4 Let thus be given such kind of map.
5 This article focuses on studying its iterations according to
6 the equation~(\ref{eq:asyn}) with a given strategy.
7 First of all, this can be interpreted as walking into its iteration graph
8 where the choice of the edge to follow is decided by the strategy.
9 Notice that the iteration graph is always a subgraph of
10 ${\mathsf{N}}$-cube augmented with all the self-loop, \textit{i.e.}, all the
11 edges $(v,v)$ for any $v \in \Bool^{\mathsf{N}}$.
12 Next, if we add probabilities on the transition graph, iterations can be
13 interpreted as Markov chains.
16 Let us consider for instance
17 the graph $\Gamma(f)$ defined
18 in \textsc{Figure~\ref{fig:iteration:f*}.} and
19 the probability function $p$ defined on the set of edges as follows:
23 = \frac{2}{3} \textrm{ if $e=(v,v)$ with $v \in \Bool^3$,}\\
24 = \frac{1}{6} \textrm{ otherwise.}
28 The matrix $P$ of the Markov chain associated to the function $f^*$ and to its probability function $p$ is
31 \begin{array}{llllllll}
46 % % Let us first recall the \emph{Total Variation} distance $\tv{\pi-\mu}$,
47 % % which is defined for two distributions $\pi$ and $\mu$ on the same set
49 % % $$\tv{\pi-\mu}=\max_{A\subset \Bool^n} |\pi(A)-\mu(A)|.$$
51 % % $$\tv{\pi-\mu}=\frac{1}{2}\sum_{x\in\Bool^n}|\pi(x)-\mu(x)|.$$
53 % % Let then $M(x,\cdot)$ be the
54 % % distribution induced by the $x$-th row of $M$. If the Markov chain
56 % % $M$ has a stationary distribution $\pi$, then we define
57 % % $$d(t)=\max_{x\in\Bool^n}\tv{M^t(x,\cdot)-\pi}.$$
58 % Intuitively $d(t)$ is the largest deviation between
59 % the distribution $\pi$ and $M^t(x,\cdot)$, which
60 % is the result of iterating $t$ times the function.
61 % Finally, let $\varepsilon$ be a positive number, the \emph{mixing time}
62 % with respect to $\varepsilon$ is given by
63 % $$t_{\rm mix}(\varepsilon)=\min\{t \mid d(t)\leq \varepsilon\}.$$
64 % It defines the smallest iteration number
65 % that is sufficient to obtain a deviation lesser than $\varepsilon$.
66 % Notice that the upper and lower bounds of mixing times cannot
67 % directly be computed with eigenvalues formulae as expressed
68 % in~\cite[Chap. 12]{LevinPeresWilmer2006}. The authors of this latter work
69 % only consider reversible Markov matrices whereas we do no restrict our
70 % matrices to such a form.
78 This section considers functions $f: \Bool^{\mathsf{N}} \rightarrow \Bool^{\mathsf{N}} $
79 issued from an hypercube where an Hamiltonian path has been removed.
80 A specific random walk in this modified hypercube is first
81 introduced. We further detail
82 a theoretical study on the length of the path
83 which is sufficient to follow to get a uniform distribution.
89 First of all, let $\pi$, $\mu$ be two distributions on $\Bool^{\mathsf{N}}$. The total
90 variation distance between $\pi$ and $\mu$ is denoted $\tv{\pi-\mu}$ and is
92 $$\tv{\pi-\mu}=\max_{A\subset \Bool^{\mathsf{N}}} |\pi(A)-\mu(A)|.$$ It is known that
93 $$\tv{\pi-\mu}=\frac{1}{2}\sum_{X\in\Bool^{\mathsf{N}}}|\pi(X)-\mu(X)|.$$ Moreover, if
94 $\nu$ is a distribution on $\Bool^{\mathsf{N}}$, one has
95 $$\tv{\pi-\mu}\leq \tv{\pi-\nu}+\tv{\nu-\mu}$$
97 Let $P$ be the matrix of a Markov chain on $\Bool^{\mathsf{N}}$. $P(X,\cdot)$ is the
98 distribution induced by the $X$-th row of $P$. If the Markov chain induced by
99 $P$ has a stationary distribution $\pi$, then we define
100 $$d(t)=\max_{X\in\Bool^{\mathsf{N}}}\tv{P^t(X,\cdot)-\pi}.$$
104 $$t_{\rm mix}(\varepsilon)=\min\{t \mid d(t)\leq \varepsilon\}.$$
107 $$t_{\rm mix}(\varepsilon)\leq \lceil\log_2(\varepsilon^{-1})\rceil t_{\rm mix}(\frac{1}{4})$$
112 % It is known that $d(t+1)\leq d(t)$. \JFC{references ? Cela a-t-il
113 % un intérêt dans la preuve ensuite.}
118 % $$t_{\rm mix}(\varepsilon)=\min\{t \mid d(t)\leq \varepsilon\}.$$
119 % One can prove that \JFc{Ou cela a-t-il été fait?}
120 % $$t_{\rm mix}(\varepsilon)\leq \lceil\log_2(\varepsilon^{-1})\rceil t_{\rm mix}(\frac{1}{4})$$
124 Let $(X_t)_{t\in \mathbb{N}}$ be a sequence of $\Bool^{\mathsf{N}}$ valued random
125 variables. A $\mathbb{N}$-valued random variable $\tau$ is a {\it stopping
126 time} for the sequence $(X_i)$ if for each $t$ there exists $B_t\subseteq
127 (\Bool^{\mathsf{N}})^{t+1}$ such that $\{\tau=t\}=\{(X_0,X_1,\ldots,X_t)\in B_t\}$.
