# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1246931662 0 # Node ID cf67ae4abeb19c3dcf5b1de5e2bbb42928202c09 # Parent ffcd1a5eafd8f36e9a11fdfc01942e5d58c641c9 ... diff -r ffcd1a5eafd8 -r cf67ae4abeb1 text/evmap.tex --- a/text/evmap.tex Sun Jul 05 15:43:09 2009 +0000 +++ b/text/evmap.tex Tue Jul 07 01:54:22 2009 +0000 @@ -167,11 +167,12 @@ Given a generator $p\otimes b$ of $CD_*(X)\otimes \bc_*(X)$ and non-negative integers $i$ and $k$ define \[ - N_{i,k}(p\ot b) \deq \Nbd_{k\ep_i}(|b|) \cup \Nbd_{k\delta_i}(|p|). + N_{i,k}(p\ot b) \deq \Nbd_{k\ep_i}(|b|) \cup \Nbd_{4^k\delta_i}(|p|). \] In other words, we use the metric to choose nested neighborhoods of $|b|\cup |p|$ (parameterized by $k$), with $\ep_i$ controlling the size of the buffer around $|b|$ and $\delta_i$ controlling the size of the buffer around $|p|$. +(The $4^k$ comes from Lemma \ref{xxxx}.) Next we define subcomplexes $G_*^{i,m} \sub CD_*(X)\otimes \bc_*(X)$. Let $p\ot b$ be a generator of $CD_*(X)\otimes \bc_*(X)$ and let $k = \deg(p\ot b) @@ -192,9 +193,9 @@ $G_*^{i,m}$ is a subcomplex where it is easy to define the evaluation map. The parameter $m$ controls the number of iterated homotopies we are able to construct -(Lemma \ref{mhtyLemma}). +(see Lemma \ref{mhtyLemma}). The larger $i$ is (i.e.\ the smaller $\ep_i$ is), the better $G_*^{i,m}$ approximates all of -$CD_*(X)\ot \bc_*(X)$ (Lemma \ref{xxxlemma}). +$CD_*(X)\ot \bc_*(X)$ (see Lemma \ref{xxxlemma}). Next we define a chain map (dependent on some choices) $e: G_*^{i,m} \to \bc_*(X)$. Let $p\ot b \in G_*^{i,m}$. @@ -218,15 +219,16 @@ (The second inclusion uses the facts that $|p_j| \subeq |p|$ and $|b_j| \subeq |b|$.) We therefore have splittings \[ - p = p'\bullet p'' , \;\; b = b'\bullet b'' , \;\; e(\bd(p\ot b)) = f'\bullet f'' , + p = p'\bullet p'' , \;\; b = b'\bullet b'' , \;\; e(\bd(p\ot b)) = f'\bullet b'' , \] where $p' \in CD_*(V)$, $p'' \in CD_*(X\setmin V)$, $b' \in \bc_*(V)$, $b'' \in \bc_*(X\setmin V)$, -$e' \in \bc_*(p(V))$, and $e'' \in \bc_*(p(X\setmin V))$. +$f' \in \bc_*(p(V))$, and $f'' \in \bc_*(p(X\setmin V))$. (Note that since the family of diffeomorphisms $p$ is constant (independent of parameters) -near $\bd V)$, the expressions $p(V) \sub X$ and $p(X\setmin V) \sub X$ are +near $\bd V$, the expressions $p(V) \sub X$ and $p(X\setmin V) \sub X$ are unambiguous.) -We also have that $\deg(b'') = 0 = \deg(p'')$. +We have $\deg(p'') = 0$ and, inductively, $f'' = p''(b'')$. +%We also have that $\deg(b'') = 0 = \deg(p'')$. Choose $x' \in \bc_*(p(V))$ such that $\bd x' = f'$. This is possible by \nn{...}. Finally, define @@ -306,7 +308,7 @@ Choose a monotone decreasing sequence of real numbers $\gamma_j$ converging to zero. Let $\cU_j$ denote the open cover of $X$ by balls of radius $\gamma_j$. Let $h_j: CD_*(X)\to CD_*(X)$ be a chain map homotopic to the identity whose image is spanned by diffeomorphisms with support compatible with $\cU_j$, as described in Lemma \ref{xxxxx}. -Recall that $h_j$ and also its homotopy back to the identity do not increase +Recall that $h_j$ and also the homotopy connecting it to the identity do not increase supports. Define \[ @@ -315,6 +317,7 @@ The next lemma says that for all generators $p\ot b$ we can choose $j$ large enough so that $g_j(p)\ot b$ lies in $G_*^{i,m}$, for arbitrary $m$ and sufficiently large $i$ (depending on $b$, $n = \deg(p)$ and $m$). +\nn{not the same $n$ as the dimension of the manifolds; fix this} \begin{lemma} Fix a blob diagram $b$, a homotopy order $m$ and a degree $n$ for $CD_*(X)$. @@ -327,36 +330,124 @@ Let $c$ be a subset of the blobs of $b$. There exists $l > 0$ such that $\Nbd_u(c)$ is homeomorphic to $|c|$ for all $u < l$ and all such $c$. -(Here we are using a piecewise smoothness assumption for $\bd c$). +(Here we are using a piecewise smoothness assumption