Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

PROBABILITY


Scaling and shifting

IfY=aX+b,whereaandbare arbitrary constants, then


MY(t)=E

[
etY

]
=E

[
et(aX+b)

]
=ebtE

[
eatX

]
=ebtMX(at). (30.88)

This result is often useful for obtaining thecentralmoments of a distribution. If the


MFG ofXisMX(t) then the variableY=X−μhas the MGFMY(t)=e−μtMX(t),


which clearly generates the central moments ofX,i.e.


E[(X−μ)n]=E[Yn]=M(Yn)(0) =

(
dn
dtn

[e−μtMX(t)]

)

t=0

.

Sums of random variables

IfX 1 ,X 2 ,...,XNare independent random variables andSN=X 1 +X 2 +···+XN


then


MSN(t)=E

[
etSN

]
=E

[
et(X^1 +X^2 +···+XN)

]
=E

[N

i=1

etXi

]

.

Since theXiareindependent,


MSN(t)=

∏N

i=1

E

[
etXi

]
=

∏N

i=1

MXi(t). (30.89)

In words, the MGF of the sum ofNindependent random variables is the product


of their individual MGFs. By combining (30.89) with (30.88), we obtain the more


general result that the MGF ofSN=c 1 X 1 +c 2 X 2 +···+cNXN(where theciare


constants) is given by


MSN(t)=

∏N

i=1

MXi(cit). (30.90)

Variable-length sums of random variables

Let us consider the sum ofNindependent random variablesXi(i=1, 2 ,...,N), all


with the same probability distribution, and let us suppose thatNis itself a random


variable with a known distribution. Following the notation of section 30.7.1,


SN=X 1 +X 2 +···+XN,

whereNis a random variable with Pr(N=n)=hnand probability generating


functionχN(t)=



hntn. For definiteness, let us assume that theXiare continuous

RVs (an analogous discussion can be given in the discrete case). Thus, the

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