Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

PROBABILITY


For evaluating binomial probabilities a useful result is the binomial recurrence

formula


Pr(X=x+1)=

p
q

(
n−x
x+1

)
Pr(X=x), (30.95)

which enables successive probabilities Pr(X=x+k),k=1, 2 ,..., to be calculated


once Pr(X=x) is known; it is often quicker to use than (30.94).


The random variableXis distributed asX∼Bin(3,^12 ). Evaluate the probability function
f(x)using the binomial recurrence formula.

The probability Pr(X= 0) may be calculated using (30.94) and is


Pr(X=0)=^3 C 0

( 1


2

) 0 ( 1


2

) 3


=^18.


The ratiop/q=^12 /^12 = 1 in this case and so, using the binomial recurrence formula
(30.95), we find


Pr(X=1)=1×

3 − 0


0+1


×


1


8


=


3


8


,


Pr(X=2)=1×

3 − 1


1+1


×


3


8


=


3


8


,


Pr(X=3)=1×

3 − 2


2+1


×


3


8


=


1


8


,


results which may be verified by direct application of (30.94).


We note that, as required, the binomial distribution satifies

∑n

x=0

f(x)=

∑n

x=0

nC
xp

xqn−x=(p+q)n=1.

Furthermore, from the definitions ofE[X]andV[X] for a discrete distribution,


we may show that for the binomial distributionE[X]=npandV[X]=npq.The


direct summations involved are, however, rather cumbersome and these results


are obtained much more simply using the moment generating function.


The moment generating function for the binomial distribution

To find the MGF for the binomial distribution we consider the binomial random


variableXto be the sum of the random variablesXi,i=1, 2 ,...,n, which are


defined by


Xi=

{
1 if a ‘success’ occurs on theith trial,
0 if a ‘failure’ occurs on theith trial.
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