joshua
/
msc-thesis
Archived
1
0
Fork 0
Code Releases Activity
Browse Source

Added part about homology. Split tex files.

master
Joshua Moerman 10 years ago
parent
7951869863
commit
cdd59f9adc
5 changed files with 128 additions and 42 deletions
Whitespace
Show all changes Ignore whitespace when comparing lines Ignore changes in amount of whitespace Ignore changes in whitespace at EOL
Split View
Diff Options
Show Stats Download Patch File Download Diff File
  1. 65
      thesis/1_Algebra.tex
  2. 89
      thesis/2_Model_Cats.tex
  3. 2
      thesis/CDGA_Model.tex
  4. 4
      thesis/preamble.tex
  5. 10
      thesis/thesis.tex

65
thesis/Definitions.tex → thesis/1_Algebra.tex
View File

@ -1,11 +1,11 @@
% -*- root: thesis.tex -*-
\section{Definitions}
\label{sec:definitions}
\subsection{Graded algebra}
\section{Differential Graded Algebra}
\label{sec:algebra}
In this section $\k$ will be any commutative ring. We will recap some of the basic definitions of commutative algebra in a graded setting. By \emph{linear}, \emph{module}, \emph{tensor product}, etc \dots we always mean $\k$-linear, $\k$-module, tensor product over $\k$, etc \dots.
\subsection{Graded algebra}
\begin{definition}
A \emph{graded module} $M$ is a family of modules $\{M_n\}_{n\in\Z}$. An element $x \in M_n$ is called a \emph{homogeneous element} and said to be of \emph{degree $\deg{x} = n$}. We will often identify $M = \bigoplus_{n \in \Z} M_n$.
\end{definition}
@ -13,7 +13,8 @@ In this section $\k$ will be any commutative ring. We will recap some of the bas
For an ordinary module $M$ we can consider the graded module $M[0]$ \emph{concentrated in degree $0$} defined by setting $M[0]_0 = M$ and $M[0]_n = 0$ for $i \neq 0$. If clear from the context we will denote this graded module by $M$. In particular $\k$ is a graded module concentrated in degree $0$.
\begin{definition}
A linear map $f: M \to N$ between graded modules is \emph{graded of degree $p$} if it respects the grading, i.e. $\restr{f}{M_n} : M_n \to N_{n+p}$.
A linear map $f: M \to N$ between graded modules is \emph{graded of degree $p$} if it respects the grading and raises the degree by $p$, i.e.
$$ \restr{f}{M_n} : M_n \to N_{n+p}. $$
\end{definition}
\begin{definition}
@ -23,9 +24,7 @@ For an ordinary module $M$ we can consider the graded module $M[0]$ \emph{concen
Note that not all linear maps can be decomposed into a sum of graded maps, so that $\Hom_{gr}(M, N) \subset \Hom(M, N)$ may be proper for some $M$ and $N$.
Recall that the tensor product of modules distributes over direct sums. So if $M = \bigoplus_{n \in \Z} M_n$ and $N = \bigoplus_{n \in \Z} N_n$, then
$$ M \tensor N \iso \bigoplus_{n \in Z} \bigoplus_{m \in Z} M_m \tensor N_n \iso \bigoplus_{n \in Z} \bigoplus_{i + j = n} M_i \tensor N_j. $$
This defines a natural grading on the tensor product.
Recall that the tensor product of modules distributes over direct sums. This defines a natural grading on the ordinary tensor product.
\begin{definition}
The graded tensor product is defined as:
