some inkspace pictures

lectures_on_knot_theory.tex

@@ -1,22 +1,39 @@
 \documentclass[12pt, twoside]{article}
-\usepackage[pdf]{pstricks}
+
 
 \usepackage{amssymb}
 \usepackage{amsmath}
-\usepackage{xfrac}
-\usepackage[english]{babel}
-\usepackage{csquotes}
-\usepackage{graphicx}
-\usepackage{float}
-\usepackage{titlesec}
-\usepackage{comment}
-\usepackage{pict2e}
-\usepackage{hyperref}
 \usepackage{advdate}
 \usepackage{amsthm}
+
+\usepackage[english]{babel}
+
+\usepackage{comment}
+\usepackage{csquotes}
+
 \usepackage[useregional]{datetime2}
+
+\usepackage{enumitem}
+\usepackage{fontspec}
+\usepackage{float}
+
+\usepackage{graphicx}
+\usepackage{hyperref}
+
+\usepackage{mathtools}
+
+\usepackage{pict2e}
+\usepackage[pdf]{pstricks}
+
 \usepackage{tikz}
+\usepackage{titlesec}
+
+\usepackage{xfrac}
+
+\usepackage{unicode-math}
+
 \usetikzlibrary{cd}
+
 \hypersetup{
     colorlinks,
     citecolor=black,
@@ -24,40 +41,45 @@
     linkcolor=black,
     urlcolor=black
 }
-\usepackage{fontspec}
-\usepackage{mathtools}
-\usepackage{unicode-math}
-\graphicspath{ {images/} }
 
+\newtheoremstyle{break}
+  {\topsep}{\topsep}%
+  {\itshape}{}%
+  {\bfseries}{}%
+  {\newline}{}%
+\theoremstyle{break}
 \newtheorem{lemma}{Lemma}
 \newtheorem{fact}{Fact}
 \newtheorem{example}{Example}
-%\theoremstyle{definition}
 \newtheorem{definition}{Definition}
-%\theoremstyle{plain}
 \newtheorem{theorem}{Theorem}
 \newtheorem{proposition}{Proposition}
-\newcommand{\contradiction}{%
-  \ensuremath{{\Rightarrow\mspace{-2mu}\Leftarrow}}%
-}
 
-%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
-%%%% For quotient groups / modding equiv relations
-%%%% Use: \quot{A}{B} --> A/B
+\newcommand{\contradiction}{%
+   \ensuremath{{\Rightarrow\mspace{-2mu}\Leftarrow}}}
 \newcommand*\quot[2]{{^{\textstyle #1}\big/_{\textstyle #2}}}
-%%%%%%%%%%%%%%%%%%%%%%%%%%%%
-\newcommand{\overbar}[1]{\mkern 1.5mu\overline{\mkern-1.5mu#1\mkern-1.5mu}\mkern 1.5mu}
+\newcommand{\overbar}[1]{%
+   \mkern 1.5mu=\overline{%
+   \mkern-1.5mu#1\mkern-1.5mu}%
+   \mkern 1.5mu}
+
+\AtBeginDocument{\renewcommand{\setminus}{%
+     \mathbin{\backslash}}}
+
+
 \DeclareMathOperator{\Hom}{Hom}
 \DeclareMathOperator{\rank}{rank}
-\AtBeginDocument{\renewcommand{\setminus}{\mathbin{\backslash}}}
+
+
+\titleformat{\section}{\normalfont \large \bfseries}{%
+     Lecture\ \thesection}{2.3ex plus .2ex}{} 
+
+%\setlist[itemize]{topsep=0pt,before=%\leavevmode\vspace{0.5em}}
+
 
 \input{knots_macros}
+\graphicspath{ {images/} }
 
-\titleformat{\section}{\normalfont \large \bfseries}
-{Lecture\ \thesection}{2.3ex plus .2ex}{} 
-\titlespacing{\subsection}{2em}{*1}{*1}
-\usepackage{enumitem}
-\setlist[itemize]{topsep=0pt,before=\leavevmode\vspace{0.5em}}
 
 \begin{document}
 \tableofcontents
@@ -74,8 +96,18 @@ A knot $K$ in $S^3$ is a smooth (PL - smooth) embedding of a circle $S^1$ in $S^
 \noindent
 Usually we think about a knot as an image of an embedding: $K = \varphi(S^1)$.
 \begin{example}
-!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
-knot and not a knot (not inection), not smooth, 
+\begin{itemize}
+\item 
+Knots:
+\includegraphics[width=0.08\textwidth]{unknot.png},
+\includegraphics[width=0.08\textwidth]{trefoil.png}.
+\item 
+Not knots: 
+\includegraphics[width=0.12\textwidth]{not_injective_knot.png}
+(it is not an injection),
+\includegraphics[width=0.08\textwidth]{not_smooth_knot.png}
+(it is not smooth).
+\end{itemize}
 \end{example}
 \begin{definition}
 %\hfill\\
@@ -89,9 +121,10 @@ $\Phi_1 = \varphi_1$.
 \end{definition}
 
