Example: 
. Then
and the chain is otherwise specivied by 
and 
. The matrix 
is
The backward equations become
while the forward equations are
Add 
first plus 
third backward equations to get
so
Put t=0 to get 
. This gives
Plug this back in to the first equation and get
Multiply by 
and get
which can be integrated to get
Alternative calculation:
can be written as
where
and
Then
Now
so we get
where
Notice: rows of 
are a stationary initial distribution. If rows are
then
so
Moreover
Fact: 
is long run fraction of time in
state 0.
Fact:
Ergodic Theorem in continuous time.
Birth and Death Processes
Consider a population of X(t) individuals. Suppose
in next time interval (t,t+h) probability of population
increase of 1 (called a birth) is 
and
probability of decrease of 1 (death) is 
.
Jargon: X is a birth and death process.
Special cases:
All 
; called a pure birth process.
All 
(0 is absorbing): pure death process.
and 
is a linear
birth and death process.
, 
: Poisson Process.
and is a linear
birth and death process with immigration.
Queuing Theory
Ingredients of Queuing Problem:
1: Queue input process.
2: Number of servers
3: Queue discipline: first come first serve? last in first out? pre-emptive priorities?
4: Service time distribution.
Example:
Imagine customers arriving at a facility at times of a Poisson
Process N with rate 
. This is the input process,
denoted M (for Markov) in queuing literature.
Single server case:
Service distribution: exponential service times, rate 
.
Queue discipline: first come first serve.
X(t) = number of customers in line at time t.
X is a Markov process called M/M/1 queue:
Example: 
queue:
Customers arrive according to PP rate . Each
customer begins service immediately. X(t) is number
being served at time t. X is a birth and death process
with
and
Stationary Initial Distributions
We have seen that a stationary initial distribution is
a probability vector solving
Rewrite this as
Interpretation: LHS is rate at which process leaves state j; process is
in state j a fraction 
of time and then makes transition at rate
. RHS is total rate of arrival in state j. For each state
is fraction of time spent in state i and
then 
the instantaneous rate of transition from i to j.
So equation says:
Rate of departure from j balances rate of arrival to j. This is called balance.
Application to birth and death processes:
Equation is
for 
and
Notice that this permits the recursion
which extends by induction to
Apply 
to get
This gives the formula announced:
If
then we have defined a probability vector which solves
Since
we see that
so that 
is constant. Put t=0 to discover that
the constant is .