diff -r 1e50c1a5e8c0 -r 76f423a9c787 text/a_inf_blob.tex --- a/text/a_inf_blob.tex Tue Aug 18 19:27:44 2009 +0000 +++ b/text/a_inf_blob.tex Fri Aug 21 23:17:10 2009 +0000 @@ -35,18 +35,57 @@ 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 $\bc_*^C(Y\times F)$ to $\bc_*^\cF(Y)$. +Next we define a map from $\phi: \bc_*^C(Y\times F) \to \bc_*^\cF(Y)$. 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 +$\cS_* \sub \bc_*^C(Y\times F)$ generated by blob diagrams which are small with +respect to some open cover of $Y\times F$. \nn{need reference to small blob lemma} We will have to show eventually that this is independent (up to homotopy) of the choice of cover. Also, for a fixed choice of cover we will only be able to define the map for blob degree less than some bound, but this bound goes to infinity as the cover become finer. +Given a decomposition $K$ of $Y$ into $k$-balls $X_i$, let $K\times F$ denote the corresponding +decomposition of $Y\times F$ into the pieces $X_i\times F$. + +%We will define $\phi$ inductively, starting at blob degree 0. +%Given a 0-blob diagram $x$ on $Y\times F$, we can choose a decomposition $K$ of $Y$ +%such that $x$ is splittable with respect to $K\times F$. +%This defines a filtration degree 0 element of $\bc_*^\cF(Y)$ + +We will define $\phi$ using a variant of the method of acyclic models. +Let $a\in S_m$ be a blob diagram on $Y\times F$. +For $m$ sufficiently small there exist decompositions of $K$ 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 $K\times F$. +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}). +(By $(a, \bar{K})$ we really mean $(a', \bar{K})$, where $a^\sharp$ is +$a$ split according to $K_0\times F$. +To simplify notation we will just write plain $a$ instead of $a^\sharp$.) +Roughly speaking, $D(a)$ consists of filtration degree 0 stuff which glues up to give +$a$, filtration degree 1 stuff which makes all of the filtration degree 0 stuff homologous, +filtration degree 2 stuff which kills the homology created by the +filtration degree 1 stuff, and so on. +More formally, + +\begin{lemma} +$D(a)$ is acyclic. +\end{lemma} + +\begin{proof} +We will prove acyclicity in the first couple of degrees, and \nn{in this draft, at least} +leave the general case to the reader. +Let $K$ and $K'$ be two decompositions of $Y$ compatible with $a$. +We want to show that $(a, K)$ and $(a, K')$ are homologous +\nn{oops -- can't really ignore $\bd a$ like this} +\end{proof} + + \nn{....} \end{proof} + \nn{need to say something about dim $< n$ above}