128 In other words, the event $\{\tau = t \}$ only depends on the values of
129 $(X_0,X_1,\ldots,X_t)$, not on $X_k$ with $k > t$.
132 Let $(X_t)_{t\in \mathbb{N}}$ be a Markov chain and $f(X_{t-1},Z_t)$ a
133 random mapping representation of the Markov chain. A {\it randomized
134 stopping time} for the Markov chain is a stopping time for
135 $(Z_t)_{t\in\mathbb{N}}$. If the Markov chain is irreducible and has $\pi$
136 as stationary distribution, then a {\it stationary time} $\tau$ is a
137 randomized stopping time (possibly depending on the starting position $X$),
138 such that the distribution of $X_\tau$ is $\pi$:
139 $$\P_X(X_\tau=Y)=\pi(Y).$$
143 If $\tau$ is a strong stationary time, then $d(t)\leq \max_{X\in\Bool^{\mathsf{N}}}
148 %Let $\Bool^n$ be the set of words of length $n$.
150 X\in \Bool^{\mathsf{N}}, Y\in \Bool^{\mathsf{N}},\ X=Y \text{ or } X\oplus Y \in 0^*10^*\}$.
151 In other words, $E$ is the set of all the edges in the classical
153 Let $h$ be a function from $\Bool^{\mathsf{N}}$ into $\llbracket 1, {\mathsf{N}} \rrbracket$.
154 Intuitively speaking $h$ aims at memorizing for each node
155 $X \in \Bool^{\mathsf{N}}$ which edge is removed in the Hamiltonian cycle,
156 \textit{i.e.} which bit in $\llbracket 1, {\mathsf{N}} \rrbracket$
161 We denote by $E_h$ the set $E\setminus\{(X,Y)\mid X\oplus Y =
162 0^{{\mathsf{N}}-h(X)}10^{h(X)-1}\}$. This is the set of the modified hypercube,
163 \textit{i.e.}, the ${\mathsf{N}}$-cube where the Hamiltonian cycle $h$
166 We define the Markov matrix $P_h$ for each line $X$ and
167 each column $Y$ as follows:
171 P_h(X,X)=\frac{1}{2}+\frac{1}{2{\mathsf{N}}} & \\
172 P_h(X,Y)=0 & \textrm{if $(X,Y)\notin E_h$}\\
173 P_h(X,Y)=\frac{1}{2{\mathsf{N}}} & \textrm{if $X\neq Y$ and $(X,Y) \in E_h$}
176 \label{eq:Markov:rairo}
179 We denote by $\ov{h} : \Bool^{\mathsf{N}} \rightarrow \Bool^{\mathsf{N}}$ the function
180 such that for any $X \in \Bool^{\mathsf{N}} $,
181 $(X,\ov{h}(X)) \in E$ and $X\oplus\ov{h}(X)=0^{{\mathsf{N}}-h(X)}10^{h(X)-1}$.
182 The function $\ov{h}$ is said {\it square-free} if for every $X\in \Bool^{\mathsf{N}}$,
183 $\ov{h}(\ov{h}(X))\neq X$.
185 \begin{lmm}\label{lm:h}
186 If $\ov{h}$ is bijective and square-free, then $h(\ov{h}^{-1}(X))\neq h(X)$.
190 Let $\ov{h}$ be bijective.
191 Let $k\in \llbracket 1, {\mathsf{N}} \rrbracket$ s.t. $h(\ov{h}^{-1}(X))=k$.
192 Then $(\ov{h}^{-1}(X),X)$ belongs to $E$ and
193 $\ov{h}^{-1}(X)\oplus X = 0^{{\mathsf{N}}-k}10^{k-1}$.
