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<div class="d-none"><math>
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label{sec 11.5}
In this section we consider two closely related descriptive quantities of
interest for ergodic chains: the mean time to return to a state and the mean
time to go from one state to another state.


Let <math>\mat{P}</math> be the transition matrix of an ergodic chain with states
<math>s_1</math>, <math>s_2</math>, \ldots, <math>s_r</math>.  Let <math>\mat {w} = (w_1,w_2,\ldots,w_r)</math> be the
unique
probability vector such that <math>\mat {w} \mat {P} = \mat {w}</math>.  Then, by the Law
of Large
Numbers for Markov chains, in the long run the process will spend a
fraction <math>w_j</math> of the time in state <math>s_j</math>.  Thus, if we start in any state,
the chain will eventually reach state <math>s_j</math>; in fact, it will be in state <math>s_j</math>
infinitely often.
Another way to see this is the following:  Form a new Markov chain by making
<math>s_j</math> an
absorbing state, that is, define <math>p_{jj} = 1</math>.  If we start at any state other
than <math>s_j</math>,
this new process will behave exactly like the original chain up to the first
time that state
<math>s_j</math> is reached.  Since the original chain was an ergodic chain, it was
possible to reach
<math>s_j</math> from any other state.  Thus the new chain is an absorbing chain with a
single absorbing
state <math>s_j</math> that will eventually be reached.  So if we start the original chain
at a state
<math>s_i</math> with <math>i \ne j</math>, we will eventually reach the state <math>s_j</math>.
Let <math>\mat{N}</math> be the fundamental matrix for the new chain.  The entries
of <math>\mat{N}</math>
give the expected number of times in each state before absorption.  In terms of
the original chain, these quantities give the expected number of times in each
of the states before reaching state <math>s_j</math> for the first time.  The <math>i</math>th
component of the vector <math>\mat {N} \mat {c}</math> gives the expected number of steps
before
absorption in the new chain, starting in state <math>s_i</math>.  In terms of the old
chain, this is the expected number of steps required to reach state <math>s_j</math> for
the first time starting at state <math>s_i</math>.
===Mean First Passage Time===
{{defncard|label=|id=|If an ergodic Markov chain is started in state <math>s_i</math>, the expected number of
steps to reach state <math>s_j</math> for the first time is called the ''mean first
passage time'' from <math>s_i</math> to <math>s_j</math>. 
It is denoted by <math>m_{ij}</math>.  By convention <math>m_{ii} = 0</math>.}}
<span id="exam 11.5.1"/>
'''Example'''
Let us return to the maze example (Example \ref{exam
11.3.3}). 
We shall make this ergodic chain into an absorbing chain by making state 5 an
absorbing state.
For example, we might assume that food is placed in the center of the maze and
once the rat finds the food, he stays to enjoy it (see Figure \ref{fig 11.5}).
<div id="PSfig11-5" class="d-flex justify-content-center">
[[File:guide_e6d15_PSfig11-5.ps | 400px | thumb |  ]]
</div>
   
