Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

PROBABILITY


0


0 246810 12 14 16 18 20


0. 2


0. 4


0. 6


0. 8


1


r=1

r=2
r=5
r=10

x

f(x)

Figure 30.16 The PDFf(x) for the gamma distributionsγ(λ, r)withλ=1
andr=1, 2 , 5 ,10.

defined for all positiverby replacing (r−1)! by Γ(r) in (30.118); see the appendix


for a discussion of the gamma function Γ(x). If a random variableXis described


by a gamma distribution of orderrwith parameterλ,wewriteX∼γ(λ, r);


we note that the exponential distribution is the special caseγ(λ,1). The gamma


distributionγ(λ, r) is plotted in figure 30.16 forλ= 1 andr=1, 2 , 5 ,10. For


larger, the gamma distribution tends to the Gaussian distribution whose mean


and variance are specified by (30.120) below.


The MGF for the gamma distribution is obtained from that for the exponential

distribution, by noting that we may consider the interval between everyrth event


in a Poisson process as the sum ofrintervals between successive events. Thus the


rth-order gamma variate is the sum ofrindependent exponentially distributed


random variables. From (30.117) and (30.90), the MGF of the gamma distribution


is therefore given by


M(t)=

(
λ
λ−t

)r
, (30.119)

from which the mean and variance are found to be


E[X]=

r
λ

,V[X]=

r
λ^2

. (30.120)


We may also use the above MGF to prove another useful theorem regarding

multiple gamma distributions. IfXi∼γ(λ, ri),i=1, 2 ,...,n, are independent


gamma variates then the random variableY=X 1 +X 2 +···+Xnhas MGF


M(t)=

∏n

i=1

(
λ
λ−t

)ri
=

(
λ
λ−t

)r 1 +r 2 +···+rn

. (30.121)


ThusYis also a gamma variate, distributed asY∼γ(λ, r 1 +r 2 +···+rn).

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