 \begin{theorem}
-Two knots $K_0$ and $K_1$ are isotopic if and only if they are ambient isotopic, i.e. there exists a family of self-diffeomorphisms $\Psi$ such that:
+Two knots $K_0$ and $K_1$ are isotopic if and only if they are ambient isotopic, i.e. there exists a family of self-diffeomorphisms $\Psi = \{\psi_t: t \in [0, 1]\}$ such that:
 \begin{align*}
-&\Psi: S^3 \hookrightarrow S^3,\\
+&\psi(t) = \psi_t \text{ is continius on $t\in [0,1]$}\\
+&\psi_t: S^3 \hookrightarrow S^3,\\
 & \psi_0 = id ,\\
 & \psi_1(K_0) = K_1.
 \end{align*}
@@ -100,7 +133,7 @@ Two knots $K_0$ and $K_1$ are isotopic if and only if they are ambient isotopic,
 A knot is trivial (unknot) if it is equivalent to an embedding $\varphi(t) = (\cos t, \sin t, 0)$, where $t \in [0, 2 \pi] $ is a parametrisation of $S^1$.
 \end{definition}
 \begin{definition}
-A link with k - components is a (smooth) embedding of\\ $\overbrace{S^1 \sqcup \ldots \sqcup S^1}^k$ in $S^3$
+A link with k - components is a (smooth) embedding of $\overbrace{S^1 \sqcup \ldots \sqcup S^1}^k$ in $S^3$
 \end{definition}
 \begin{example}
 Links:
@@ -118,24 +151,23 @@ Borromean link:
 \includegraphics[width=0.1\textwidth]{BorromeanRings.png},
 \end{itemize}
 \end{example}
-
+%
+%
+%
 \begin{definition}
 A link diagram is a picture over projection of a link is $S^3$($\mathbb{R}^3$) such that:
-\begin{enumerate}
+\begin{enumerate}[label={(\arabic*)}]
 \item 
-${D_{\pi}}_{\big|L}$ is non degenerate
-\includegraphics[width=0.02\textwidth]{LinkDiagram1.png},
-\item the double points are not degenerate
-\includegraphics[width=0.02\textwidth]{LinkDiagram2.png},
-\item there are no triple point
-\includegraphics[width=0.03\textwidth]{LinkDiagram3.png}.
+${D_{\pi}}_{\big|L}$ is non degenerate: \includegraphics[width=0.05\textwidth]{LinkDiagram1.png},
+\item the double points are not degenerate: \includegraphics[width=0.05\textwidth]{LinkDiagram2.png},
+\item there are no triple point:  \includegraphics[width=0.05\textwidth]{LinkDiagram3.png}.
 \end{enumerate}
 \end{definition}
 There are under- and overcrossings  (tunnels and bridges) on a link diagrams with an obvious meaning.\\
 Every link admits a link diagram.
 %\begin{comment}
 
-\subsection{Reidemeister moves}
+\section*{Reidemeister moves}
 A Reidemeister move is one of the three types of operation on a link diagram as shown in Figure~\ref{fig: reidemeister}.
 %
 The first Reidemeister move inserts or removes a coil. 
@@ -211,7 +243,12 @@ Are there in concordance group torsion elements that are not $2$ torsion element
 \end{example}
 \noindent
 Remark: $K \sim K^{\prime} \Leftrightarrow K \# -K^{\prime}$ is slice.
+
+%
+%
 \section{\hfill\DTMdate{2019-04-08}}
+%
+%
 $X$ is a closed orientable four-manifold. Assume $\pi_1(X) = 0$ (it is not needed to define the intersection form). In particular $H_1(X) = 0$. 
 $H_2$ is free (exercise). 
 \begin{align*}
@@ -262,7 +299,7 @@ Let $K \in S^1$ be a knot, $\Sigma(K)$ its double branched cover. If $V$ is a Se
 $H_1(\Sigma(K), \mathbb{Z}) \cong  \quot{\mathbb{Z}^n}{A\mathbb{Z}}$ where 
 $A = V \times V^T$, where $n = \rank V$.
 %\input{ink_diag}
-\begin{figure}[h]
+\begin{figure}[H]
 \fontsize{40}{10}\selectfont
 \centering{
 \def\svgwidth{\linewidth}
@@ -294,7 +331,7 @@ In general
 
 \section{\hfill\DTMdate{2019-05-20}}
 
-Let $M$ be closed, oriented, compact four-dimensional manifold.\\
+Let $M$ be compact, oriented, connected four-dimensional manifold.\\
 ??????????????????????????????????\\
 If $H_1(M, \mathbb{Z}) = 0$ then there exists a 
 bilinear form - the intersection form on $M$: 
@@ -327,9 +364,9 @@ Then: $H_2(M, \mathbb{Z})
 H_2(M, \mathbb{Z}) \longrightarrow \Hom (H_2(M, \mathbb{Z}), \mathbb{Z})\\
 (a, b) \mapsto \mathbb{Z}\\
 a \mapsto (a, \_) H_2(M, \mathbb{Z})
-\end{align*} has coker 
-
-
+\end{align*}
+has coker precisely $H_1(Y, \mathbb{Z})$. 
+\\???????????????\\
 Let $K \subset S^3$  be a knot, \\
 $X = S^3 \setminus K$ - a knot complement,  \\
 $\widetilde{X} \xrightarrow{\enspace \rho \enspace} X$ - an infinite cyclic cover (universal abelian cover).
@@ -551,4 +588,8 @@ A square hermitian matrix $A$ of size $n$.
 \end{definition}
 
 field of fractions
+
+
+\section{balagan}
+
 \end{document}