The new transition matrix in canonical form is
<math display="block">
\mat {P}\;= \bordermatrix{&               
\hbox{1}&\hbox{2}&\hbox{3}&\hbox{4}&\hbox{6}&\hbox{7}&\hbox{8}
&\hbox{9}&\omit\hfil&\hbox{5}\cr
\hbox{1}\strut  &  0    &1/2    &  0    &  0    & 1/2    &  0    & 0     
&    0  &\srule    & 0 \cr
\hbox{2}\strut  &1/3    &  0    &1/3    &  0    &  0    &  0    & 0   
&    0  &\srule    &1/3\cr
\hbox{3}\strut  &  0    &1/2    &  0    & 1/2    &  0    &  0    & 0   
&    0  &\srule    & 0 \cr
\hbox{4}\strut  &  0    &  0    &1/3    &  0    &  0    &1/3    & 0   
& 1/3    &\srule    &1/3\cr
\hbox{6}\strut  &1/3    &  0    &  0    &  0    &  0    &  0    & 0   
&  0    &\srule    &1/3\cr
\hbox{7}\strut  &  0    &  0    &  0    &  0    &1/2    &  0    & 1/2 
&  0    &\srule    &0  \cr
\hbox{8}\strut  &  0    &  0    &  0    &  0    &  0    &1/3    & 0   
& 1/3    &\srule    &1/3\cr
\hbox{9}\strut  &  0    &  0    &  0    &1/2    &  0    &  0    & 1/2& 
0        &\srule    & 0 \cr
\middlehrule{8}{1}
\hbox{5}\strut  &  0    &  0    &  0    &  0    & 0      & 0      & 0   
& 0      &\srule 
& 1}\ .
</math>
If we compute the fundamental matrix <math>\mat{N}</math>, we obtain
<math display="block">
\mat {N} = \frac18 \pmatrix{
14 & 9 & 4 & 3 & 9 & 4 & 3 & 2 \cr
6 & 14 & 6 & 4 & 4 & 2 & 2 & 2 \cr
4 & 9 & 14 & 9 & 3 & 2 & 3 & 4 \cr
2 & 4 & 6 & 14 & 2 & 2 & 4 & 6 \cr
6 & 4 & 2 & 2 & 14 & 6 & 4 & 2 \cr
4 & 3 & 2 & 3 & 9 & 14 & 9 & 4 \cr
2 & 2 & 2 & 4 & 4 & 6 & 14 & 6 \cr
2 & 3 & 4 & 9 & 3 & 4 & 9 & 14 \cr}\ .
</math>
The expected time to absorption for different starting states is given by the
vector <math>\mat {N} \mat {c}</math>, where
<math display="block">
\mat {N} \mat {c} = \pmatrix{ 6 \cr 5 \cr 6 \cr 5 \cr 5 \cr 6 \cr 5 \cr 6 \cr}\
.
</math>
We see that, starting from compartment 1, it will take on the average six steps
to reach food.  It is clear from symmetry that we should get the same answer
for starting at state 3, 7, or 9.  It is also clear that it should take one
more step, starting at one of these states, than it would starting at 2, 4, 6,
or 8.  Some of the results obtained from <math>\mat{N}</math> are not so obvious.  For
instance, we note that the expected number of times in the starting state is
14/8 regardless of the state in which we start.
===Mean Recurrence Time===
A quantity that is closely related to the mean first passage time is the
''mean recurrence
time,'' defined as follows.  Assume that we start in state <math>s_i</math>; consider the
length of time
before we return to <math>s_i</math> for the first time.  It is clear that we must return,
since we either
stay at <math>s_i</math> the first step or go to some other state <math>s_j</math>, and from any
other
state <math>s_j</math>, we will eventually reach <math>s_i</math> because the chain is ergodic.
{{defncard|label=|id=|If an ergodic Markov chain is started in state <math>s_i</math>, the expected number of
steps to return to <math>s_i</math> for the first time is the ''mean recurrence time''
for <math>s_i</math>.  It is denoted by <math>r_i</math>.}}
We need to develop some basic properties of the mean first passage time.
Consider the mean first
passage time from <math>s_i</math> to <math>s_j</math>; assume that <math>i \ne j</math>.  This may be computed
as follows: take
the expected number of steps required given the outcome of the first step,
multiply by the
probability that this outcome occurs, and add.  If the first step is to <math>s_j</math>,
the expected
number of steps required is 1; if it is to some other state <math>s_k</math>, the expected
number of steps required is <math>m_{kj}</math> plus 1 for the step already taken.  Thus,
<math display="block">
m_{ij} = p_{ij} + \sum_{k \ne j} p_{ik}(m_{kj} + 1)\ ,
</math>
or, since <math>\sum_k p_{ik} = 1</math>,
<span id{{=}}"eq 11.5.1"/>
<math display="block">
\begin{equation}
m_{ij} = 1 + \sum_{k \ne j}p_{ik} m_{kj}\ .\label{eq 11.5.1}
\end{equation}
</math>
Similarly, starting in <math>s_i</math>, it must take at least one step to return.
Considering all possible first steps gives us
<span id{{=}}"eq 11.5.2"/>
<math display="block">
\begin{eqnarray}
r_i &=& \sum_k p_{ik}(m_{ki} + 1) \\
  &=& 1 + \sum_k p_{ik} m_{ki}\ .\label{eq 11.5.2}
\end{eqnarray}
</math>
===Mean First Passage Matrix and Mean Recurrence Matrix===
Let us now define two matrices <math>\mat{M}</math> and <math>\mat{D}</math>.  The <math>ij</math>th
entry <math>m_{ij}</math>
of <math>\mat{M}</math> is the mean first passage time to go from <math>s_i</math> to <math>s_j</math> if <math>i \ne
j</math>;
the diagonal entries are 0.  The matrix <math>\mat{M}</math> is called the ''mean
first passage
matrix.''
The matrix <math>\mat{D}</math> is the matrix with all
entries 0 except
the diagonal entries <math>d_{ii} = r_i</math>.  The matrix <math>\mat{D}</math> is called the ''mean recurrence
matrix.''
Let <math>\mat {C}</math> be an <math>r \times r</math> matrix with all entries 1.  Using
[[#eq 11.5.1 |Equation]] for
the case <math>i \ne j</math> and [[#eq 11.5.2 |Equation]] for the case <math>i = j</math>, we obtain
the matrix equation
<span id{{=}}"eq 11.5.3"/>
<math display="block">
\begin{equation}
\mat{M} = \mat{P} \mat{M} + \mat{C} - \mat{D}\ , 
\label{eq 11.5.3}
\end{equation}
</math>
or
<span id{{=}}"eq 11.5.4"/>
<math display="block">
\begin{equation}
(\mat{I} - \mat{P}) \mat{M} = \mat{C} - \mat{D}\ .
\label{eq 11.5.4}
\end{equation}
</math>
[[#eq 11.5.4 |Equation]] with <math>m_{ii} = 0</math> implies [[#eq 11.5.1 |Equations]]
[[#eq 11.5.2 |and]].  We are now in a position to prove our first basic
theorem.
{{proofcard|Theorem|theorem-1|For an ergodic Markov chain, the mean recurrence time for state <math>s_i</math> is <math>r_i =
1/w_i</math>, where <math>w_i</math> is the <math>i</math>th component of the fixed probability vector for
the transition matrix.\n|Multiplying both sides of [[#eq 11.5.4 |Equation]] by <math>\mat{w}</math> and using the
fact
that
<math display="block">
\mat {w}(\mat {I} - \mat {P}) = \mat {0}
</math>
gives
<math display="block">
\mat {w} \mat {C} - \mat {w} \mat {D} = \mat {0}\ .
</math>
Here <math>\mat {w} \mat {C}</math> is a row vector with all entries 1 and <math>\mat {w} \mat
{D}</math>
is a row vector with <math>i</math>th entry <math>w_i r_i</math>.  Thus
<math display="block">
(1,1,\ldots,1) = (w_1r_1,w_2r_2,\ldots,w_nr_n)
</math>
and
<math display="block">
r_i = 1/w_i\ ,
</math>
as was to be proved.}}
{{proofcard|Corollary|cor_11.5.17|For an ergodic Markov chain, the components of the fixed probability
vector '''
w''' are strictly positive.\n|We know that the values of <math>r_i</math> are finite and so <math>w_i = 1/r_i</math> cannot be 0.}}
'''Example'''
In [[guide:E5c38a1e8a#exam 11.3.3 |Example]] we found the fixed probability vector for the maze
example to be
<math display="block">
\mat {w} = \pmatrix{ \frac1{12} & \frac18 & \frac1{12} & \frac18 & \frac16 &
\frac18 & \frac1{12} & \frac18 & \frac1{12}}\ .
</math>
Hence, the mean recurrence times are given by the reciprocals of these
probabilities.  That is,
<math display="block">
\mat {r} = \pmatrix{ 12 & 8 & 12 & 8 & 6 & 8 & 12 & 8 & 12 }\ .
</math>
Returning to the Land of Oz, we found that the weather in the Land of Oz could
be represented by a Markov chain with states rain, nice, and snow.  In
Section \ref{sec 11.3} we found that the limiting vector was <math>\mat {w} =
(2/5,1/5,2/5)</math>.  From this we see that the mean number of days between rainy
days
is 5/2, between nice days is 5, and between snowy days is 5/2.
===Fundamental Matrix===
We shall now develop a fundamental matrix for ergodic chains that will play a
role
similar to that of the fundamental matrix <math>\mat {N} = (\mat {I} - \mat
{Q})^{-1}</math>
for absorbing chains.  As was the case with absorbing chains, the fundamental
matrix
can be used to find a number of interesting quantities involving ergodic
chains.
Using this matrix, we will give a method for calculating
the mean first passage times for ergodic chains that is easier to use than the
method
given above.  In addition, we will state (but not prove) the Central Limit
Theorem for
Markov Chains, the statement of which uses the fundamental matrix. 
We begin by considering the case that \mat{P} is the transition matrix of a
regular
Markov chain.  Since there are no absorbing states, we might be tempted to try
<math>\mat {Z} = (\mat {I} - \mat {P})^{-1}</math> for a fundamental matrix.  But <math>\mat
{I} - \mat {P}</math>
does not  have an inverse.  To see this, recall that a matrix <math>\mat{R}</math> has an
inverse if and
only if <math>\mat {R} \mat {x} = \mat {0}</math> implies <math>\mat {x} = \mat {0}</math>.  But
since <math>\mat {P}
\mat {c} = \mat {c}</math> we have <math>(\mat {I} - \mat {P})\mat {c} = \mat {0}</math>, and so
<math>\mat {I} -
\mat {P}</math> does not have an inverse. 
We recall that if we have an absorbing Markov chain, and \mat{Q} is the
restriction of the transition matrix to the set of transient states, then the
fundamental
matrix \mat {N} could be written as
<math display="block">
\mat {N} = \mat {I} + \mat {Q} + \mat {Q}^2 + \cdots\ .
</math>
The reason that this power series converges is that <math>\mat {Q}^n \rightarrow 0</math>,
so this series
acts like a convergent geometric series.
This idea might prompt one to try to find a similar series for regular chains.
Since we
know that <math>\mat {P}^n \rightarrow \mat {W}</math>, we might consider the series
<span id{{=}}"eq
11.5.8"/>
<math display="block">
\begin{equation}
\mat {I} + (\mat {P} -\mat {W}) + (\mat {P}^2 - \mat{W}) + \cdots\ .\label{eq
11.5.8}
\end{equation}
</math>
We now use special properties of \mat {P} and \mat {W} to rewrite this series.
The special
properties are:  1) <math>\mat {P}\mat {W} = \mat {W}</math>, and 2) <math>\mat {W}^k = \mat
{W}</math> for all
positive integers <math>k</math>.  These facts are easy to verify, and are left as an
exercise (see
Exercise [[exercise:2e4acd3b92 |Exercise]]).  Using these facts, we see that
<math display="block">
\begin{eqnarray*}
(\mat {P} - \mat {W})^n &=& \sum_{i = 0}^n (-1)^i{n \choose i}\mat
{P}^{n-i}\mat {W}^i \\
&=& \mat {P}^n + \sum_{i = 1}^n (-1)^i{n \choose i} \mat {W}^i \\
&=& \mat {P}^n + \sum_{i = 1}^n (-1)^i{n \choose i} \mat {W} \\
&=& \mat {P}^n + \Biggl(\sum_{i = 1}^n (-1)^i{n \choose i}\Biggr) \mat {W}\ .
\end{eqnarray*}
</math>
If we expand the expression <math>(1-1)^n</math>, using the Binomial Theorem, we obtain
the expression in
parenthesis above, except that we have an extra term (which equals 1).  Since
<math>(1-1)^n = 0</math>,
we see that the above expression equals -1.  So we have
<math display="block">
(\mat {P} - \mat {W})^n = \mat {P}^n - \mat {W}\ ,
</math>
for all <math>n \ge 1</math>.
We can now rewrite the series in \ref{eq 11.5.8} as
<math display="block">
\mat {I} + (\mat {P} - \mat {W}) + (\mat {P} - \mat {W})^2 + \cdots\ .
</math>
Since the <math>n</math>th term in this series is equal to <math>\mat {P}^n - \mat {W}</math>, the
<math>n</math>th term goes
to 0 as <math>n</math> goes to infinity.  This is sufficient to show that this series
converges, and
sums to the inverse of the matrix <math>\mat {I} - \mat {P} + \mat {W}</math>.  We call
