diff --git a/module2/exo1/fige.png b/module2/exo1/fige.png
new file mode 100644
index 0000000000000000000000000000000000000000..55be04f1fff3203f4b44a845f11f7b86a6801eb2
Binary files /dev/null and b/module2/exo1/fige.png differ
diff --git a/module2/exo1/toy_document_orgmode_python_fr.html b/module2/exo1/toy_document_orgmode_python_fr.html
new file mode 100644
index 0000000000000000000000000000000000000000..b5c79300c47b72eded04f42922b8781438556f10
--- /dev/null
+++ b/module2/exo1/toy_document_orgmode_python_fr.html
@@ -0,0 +1,381 @@
+<?xml version="1.0" encoding="utf-8"?>
+<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN"
+"http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd">
+<html xmlns="http://www.w3.org/1999/xhtml" lang="fr" xml:lang="fr">
+<head>
+<!-- 2020-04-01 Wed 10:17 -->
+<meta http-equiv="Content-Type" content="text/html;charset=utf-8" />
+<meta name="viewport" content="width=device-width, initial-scale=1" />
+<title>À propos du calcul de &pi;</title>
+<meta name="generator" content="Org mode" />
+<meta name="author" content="Clément" />
+<style type="text/css">
+ <!--/*--><![CDATA[/*><!--*/
+  .title  { text-align: center;
+             margin-bottom: .2em; }
+  .subtitle { text-align: center;
+              font-size: medium;
+              font-weight: bold;
+              margin-top:0; }
+  .todo   { font-family: monospace; color: red; }
+  .done   { font-family: monospace; color: green; }
+  .priority { font-family: monospace; color: orange; }
+  .tag    { background-color: #eee; font-family: monospace;
+            padding: 2px; font-size: 80%; font-weight: normal; }
+  .timestamp { color: #bebebe; }
+  .timestamp-kwd { color: #5f9ea0; }
+  .org-right  { margin-left: auto; margin-right: 0px;  text-align: right; }
+  .org-left   { margin-left: 0px;  margin-right: auto; text-align: left; }
+  .org-center { margin-left: auto; margin-right: auto; text-align: center; }
+  .underline { text-decoration: underline; }
+  #postamble p, #preamble p { font-size: 90%; margin: .2em; }
+  p.verse { margin-left: 3%; }
+  pre {
+    border: 1px solid #ccc;
+    box-shadow: 3px 3px 3px #eee;
+    padding: 8pt;
+    font-family: monospace;
+    overflow: auto;
+    margin: 1.2em;
+  }
+  pre.src {
+    position: relative;
+    overflow: visible;
+    padding-top: 1.2em;
+  }
+  pre.src:before {
+    display: none;
+    position: absolute;
+    background-color: white;
+    top: -10px;
+    right: 10px;
+    padding: 3px;
+    border: 1px solid black;
+  }
+  pre.src:hover:before { display: inline;}
+  /* Languages per Org manual */
+  pre.src-asymptote:before { content: 'Asymptote'; }
+  pre.src-awk:before { content: 'Awk'; }
+  pre.src-C:before { content: 'C'; }
+  /* pre.src-C++ doesn't work in CSS */
+  pre.src-clojure:before { content: 'Clojure'; }
+  pre.src-css:before { content: 'CSS'; }
+  pre.src-D:before { content: 'D'; }
+  pre.src-ditaa:before { content: 'ditaa'; }
+  pre.src-dot:before { content: 'Graphviz'; }
+  pre.src-calc:before { content: 'Emacs Calc'; }
+  pre.src-emacs-lisp:before { content: 'Emacs Lisp'; }
+  pre.src-fortran:before { content: 'Fortran'; }
+  pre.src-gnuplot:before { content: 'gnuplot'; }
+  pre.src-haskell:before { content: 'Haskell'; }
+  pre.src-hledger:before { content: 'hledger'; }