for $\bd c$, and also +the fact that $\bd c$ is collared.) -Let $r = \deg(b)$. +Let $r = \deg(b)$ and +\[ + t = r+n+m+1 . +\] Choose $k = k_{bmn}$ such that \[ - (r+n+m+1)\ep_k < l + t\ep_k < l \] and \[ - n\cdot (3\delta_k\cdot(r+n+m+1)) < \ep_k . + n\cdot ( 4^t \delta_i) < \ep_k/3 . \] Let $i \ge k_{bmn}$. Choose $j = j_i$ so that \[ - 3\cdot(r+n+m+1)\gamma_j < \ep_i + t\gamma_j < \ep_i/3 \] -and also so that for any subset $S\sub X$ of diameter less than or equal to -$2n\gamma_j$ we have that $\Nbd_u(S)$ is +and also so that $\gamma_j$ is less than the constant $\eta(X, m, k)$ of Lemma \ref{xxyy5}. + +\nn{...} + +\end{proof} + +In the next few lemmas we have made no effort to optimize the various bounds. +(The bounds are, however, optimal in the sense of minimizing the amount of work +we do. Equivalently, they are the first bounds we thought of.) + +We say that a subset $S$ of a metric space has radius $\le r$ if $S$ is contained in +some metric ball of radius $r$. + +\begin{lemma} +Let $S \sub \ebb^n$ (Euclidean $n$-space) have radius $\le r$. +Then $\Nbd_a(S)$ is homeomorphic to a ball for $a \ge 2r$. +\end{lemma} + +\begin{proof} \label{xxyy2} +Let $S$ be contained in $B_r(y)$, $y \in \ebb^n$. +Note that $\Nbd_a(S) \sup B_r(y)$. +Simple applications of the triangle inequality show that $\Nbd_a(S)$ +is star-shaped with respect to $y$. \end{proof} +\begin{lemma} \label{xxyy3} +Let $S \sub \ebb^n$ be contained in a union (not necessarily disjoint) +of $k$ metric balls of radius $r$. +Then there exists a neighborhood $U$ of $S$ such that $U$ is homeomorphic to a disjoint union +of balls and +\[ + \Nbd_{2r}(S) \subeq U \subeq \Nbd_{4^k r}(S) . +\] +\end{lemma} + +\begin{proof} +Partition $S$ into $k$ disjoint subsets $S_1,\ldots,S_k$, each of radius $\le r$. +By Lemma \ref{xxyy2}, each $\Nbd(S_i)$ is homeomorphic to a ball. +If these balls are disjoint (always the case if $k=1$) we are done. +If two (or more) of them intersect, then $S$ is contained in a union of $k-1$ metric +balls of radius $4r$. +By induction, there is a neighborhood $U$ of $S$ such that +\[ + U \subeq \Nbd_{4^{k-1}\cdot4r} . +\] +\end{proof} + +\begin{lemma} \label{xxyy4} +Let $S \sub \ebb^n$ be contained in a union (not necessarily disjoint) +of $k$ metric balls of radius $r$. +Then there exist neighborhoods $U_0, U_1, U_2, \ldots$ of $S$, +each homeomorphic to a disjoint union of balls, such that +\[ + \Nbd_{2r}(S) \subeq U_0 \subeq \Nbd_{4^k r}(S) + \subeq U_1 \subeq \Nbd_{4^{2k} r}(S) + \subeq U_2 \subeq \Nbd_{4^{3k} r}(S) \cdots +\] +\end{lemma} + +\begin{proof} +Apply Lemma \ref {xxyy3} repeatedly. +\end{proof} + +\begin{lemma} \label{xxyy5} +Let $M$ be a Riemannian $n$-manifold and positive integers $m$ and $k$. +There exists a constant $\eta(M, m, k)$ such that for all subsets +$S\subeq M$ which are contained in a (not necessarily disjoint) union of +$k$ metric balls of radius $r$, $r < \eta(M, m, k)$, +there exist neighborhoods $U_0, U_1, \ldots, U_m$ of $S$, +each homeomorphic to a disjoint union of balls, such that +\[ + \Nbd_{2r}(S) \subeq U_0 \subeq \Nbd_{4^k r}(S) + \subeq U_1 \subeq \Nbd_{4^{2k} r}(S) \cdots + \subeq U_m \subeq \Nbd_{4^{(m+1)k} r}(S) . +\] + +\end{lemma} + +\begin{proof} +Choose $\eta = \eta(M, m, k)$ small enough so that metric balls of radius $4^{(m+1)k} \eta$ +are injective and also have small distortion with respect to a Euclidean metric. +Then proceed as in the proof of Lemma \ref{xxyy4}. +\end{proof} \medskip + + + + \noop{ \begin{lemma} \end{lemma} + \begin{proof} \end{proof} diff -r ffcd1a5eafd8 -r cf67ae4abeb1 text/kw_macros.tex --- a/text/kw_macros.tex Sun Jul 05 15:43:09 2009 +0000 +++ b/text/kw_macros.tex Tue Jul 07 01:54:22 2009 +0000 @@ -6,6 +6,7 @@ \def\r{\mathbb{R}} \def\c{\mathbb{C}} \def\t{\mathbb{T}} +\def\ebb{\mathbb{E}} \def\du{\sqcup} \def\bd{\partial}