this inverse the
''fundamental matrix'' associated with the chain, and we denote it by \mat
{Z}.
In the case that the chain is ergodic, but not regular, it is not true that
<math>\mat {P}^n
\rightarrow \mat {W}</math> as <math>n \rightarrow \infty</math>.  Nevertheless, the matrix
<math>\mat {I} - \mat
{P} + \mat {W}</math> still has an inverse, as we will now show.
{{proofcard|Proposition|proposition-1|Let \mat {P} be the transition matrix of an ergodic chain, and let \mat {W} be
the matrix all
of whose rows are the fixed probability row vector for \mat {P}.  Then the
matrix
<math display="block">
\mat {I} - \mat {P} + \mat {W}
</math>
has an inverse.\n|Let <math>\mat{x}</math> be a column vector such that
<math display="block">
(\mat {I} - \mat {P} + \mat {W})\mat {x} = \mat {0}\ .
</math>
To prove the proposition, it is sufficient to show that \mat {x} must be the
zero vector.
Multiplying this equation by <math>\mat{w}</math> and using the fact that <math>\mat{w}(\mat{I}
- \mat{
P}) = \mat{0}</math> and <math>\mat{w} \mat{W} = \mat {w}</math>, we have
<math display="block">
\mat {w}(\mat {I} - \mat {P} + \mat {W})\mat {x} = \mat {w} \mat {x} = \mat
{0}\ .
</math>
Therefore,
<math display="block">
(\mat {I} - \mat {P})\mat {x} = \mat {0}\ .
</math>
But this means that <math>\mat {x} = \mat {P} \mat {x}</math> is a fixed column vector
for <math>\mat{P}</math>.
By [[guide:E5c38a1e8a#thm 11.3.10 |Theorem]], this can only happen if <math>\mat{x}</math> is a constant
vector. 
Since <math>\mat {w}\mat {x} = 0</math>, and \mat {w} has strictly positive entries, we
see that
<math>\mat {x} = \mat {0}</math>.  This completes the proof.}}
As in the regular case, we will call the inverse of the matrix <math>\mat {I} - \mat
{P} + \mat {W}</math>
the ''fundamental matrix'' for the ergodic chain with transition
matrix \mat {P}, and we will
use \mat {Z} to denote this fundamental matrix.
<span id="exam 11.5.2"/>
'''Example'''
Let <math>\mat{P}</math> be the transition matrix for the weather in the Land of Oz.  Then
<math display="block">
\begin{eqnarray*}
\mat{I} - \mat{P} + \mat{W} &=& \pmatrix{
1 & 0 & 0\cr
0 & 1 & 0\cr
0 & 0 & 1\cr} - \pmatrix{
1/2 & 1/4 & 1/4\cr
1/2 & 0  & 1/2\cr
1/4 & 1/4 & 1/2\cr} + \pmatrix{
2/5 & 1/5 & 2/5\cr
2/5 & 1/5 & 2/5\cr
2/5 & 1/5 & 2/5\cr} \cr
&=& \pmatrix{
9/10 & -1/20 & 3/20\cr
-1/10 & 6/5  & -1/10\cr
3/20 & -1/20 & 9/10\cr}\ ,\cr
\end{eqnarray*}
</math>
so
<math display="block">
\mat{Z} = (\mat{I} - \mat{P} + \mat{W})^{-1} =
\pmatrix{                 
86/75 & 1/25 & -14/75\cr
2/25 & 21/25 & 2/25\cr
-14/75 & 1/25 & 86/75\cr}\ .       
</math>
\subsection*{Using the Fundamental Matrix to Calculate the Mean First Passage
Matrix}
We shall show how one can obtain the mean first passage matrix \mat{M} from the
fundamental
matrix \mat{Z} for an ergodic Markov chain.  Before stating the theorem which
gives the first
passage times, we need a few facts about \mat{Z}.
{{proofcard|Lemma|thm_11.5.18|Let <math>\mat{Z} = (\mat{I} - \mat{P} + \mat{W})^{-1}</math>, and let <math>\mat{c}</math> be a
column vector of all
1's.  Then
<math display="block">
\mat{Z}\mat{c} = \mat{c}\ ,
</math>
<math display="block">
\mat{w}\mat{Z} = \mat{w}\ ,
</math>
and
<math display="block">
\mat{Z}(\mat{I} - \mat{P}) = \mat{I} - \mat{W}\ .
</math>\n|Since <math>\mat{P}\mat{c} = \mat{c}</math> and <math>\mat{W}\mat{c} = \mat{c}</math>,
<math display="block">
\mat{c} = (\mat{I} - \mat{P} + \mat{W}) \mat{c}\ .
</math>
If we multiply both sides of this equation on the left by <math>\mat{Z}</math>, we obtain
<math display="block">
\mat{Z}\mat{c} = \mat{c}\ .
</math>
Similarly, since <math>\mat{w}\mat{P} = \mat{w}</math> and <math>\mat{w}\mat{W} = \mat{w}</math>,
<math display="block">
\mat{w} = \mat{w}(\mat{I} - \mat{P} + \mat{W})\ .
</math>
If we multiply both sides of this equation on the right by <math>\mat{Z}</math>, we obtain
<math display="block">
\mat{w}\mat{Z} = \mat{w}\ .
</math>
Finally, we have
<math display="block">
\begin{eqnarray*}
(\mat{I} - \mat{P} + \mat{W})(\mat{I} - \mat{W}) &=&
\mat{I} - \mat{W} - \mat{P} + \mat{W} + \mat{W} - \mat{W}\\
  &=& \mat{I} - \mat{P}\ .
\end{eqnarray*}
</math>
Multiplying on the left by \mat{Z}, we obtain
<math display="block">
\mat{I} - \mat{W} = \mat{Z}(\mat{I} - \mat{P})\ .
</math>
This completes the proof.}}
The following theorem shows how one can obtain the mean first passage times
from the
fundamental matrix.
{{proofcard|Theorem|thm_11.5.19|The mean first passage matrix <math>\mat{M}</math> for an ergodic chain is determined from
the
fundamental matrix <math>\mat{Z}</math> and the fixed row probability vector <math>\mat{w}</math> by
<math display="block">
m_{ij} = \frac{z_{jj} - z_{ij}}{w_j}\ .
</math>\n|We showed in [[#eq 11.5.4 |Equation]] that
<math display="block">
(\mat {I} - \mat {P})\mat {M} = \mat {C} - \mat {D}\ .
</math>
Thus,
<math display="block">
\mat {Z}(\mat {I} - \mat {P})\mat {M} = \mat {Z} \mat {C} - \mat {Z} \mat {D}\
,
</math>
and from [[#thm 11.5.18 |Lemma]],
<math display="block">
\mat {Z}(\mat {I} - \mat {P})\mat {M} = \mat {C} - \mat {Z} \mat {D}\ .
</math>
Again using [[#thm 11.5.18 |Lemma]], we have
<math display="block">
\mat {M} - \mat{W}\mat {M} = \mat {C} - \mat {Z} \mat {D}
</math>
or
<math display="block">
\mat {M} = \mat {C} - \mat {Z} \mat {D} + \mat{W}\mat {M}\ .
</math>
From this equation, we see that
<span id{{=}}"eq 11.5.6"/>
<math display="block">
\begin{equation}
m_{ij} = 1 - z_{ij}r_j + (\mat{w} \mat{M})_j\ .  \label{eq 11.5.6}
\end{equation}
</math>
But <math>m_{jj} = 0</math>, and so
<math display="block">
0 = 1 - z_{jj}r_j + (\mat {w} \mat {M})_j\ ,
</math>
or
<span id{{=}}"eq 11.5.7"/>
<math display="block">
\begin{equation}
(\mat{w} \mat{M})_j = z_{jj}r_j - 1\ .  \label{eq 11.5.7}
\end{equation}
</math>
From [[#eq 11.5.6 |Equations]] [[#eq 11.5.7 |and]], we have
<math display="block">
m_{ij} = (z_{jj} - z_{ij}) \cdot r_j\ .
</math>
Since <math>r_j = 1/w_j</math>,
<math display="block">
m_{ij} = \frac{z_{jj} - z_{ij}}{w_j}\ .
</math>}}
<span id="exam 11.5.3"/>
'''Example'''
In the Land of Oz example, we find that
<math display="block">
\mat{Z} = (\mat{I} - \mat{P} + \mat{W})^{-1} =
\pmatrix{                 
86/75 & 1/25 & -14/75\cr
2/25 & 21/25 & 2/25\cr
-14/75 & 1/25 & 86/75\cr}\ .       
</math>
We have also seen that <math>\mat {w} = (2/5,1/5, 2/5)</math>.  So, for example,
<math display="block">
\begin{eqnarray*}
m_{12} &=& \frac{z_{22} - z_{12}}{w_2} \\
      &=& \frac{21/25 - 1/25}{1/5} \\
      &=& 4\ ,\\
\end{eqnarray*}
</math>
by [[#thm 11.5.19 |Theorem]].  Carrying out the calculations for
the other entries of <math>\mat{M}</math>, we obtain
<math display="block">
\mat {M} = \pmatrix{
  0 & 4 & 10/3\cr
8/3 & 0 & 8/3\cr
10/3 & 4 & 0\cr}\ .
</math>
===Computation===
The program ''' ErgodicChain'''
calculates the fundamental matrix, the fixed vector, the mean recurrence
matrix <math>\mat{D}</math>,
and the mean first passage matrix <math>\mat{M}</math>.  We have run the program for the
Ehrenfest
urn model [[guide:52e01d4de7#exam 11.1.6 |(Example]]).
We obtain:
<math display="block">
\mat {P} = \bordermatrix{
  &  0  & 1 & 2 & 3 & 4 \cr
0 &  .0000 & 1.0000 &  .0000 &  .0000 &  .0000\cr
1 &  .2500 & .0000  &  .7500 &  .0000 &  .0000\cr
2 &  .0000 & .5000  &  .0000 &  .5000 &  .0000\cr
3 &  .0000 & .0000  &  .7500 &  .0000 &  .2500\cr
4 &  .0000 & .0000  &  .0000 &  1.0000&  .0000}\ ;
</math>
<math display="block">
\mat {w} = \bordermatrix{
&    0  &  1  &  2  &  3  &    4\cr
& .0625  &.2500  &.3750  &.2500  &.0625}\ ;
</math>
<math display="block">
\mat {r} = \bordermatrix{
&      0  &      1  &      2 &      3 &      4\cr
& 16.0000  & 4.0000  & 2.6667 &  4.0000 & 16.0000}\ ;
</math>
<math display="block">
\mat {M} = \bordermatrix{
&        0 &      1 &      2 &      3 &      4\cr
0 &    .0000 & 1.0000 & 2.6667 &  6.3333 & 21.3333\cr
1 &  15.0000 &  .0000 & 1.6667 &  5.3333 & 20.3333\cr
2 &  18.6667 & 3.6667 &  .0000 &  3.6667 & 18.6667\cr
3 &  20.3333 & 5.3333 & 1.6667 &  .0000 & 15.0000\cr
4 &  21.3333 & 6.3333 & 2.6667 &  1.0000 &  .0000}\ .
</math>
From the mean first passage matrix, we see that the mean time to go from
0 balls in urn 1 to 2 balls in urn 1 is 2.6667 steps while the mean time to go
from 2 balls in urn 1 to 0 balls in urn 1 is 18.6667.  This reflects the
fact that the model exhibits a central tendency.  Of course, the physicist is
interested in the case of a large number of molecules, or balls, and so we
should consider this example for <math>n</math> so large that we cannot compute it even
with a computer.
===Ehrenfest Model===
'''Example'''
Let us consider the Ehrenfest model (see Example \ref{exam
11.1.6})
for gas
diffusion  for the general case of <math>2n</math> balls.  Every second, one of the <math>2n</math>
balls is chosen
at random and moved from the urn it was in to the other urn.  If there are
<math>i</math> balls
in the first urn, then with probability <math>i/2n</math> we take one of them out and put
it
in the second urn, and
with probability <math>(2n - i)/2n</math> we take a ball from the second urn and put it in
the first urn.  At each second we let the number <math>i</math> of balls in the first urn
be the state of the system.  Then from state <math>i</math> we can pass only to state <math>i -
1</math> and <math>i + 1</math>, and the transition probabilities are given by
<math display="block">
p_{ij} = \left \{ \matrix{
              \frac i{2n}\ , & \mbox{if} \,\,j = i-1, \cr
              1 - \frac i{2n}\ , & \mbox{if} \,\,j = i+1, \cr
              0\ , & \mbox{otherwise.}\cr}\right.
</math>
This defines the transition matrix of an ergodic, non-regular Markov chain
(see [[guide:E5c38a1e8a#exer 11.3.14 |Exercise]]).  Here the physicist is interested in
long-term
predictions about the state occupied.  In [[guide:E5c38a1e8a#exam 11.3.4 |Example]], we gave an
intuitive reason for expecting that the fixed vector <math>\mat{w}</math> is the binomial
distribution with parameters <math>2n</math> and <math>1/2</math>.  It is easy to check that this is
correct.  So,
<math display="block">
w_i = \frac{{2n \choose i}}{2^{2n}}\ .
</math>
Thus the mean recurrence time for state <math>i</math> is
<math display="block">
r_i = \frac{2^{2n}}{{2n \choose i}}\ .
</math>
Consider in particular the central term <math>i = n</math>.  We have seen that this term
is
approximately <math>1/\sqrt{\pi n}</math>.  Thus we may approximate <math>r_n</math> by <math>\sqrt{\pi
n}</math>.
This model was used to explain the concept of reversibility in physical
systems.  Assume that we let our system run until it is in equilibrium.  At
this
point, a movie is made, showing the system's progress.  The movie is then shown
to you, and you are asked to tell if the movie was shown in the forward or
the reverse direction.  It would seem that there
should always be a tendency to move toward an equal proportion of balls so that
the correct order of time should be the one with the most transitions from <math>i</math>
to
<math>i - 1</math> if <math>i  >  n</math> and <math>i</math> to <math>i + 1</math> if <math>i  <  n</math>.
<div id="PSfig11-6" class="d-flex justify-content-center">
[[File:guide_e6d15_PSfig11-6.ps | 400px | thumb |  ]]
</div>
   
