Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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30.7 GENERATING FUNCTIONS


variance of both sides of (30.66), and using (30.68), we find


V[Z(X, Y)]≈

(
∂Z
∂X

) 2
V[X]+

(
∂Z
∂Y

) 2
V[Y], (30.69)

the partial derivatives being evaluated atX=μXandY=μY.


30.7 Generating functions

As we saw in chapter 16, when dealing with particular sets of functionsfn,


each member of the set being characterised by a different non-negative integer


n, it is sometimes possible to summarise the whole set by a single function of a


dummy variable (sayt), called a generating function. The relationship between


the generating function and thenth memberfnof the set is that if the generating


function is expanded as a power series intthenfnis the coefficient oftn.For


example, in the expansion of the generating functionG(z, t)=(1− 2 zt+t^2 )−^1 /^2 ,


the coefficient oftnis thenth Legendre polynomialPn(z), i.e.


G(z, t)=(1− 2 zt+t^2 )−^1 /^2 =

∑∞

n=0

Pn(z)tn.

We found that many useful properties of, and relationships between, the members


of a set of functions could be established using the generating function and other


functions obtained from it, e.g. its derivatives.


Similar ideas can be used in the area of probability theory, and two types of

generating function can be usefully defined, one more generally applicable than


the other. The more restricted of the two, applicable only to discrete integral


distributions, is called a probability generating function; this is discussed in the


next section. The second type, a moment generating function, can be used with


both discrete and continuous distributions and is considered in subsection 30.7.2.


From the moment generating function, we may also construct the closely re-


lated characteristic and cumulant generating functions; these are discussed in


subsections 30.7.3 and 30.7.4 respectively.


30.7.1 Probability generating functions

As already indicated, probability generating functions are restricted in applicabil-


ity to integer distributions, of which the most common (the binomial, the Poisson


and the geometric) are considered in this and later subsections. In such distribu-


tions a random variable may take only non-negative integer values. The actual


possible values may be finite or infinite in number, but, for formal purposes,


all integers, 0, 1 , 2 ,...are considered possible. If only a finite number of integer


values can occur in any particular case then those that cannot occur are included


but are assigned zero probability.

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