@ -42,7 +41,7 @@ The graded modules together with graded maps of degree $0$ form the category $\g
A map between two graded algebra will be called a \emph{graded algebra map} if the map is compatible with the multiplication and unit. Such a map is necessarily of degree $0$.
\end{definition}
Again these objects form a category, denoted as $\grAlg{\k}$.
Again these objects and maps form a category, denoted as $\grAlg{\k}$.
\begin{definition}
A graded algebra $A$ is \emph{commutative} if for all $x, y \in A$
@ -74,38 +73,26 @@ It is not hard to see that this definition precisely defines the monoidal object
Let $M$ be a DGA, just as before $M$ is called a \emph{chain algebras} if $M_i = 0$ for $i < 0$. Similarly if $M^i = 0$ for all $i < 0$, then $M$ is a \emph{cochain algebra}.
\subsection{Model categories}
\subsection{Homology}
\newcommand{\W}{\mathfrak{W}}
\newcommand{\Fib}{\mathfrak{Fib}}
\newcommand{\Cof}{\mathfrak{Cof}}
Whenever we have a differential graded module we have $d \circ d = 0$, or put in other words: the image of $d$ is a submodule of the kernel of $d$. The quotient of the two graded modules will be of interest.
\begin{definition}
A \emph{model category} is a category $\cat{C}$ together with three subcategories:
\begin{itemize}
\item the class of weak equivalences $\W$,
\item the class of fibrations $\Fib$ and
\item the class of cofibrations $\Cof$,
\end{itemize}
such that the following five axioms hold:
\begin{itemize}
\item[MC1] All finite limits and colimits exist in $\cat{C}$.
\item[MC2] If $f$, $g$ and $fg$ are maps such that two of them are weak equivalences, then so it the third. This is called the \emph{2-out-of-3} property.
\item[MC3] All three classes of maps are closed under retracts\todo{Either draw the diagram or define a retract earlier}.
\item[MC4] In any commuting square as follows where $i \in \Cof$ and $p \in \Fib$, there exist a lift if either
\begin{itemize}
\item[a)] $i \in \W$ or
\item[b)] $p \in \W$.
\end{itemize}
\todo{insert diagram}
\item[MC5] Any map $f : A \to B$ can be factored as $f = pi$, where either
\begin{itemize}
\item[a)] $i \in \Cof \cap \W$ and $p \in \Fib$ or
\item[b)] $i \in \Cof$ and $p \in \Fib \cap \W$.
\end{itemize}
\end{itemize}
Given a differential graded modules $(M, d)$ we define the \emph{homology} of $M$ as: $H(M, d) = \ker(d) / \im(d)$.
It is naturally graded as follows:
$$ H(M, d)_i = H_i(M, d) = \ker(\restr{d}{M_i}) / d(M_{i+1}). $$
If $d$ has degree $+1$ we define the \emph{cohomology} as:
$$ H(M, d)^i = H^i(M, d) = \ker(\restr{d}{M^i}) / d(M^{i-1}). $$
\end{definition}
\todo{define notation $\cof$ $\fib$}
\todo{define (co)fibrant objects}
\todo{maybe some basic propositions}
For differential graded algebras we can consider the (co)homology by forgetting the multiplicative structure. However this multiplication will actually pass to (co)homology:
\begin{lemma}
Let $(A, d)$ be a differential graded algebra. The kernel $\ker(d)$ is a subalgebra of $A$ and the image $d(A)$ is an ideal, so that the quotient
$$ H(A) = \ker(d) / \im(d) $$
is a graded algebra.
\end{lemma}
\begin{proof}
\todo{}
\end{proof}