In Figure \ref{fig 11.6} we show the results of simulating the Ehrenfest urn
model for the
case of <math>n = 50</math> and 1000 time units, using the program '''
EhrenfestUrn'''.  The top graph shows these results graphed in the
order in which they occurred and the bottom graph shows the same results but with time
reversed.  There is no apparent difference.
We note that if we had not started in equilibrium, the two graphs would
typically
look quite different.
===Reversibility===
If the Ehrenfest model is started in equilibrium, then the process has no
apparent time
direction.  The reason for this is that this process has a property called ''reversibility.''  Define <math>X_n</math> to be the number of balls
in
the left urn at step <math>n</math>.  We can calculate, for a general ergodic chain, the
reverse transition
probability:
<math display="block">
\begin{eqnarray*}
P(X_{n - 1} = j | X_n = i) &=& \frac{P(X_{n - 1} = j,X_n = i)}{P(X_n = i)} \\
    &=& \frac{P(X_{n - 1} = j) P(X_n = i | X_{n - 1} = j)}{P(X_n = i)} \\
    &=& \frac{P(X_{n - 1} = j) p_{ji}}{P(X_n = i)}\ .\\
\end{eqnarray*}
</math>
In general, this will depend upon <math>n</math>, since <math>P(X_n = j)</math> and also <math>P(X_{n - 1}
= j)</math> change with <math>n</math>.  However, if we start with the vector <math>\mat{w}</math> or wait
until equilibrium is reached, this will not be the case.  Then we can define
<math display="block">
p_{ij}^* = \frac{w_j p_{ji}}{w_i}
</math>
as a transition matrix for the process watched with time reversed.
Let us calculate a typical transition probability for the reverse chain <math>\mat{
P}^* = \{p_{ij}^*\}</math> in the Ehrenfest model.  For example,
<math display="block">
\begin{eqnarray*}
p_{i,i - 1}^* &=& \frac{w_{i - 1} p_{i - 1,i}}{w_i} =
\frac{{2n \choose {i - 1}}}{2^{2n}}
                \times \frac{2n - i + 1}{2n} \times
\frac{2^{2n}}{{2n \choose i}}\\
              &=& \frac{(2n)!}{(i - 1)!\,(2n - i + 1)!} \times
\frac{(2n - i + 1) i!\,
                (2n - i)!}{2n(2n)!} \\
              &=& \frac{i}{2n} = p_{i,i - 1}\ .\\
\end{eqnarray*}
</math>
Similar calculations for the other transition probabilities show that <math>\mat
{P}^*
= \mat {P}</math>.  When this occurs the process is called ''reversible.''
Clearly,
an ergodic chain is reversible if, and only if, for every pair of states
<math>s_i</math> and <math>s_j</math>, <math>w_i p_{ij} = w_j p_{ji}</math>.  In particular, for the Ehrenfest
model
this means that <math>w_i p_{i,i - 1} = w_{i - 1} p_{i - 1,i}</math>.  Thus, in
equilibrium, the pairs <math>(i, i - 1)</math> and <math>(i - 1, i)</math> should occur with the same
frequency.  While many of the Markov chains that occur in applications are
reversible, this is a very strong condition.  In Exercise [[exercise:20a3e63037 |Exercise]]
you
are asked to find an example of a Markov chain which is not reversible.
===The Central Limit Theorem for Markov Chains===
Suppose that we have an ergodic Markov chain with states <math>s_1, s_2, \ldots,
s_k</math>.
It is natural to consider the distribution of the random variables <math>S^{(n)}_j</math>,
which
denotes the number of times that the chain is in state <math>s_j</math> in the first <math>n</math>
steps.
The <math>j</math>th component <math>w_j</math> of the fixed probability row vector <math>\mat{w}</math> is the
proportion of
times that the chain is in state <math>s_j</math> in the long run.  Hence, it is
reasonable to conjecture
that the expected value of the random variable <math>S^{(n)}_j</math>, as <math>n \rightarrow
\infty</math>, is
asymptotic to <math>nw_j</math>, and it is easy to show that this is the case (see
Exercise \ref{exer
11.5.29}).
It is also natural to ask whether there is a limiting distribution of the
random variables
<math>S^{(n)}_j</math>.  The answer is yes, and in fact, this limiting distribution is the
normal
distribution.  As in the case of independent trials, one must normalize these
random
variables.  Thus, we must subtract from <math>S^{(n)}_j</math> its expected value, and
then
divide by its standard deviation.  In both cases, we will use the asymptotic
values of these
quantities, rather than the values themselves.  Thus, in the first case, we
will use the
value <math>nw_j</math>.  It is not so clear what we should use in the second case.  It
turns out that
the quantity
<span id{{=}}"eq 11.5.9"/>
<math display="block">
\begin{equation}
\sigma_j^2 = 2w_jz_{jj} - w_j - w_j^2
\label{eq 11.5.9}
\end{equation}
</math>
represents the asymptotic variance.  Armed with these ideas, we can state the
following
theorem.
{{proofcard|Theorem|thm_11.5.20|''' (Central Limit Theorem for Markov
Chains)'''
For an ergodic chain, for any real numbers <math>r  <  s</math>, we have
<math display="block">
P\Biggl(r  <  {{S^{(n)}_j - nw_j}\over{\sqrt{n\sigma_j^2}}} <  s\Biggr)
\rightarrow
{1\over{\sqrt {2\pi}}}\int_r^s e^{-x^2/2}\,dx\
,
</math>
as <math>n \rightarrow \infty</math>, for any choice of starting state, where
<math>\sigma_j^2</math> is
the quantity defined in [[#eq 11.5.9 |Equation]].|}}
===Historical Remarks===
Markov chains were introduced by Andre\u i Andreevich Markov (1856--1922) and
were named in his honor.  He was a talented undergraduate who received a gold
medal for his undergraduate thesis at St. Petersburg University.  Besides being
an active research mathematician and teacher, he was also active in politics
and patricipated in the liberal movement in Russia at the beginning of the
twentieth century.  In 1913, when the government celebrated the 300th
anniversary of the House of Romanov family, Markov organized a
counter-celebration of the 200th anniversary of Bernoulli's discovery of the
Law of Large Numbers.
Markov was led to develop Markov chains as a natural extension of sequences of
independent random variables.  In his first paper, in 1906, he proved that for
a Markov chain with positive transition probabilities and numerical states the
average of the outcomes converges to the expected value of the limiting
distribution (the fixed vector).  In a later paper he proved the central limit
theorem for such chains.  Writing about Markov, A. P. Youschkevitch remarks:
<blockquote>
Markov arrived at his chains starting from the internal needs of probability
theory, and he never wrote about their applications to physical science.  For
him the only real examples of the chains were literary texts, where the two
states denoted the vowels and consonants.<ref group="Notes" >See ''Dictionary of
Scientific Biography,'' ed. C. C. Gillespie (New York: Scribner's Sons, 1970),
pp. 124--130.</ref>
</blockquote>
In a paper written in 1913,<ref group="Notes" >A. A. Markov, “An Example of Statistical
Analysis of the Text of Eugene Onegin Illustrating the Association of Trials
into a Chain,” ''Bulletin de l'Acadamie Imperiale des Sciences de
St. Petersburg,'' ser. 6, vol. 7 (1913), pp. 153--162.</ref> Markov chose a sequence
of 20,00 letters from Pushkin's ''Eugene Onegin'' to see if this
sequence can be approximately considered a simple chain.  He obtained the
Markov chain with transition matrix
<math display="block">
\bordermatrix{
& \mbox{vowel} & \mbox{consonant} \cr
\mbox{vowel} & .128 & .872 \cr
\mbox{consonant} & .663 & .337}\ .
</math>
The fixed vector for this chain is <math>(.432, .568)</math>, indicating that we should
expect about 43.2 percent vowels and 56.8 percent consonants in the novel,
which was borne out by the actual count.
Claude Shannon considered an interesting extension of this idea in his book
''
The Mathematical Theory of Communication,''<ref group="Notes" >C. E.
Shannon and W. Weaver, ''The Mathematical Theory of Communication'' (Urbana:
Univ.\ of
Illinois Press, 1964).</ref> in which he developed the informa\-tion-theoretic
concept
of entropy.  Shannon considers a series of Markov chain approximations to
English
prose.  He does this first by chains in which the states are letters and then
by chains in which the states are words.  For example, for the case of words he
presents first a simulation where the words are chosen independently but with
appropriate frequencies.
<blockquote>
REPRESENTING AND SPEEDILY IS AN GOOD APT OR COME CAN DIFFERENT NATURAL HERE HE
THE A IN CAME THE TO OF TO EXPERT GRAY COME TO FURNISHES THE LINE MESSAGE HAD
BE THESE.
</blockquote>
He then notes the increased resemblence to ordinary English text when the words
are chosen as a Markov chain, in which case he obtains
<blockquote>
THE HEAD AND IN FRONTAL ATTACK ON AN ENGLISH WRI\-TER THAT THE CHARACTER OF
THIS
POINT IS THEREFORE ANOTHER METHOD FOR THE LETTERS THAT THE TIME OF WHO EVER
TOLD THE PROBLEM FOR AN UNEXPECTED.
</blockquote>
A simulation like the last one is carried out by opening a book and choosing
the first word, say it is ''the.''  Then the book is read until the word
''the''
appears again and the word after this is chosen as the second word, which
turned out to be
''head.''  The book is then read until the word ''head'' appears again
and the next
word, ''and,'' is chosen, and so on.
Other early examples of the use of Markov chains occurred in Galton's study of
the problem of survival of family names in 1889 and in the Markov chain
introduced by P. and T. Ehrenfest in 1907 for diffusion.
Poincar\'{e} in 1912 dicussed card shuffling in terms of an ergodic Markov
chain defined
on a permutation group.  Brownian motion, a continuous time version of random
walk,
was introducted in 1900--1901 by L. Bachelier in his  study of the stock
market,
and in 1905--1907 in the works of A. Einstein and M. Smoluchowsky in their
study of
physical processes.
One of the first systematic studies of finite Markov chains was carried out by
M. Frechet.<ref group="Notes" >M. Frechet, “Théorie des
événements en chaine dans
le cas d'un nombre fini d'états possible,” in ''Recherches théoriques
Modernes sur le calcul des probabilités,'' vol. 2 (Paris, 1938).</ref>  The
treatment of Markov chains in terms of the two fundamental matrices that we
have used was developed by Kemeny and Snell
<ref group="Notes" >J. G. Kemeny and J. L. Snell, ''
Finite Markov Chains.''</ref> to avoid the use of eigenvalues that one of these
authors found too complex.  The fundamental matrix <math>\mat{N}</math> occurred also in
the
work of J. L. Doob and others in studying the connection between Markov
processes and classical potential theory.  The fundamental matrix <math>\mat{Z}</math> for
ergodic chains appeared first in the work of Frechet, who used it to find the
limiting variance for the central limit theorem for Markov chains.
\exercises
\choice{}{% Modified on 6-4-05.==General references==
{{cite web |url=https://math.dartmouth.edu/~prob/prob/prob.pdf |title=Grinstead and Snell’s Introduction to Probability |last=Doyle |first=Peter G.|date=2006 |access-date=June 6, 2024}}
==Notes==
{{Reflist|group=Notes}}