+  pre.src-java:before { content: 'Java'; }
+  pre.src-js:before { content: 'Javascript'; }
+  pre.src-latex:before { content: 'LaTeX'; }
+  pre.src-ledger:before { content: 'Ledger'; }
+  pre.src-lisp:before { content: 'Lisp'; }
+  pre.src-lilypond:before { content: 'Lilypond'; }
+  pre.src-lua:before { content: 'Lua'; }
+  pre.src-matlab:before { content: 'MATLAB'; }
+  pre.src-mscgen:before { content: 'Mscgen'; }
+  pre.src-ocaml:before { content: 'Objective Caml'; }
+  pre.src-octave:before { content: 'Octave'; }
+  pre.src-org:before { content: 'Org mode'; }
+  pre.src-oz:before { content: 'OZ'; }
+  pre.src-plantuml:before { content: 'Plantuml'; }
+  pre.src-processing:before { content: 'Processing.js'; }
+  pre.src-python:before { content: 'Python'; }
+  pre.src-R:before { content: 'R'; }
+  pre.src-ruby:before { content: 'Ruby'; }
+  pre.src-sass:before { content: 'Sass'; }
+  pre.src-scheme:before { content: 'Scheme'; }
+  pre.src-screen:before { content: 'Gnu Screen'; }
+  pre.src-sed:before { content: 'Sed'; }
+  pre.src-sh:before { content: 'shell'; }
+  pre.src-sql:before { content: 'SQL'; }
+  pre.src-sqlite:before { content: 'SQLite'; }
+  /* additional languages in org.el's org-babel-load-languages alist */
+  pre.src-forth:before { content: 'Forth'; }
+  pre.src-io:before { content: 'IO'; }
+  pre.src-J:before { content: 'J'; }
+  pre.src-makefile:before { content: 'Makefile'; }
+  pre.src-maxima:before { content: 'Maxima'; }
+  pre.src-perl:before { content: 'Perl'; }
+  pre.src-picolisp:before { content: 'Pico Lisp'; }
+  pre.src-scala:before { content: 'Scala'; }
+  pre.src-shell:before { content: 'Shell Script'; }
+  pre.src-ebnf2ps:before { content: 'ebfn2ps'; }
+  /* additional language identifiers per "defun org-babel-execute"
+       in ob-*.el */
+  pre.src-cpp:before  { content: 'C++'; }
+  pre.src-abc:before  { content: 'ABC'; }
+  pre.src-coq:before  { content: 'Coq'; }
+  pre.src-groovy:before  { content: 'Groovy'; }
+  /* additional language identifiers from org-babel-shell-names in
+     ob-shell.el: ob-shell is the only babel language using a lambda to put
+     the execution function name together. */
+  pre.src-bash:before  { content: 'bash'; }
+  pre.src-csh:before  { content: 'csh'; }
+  pre.src-ash:before  { content: 'ash'; }
+  pre.src-dash:before  { content: 'dash'; }
+  pre.src-ksh:before  { content: 'ksh'; }
+  pre.src-mksh:before  { content: 'mksh'; }
+  pre.src-posh:before  { content: 'posh'; }
+  /* Additional Emacs modes also supported by the LaTeX listings package */
+  pre.src-ada:before { content: 'Ada'; }
+  pre.src-asm:before { content: 'Assembler'; }
+  pre.src-caml:before { content: 'Caml'; }
+  pre.src-delphi:before { content: 'Delphi'; }
+  pre.src-html:before { content: 'HTML'; }
+  pre.src-idl:before { content: 'IDL'; }
+  pre.src-mercury:before { content: 'Mercury'; }
+  pre.src-metapost:before { content: 'MetaPost'; }
+  pre.src-modula-2:before { content: 'Modula-2'; }
+  pre.src-pascal:before { content: 'Pascal'; }
+  pre.src-ps:before { content: 'PostScript'; }
+  pre.src-prolog:before { content: 'Prolog'; }
+  pre.src-simula:before { content: 'Simula'; }
+  pre.src-tcl:before { content: 'tcl'; }
+  pre.src-tex:before { content: 'TeX'; }
+  pre.src-plain-tex:before { content: 'Plain TeX'; }
