Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

30.12 PROPERTIES OF JOINT DISTRIBUTIONS


30.11.3 Marginal and conditional distributions

Given a bivariate distributionf(x, y), we may be interested only in the proba-


bility function forXirrespective of the value ofY(or vice versa). Thismarginal


distribution ofXis obtained by summing or integrating, as appropriate, the


joint probability distribution over all allowed values ofY. Thus, the marginal


distribution ofX(for example) is given by


fX(x)=

{∑

∫jf(x, yj) for a discrete distribution,
f(x, y)dy for a continuous distribution.

(30.130)

It is clear that an analogous definition exists for the marginal distribution ofY.


Alternatively, one might be interested in the probability function ofXgiven

thatYtakes some specific value ofY=y 0 ,i.e.Pr(X=x|Y=y 0 ). Thisconditional


distribution ofXis given by


g(x)=

f(x, y 0 )
fY(y 0 )

,

wherefY(y) is the marginal distribution ofY. The division byfY(y 0 ) is necessary


in order thatg(x) is properly normalised.


30.12 Properties of joint distributions

The probability density functionf(x, y) contains all the information on the joint


probability distribution of two random variablesXandY. In a similar manner


to that presented for univariate distributions, however, it is conventional to


characterisef(x, y) by certain of its properties, which we now discuss. Once


again, most of these properties are based on the concept of expectation values,


which are defined for joint distributions in an analogous way to those for single-


variable distributions (30.46). Thus, the expectation value of any functiong(X, Y)


of the random variablesXandYis given by


E[g(X, Y)] =

{∑
i


∫ jg(xi,yj)f(xi,yj) for the discrete case,

−∞

∫∞
−∞g(x, y)f(x, y)dx dy for the continuous case.

30.12.1 Means

The means ofXandYare defined respectively as the expectation values of the


variablesXandY. Thus, the mean ofXis given by


E[X]=μX=

{∑
i


jxif(xi,yj) for the discrete case,
∫∞
−∞

∫∞
−∞xf(x, y)dx dy for the continuous case. (30.131)

E[Y] is obtained in a similar manner.

Free download pdf