Revision as of 02:38, 9 June 2024

[math] \newcommand{\NA}{{\rm NA}} \newcommand{\mat}[1]{{\bf#1}} \newcommand{\exref}[1]{\ref{##1}} \newcommand{\secstoprocess}{\all} \newcommand{\NA}{{\rm NA}} \newcommand{\mathds}{\mathbb}[/math]

label{sec 11.5} In this section we consider two closely related descriptive quantities of interest for ergodic chains: the mean time to return to a state and the mean time to go from one state to another state.


Let [math]\mat{P}[/math] be the transition matrix of an ergodic chain with states [math]s_1[/math], [math]s_2[/math], \ldots, [math]s_r[/math]. Let [math]\mat {w} = (w_1,w_2,\ldots,w_r)[/math] be the unique probability vector such that [math]\mat {w} \mat {P} = \mat {w}[/math]. Then, by the Law of Large Numbers for Markov chains, in the long run the process will spend a fraction [math]w_j[/math] of the time in state [math]s_j[/math]. Thus, if we start in any state, the chain will eventually reach state [math]s_j[/math]; in fact, it will be in state [math]s_j[/math] infinitely often.


Another way to see this is the following: Form a new Markov chain by making [math]s_j[/math] an absorbing state, that is, define [math]p_{jj} = 1[/math]. If we start at any state other than [math]s_j[/math], this new process will behave exactly like the original chain up to the first time that state [math]s_j[/math] is reached. Since the original chain was an ergodic chain, it was possible to reach [math]s_j[/math] from any other state. Thus the new chain is an absorbing chain with a single absorbing state [math]s_j[/math] that will eventually be reached. So if we start the original chain at a state [math]s_i[/math] with [math]i \ne j[/math], we will eventually reach the state [math]s_j[/math].


Let [math]\mat{N}[/math] be the fundamental matrix for the new chain. The entries of [math]\mat{N}[/math] give the expected number of times in each state before absorption. In terms of the original chain, these quantities give the expected number of times in each of the states before reaching state [math]s_j[/math] for the first time. The [math]i[/math]th component of the vector [math]\mat {N} \mat {c}[/math] gives the expected number of steps before absorption in the new chain, starting in state [math]s_i[/math]. In terms of the old chain, this is the expected number of steps required to reach state [math]s_j[/math] for the first time starting at state [math]s_i[/math].

Mean First Passage Time

Definition

If an ergodic Markov chain is started in state [math]s_i[/math], the expected number of steps to reach state [math]s_j[/math] for the first time is called the mean first passage time from [math]s_i[/math] to [math]s_j[/math]. It is denoted by [math]m_{ij}[/math]. By convention [math]m_{ii} = 0[/math].

Example Let us return to the maze example (Example \ref{exam 11.3.3}). We shall make this ergodic chain into an absorbing chain by making state 5 an absorbing state. For example, we might assume that food is placed in the center of the maze and once the rat finds the food, he stays to enjoy it (see Figure \ref{fig 11.5}).


The new transition matrix in canonical form is

[[math]] \mat {P}\;= \bordermatrix{& \hbox{1}&\hbox{2}&\hbox{3}&\hbox{4}&\hbox{6}&\hbox{7}&\hbox{8} &\hbox{9}&\omit\hfil&\hbox{5}\cr \hbox{1}\strut & 0 &1/2 & 0 & 0 & 1/2 & 0 & 0 & 0 &\srule & 0 \cr \hbox{2}\strut &1/3 & 0 &1/3 & 0 & 0 & 0 & 0 & 0 &\srule &1/3\cr \hbox{3}\strut & 0 &1/2 & 0 & 1/2 & 0 & 0 & 0 & 0 &\srule & 0 \cr \hbox{4}\strut & 0 & 0 &1/3 & 0 & 0 &1/3 & 0 & 1/3 &\srule &1/3\cr \hbox{6}\strut &1/3 & 0 & 0 & 0 & 0 & 0 & 0 & 0 &\srule &1/3\cr \hbox{7}\strut & 0 & 0 & 0 & 0 &1/2 & 0 & 1/2 & 0 &\srule &0 \cr \hbox{8}\strut & 0 & 0 & 0 & 0 & 0 &1/3 & 0 & 1/3 &\srule &1/3\cr \hbox{9}\strut & 0 & 0 & 0 &1/2 & 0 & 0 & 1/2& 0 &\srule & 0 \cr \middlehrule{8}{1} \hbox{5}\strut & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 &\srule & 1}\ . [[/math]]

If we compute the fundamental matrix [math]\mat{N}[/math], we obtain

[[math]] \mat {N} = \frac18 \pmatrix{ 14 & 9 & 4 & 3 & 9 & 4 & 3 & 2 \cr 6 & 14 & 6 & 4 & 4 & 2 & 2 & 2 \cr 4 & 9 & 14 & 9 & 3 & 2 & 3 & 4 \cr 2 & 4 & 6 & 14 & 2 & 2 & 4 & 6 \cr 6 & 4 & 2 & 2 & 14 & 6 & 4 & 2 \cr 4 & 3 & 2 & 3 & 9 & 14 & 9 & 4 \cr 2 & 2 & 2 & 4 & 4 & 6 & 14 & 6 \cr 2 & 3 & 4 & 9 & 3 & 4 & 9 & 14 \cr}\ . [[/math]]

The expected time to absorption for different starting states is given by the vector [math]\mat {N} \mat {c}[/math], where

[[math]] \mat {N} \mat {c} = \pmatrix{ 6 \cr 5 \cr 6 \cr 5 \cr 5 \cr 6 \cr 5 \cr 6 \cr}\ . [[/math]]

We see that, starting from compartment 1, it will take on the average six steps to reach food. It is clear from symmetry that we should get the same answer for starting at state 3, 7, or 9. It is also clear that it should take one more step, starting at one of these states, than it would starting at 2, 4, 6, or 8. Some of the results obtained from [math]\mat{N}[/math] are not so obvious. For instance, we note that the expected number of times in the starting state is 14/8 regardless of the state in which we start.


Mean Recurrence Time

A quantity that is closely related to the mean first passage time is the mean recurrence time, defined as follows. Assume that we start in state [math]s_i[/math]; consider the length of time before we return to [math]s_i[/math] for the first time. It is clear that we must return, since we either stay at [math]s_i[/math] the first step or go to some other state [math]s_j[/math], and from any other state [math]s_j[/math], we will eventually reach [math]s_i[/math] because the chain is ergodic.

Definition

If an ergodic Markov chain is started in state [math]s_i[/math], the expected number of steps to return to [math]s_i[/math] for the first time is the mean recurrence time for [math]s_i[/math]. It is denoted by [math]r_i[/math].

We need to develop some basic properties of the mean first passage time. Consider the mean first passage time from [math]s_i[/math] to [math]s_j[/math]; assume that [math]i \ne j[/math]. This may be computed as follows: take the expected number of steps required given the outcome of the first step, multiply by the probability that this outcome occurs, and add. If the first step is to [math]s_j[/math], the expected number of steps required is 1; if it is to some other state [math]s_k[/math], the expected number of steps required is [math]m_{kj}[/math] plus 1 for the step already taken. Thus,

[[math]] m_{ij} = p_{ij} + \sum_{k \ne j} p_{ik}(m_{kj} + 1)\ , [[/math]]

or, since [math]\sum_k p_{ik} = 1[/math],

[[math]] \begin{equation} m_{ij} = 1 + \sum_{k \ne j}p_{ik} m_{kj}\ .\label{eq 11.5.1} \end{equation} [[/math]]


Similarly, starting in [math]s_i[/math], it must take at least one step to return. Considering all possible first steps gives us

[[math]] \begin{eqnarray} r_i &=& \sum_k p_{ik}(m_{ki} + 1) \\ &=& 1 + \sum_k p_{ik} m_{ki}\ .\label{eq 11.5.2} \end{eqnarray} [[/math]]


Mean First Passage Matrix and Mean Recurrence Matrix

Let us now define two matrices [math]\mat{M}[/math] and [math]\mat{D}[/math]. The [math]ij[/math]th entry [math]m_{ij}[/math] of [math]\mat{M}[/math] is the mean first passage time to go from [math]s_i[/math] to [math]s_j[/math] if [math]i \ne j[/math]; the diagonal entries are 0. The matrix [math]\mat{M}[/math] is called the mean first passage matrix.

