# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1255469526 0 # Node ID d4e6bf589ebea753947ad463cb00b1ceae49b9c2 # Parent eb9de49b98b4002a2b5d2000ad6bf340443734e6 ... diff -r eb9de49b98b4 -r d4e6bf589ebe text/a_inf_blob.tex --- a/text/a_inf_blob.tex Wed Oct 07 18:33:41 2009 +0000 +++ b/text/a_inf_blob.tex Tue Oct 13 21:32:06 2009 +0000 @@ -54,8 +54,8 @@ %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 +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 $K\times F$. 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 diff -r eb9de49b98b4 -r d4e6bf589ebe text/ncat.tex --- a/text/ncat.tex Wed Oct 07 18:33:41 2009 +0000 +++ b/text/ncat.tex Tue Oct 13 21:32:06 2009 +0000 @@ -218,7 +218,7 @@ \[ (a\times D')\bullet(a\times D'') = a\times (D'\bullet D'') . \] -\nn{problem: if pinched boundary, then only one factor} +\nn{if pinched boundary, then remove first case above} Product morphisms are associative: \[ (a\times D)\times D' = a\times (D\times D') . @@ -234,6 +234,14 @@ \nn{need even more subaxioms for product morphisms?} +\nn{Almost certainly we need a little more than the above axiom. +More specifically, in order to bootstrap our way from the top dimension +properties of identity morphisms to low dimensions, we need regular products, +pinched products and even half-pinched products. +I'm not sure what the best way to cleanly axiomatize the properties of these various is. +For the moment, I'll assume that all flavors of the product are at +our disposal, and I'll plan on revising the axioms later.} + All of the axioms listed above hold for both ordinary $n$-categories and $A_\infty$ $n$-categories. The last axiom (below), concerning actions of homeomorphisms in the top dimension $n$, distinguishes the two cases. @@ -260,6 +268,8 @@ Let $X$ be an $n$-ball and $Y\sub\bd X$ be an $n{-}1$-ball. Let $J$ be a 1-ball (interval). We have a collaring homeomorphism $s_{Y,J}: X\cup_Y (Y\times J) \to X$. +(Here we use the ``pinched" version of $Y\times J$. +\nn{need notation for this}) We define a map \begin{eqnarray*} \psi_{Y,J}: \cC(X) &\to& \cC(X) \\ @@ -873,7 +883,7 @@ \item say something about unoriented vs oriented vs spin vs pin for $n=1$ (and $n=2$?) \item spell out what difference (if any) Top vs PL vs Smooth makes \item explain relation between old-fashioned blob homology and new-fangled blob homology -(follows as special case of product formula (product with a point). +(follows as special case of product formula (product with a point)). \item define $n{+}1$-cat of $n$-cats (a.k.a.\ $n{+}1$-category of generalized bimodules a.k.a.\ $n{+}1$-category of sphere modules); discuss Morita equivalence \end{itemize}