Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

30.11 JOINT DISTRIBUTIONS


consult one of the many specialised texts. However, we do discuss the multinomial


and multivariate Gaussian distributions, in section 30.15.


The first thing to note when dealing with bivariate distributions is that the

distinction between discrete and continuous distributions may not be as clear as


for the single variable case; the random variables can both be discrete, or both


continuous, or one discrete and the other continuous. In general, for the random


variablesXandY, the joint distribution will take an infinite number of values


unless bothXandYhave only a finite number of values. In this chapter we


will consider only the cases whereXandY are either both discrete or both


continuous random variables.


30.11.1 Discrete bivariate distributions

In direct analogy with the one-variable (univariate) case, ifXis a discrete random


variable that takes the values{xi}andYone that takes the values{yj}then the


probability function of the joint distribution is defined as


f(x, y)=

{
Pr(X=xi,Y=yj)forx=xi,y=yj,

0otherwise.

We may therefore think off(x, y) as a set of spikes at valid points in thexy-plane,


whose height at (xi,yi) represents the probability of obtainingX=xiandY=yj.


The normalisation off(x, y) implies



i


j

f(xi,yj)=1, (30.125)

where the sums overiandjtake all valid pairs of values. We can also define the


cumulative probability function


F(x, y)=


xi≤x


yj≤y

f(xi,yj), (30.126)

from which it follows that the probability thatXlies in the range [a 1 ,a 2 ]andY


lies in the range [b 1 ,b 2 ] is given by


Pr(a 1 <X≤a 2 ,b 1 <Y≤b 2 )=F(a 2 ,b 2 )−F(a 1 ,b 2 )−F(a 2 ,b 1 )+F(a 1 ,b 1 ).

Finally, we defineXandYto beindependentif we can write their joint distribution


in the form


f(x, y)=fX(x)fY(y), (30.127)

i.e. as the product of two univariate distributions.

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