The matrix [math]\mat{D}[/math] is the matrix with all

entries 0 except the diagonal entries [math]d_{ii} = r_i[/math]. The matrix [math]\mat{D}[/math] is called the mean recurrence matrix.

Let [math]\mat {C}[/math] be an [math]r \times r[/math] matrix with all entries 1. Using Equation for the case [math]i \ne j[/math] and Equation for the case [math]i = j[/math], we obtain the matrix equation

[[math]] \begin{equation} \mat{M} = \mat{P} \mat{M} + \mat{C} - \mat{D}\ , \label{eq 11.5.3} \end{equation} [[/math]]

or

[[math]] \begin{equation} (\mat{I} - \mat{P}) \mat{M} = \mat{C} - \mat{D}\ . \label{eq 11.5.4} \end{equation} [[/math]]

Equation with [math]m_{ii} = 0[/math] implies Equations and. We are now in a position to prove our first basic theorem.

Theorem

For an ergodic Markov chain, the mean recurrence time for state [math]s_i[/math] is [math]r_i = 1/w_i[/math], where [math]w_i[/math] is the [math]i[/math]th component of the fixed probability vector for the transition matrix.\n

Show Proof

Multiplying both sides of Equation by [math]\mat{w}[/math] and using the fact that

[[math]] \mat {w}(\mat {I} - \mat {P}) = \mat {0} [[/math]]

gives

[[math]] \mat {w} \mat {C} - \mat {w} \mat {D} = \mat {0}\ . [[/math]]
Here [math]\mat {w} \mat {C}[/math] is a row vector with all entries 1 and [math]\mat {w} \mat {D}[/math] is a row vector with [math]i[/math]th entry [math]w_i r_i[/math]. Thus

[[math]] (1,1,\ldots,1) = (w_1r_1,w_2r_2,\ldots,w_nr_n) [[/math]]
and

[[math]] r_i = 1/w_i\ , [[/math]]
as was to be proved.

Corollary

For an ergodic Markov chain, the components of the fixed probability vector w are strictly positive.\n

Show Proof

We know that the values of [math]r_i[/math] are finite and so [math]w_i = 1/r_i[/math] cannot be 0.

Example In Example we found the fixed probability vector for the maze example to be

[[math]] \mat {w} = \pmatrix{ \frac1{12} & \frac18 & \frac1{12} & \frac18 & \frac16 & \frac18 & \frac1{12} & \frac18 & \frac1{12}}\ . [[/math]]

Hence, the mean recurrence times are given by the reciprocals of these probabilities. That is,

[[math]] \mat {r} = \pmatrix{ 12 & 8 & 12 & 8 & 6 & 8 & 12 & 8 & 12 }\ . [[/math]]

Returning to the Land of Oz, we found that the weather in the Land of Oz could be represented by a Markov chain with states rain, nice, and snow. In Section \ref{sec 11.3} we found that the limiting vector was [math]\mat {w} = (2/5,1/5,2/5)[/math]. From this we see that the mean number of days between rainy days is 5/2, between nice days is 5, and between snowy days is 5/2.

Fundamental Matrix

We shall now develop a fundamental matrix for ergodic chains that will play a role similar to that of the fundamental matrix [math]\mat {N} = (\mat {I} - \mat {Q})^{-1}[/math] for absorbing chains. As was the case with absorbing chains, the fundamental matrix can be used to find a number of interesting quantities involving ergodic chains. Using this matrix, we will give a method for calculating the mean first passage times for ergodic chains that is easier to use than the method given above. In addition, we will state (but not prove) the Central Limit Theorem for Markov Chains, the statement of which uses the fundamental matrix.


We begin by considering the case that \mat{P} is the transition matrix of a regular Markov chain. Since there are no absorbing states, we might be tempted to try [math]\mat {Z} = (\mat {I} - \mat {P})^{-1}[/math] for a fundamental matrix. But [math]\mat {I} - \mat {P}[/math] does not have an inverse. To see this, recall that a matrix [math]\mat{R}[/math] has an inverse if and only if [math]\mat {R} \mat {x} = \mat {0}[/math] implies [math]\mat {x} = \mat {0}[/math]. But since [math]\mat {P} \mat {c} = \mat {c}[/math] we have [math](\mat {I} - \mat {P})\mat {c} = \mat {0}[/math], and so [math]\mat {I} - \mat {P}[/math] does not have an inverse.


We recall that if we have an absorbing Markov chain, and \mat{Q} is the restriction of the transition matrix to the set of transient states, then the fundamental matrix \mat {N} could be written as

[[math]] \mat {N} = \mat {I} + \mat {Q} + \mat {Q}^2 + \cdots\ . [[/math]]

The reason that this power series converges is that [math]\mat {Q}^n \rightarrow 0[/math], so this series acts like a convergent geometric series.


This idea might prompt one to try to find a similar series for regular chains. Since we know that [math]\mat {P}^n \rightarrow \mat {W}[/math], we might consider the series

[[math]] \begin{equation} \mat {I} + (\mat {P} -\mat {W}) + (\mat {P}^2 - \mat{W}) + \cdots\ .\label{eq 11.5.8} \end{equation} [[/math]]

We now use special properties of \mat {P} and \mat {W} to rewrite this series. The special properties are: 1) [math]\mat {P}\mat {W} = \mat {W}[/math], and 2) [math]\mat {W}^k = \mat {W}[/math] for all positive integers [math]k[/math]. These facts are easy to verify, and are left as an exercise (see Exercise Exercise). Using these facts, we see that

[[math]] \begin{eqnarray*} (\mat {P} - \mat {W})^n &=& \sum_{i = 0}^n (-1)^i{n \choose i}\mat {P}^{n-i}\mat {W}^i \\ &=& \mat {P}^n + \sum_{i = 1}^n (-1)^i{n \choose i} \mat {W}^i \\ &=& \mat {P}^n + \sum_{i = 1}^n (-1)^i{n \choose i} \mat {W} \\ &=& \mat {P}^n + \Biggl(\sum_{i = 1}^n (-1)^i{n \choose i}\Biggr) \mat {W}\ . \end{eqnarray*} [[/math]]

If we expand the expression [math](1-1)^n[/math], using the Binomial Theorem, we obtain the expression in parenthesis above, except that we have an extra term (which equals 1). Since [math](1-1)^n = 0[/math], we see that the above expression equals -1. So we have

[[math]] (\mat {P} - \mat {W})^n = \mat {P}^n - \mat {W}\ , [[/math]]

for all [math]n \ge 1[/math].


We can now rewrite the series in \ref{eq 11.5.8} as

[[math]] \mat {I} + (\mat {P} - \mat {W}) + (\mat {P} - \mat {W})^2 + \cdots\ . [[/math]]

Since the [math]n[/math]th term in this series is equal to [math]\mat {P}^n - \mat {W}[/math], the [math]n[/math]th term goes to 0 as [math]n[/math] goes to infinity. This is sufficient to show that this series converges, and sums to the inverse of the matrix [math]\mat {I} - \mat {P} + \mat {W}[/math]. We call this inverse the fundamental matrix associated with the chain, and we denote it by \mat {Z}.


In the case that the chain is ergodic, but not regular, it is not true that [math]\mat {P}^n \rightarrow \mat {W}[/math] as [math]n \rightarrow \infty[/math]. Nevertheless, the matrix [math]\mat {I} - \mat {P} + \mat {W}[/math] still has an inverse, as we will now show.

Proposition

Let \mat {P} be the transition matrix of an ergodic chain, and let \mat {W} be the matrix all of whose rows are the fixed probability row vector for \mat {P}. Then the matrix

[[math]] \mat {I} - \mat {P} + \mat {W} [[/math]]
has an inverse.\n

Show Proof

Let [math]\mat{x}[/math] be a column vector such that

[[math]] (\mat {I} - \mat {P} + \mat {W})\mat {x} = \mat {0}\ . [[/math]]
To prove the proposition, it is sufficient to show that \mat {x} must be the zero vector. Multiplying this equation by [math]\mat{w}[/math] and using the fact that [math]\mat{w}(\mat{I} - \mat{ P}) = \mat{0}[/math] and [math]\mat{w} \mat{W} = \mat {w}[/math], we have

[[math]] \mat {w}(\mat {I} - \mat {P} + \mat {W})\mat {x} = \mat {w} \mat {x} = \mat {0}\ . [[/math]]
Therefore,

[[math]] (\mat {I} - \mat {P})\mat {x} = \mat {0}\ . [[/math]]

But this means that [math]\mat {x} = \mat {P} \mat {x}[/math] is a fixed column vector for [math]\mat{P}[/math]. By Theorem, this can only happen if [math]\mat{x}[/math] is a constant vector. Since [math]\mat {w}\mat {x} = 0[/math], and \mat {w} has strictly positive entries, we see that [math]\mat {x} = \mat {0}[/math]. This completes the proof.


As in the regular case, we will call the inverse of the matrix [math]\mat {I} - \mat {P} + \mat {W}[/math] the fundamental matrix for the ergodic chain with transition matrix \mat {P}, and we will use \mat {Z} to denote this fundamental matrix. Example Let [math]\mat{P}[/math] be the transition matrix for the weather in the Land of Oz. Then

[[math]] \begin{eqnarray*} \mat{I} - \mat{P} + \mat{W} &=& \pmatrix{ 1 & 0 & 0\cr 0 & 1 & 0\cr 0 & 0 & 1\cr} - \pmatrix{ 1/2 & 1/4 & 1/4\cr 1/2 & 0 & 1/2\cr 1/4 & 1/4 & 1/2\cr} + \pmatrix{ 2/5 & 1/5 & 2/5\cr 2/5 & 1/5 & 2/5\cr 2/5 & 1/5 & 2/5\cr} \cr &=& \pmatrix{ 9/10 & -1/20 & 3/20\cr -1/10 & 6/5 & -1/10\cr 3/20 & -1/20 & 9/10\cr}\ ,\cr \end{eqnarray*} [[/math]]

so

[[math]] \mat{Z} = (\mat{I} - \mat{P} + \mat{W})^{-1} = \pmatrix{ 86/75 & 1/25 & -14/75\cr 2/25 & 21/25 & 2/25\cr -14/75 & 1/25 & 86/75\cr}\ . [[/math]]

\subsection*{Using the Fundamental Matrix to Calculate the Mean First Passage Matrix} We shall show how one can obtain the mean first passage matrix \mat{M} from the fundamental matrix \mat{Z} for an ergodic Markov chain. Before stating the theorem which gives the first passage times, we need a few facts about \mat{Z}.

