Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

30.8 IMPORTANT DISCRETE DISTRIBUTIONS


1


1


12


2


2 3


3


3 4


4


4 5


5


5 6


6


7


7891011


0


0


0


0


0


0


0. 1 0. 1


0. 1


0. 2


0. 2 0. 2


0. 3


0. 3 0. 3


x

x

x

f(x)

f(x)

f(x)

λ=1 λ=2

λ=5

Figure 30.12 Three Poisson distributions for different values of the parame-
terλ.

The above example illustrates the point that a Poisson distribution typically

rises and then falls. It either has a maximum whenxis equal to the integer part


ofλor, ifλhappens to be an integer, has equal maximal values atx=λ−1and


x=λ. The Poisson distribution always has a long ‘tail’ towards higher values ofX


but the higher the value of the mean the more symmetric the distribution becomes.


Typical Poisson distributions are shown in figure 30.12. Using the definitions of


mean and variance, we may show that, for the Poisson distribution,E[X]=λand


V[X]=λ. Nevertheless, as in the case of the binomial distribution, performing


the relevant summations directly is rather tiresome, and these results are much


more easily proved using the MGF.


The moment generating function for the Poisson distribution

The MGF of the Poisson distribution is given by


MX(t)=E

[
etX

]
=

∑∞

x=0

etxe−λλx
x!

=e−λ

∑∞

x=0

(λet)x
x!

=e−λeλe

t
=eλ(e

t−1)

(30.104)
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