# HG changeset patch # User Kevin Walker # Date 1280457861 14400 # Node ID fdb012a1c8fe3fd83f6ee1340cceba0474ef77fd # Parent 5702ddb104dc00d898cf82196dbbfb9c06d4b124 minor diff -r 5702ddb104dc -r fdb012a1c8fe text/appendixes/moam.tex --- a/text/appendixes/moam.tex Thu Jul 29 21:44:49 2010 -0400 +++ b/text/appendixes/moam.tex Thu Jul 29 22:44:21 2010 -0400 @@ -14,7 +14,7 @@ Let $\Compat(D^\bullet_*)$ denote the subcomplex of maps from $F_*$ to $G_*$ such that the image of each higher homotopy applied to $x_{kj}$ lies in $D^{kj}_*$. -\begin{thm}[Acyclic models] +\begin{thm}[Acyclic models] \label{moam-thm} Suppose \begin{itemize} \item $D^{k-1,l}_* \sub D^{kj}_*$ whenever $x_{k-1,l}$ occurs in $\bd x_{kj}$ diff -r 5702ddb104dc -r fdb012a1c8fe text/comm_alg.tex --- a/text/comm_alg.tex Thu Jul 29 21:44:49 2010 -0400 +++ b/text/comm_alg.tex Thu Jul 29 22:44:21 2010 -0400 @@ -31,24 +31,9 @@ \end{prop} \begin{proof} -%To define the chain maps between the two complexes we will use the following lemma: -% -%\begin{lemma} -%Let $A_*$ and $B_*$ be chain complexes, and assume $A_*$ is equipped with -%a basis (e.g.\ blob diagrams or singular simplices). -%For each basis element $c \in A_*$ assume given a contractible subcomplex $R(c)_* \sub B_*$ -%such that $R(c')_* \sub R(c)_*$ whenever $c'$ is a basis element which is part of $\bd c$. -%Then the complex of chain maps (and (iterated) homotopies) $f:A_*\to B_*$ such that -%$f(c) \in R(c)_*$ for all $c$ is contractible (and in particular non-empty). -%\end{lemma} -% -%\begin{proof} -%\nn{easy, but should probably write the details eventually} -%\nn{this is just the standard ``method of acyclic models" set up, so we should just give a reference for that} -%\end{proof} -We will use acyclic models \nn{need ref}. +We will use acyclic models (\S \ref{sec:moam}). Our first task: For each blob diagram $b$ define a subcomplex $R(b)_* \sub C_*(\Sigma^\infty(M))$ -satisfying the conditions of \nn{need ref}. +satisfying the conditions of Theorem \ref{moam-thm}. If $b$ is a 0-blob diagram, then it is just a $k[t]$ field on $M$, which is a finite unordered collection of points of $M$ with multiplicities, which is a point in $\Sigma^\infty(M)$. @@ -63,12 +48,12 @@ Define $R(B, u, r)_*$ to be the singular chain complex of $X$, thought of as a subspace of $\Sigma^\infty(M)$. It is easy to see that $R(\cdot)_*$ satisfies the condition on boundaries from -\nn{need ref, or state condition}. +Theorem \ref{moam-thm}. Thus we have defined (up to homotopy) a map from -$\bc_*(M^n, k[t])$ to $C_*(\Sigma^\infty(M))$. +$\bc_*(M, k[t])$ to $C_*(\Sigma^\infty(M))$. Next we define, for each simplex $c$ of $C_*(\Sigma^\infty(M))$, a contractible subspace -$R(c)_* \sub \bc_*(M^n, k[t])$. +$R(c)_* \sub \bc_*(M, k[t])$. If $c$ is a 0-simplex we use the identification of the fields $\cC(M)$ and $\Sigma^\infty(M)$ described above. Now let $c$ be an $i$-simplex of $\Sigma^j(M)$. @@ -80,7 +65,7 @@ \nn{do we need to define this precisely?} Choose a neighborhood $D$ of $T$ which is a disjoint union of balls of small diameter. \nn{need to say more precisely how small} -Define $R(c)_*$ to be $\bc_*(D, k[t]) \sub \bc_*(M^n, k[t])$. +Define $R(c)_*$ to be $\bc_*(D; k[t]) \sub \bc_*(M; k[t])$. This is contractible by Proposition \ref{bcontract}. We can arrange that the boundary/inclusion condition is satisfied if we start with low-dimensional simplices and work our way up.