Lemma

Let [math]\mat{Z} = (\mat{I} - \mat{P} + \mat{W})^{-1}[/math], and let [math]\mat{c}[/math] be a column vector of all 1's. Then

[[math]] \mat{Z}\mat{c} = \mat{c}\ , [[/math]]

[[math]] \mat{w}\mat{Z} = \mat{w}\ , [[/math]]
and

[[math]] \mat{Z}(\mat{I} - \mat{P}) = \mat{I} - \mat{W}\ . [[/math]]
\n

Show Proof

Since [math]\mat{P}\mat{c} = \mat{c}[/math] and [math]\mat{W}\mat{c} = \mat{c}[/math],

[[math]] \mat{c} = (\mat{I} - \mat{P} + \mat{W}) \mat{c}\ . [[/math]]
If we multiply both sides of this equation on the left by [math]\mat{Z}[/math], we obtain

[[math]] \mat{Z}\mat{c} = \mat{c}\ . [[/math]]


Similarly, since [math]\mat{w}\mat{P} = \mat{w}[/math] and [math]\mat{w}\mat{W} = \mat{w}[/math],

[[math]] \mat{w} = \mat{w}(\mat{I} - \mat{P} + \mat{W})\ . [[/math]]
If we multiply both sides of this equation on the right by [math]\mat{Z}[/math], we obtain

[[math]] \mat{w}\mat{Z} = \mat{w}\ . [[/math]]


Finally, we have

[[math]] \begin{eqnarray*} (\mat{I} - \mat{P} + \mat{W})(\mat{I} - \mat{W}) &=& \mat{I} - \mat{W} - \mat{P} + \mat{W} + \mat{W} - \mat{W}\\ &=& \mat{I} - \mat{P}\ . \end{eqnarray*} [[/math]]
Multiplying on the left by \mat{Z}, we obtain

[[math]] \mat{I} - \mat{W} = \mat{Z}(\mat{I} - \mat{P})\ . [[/math]]
This completes the proof.

The following theorem shows how one can obtain the mean first passage times from the fundamental matrix.

Theorem

The mean first passage matrix [math]\mat{M}[/math] for an ergodic chain is determined from the fundamental matrix [math]\mat{Z}[/math] and the fixed row probability vector [math]\mat{w}[/math] by

[[math]] m_{ij} = \frac{z_{jj} - z_{ij}}{w_j}\ . [[/math]]
\n

Show Proof

We showed in Equation that

[[math]] (\mat {I} - \mat {P})\mat {M} = \mat {C} - \mat {D}\ . [[/math]]
Thus,

[[math]] \mat {Z}(\mat {I} - \mat {P})\mat {M} = \mat {Z} \mat {C} - \mat {Z} \mat {D}\ , [[/math]]
and from Lemma,

[[math]] \mat {Z}(\mat {I} - \mat {P})\mat {M} = \mat {C} - \mat {Z} \mat {D}\ . [[/math]]
Again using Lemma, we have

[[math]] \mat {M} - \mat{W}\mat {M} = \mat {C} - \mat {Z} \mat {D} [[/math]]
or

[[math]] \mat {M} = \mat {C} - \mat {Z} \mat {D} + \mat{W}\mat {M}\ . [[/math]]
From this equation, we see that

[[math]] \begin{equation} m_{ij} = 1 - z_{ij}r_j + (\mat{w} \mat{M})_j\ . \label{eq 11.5.6} \end{equation} [[/math]]
But [math]m_{jj} = 0[/math], and so

[[math]] 0 = 1 - z_{jj}r_j + (\mat {w} \mat {M})_j\ , [[/math]]
or

[[math]] \begin{equation} (\mat{w} \mat{M})_j = z_{jj}r_j - 1\ . \label{eq 11.5.7} \end{equation} [[/math]]
From Equations and, we have

[[math]] m_{ij} = (z_{jj} - z_{ij}) \cdot r_j\ . [[/math]]
Since [math]r_j = 1/w_j[/math],

[[math]] m_{ij} = \frac{z_{jj} - z_{ij}}{w_j}\ . [[/math]]

Example In the Land of Oz example, we find that

[[math]] \mat{Z} = (\mat{I} - \mat{P} + \mat{W})^{-1} = \pmatrix{ 86/75 & 1/25 & -14/75\cr 2/25 & 21/25 & 2/25\cr -14/75 & 1/25 & 86/75\cr}\ . [[/math]]

We have also seen that [math]\mat {w} = (2/5,1/5, 2/5)[/math]. So, for example,

[[math]] \begin{eqnarray*} m_{12} &=& \frac{z_{22} - z_{12}}{w_2} \\ &=& \frac{21/25 - 1/25}{1/5} \\ &=& 4\ ,\\ \end{eqnarray*} [[/math]]

by Theorem. Carrying out the calculations for the other entries of [math]\mat{M}[/math], we obtain

[[math]] \mat {M} = \pmatrix{ 0 & 4 & 10/3\cr 8/3 & 0 & 8/3\cr 10/3 & 4 & 0\cr}\ . [[/math]]


Computation

The program ErgodicChain calculates the fundamental matrix, the fixed vector, the mean recurrence matrix [math]\mat{D}[/math], and the mean first passage matrix [math]\mat{M}[/math]. We have run the program for the Ehrenfest urn model (Example). We obtain:

[[math]] \mat {P} = \bordermatrix{ & 0 & 1 & 2 & 3 & 4 \cr 0 & .0000 & 1.0000 & .0000 & .0000 & .0000\cr 1 & .2500 & .0000 & .7500 & .0000 & .0000\cr 2 & .0000 & .5000 & .0000 & .5000 & .0000\cr 3 & .0000 & .0000 & .7500 & .0000 & .2500\cr 4 & .0000 & .0000 & .0000 & 1.0000& .0000}\ ; [[/math]]


[[math]] \mat {w} = \bordermatrix{ & 0 & 1 & 2 & 3 & 4\cr & .0625 &.2500 &.3750 &.2500 &.0625}\ ; [[/math]]


[[math]] \mat {r} = \bordermatrix{ & 0 & 1 & 2 & 3 & 4\cr & 16.0000 & 4.0000 & 2.6667 & 4.0000 & 16.0000}\ ; [[/math]]


[[math]] \mat {M} = \bordermatrix{ & 0 & 1 & 2 & 3 & 4\cr 0 & .0000 & 1.0000 & 2.6667 & 6.3333 & 21.3333\cr 1 & 15.0000 & .0000 & 1.6667 & 5.3333 & 20.3333\cr 2 & 18.6667 & 3.6667 & .0000 & 3.6667 & 18.6667\cr 3 & 20.3333 & 5.3333 & 1.6667 & .0000 & 15.0000\cr 4 & 21.3333 & 6.3333 & 2.6667 & 1.0000 & .0000}\ . [[/math]]


From the mean first passage matrix, we see that the mean time to go from 0 balls in urn 1 to 2 balls in urn 1 is 2.6667 steps while the mean time to go from 2 balls in urn 1 to 0 balls in urn 1 is 18.6667. This reflects the fact that the model exhibits a central tendency. Of course, the physicist is interested in the case of a large number of molecules, or balls, and so we should consider this example for [math]n[/math] so large that we cannot compute it even with a computer.

Ehrenfest Model

Example Let us consider the Ehrenfest model (see Example \ref{exam 11.1.6}) for gas diffusion for the general case of [math]2n[/math] balls. Every second, one of the [math]2n[/math] balls is chosen at random and moved from the urn it was in to the other urn. If there are [math]i[/math] balls in the first urn, then with probability [math]i/2n[/math] we take one of them out and put it in the second urn, and with probability [math](2n - i)/2n[/math] we take a ball from the second urn and put it in the first urn. At each second we let the number [math]i[/math] of balls in the first urn be the state of the system. Then from state [math]i[/math] we can pass only to state [math]i - 1[/math] and [math]i + 1[/math], and the transition probabilities are given by

[[math]] p_{ij} = \left \{ \matrix{ \frac i{2n}\ , & \mbox{if} \,\,j = i-1, \cr 1 - \frac i{2n}\ , & \mbox{if} \,\,j = i+1, \cr 0\ , & \mbox{otherwise.}\cr}\right. [[/math]]


This defines the transition matrix of an ergodic, non-regular Markov chain (see Exercise). Here the physicist is interested in long-term predictions about the state occupied. In Example, we gave an intuitive reason for expecting that the fixed vector [math]\mat{w}[/math] is the binomial distribution with parameters [math]2n[/math] and [math]1/2[/math]. It is easy to check that this is correct. So,

[[math]] w_i = \frac{{2n \choose i}}{2^{2n}}\ . [[/math]]

Thus the mean recurrence time for state [math]i[/math] is

[[math]] r_i = \frac{2^{2n}}{{2n \choose i}}\ . [[/math]]


Consider in particular the central term [math]i = n[/math]. We have seen that this term is approximately [math]1/\sqrt{\pi n}[/math]. Thus we may approximate [math]r_n[/math] by [math]\sqrt{\pi n}[/math].


This model was used to explain the concept of reversibility in physical systems. Assume that we let our system run until it is in equilibrium. At this point, a movie is made, showing the system's progress. The movie is then shown to you, and you are asked to tell if the movie was shown in the forward or the reverse direction. It would seem that there should always be a tendency to move toward an equal proportion of balls so that the correct order of time should be the one with the most transitions from [math]i[/math] to [math]i - 1[/math] if [math]i \gt n[/math] and [math]i[/math] to [math]i + 1[/math] if [math]i \lt n[/math].


In Figure \ref{fig 11.6} we show the results of simulating the Ehrenfest urn model for the case of [math]n = 50[/math] and 1000 time units, using the program EhrenfestUrn. The top graph shows these results graphed in the order in which they occurred and the bottom graph shows the same results but with time reversed. There is no apparent difference.