194 Let us suppose $h(X) = h(\ov{h}^{-1}(X))$. In such a case, $h(X) =k$.
195 By definition of $\ov{h}$, $(X, \ov{h}(X)) \in E $ and
196 $X\oplus\ov{h}(X)=0^{{\mathsf{N}}-h(X)}10^{h(X)-1} = 0^{{\mathsf{N}}-k}10^{k-1}$.
197 Thus $\ov{h}(X)= \ov{h}^{-1}(X)$, which leads to $\ov{h}(\ov{h}(X))= X$.
198 This contradicts the square-freeness of $\ov{h}$.
201 Let $Z$ be a random variable that is uniformly distributed over
202 $\llbracket 1, {\mathsf{N}} \rrbracket \times \Bool$.
203 For $X\in \Bool^{\mathsf{N}}$, we
204 define, with $Z=(i,b)$,
208 f(X,Z)=X\oplus (0^{{\mathsf{N}}-i}10^{i-1}) & \text{if } b=1 \text{ and } i\neq h(X),\\
209 f(X,Z)=X& \text{otherwise.}
213 The Markov chain is thus defined as
220 %%%%%%%%%%%%%%%%%%%%%%%%%%%ù
221 %\section{Stopping time}
223 An integer $\ell\in \llbracket 1,{\mathsf{N}} \rrbracket$ is said {\it fair}
225 exists $0\leq j <t$ such that $Z_{j+1}=(\ell,\cdot)$ and $h(X_j)\neq \ell$.
226 In other words, there exist a date $j$ before $t$ where
227 the first element of the random variable $Z$ is exactly $l$
228 (\textit{i.e.}, $l$ is the strategy at date $j$)
229 and where the configuration $X_j$ allows to traverse the edge $l$.
231 Let $\ts$ be the first time all the elements of $\llbracket 1, {\mathsf{N}} \rrbracket$
232 are fair. The integer $\ts$ is a randomized stopping time for
233 the Markov chain $(X_t)$.
237 The integer $\ts$ is a strong stationary time.
241 Let $\tau_\ell$ be the first time that $\ell$ is fair. The random variable
242 $Z_{\tau_\ell}$ is of the form $(\ell,b)$ %with $\delta\in\{0,1\}$ and
244 $b=1$ with probability $\frac{1}{2}$ and $b=0$ with probability
245 $\frac{1}{2}$. Since $h(X_{\tau_\ell-1})\neq\ell$ the value of the $\ell$-th
246 bit of $X_{\tau_\ell}$
247 is $0$ or $1$ with the same probability ($\frac{1}{2}$).
249 Moving next in the chain, at each step,
250 the $l$-th bit is switched from $0$ to $1$ or from $1$ to $0$ each time with
251 the same probability. Therefore, for $t\geq \tau_\ell$, the
252 $\ell$-th bit of $X_t$ is $0$ or $1$ with the same probability, proving the
255 \begin{thrm} \label{prop:stop}
256 If $\ov{h}$ is bijective and square-free, then
257 $E[\ts]\leq 8{\mathsf{N}}^2+ {\mathsf{N}}\ln ({\mathsf{N}}+1)$.
260 For each $X\in \Bool^{\mathsf{N}}$ and $\ell\in\llbracket 1,{\mathsf{N}}\rrbracket$,
261 let $S_{X,\ell}$ be the
262 random variable that counts the number of steps
263 from $X$ until we reach a configuration where
264 $\ell$ is fair. More formally
265 $$S_{X,\ell}=\min \{t \geq 1\mid h(X_{t-1})\neq \ell\text{ and }Z_t=(\ell,.)\text{ and } X_0=X\}.$$
268 $$\lambda_h=\max_{X,\ell} S_{X,\ell}.$$
271 \begin{lmm}\label{prop:lambda}
272 If $\ov{h}$ is a square-free bijective function, then the inequality
273 $E[\lambda_h]\leq 8{\mathsf{N}}^2$ is established.
278 For every $X$, every $\ell$, one has $\P(S_{X,\ell})\leq 2)\geq
279 \frac{1}{4{\mathsf{N}}^2}$.
283 \item if $h(X)\neq \ell$, then
284 $\P(S_{X,\ell}=1)=\frac{1}{2{\mathsf{N}}}\geq \frac{1}{4{\mathsf{N}}^2}$.
285 \item otherwise, $h(X)=\ell$, then
286 $\P(S_{X,\ell}=1)=0$.
287 But in this case, intutively, it is possible to move
288 from $X$ to $\ov{h}^{-1}(X)$ (with probability $\frac{1}{2N}$). And in
289 $\ov{h}^{-1}(X)$ the $l$-th bit can be switched.