89
thesis/2_Model_Cats.tex
View File

@ -0,0 +1,89 @@
\section{Model categories}
\label{sec:model_cats}
\newcommand{\W}{\mathfrak{W}}
\newcommand{\Fib}{\mathfrak{Fib}}
\newcommand{\Cof}{\mathfrak{Cof}}
\begin{definition}
A \emph{model category} is a category $\cat{C}$ together with three subcategories:
\begin{itemize}
\item the class of weak equivalences $\W$,
\item the class of fibrations $\Fib$ and
\item the class of cofibrations $\Cof$,
\end{itemize}
such that the following five axioms hold:
\begin{itemize}
\item[MC1] All finite limits and colimits exist in $\cat{C}$.
\item[MC2] If $f$, $g$ and $fg$ are maps such that two of them are weak equivalences, then so it the third. This is called the \emph{2-out-of-3} property.
\item[MC3] All three classes of maps are closed under retracts\todo{Either draw the diagram or define a retract earlier}.
\item[MC4] In any commuting square as follows where $i \in \Cof$ and $p \in \Fib$,
\begin{center}
\begin{tikzpicture}
\matrix (m) [matrix of math nodes]{
A & X \\
B & Y \\
};
\path[->] (m-1-1) edge (m-1-2);
\path[->] (m-2-1) edge (m-2-2);
\path[->] (m-1-1) edge node[auto] {$i$} (m-2-1);
\path[->] (m-1-2) edge node[auto] {$p$} (m-2-2);
\end{tikzpicture}
\end{center}
there exist a lift $h: B \to Y$ if either
\begin{itemize}
\item[a)] $i \in \W$ or
\item[b)] $p \in \W$.
\end{itemize}
\item[MC5] Any map $f : A \to B$ can be factored in two ways:
\begin{itemize}
\item[a)] as $f = pi$, where $i \in \Cof \cap \W$ and $p \in \Fib$ and
\item[b)] as $f = pi$, where $i \in \Cof$ and $p \in \Fib \cap \W$.
\end{itemize}
\end{itemize}
\end{definition}
\begin{notation} For brevity
\begin{itemize}
\item we write $f: A \fib B$ when $f$ is a fibration,
\item we write $f: A \cof B$ when $f$ is a cofibration and
\item we write $f: A \we B$ when $f$ is a weak equivalence.
\end{itemize}
\end{notation}
\begin{definition}
An object $A$ in a model category $\cat{C}$ will be called \emph{fibrant} if $A \to \cat{1}$ is a fibration and \emph{cofibrant} if $\cat{0} \to A$ is a cofibration.
\end{definition}
Note that axiom [MC5a] allows us to replace any object $X$ with a weakly equivalent fibrant object $X^{fib}$ and a weakly equivalent cofibrant object $X^{cof}$, as seen in the following diagram:
\begin{center}
\begin{tikzpicture}
\matrix (m) [matrix of math nodes]{
\cat{0} & & X \\
& X^{cof} & \\
};
\path[->] (m-1-1) edge (m-1-3);
\path[right hook->] (m-1-1) edge (m-2-2);
\path[->>] (m-2-2) edge node[auto] {$ \simeq $} (m-1-3);
\end{tikzpicture}\quad
\begin{tikzpicture}
\matrix (m) [matrix of math nodes]{
X & & \cat{1} \\
& X^{fib} & \\
};
\path[->] (m-1-1) edge (m-1-3);
\path[right hook->] (m-1-1) edge node[auto] {$ \simeq $} (m-2-2);
\path[->>] (m-2-2) edge (m-1-3);
\end{tikzpicture}
\end{center}
\todo{maybe some basic propositions}

2
thesis/CDGA_Model.tex
View File

@ -1,4 +1,4 @@
% -*- root: thesis.tex -*-
\section{Model structure on $\CDGA_\k$}
In this section we will define a model structure on CDGAs over a field $\k$ \todo{Can $\k$ be a c. ring here?}, where the weak equivalences are quasi isomorphisms and fibrations are surjective maps. The cofibrations are defined to be the maps with a left lifting property with respect to trivial fibrations.

4
thesis/preamble.tex
View File

@ -1,4 +1,4 @@
% -*- root: thesis.tex -*-
% clickable tocs
\usepackage{hyperref}
@ -62,6 +62,7 @@
\newcommand{\eq}{\sim} % homotopic
\newcommand{\tot}[1]{\xrightarrow{\,\,{#1}\,\,}} % arrow with name
\newcommand{\mapstot}[1]{\xmapsto{\,\,{#1}\,\,}} % mapsto with name
\DeclareMathOperator*{\im}{im}
\DeclareMathOperator*{\colim}{colim}
\DeclareMathOperator*{\tensor}{\otimes}
\DeclareMathOperator*{\bigtensor}{\bigotimes}
@ -89,6 +90,7 @@
\theoremstyle{definition}
\newtheorem{definition}[theorem]{Definition}
\newtheorem{notation}[theorem]{Notation}
\newtheorem{example}[theorem]{Example}
% headings for a table

10
thesis/thesis.tex
View File

@ -11,7 +11,15 @@
\maketitle
\tableofcontents
\input{Definitions} \newpage
Some general notation: \todo{leave this out, or define somewhere else?}
\begin{itemize}
\item $\cat{0}$ (resp. $\cat{1}$) will denote the initial (resp. final) objects in a category.
\item $\Hom_\cat{C}(A, B)$ will denote the set of maps from $A$ to $B$ in the category $\cat{C}$.
\end{itemize}
\newpage
\input{1_Algebra} \newpage
\input{2_Model_Cats} \newpage
\input{CDGA_Model} \newpage
\nocite{*}