+  pre.src-verilog:before { content: 'Verilog'; }
+  pre.src-vhdl:before { content: 'VHDL'; }
+  pre.src-xml:before { content: 'XML'; }
+  pre.src-nxml:before { content: 'XML'; }
+  /* add a generic configuration mode; LaTeX export needs an additional
+     (add-to-list 'org-latex-listings-langs '(conf " ")) in .emacs */
+  pre.src-conf:before { content: 'Configuration File'; }
+
+  table { border-collapse:collapse; }
+  caption.t-above { caption-side: top; }
+  caption.t-bottom { caption-side: bottom; }
+  td, th { vertical-align:top;  }
+  th.org-right  { text-align: center;  }
+  th.org-left   { text-align: center;   }
+  th.org-center { text-align: center; }
+  td.org-right  { text-align: right;  }
+  td.org-left   { text-align: left;   }
+  td.org-center { text-align: center; }
+  dt { font-weight: bold; }
+  .footpara { display: inline; }
+  .footdef  { margin-bottom: 1em; }
+  .figure { padding: 1em; }
+  .figure p { text-align: center; }
+  .equation-container {
+    display: table;
+    text-align: center;
+    width: 100%;
+  }
+  .equation {
+    vertical-align: middle;
+  }
+  .equation-label {
+    display: table-cell;
+    text-align: right;
+    vertical-align: middle;
+  }
+  .inlinetask {
+    padding: 10px;
+    border: 2px solid gray;
+    margin: 10px;
+    background: #ffffcc;
+  }
+  #org-div-home-and-up
+   { text-align: right; font-size: 70%; white-space: nowrap; }
+  textarea { overflow-x: auto; }
+  .linenr { font-size: smaller }
+  .code-highlighted { background-color: #ffff00; }
+  .org-info-js_info-navigation { border-style: none; }
+  #org-info-js_console-label
+    { font-size: 10px; font-weight: bold; white-space: nowrap; }
+  .org-info-js_search-highlight
+    { background-color: #ffff00; color: #000000; font-weight: bold; }
+  .org-svg { width: 90%; }
+  /*]]>*/-->
+</style>
+<script src="https://ajax.googleapis.com/ajax/libs/jquery/2.1.3/jquery.min.js"></script>
+<script src="https://maxcdn.bootstrapcdn.com/bootstrap/3.3.4/js/bootstrap.min.js"></script>
+<script type="text/javascript" src="http://www.pirilampo.org/styles/lib/js/jquery.stickytableheaders.js"></script>
+<script type="text/javascript" src="http://www.pirilampo.org/styles/readtheorg/js/readtheorg.js"></script>
+<script type="text/javascript">
+/*
+@licstart  The following is the entire license notice for the
+JavaScript code in this tag.
+
+Copyright (C) 2012-2019 Free Software Foundation, Inc.
+
+The JavaScript code in this tag is free software: you can
+redistribute it and/or modify it under the terms of the GNU
+General Public License (GNU GPL) as published by the Free Software
+Foundation, either version 3 of the License, or (at your option)
+any later version.  The code is distributed WITHOUT ANY WARRANTY;
+without even the implied warranty of MERCHANTABILITY or FITNESS
+FOR A PARTICULAR PURPOSE.  See the GNU GPL for more details.
+
+As additional permission under GNU GPL version 3 section 7, you
+may distribute non-source (e.g., minimized or compacted) forms of
+that code without the copy of the GNU GPL normally required by
+section 4, provided you include this license notice and a URL
+through which recipients can access the Corresponding Source.
+
+
+@licend  The above is the entire license notice
+for the JavaScript code in this tag.