291 since $\ov{h}$ is square-free,
292 $\ov{h}(X)=\ov{h}(\ov{h}(\ov{h}^{-1}(X)))\neq \ov{h}^{-1}(X)$. It follows
293 that $(X,\ov{h}^{-1}(X))\in E_h$. We thus have
294 $P(X_1=\ov{h}^{-1}(X))=\frac{1}{2{\mathsf{N}}}$. Now, by Lemma~\ref{lm:h},
295 $h(\ov{h}^{-1}(X))\neq h(X)$. Therefore $\P(S_{x,\ell}=2\mid
296 X_1=\ov{h}^{-1}(X))=\frac{1}{2{\mathsf{N}}}$, proving that $\P(S_{x,\ell}\leq 2)\geq
297 \frac{1}{4{\mathsf{N}}^2}$.
303 Therefore, $\P(S_{X,\ell}\geq 3)\leq 1-\frac{1}{4{\mathsf{N}}^2}$. By induction, one
304 has, for every $i$, $\P(S_{X,\ell}\geq 2i)\leq
305 \left(1-\frac{1}{4{\mathsf{N}}^2}\right)^i$.
307 since $S_{X,\ell}$ is positive, it is known~\cite[lemma 2.9]{proba}, that
308 $$E[S_{X,\ell}]=\sum_{i=1}^{+\infty}\P(S_{X,\ell}\geq i).$$
309 Since $\P(S_{X,\ell}\geq i)\geq \P(S_{X,\ell}\geq i+1)$, one has
310 $$E[S_{X,\ell}]=\sum_{i=1}^{+\infty}\P(S_{X,\ell}\geq i)\leq
311 \P(S_{X,\ell}\geq 1)+\P(S_{X,\ell}\geq 2)+2 \sum_{i=1}^{+\infty}\P(S_{X,\ell}\geq 2i).$$
313 $$E[S_{X,\ell}]\leq 1+1+2
314 \sum_{i=1}^{+\infty}\left(1-\frac{1}{4{\mathsf{N}}^2}\right)^i=2+2(4{\mathsf{N}}^2-1)=8{\mathsf{N}}^2,$$
315 which concludes the proof.
318 Let $\ts^\prime$ be the first time that there are exactly ${\mathsf{N}}-1$ fair
321 \begin{lmm}\label{lm:stopprime}
322 One has $E[\ts^\prime]\leq {\mathsf{N}} \ln ({\mathsf{N}}+1).$
326 This is a classical Coupon Collector's like problem. Let $W_i$ be the
327 random variable counting the number of moves done in the Markov chain while
328 we had exactly $i-1$ fair bits. One has $\ts^\prime=\sum_{i=1}^{{\mathsf{N}}-1}W_i$.
329 But when we are at position $X$ with $i-1$ fair bits, the probability of
330 obtaining a new fair bit is either $1-\frac{i-1}{{\mathsf{N}}}$ if $h(X)$ is fair,
331 or $1-\frac{i-2}{{\mathsf{N}}}$ if $h(X)$ is not fair. It follows that
332 $E[W_i]\leq \frac{{\mathsf{N}}}{{\mathsf{N}}-i+2}$. Therefore
333 $$E[\ts^\prime]=\sum_{i=1}^{{\mathsf{N}}-1}E[W_i]\leq {\mathsf{N}}\sum_{i=1}^{{\mathsf{N}}-1}
334 \frac{1}{{\mathsf{N}}-i+2}={\mathsf{N}}\sum_{i=3}^{{\mathsf{N}}+1}\frac{1}{i}.$$
336 But $\sum_{i=1}^{{\mathsf{N}}+1}\frac{1}{i}\leq 1+\ln({\mathsf{N}}+1)$. It follows that
337 $1+\frac{1}{2}+\sum_{i=3}^{{\mathsf{N}}+1}\frac{1}{i}\leq 1+\ln({\mathsf{N}}+1).$
339 $E[\ts^\prime]\leq {\mathsf{N}} (-\frac{1}{2}+\ln({\mathsf{N}}+1))\leq {\mathsf{N}}\ln({\mathsf{N}}+1)$.
342 One can now prove Theorem~\ref{prop:stop}.
345 One has $\ts\leq \ts^\prime+\lambda_h$. Therefore,
346 Theorem~\ref{prop:stop} is a direct application of
347 lemma~\ref{prop:lambda} and~\ref{lm:stopprime}.
350 Notice that the calculus of the stationary time upper bound is obtained
351 under the following constraint: for each vertex in the $\mathsf{N}$-cube
352 there are one ongoing arc and one outgoing arc that are removed.
353 The calculus does not consider (balanced) hamiltonian cycles, which
354 are more regular and more binding than this constraint.
355 In this later context, we claim that the upper bound for the stopping time