# HG changeset patch # User kevin@6e1638ff-ae45-0410-89bd-df963105f760 # Date 1255735731 0 # Node ID cd2ebc293e6bd97d8102b5f49bebd76c1a99b22f # Parent 29beaf2e4577328c46ad4f035e1d8c57e32b6900 ... diff -r 29beaf2e4577 -r cd2ebc293e6b diagrams/pdf/tempkw/zo1.pdf Binary file diagrams/pdf/tempkw/zo1.pdf has changed diff -r 29beaf2e4577 -r cd2ebc293e6b diagrams/pdf/tempkw/zo2.pdf Binary file diagrams/pdf/tempkw/zo2.pdf has changed diff -r 29beaf2e4577 -r cd2ebc293e6b diagrams/pdf/tempkw/zo3.pdf Binary file diagrams/pdf/tempkw/zo3.pdf has changed diff -r 29beaf2e4577 -r cd2ebc293e6b diagrams/pdf/tempkw/zo4.pdf Binary file diagrams/pdf/tempkw/zo4.pdf has changed diff -r 29beaf2e4577 -r cd2ebc293e6b text/comparing_defs.tex --- a/text/comparing_defs.tex Fri Oct 16 22:44:25 2009 +0000 +++ b/text/comparing_defs.tex Fri Oct 16 23:28:51 2009 +0000 @@ -114,6 +114,14 @@ Isotopy invariance implies that this is associative. We will define a ``horizontal" composition later. +\begin{figure}[t] +\begin{equation*} +\mathfig{.73}{tempkw/zo1} +\end{equation*} +\caption{Vertical composition of 2-morphisms} +\label{fzo1} +\end{figure} + Given $a\in C^1$, define $\id_a = a\times I \in C^1$ (pinched boundary). Extended isotopy invariance for $\cC$ shows that this morphism is an identity for vertical composition. @@ -124,17 +132,41 @@ Define let $a: y\to x$ be a 1-morphism. Define maps $a \to a\bullet \id_x$ and $a\bullet \id_x \to a$ as shown in Figure \ref{fzo2}. +\begin{figure}[t] +\begin{equation*} +\mathfig{.73}{tempkw/zo2} +\end{equation*} +\caption{blah blah} +\label{fzo2} +\end{figure} In that figure, the red cross-hatched areas are the product of $x$ and a smaller bigon, while the remained is a half-pinched version of $a\times I$. +\nn{the red region is unnecessary; remove it? or does it help? +(because it's what you get if you bigonify the natural rectangular picture)} We must show that the two compositions of these two maps give the identity 2-morphisms on $a$ and $a\bullet \id_x$, as defined above. Figure \ref{fzo3} shows one case. +\begin{figure}[t] +\begin{equation*} +\mathfig{.83}{tempkw/zo3} +\end{equation*} +\caption{blah blah} +\label{fzo3} +\end{figure} In the first step we have inserted a copy of $id(id(x))$ \nn{need better notation for this}. \nn{also need to talk about (somewhere above) -how this sort of insertion is allowed by extended isotopy invariance and gluing} +how this sort of insertion is allowed by extended isotopy invariance and gluing. +Also: maybe half-pinched and unpinched products can be derived from fully pinched +products after all (?)} Figure \ref{fzo4} shows the other case. -\nn{At the moment, I don't see how the case follows from our candidate axioms for products. -Probably the axioms need to be strengthened a little bit.} +\begin{figure}[t] +\begin{equation*} +\mathfig{.83}{tempkw/zo4} +\end{equation*} +\caption{blah blah} +\label{fzo4} +\end{figure} +We first collapse the red region, then remove a product morphism from the boundary, \nn{postponing horizontal composition of 2-morphisms until we make up our minds about product axioms.}