+*/
+<!--/*--><![CDATA[/*><!--*/
+ function CodeHighlightOn(elem, id)
+ {
+   var target = document.getElementById(id);
+   if(null != target) {
+     elem.cacheClassElem = elem.className;
+     elem.cacheClassTarget = target.className;
+     target.className = "code-highlighted";
+     elem.className   = "code-highlighted";
+   }
+ }
+ function CodeHighlightOff(elem, id)
+ {
+   var target = document.getElementById(id);
+   if(elem.cacheClassElem)
+     elem.className = elem.cacheClassElem;
+   if(elem.cacheClassTarget)
+     target.className = elem.cacheClassTarget;
+ }
+/*]]>*///-->
+</script>
+<script type="text/x-mathjax-config">
+    MathJax.Hub.Config({
+        displayAlign: "center",
+        displayIndent: "0em",
+
+        "HTML-CSS": { scale: 100,
+                        linebreaks: { automatic: "false" },
+                        webFont: "TeX"
+                       },
+        SVG: {scale: 100,
+              linebreaks: { automatic: "false" },
+              font: "TeX"},
+        NativeMML: {scale: 100},
+        TeX: { equationNumbers: {autoNumber: "AMS"},
+               MultLineWidth: "85%",
+               TagSide: "right",
+               TagIndent: ".8em"
+             }
+});
+</script>
+<script type="text/javascript"
+        src="https://cdnjs.cloudflare.com/ajax/libs/mathjax/2.7.0/MathJax.js?config=TeX-AMS_HTML"></script>
+</head>
+<body>
+<div id="content">
+<h1 class="title">À propos du calcul de &pi;</h1>
+<div id="table-of-contents">
+<h2>Table des matières</h2>
+<div id="text-table-of-contents">
+<ul>
+<li><a href="#org3de6e6c">1. En demandant à la lib maths</a></li>
+<li><a href="#org833fcbb">2. En utilisant la méthode des aiguilles de Buffon</a></li>
+<li><a href="#org9658f1f">3. Avec un argument "fréquentiel" de surface</a></li>
+</ul>
+</div>
+</div>
+
+<div id="outline-container-org3de6e6c" class="outline-2">
+<h2 id="org3de6e6c"><span class="section-number-2">1</span> En demandant à la lib maths</h2>
+<div class="outline-text-2" id="text-1">
+<p>
+Mon ordinateur m'indique que &pi; vaut <i>approximativement</i> :
+</p>
+
+<div class="org-src-container">
+<pre class="src src-python"><span style="color: #0000FF;">from</span> math <span style="color: #0000FF;">import</span> *
+pi
+</pre>
+</div>
+
+<pre class="example">
+3.141592653589793
+</pre>
+</div>
+</div>
+
+<div id="outline-container-org833fcbb" class="outline-2">
+<h2 id="org833fcbb"><span class="section-number-2">2</span> En utilisant la méthode des aiguilles de Buffon</h2>
+<div class="outline-text-2" id="text-2">
+<p>
+Mais calculé avec la <b>méthode</b> des <a href="https://fr.wikipedia.org/wiki/Aiguille_de_Buffon">aiguilles de Buffon</a>, on obtiendrait comme
+<b>approximation</b> :
+</p>
+
+<div class="org-src-container">
+<pre class="src src-python"><span style="color: #0000FF;">import</span> numpy <span style="color: #0000FF;">as</span> np
+np.random.seed(seed=42)
+<span style="color: #BA36A5;">N</span> = 10000
+<span style="color: #BA36A5;">x</span> = np.random.uniform(size=N, low=0, high=1)
+<span style="color: #BA36A5;">theta</span> = np.random.uniform(size=N, low=0, high=pi/2)