We note that if we had not started in equilibrium, the two graphs would typically look quite different.


Reversibility

If the Ehrenfest model is started in equilibrium, then the process has no apparent time direction. The reason for this is that this process has a property called reversibility. Define [math]X_n[/math] to be the number of balls in the left urn at step [math]n[/math]. We can calculate, for a general ergodic chain, the reverse transition probability:

[[math]] \begin{eqnarray*} P(X_{n - 1} = j | X_n = i) &=& \frac{P(X_{n - 1} = j,X_n = i)}{P(X_n = i)} \\ &=& \frac{P(X_{n - 1} = j) P(X_n = i | X_{n - 1} = j)}{P(X_n = i)} \\ &=& \frac{P(X_{n - 1} = j) p_{ji}}{P(X_n = i)}\ .\\ \end{eqnarray*} [[/math]]


In general, this will depend upon [math]n[/math], since [math]P(X_n = j)[/math] and also [math]P(X_{n - 1} = j)[/math] change with [math]n[/math]. However, if we start with the vector [math]\mat{w}[/math] or wait until equilibrium is reached, this will not be the case. Then we can define

[[math]] p_{ij}^* = \frac{w_j p_{ji}}{w_i} [[/math]]

as a transition matrix for the process watched with time reversed.


Let us calculate a typical transition probability for the reverse chain [math]\mat{ P}^* = \{p_{ij}^*\}[/math] in the Ehrenfest model. For example,

[[math]] \begin{eqnarray*} p_{i,i - 1}^* &=& \frac{w_{i - 1} p_{i - 1,i}}{w_i} = \frac{{2n \choose {i - 1}}}{2^{2n}} \times \frac{2n - i + 1}{2n} \times \frac{2^{2n}}{{2n \choose i}}\\ &=& \frac{(2n)!}{(i - 1)!\,(2n - i + 1)!} \times \frac{(2n - i + 1) i!\, (2n - i)!}{2n(2n)!} \\ &=& \frac{i}{2n} = p_{i,i - 1}\ .\\ \end{eqnarray*} [[/math]]


Similar calculations for the other transition probabilities show that [math]\mat {P}^* = \mat {P}[/math]. When this occurs the process is called reversible. Clearly, an ergodic chain is reversible if, and only if, for every pair of states [math]s_i[/math] and [math]s_j[/math], [math]w_i p_{ij} = w_j p_{ji}[/math]. In particular, for the Ehrenfest model this means that [math]w_i p_{i,i - 1} = w_{i - 1} p_{i - 1,i}[/math]. Thus, in equilibrium, the pairs [math](i, i - 1)[/math] and [math](i - 1, i)[/math] should occur with the same frequency. While many of the Markov chains that occur in applications are reversible, this is a very strong condition. In Exercise Exercise you are asked to find an example of a Markov chain which is not reversible.


The Central Limit Theorem for Markov Chains

Suppose that we have an ergodic Markov chain with states [math]s_1, s_2, \ldots, s_k[/math]. It is natural to consider the distribution of the random variables [math]S^{(n)}_j[/math], which denotes the number of times that the chain is in state [math]s_j[/math] in the first [math]n[/math] steps. The [math]j[/math]th component [math]w_j[/math] of the fixed probability row vector [math]\mat{w}[/math] is the proportion of times that the chain is in state [math]s_j[/math] in the long run. Hence, it is reasonable to conjecture that the expected value of the random variable [math]S^{(n)}_j[/math], as [math]n \rightarrow \infty[/math], is asymptotic to [math]nw_j[/math], and it is easy to show that this is the case (see Exercise \ref{exer 11.5.29}).


It is also natural to ask whether there is a limiting distribution of the random variables [math]S^{(n)}_j[/math]. The answer is yes, and in fact, this limiting distribution is the normal distribution. As in the case of independent trials, one must normalize these random variables. Thus, we must subtract from [math]S^{(n)}_j[/math] its expected value, and then divide by its standard deviation. In both cases, we will use the asymptotic values of these quantities, rather than the values themselves. Thus, in the first case, we will use the value [math]nw_j[/math]. It is not so clear what we should use in the second case. It turns out that the quantity

[[math]] \begin{equation} \sigma_j^2 = 2w_jz_{jj} - w_j - w_j^2 \label{eq 11.5.9} \end{equation} [[/math]]

represents the asymptotic variance. Armed with these ideas, we can state the following theorem.

Theorem

(Central Limit Theorem for Markov Chains) For an ergodic chain, for any real numbers [math]r \lt s[/math], we have

[[math]] P\Biggl(r \lt {{S^{(n)}_j - nw_j}\over{\sqrt{n\sigma_j^2}}} \lt s\Biggr) \rightarrow {1\over{\sqrt {2\pi}}}\int_r^s e^{-x^2/2}\,dx\ , [[/math]]
as [math]n \rightarrow \infty[/math], for any choice of starting state, where [math]\sigma_j^2[/math] is the quantity defined in Equation.


Historical Remarks

Markov chains were introduced by Andre\u i Andreevich Markov (1856--1922) and were named in his honor. He was a talented undergraduate who received a gold medal for his undergraduate thesis at St. Petersburg University. Besides being an active research mathematician and teacher, he was also active in politics and patricipated in the liberal movement in Russia at the beginning of the twentieth century. In 1913, when the government celebrated the 300th anniversary of the House of Romanov family, Markov organized a counter-celebration of the 200th anniversary of Bernoulli's discovery of the Law of Large Numbers.


Markov was led to develop Markov chains as a natural extension of sequences of independent random variables. In his first paper, in 1906, he proved that for a Markov chain with positive transition probabilities and numerical states the average of the outcomes converges to the expected value of the limiting distribution (the fixed vector). In a later paper he proved the central limit theorem for such chains. Writing about Markov, A. P. Youschkevitch remarks:

Markov arrived at his chains starting from the internal needs of probability theory, and he never wrote about their applications to physical science. For him the only real examples of the chains were literary texts, where the two states denoted the vowels and consonants.[Notes 1]


In a paper written in 1913,[Notes 2] Markov chose a sequence of 20,00 letters from Pushkin's Eugene Onegin to see if this sequence can be approximately considered a simple chain. He obtained the Markov chain with transition matrix

[[math]] \bordermatrix{ & \mbox{vowel} & \mbox{consonant} \cr \mbox{vowel} & .128 & .872 \cr \mbox{consonant} & .663 & .337}\ . [[/math]]


The fixed vector for this chain is [math](.432, .568)[/math], indicating that we should expect about 43.2 percent vowels and 56.8 percent consonants in the novel, which was borne out by the actual count.


Claude Shannon considered an interesting extension of this idea in his book The Mathematical Theory of Communication,[Notes 3] in which he developed the informa\-tion-theoretic concept of entropy. Shannon considers a series of Markov chain approximations to English prose. He does this first by chains in which the states are letters and then by chains in which the states are words. For example, for the case of words he presents first a simulation where the words are chosen independently but with appropriate frequencies.


REPRESENTING AND SPEEDILY IS AN GOOD APT OR COME CAN DIFFERENT NATURAL HERE HE THE A IN CAME THE TO OF TO EXPERT GRAY COME TO FURNISHES THE LINE MESSAGE HAD BE THESE.


He then notes the increased resemblence to ordinary English text when the words are chosen as a Markov chain, in which case he obtains

THE HEAD AND IN FRONTAL ATTACK ON AN ENGLISH WRI\-TER THAT THE CHARACTER OF THIS POINT IS THEREFORE ANOTHER METHOD FOR THE LETTERS THAT THE TIME OF WHO EVER TOLD THE PROBLEM FOR AN UNEXPECTED.


A simulation like the last one is carried out by opening a book and choosing the first word, say it is the. Then the book is read until the word the appears again and the word after this is chosen as the second word, which turned out to be head. The book is then read until the word head appears again and the next word, and, is chosen, and so on.


Other early examples of the use of Markov chains occurred in Galton's study of the problem of survival of family names in 1889 and in the Markov chain introduced by P. and T. Ehrenfest in 1907 for diffusion. Poincar\'{e} in 1912 dicussed card shuffling in terms of an ergodic Markov chain defined on a permutation group. Brownian motion, a continuous time version of random walk, was introducted in 1900--1901 by L. Bachelier in his study of the stock market, and in 1905--1907 in the works of A. Einstein and M. Smoluchowsky in their study of physical processes.


One of the first systematic studies of finite Markov chains was carried out by M. Frechet.[Notes 4] The treatment of Markov chains in terms of the two fundamental matrices that we have used was developed by Kemeny and Snell [Notes 5] to avoid the use of eigenvalues that one of these authors found too complex. The fundamental matrix [math]\mat{N}[/math] occurred also in the work of J. L. Doob and others in studying the connection between Markov processes and classical potential theory. The fundamental matrix [math]\mat{Z}[/math] for ergodic chains appeared first in the work of Frechet, who used it to find the limiting variance for the central limit theorem for Markov chains. \exercises


\choice{}{% Modified on 6-4-05.==General references== Doyle, Peter G. (2006). "Grinstead and Snell's Introduction to Probability" (PDF). Retrieved June 6, 2024.

Notes

  1. See Dictionary of Scientific Biography, ed. C. C. Gillespie (New York: Scribner's Sons, 1970), pp. 124--130.
  2. A. A. Markov, “An Example of Statistical Analysis of the Text of Eugene Onegin Illustrating the Association of Trials into a Chain,” Bulletin de l'Acadamie Imperiale des Sciences de St. Petersburg, ser. 6, vol. 7 (1913), pp. 153--162.
  3. C. E. Shannon and W. Weaver, The Mathematical Theory of Communication (Urbana: Univ.\ of Illinois Press, 1964).
  4. M. Frechet, “Théorie des événements en chaine dans le cas d'un nombre fini d'états possible,” in Recherches théoriques Modernes sur le calcul des probabilités, vol. 2 (Paris, 1938).
  5. J. G. Kemeny and J. L. Snell, Finite Markov Chains.