X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/rairo15.git/blobdiff_plain/0460168a2dfc97f19e903ca82aa02d8884e0c980..9fc003099dc86caaa2ccf0645be2764c81418534:/main.tex?ds=sidebyside diff --git a/main.tex b/main.tex index 233d448..3072c78 100644 --- a/main.tex +++ b/main.tex @@ -1,17 +1,37 @@ \documentclass{ita} \usepackage{graphicx} +\usepackage{caption} +\usepackage{subcaption} + \usepackage{dsfont} \usepackage{stmaryrd} -\usepackage[font=footnotesize]{subfig} +%\usepackage[font=footnotesize]{subfig} \usepackage{ifthen} \usepackage{color} \usepackage{algorithm2e} +\usepackage{epstopdf} +%\usepackage{ntheorem} + +\usepackage[utf8]{inputenc} +\usepackage[T1]{fontenc} +\usepackage[english]{babel} +\usepackage{amsmath,amssymb,latexsym,eufrak,euscript} +\usepackage{pstricks,pst-node,pst-coil} + + +\usepackage{url,tikz} +\usepackage{pgflibrarysnakes} +\usepackage{multicol} +\usetikzlibrary{arrows} +\usetikzlibrary{automata} +\usetikzlibrary{snakes} +\usetikzlibrary{shapes} %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% -% Définitions personnelles +% Définitions personnelles %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \definecolor{bleuclair}{rgb}{0.75,0.75,1.0} @@ -28,22 +48,23 @@ } } -% \theoremstyle{plain} -% \theoremheaderfont{\normalfont\bfseries\sc} -% \theorembodyfont{\slshape} -% \theoremsymbol{\ensuremath{\diamondsuit}} -% \theoremprework{\bigskip} -% \theoremseparator{.} -\newtheorem{Def}{\underline{Définition}} -\newtheorem{Lemma}{\underline{Lemme}} -\newtheorem{Theo}{\underline{Théorème}} -% \theoremheaderfont{\sc} -% \theorembodyfont{\upshape} -% \theoremstyle{nonumberplain} -% \theoremseparator{} -% \theoremsymbol{\rule{1ex}{1ex}} -\newtheorem{Proof}{Preuve :} -\newtheorem{xpl}{Exemple illustratif :} + + +\newcommand {\tv}[1] {\lVert #1 \rVert_{\rm TV}} +\def \top {1.8} +\def \topt {2.3} +\def \P {\mathbb{P}} +\def \ov {\overline} +\def \ts {\tau_{\rm stop}} + + +\newtheorem{Def}{Definition} +%\newtheorem{Lemma}{\underline{Lemma}} +\newtheorem{Theo}{Theorem} +\newtheorem{Corollary}{Corollary} +\newtheorem{Lemma}{Lemma} +\newtheorem{proposition}{Proposition} +\newtheorem*{xpl}{Running Example} \newcommand{\vectornorm}[1]{\ensuremath{\left|\left|#1\right|\right|_2}} %\newcommand{\ie}{\textit{i.e.}} @@ -55,7 +76,7 @@ \newcommand{\Gall}[0]{\ensuremath{\mathcal{G}}} -\newcommand{\JFC}[1]{\begin{color}{green}\textit{}\end{color}} +\newcommand{\JFC}[1]{\begin{color}{green}\textit{#1}\end{color}} \newcommand{\CG}[1]{\begin{color}{blue}\textit{}\end{color}} \newcommand{\og}[0]{``} \newcommand{\fg}[1]{''} @@ -65,62 +86,66 @@ -\title{XXX} +\title{Random Walk in a N-cube Without Hamiltonian Cycle + to Chaotic Pseudorandom Number Generation: Theoretical and Practical + Considerations} \begin{document} -\author{Jean-François Couchot, Christophe Guyeux, Pierre-Cyrile Heam} -\address{Institut FEMTO-ST, Université de Franche-Comté, Belfort, France} +\author{Jean-François Couchot, Christophe Guyeux, Pierre-Cyrile Heam} +\address{Institut FEMTO-ST, Université de Franche-Comté, Belfort, France} -\author{Sylvain Contassot-Vivier} -\address{Loria - UMR 7503, Université de Lorraine, Nancy, France} -\date{...} \begin{abstract} -This paper extends the results presented in~\cite{bcgr11ip} -and~\cite{chgw14oip} by using the \emph{chaotic} updating mode, in the sense -of F. Robert~\cite{Robert}. In this mode, several components of the system -may be updated at each iteration. At the theoretical level, we show that - the properties of chaos and uniformity of the obtained PRNG are preserved. - At the practical level, we show that the algorithm that builds strongly - connected iteration graphs, with doubly stochastic Markov matrix, has a - reduced mixing time. +This paper is dedicated to the design of chaotic random generators +and extends previous works proposed by some of the authors. +We propose a theoretical framework proving both the chaotic properties and +that the limit distribution is uniform. +A theoretical bound on the stationary time is given and +practical experiments show that the generators successfully passe +the classical statsitcal tests. \end{abstract} +\maketitle + \section{Introduction} -%\input{intro} +\input{intro} \section{\uppercase{Preliminaries}}\label{sec:preliminaries} \input{preliminaries} -\section{Stopping Time} -% Donner la borne du stopping time quand on marche dedans (nouveau). -% Énoncer le problème de la taille de cette borne (elle est certes finie, mais grande). +\section{Proof Of Chaos}\label{sec:proofOfChaos} +\input{chaos} +\section{Functions with Strongly Connected $\Gamma_{\{b\}}(f)$}\label{sec:SCCfunc} +\input{generating} -\section{Jumping in a specific $n$-cube} -% Proposer alors les sauts dans ce n-cube (nouveau) -% Il y a des preuves que j'ai faites dans TSI sur la préservation des propriétés de chaos lorsqu'on saute, qu'on peut traduire et qui n'ont pas été publiées en anglais, je crois (nouveau). +\section{Random walk on the modified Hypercube}\label{sec:hypercube} +\input{stopping} -\section{Stopping Time (continued)} % Donner la borne du stopping time quand on marche dedans (nouveau). -% Énoncer le problème de la taille de cette borne (elle est certes finie, mais grande). +% Énoncer le problème de la taille de cette borne +% (elle est certes finie, mais grande). + + -\section{Quality study of the strategy} -%6) Se pose alors la question de comment générer une stratégie de "bonne qualité". Par exemple, combien de générateurs aléatoires embarquer ? (nouveau) +%\section{Quality study of the strategy} +%6) Se pose alors la question de comment générer une stratégie de "bonne qualité". Par exemple, combien de générateurs aléatoires embarquer ? (nouveau) + + +\section{Experiments}\label{sec:prng} +\input{prng} -\section{Expérimentations} -% \section{Conclusion} -%\input{conclusion} +\input{conclusion} %\acknowledgements{...} - +\bibliographystyle{alpha} \bibliography{biblio} \end{document}