+2/(<span style="color: #006FE0;">sum</span>((x+np.sin(theta))&gt;1)/N)
+</pre>
+</div>
+
+<pre class="example">
+3.128911138923655
+</pre>
+</div>
+</div>
+
+<div id="outline-container-org9658f1f" class="outline-2">
+<h2 id="org9658f1f"><span class="section-number-2">3</span> Avec un argument "fréquentiel" de surface</h2>
+<div class="outline-text-2" id="text-3">
+<p>
+Sinon, une méthode plus simple à comprendre et ne faisant pas intervenir d'appel
+à la fonction sinus se base sur le fait que si \(X \sim U(0,1)\) et \(Y \sim U(0,1)\)
+alors \(P[X^2+Y^2 \leq1] = \pi/4\) (voir
+<a href="https://fr.wikipedia.org/wiki/M%C3%A9thode_de_Monte-Carlo#D%C3%A9termination_de_la_valeur_de_%CF%80">méthode
+yde Monte Carlo</a> sur Wikipedia). Le code suivant illustre ce fait :
+</p>
+
+<div class="org-src-container">
+<pre class="src src-python"><span style="color: #0000FF;">import</span> matplotlib.pyplot <span style="color: #0000FF;">as</span> plt
+
+np.random.seed(seed=42)
+<span style="color: #BA36A5;">N</span> = 1000
+<span style="color: #BA36A5;">x</span> = np.random.uniform(size=N, low=0, high=1)
+<span style="color: #BA36A5;">y</span> = np.random.uniform(size=N, low=0, high=1)
+
+<span style="color: #BA36A5;">accept</span> = (x*x+y*y) &lt;= 1
+<span style="color: #BA36A5;">reject</span> = np.logical_not(accept)
+
+<span style="color: #BA36A5;">fig</span>, <span style="color: #BA36A5;">ax</span> = plt.subplots(1)
+ax.scatter(x[accept], y[accept], c=<span style="color: #008000;">'b'</span>, alpha=0.2, edgecolor=<span style="color: #D0372D;">None</span>)
+ax.scatter(x[reject], y[reject], c=<span style="color: #008000;">'r'</span>, alpha=0.2, edgecolor=<span style="color: #D0372D;">None</span>)
+ax.set_aspect(<span style="color: #008000;">'equal'</span>)
+
+plt.savefig(matplot_lib_filename)
+matplot_lib_filename
+</pre>
+</div>
+
+<p>
+<img src="fige.png" alt="fige.png" />
+Il est alors aisé d'obtenir une approximation (pas terrible) de &pi; en comptant
+combien de fois, en moyenne, \(X^2+Y^2\) est inférieur à 1 : 
+</p>
+<div class="org-src-container">
+<pre class="src src-python">4*np.mean(accept)
+</pre>
+</div>
+
+<pre class="example">
+3.112
+</pre>
+</div>
+</div>
+</div>
+<div id="postamble" class="status">
+<p class="date">Date: 01/04/2020</p>
+<p class="author">Auteur: Clément</p>
+<p class="date">Created: 2020-04-01 Wed 10:17</p>
+<p class="validation"><a href="http://validator.w3.org/check?uri=referer">Validate</a></p>
+</div>
+</body>
+</html>
diff --git a/module2/exo1/toy_document_orgmode_python_fr.org b/module2/exo1/toy_document_orgmode_python_fr.org
index c7157ba42216cf2e1d291112bb351ce48811115c..cf15efe79c75a2a219e67dea8bd6db2632ffe616 100644
--- a/module2/exo1/toy_document_orgmode_python_fr.org
+++ b/module2/exo1/toy_document_orgmode_python_fr.org
@@ -1,17 +1,82 @@
-#+TITLE:  Votre titre
-#+AUTHOR: Votre nom
-#+DATE:   La date du jour
+#+TITLE: À propos du calcul de \pi
+#+AUTHOR: Clément
+#+DATE:   01/04/2020
 #+LANGUAGE: fr
 # #+PROPERTY: header-args :eval never-export
 
-#+HTML_HEAD: <link rel="stylesheet" type="text/css" href="http://www.pirilampo.org/styles/readtheorg/css/htmlize.css"/>
