Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

30.7 GENERATING FUNCTIONS


The MGF will exist for all values oftprovided thatXis bounded and always


exists at the pointt=0whereM(0) =E(1) = 1.


It will be apparent that the PGF and the MGF for a random variableX

are closely related. The former is the expectation oftXwhilst the latter is the


expectation ofetX:


ΦX(t)=E

[
tX

]
,MX(t)=E

[
etX

]
.

The MGF can thus be obtained from the PGF by replacingtbyet, and vice


versa. The MGF has more general applicability, however, since it can be used


with both continuous and discrete distributions whilst the PGF is restricted to


non-negative integer distributions.


As its name suggests, the MGF is particularly useful for obtaining the moments

of a distribution, as is easily seen by noting that


E

[
etX

]
=E

[
1+tX+

t^2 X^2
2!

+···

]

=1+E[X]t+E

[
X^2

]t^2
2!

+···.

Assuming that the MGF exists for alltaround the pointt= 0, we can deduce


that the moments of a distribution are given in terms of its MGF by


E[Xn]=

dnMX(t)
dtn





t=0

. (30.86)


Similarly, by substitution in (30.51), the variance of the distribution is given by


V[X]=M′′X(0)−

[
M′X(0)

] 2
, (30.87)

where the prime denotes differentiation with respect tot.


The MGF for the Gaussian distribution (see the end of subsection 30.9.1) is given by
MX(t)=exp

(


μt+^12 σ^2 t^2

)


.


Find the expectation and variance of this distribution.

Using (30.86),


MX′(t)=

(


μ+σ^2 t

)


exp

(


μt+^12 σ^2 t^2

)


⇒ E[X]=M′X(0) =μ,

MX′′(t)=

[


σ^2 +(μ+σ^2 t)^2

]


exp

(


μt+^12 σ^2 t^2

)


⇒ MX′′(0) =σ^2 +μ^2.

Thus, using (30.87),


V[X]=σ^2 +μ^2 −μ^2 =σ^2.

That the mean is found to beμand the varianceσ^2 justifies the use of these symbols in
the Gaussian distribution.


The moment generating function has several useful properties that follow from

its definition and can be employed in simplifying calculations.

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