glues those pieces back together, yielding the same $a$ we started with. + +$\phi\circ\psi$ is the identity up to homotopy by another MoAM argument... + +This concludes the proof of Theorem \ref{product_thm}. +\nn{at least I think it does; it's pretty rough at this point.} \end{proof} - \nn{need to say something about dim $< n$ above} +\medskip +\begin{cor} +The new-fangled and old-fashioned blob complexes are homotopic. +\end{cor} +\begin{proof} +Apply Theorem \ref{product_thm} with the fiber $F$ equal to a point. +\end{proof} \medskip \hrule