-#+HTML_HEAD: <link rel="stylesheet" type="text/css" href="http://www.pirilampo.org/styles/readtheorg/css/readtheorg.css"/>
+# #+HTML_HEAD: <link rel="stylesheet" type="text/css" href="http://www.pirilampo.org/styles/readtheorg/css/htmlize.css"/>
+# #+HTML_HEAD: <link rel="stylesheet" type="text/css" href="http://www.pirilampo.org/styles/readtheorg/css/readtheorg.css"/>
 #+HTML_HEAD: <script src="https://ajax.googleapis.com/ajax/libs/jquery/2.1.3/jquery.min.js"></script>
 #+HTML_HEAD: <script src="https://maxcdn.bootstrapcdn.com/bootstrap/3.3.4/js/bootstrap.min.js"></script>
 #+HTML_HEAD: <script type="text/javascript" src="http://www.pirilampo.org/styles/lib/js/jquery.stickytableheaders.js"></script>
 #+HTML_HEAD: <script type="text/javascript" src="http://www.pirilampo.org/styles/readtheorg/js/readtheorg.js"></script>
 
-* Quelques explications
+* En demandant à la lib maths
+Mon ordinateur m'indique que \pi vaut /approximativement/ :
+
+#+begin_src python :session :exports both
+from math import *
+pi
+#+end_src
+
+#+RESULTS:
+: 3.141592653589793
+
+* En utilisant la méthode des aiguilles de Buffon
+Mais calculé avec la *méthode* des [[https://fr.wikipedia.org/wiki/Aiguille_de_Buffon][aiguilles de Buffon]], on obtiendrait comme
+*approximation* :
+
+#+begin_src python :session :exports both
+import numpy as np
+np.random.seed(seed=42)
+N = 10000
+x = np.random.uniform(size=N, low=0, high=1)
+theta = np.random.uniform(size=N, low=0, high=pi/2)
+2/(sum((x+np.sin(theta))>1)/N)
+#+end_src
+
+#+RESULTS:
+: 3.128911138923655
+
+* Avec un argument "fréquentiel" de surface
+Sinon, une méthode plus simple à comprendre et ne faisant pas intervenir d'appel
+à la fonction sinus se base sur le fait que si \(X \sim U(0,1)\) et \(Y \sim U(0,1)\)
+alors \(P[X^2+Y^2 \leq1] = \pi/4\) (voir
+[[https://fr.wikipedia.org/wiki/M%C3%A9thode_de_Monte-Carlo#D%C3%A9termination_de_la_valeur_de_%CF%80][méthode
+yde Monte Carlo]] sur Wikipedia). Le code suivant illustre ce fait :
+
+#+begin_src python :exports both :session :var matplot_lib_filename="fige.png" :results file
+import matplotlib.pyplot as plt
+
+np.random.seed(seed=42)
+N = 1000
+x = np.random.uniform(size=N, low=0, high=1)
+y = np.random.uniform(size=N, low=0, high=1)
+
+accept = (x*x+y*y) <= 1
+reject = np.logical_not(accept)
+
+fig, ax = plt.subplots(1)
+ax.scatter(x[accept], y[accept], c='b', alpha=0.2, edgecolor=None)
+ax.scatter(x[reject], y[reject], c='r', alpha=0.2, edgecolor=None)
+ax.set_aspect('equal')
+
+plt.savefig(matplot_lib_filename)
+matplot_lib_filename
+#+end_src
+
+#+RESULTS:
+[[file:fige.png]]
+Il est alors aisé d'obtenir une approximation (pas terrible) de \pi en comptant
+combien de fois, en moyenne, \(X^2+Y^2\) est inférieur à 1 : 
+#+begin_src python :results output :session :exports both
+4*np.mean(accept)
+#+end_src
+
+#+RESULTS:
+: 3.112
+
+* Quelques explications                                            :noexport:
 
 Ceci est un document org-mode avec quelques exemples de code
 python. Une fois ouvert dans emacs, ce document peut aisément être