Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

PROBABILITY


A random variableXhas a PDFf(x)given byAe−xin the interval 0 <x<∞and zero
elsewhere. Find the value of the constantAand hence calculate the probability thatXlies
in the interval 1 <X≤ 2.

We require the integral off(x) between 0 and∞to equal unity. Evaluating this integral,
we find ∫


0

Ae−xdx=

[


−Ae−x

]∞


0 =A,


and henceA= 1. From (30.42), we then obtain


Pr(1<X≤2) =

∫ 2


1

f(x)dx=

∫ 2


1

e−xdx=−e−^2 −(−e−^1 )=0. 23 .

It is worth mentioning here that adiscreteRV can in fact be treated as

continuous and assigned a corresponding probability density function. IfXis a


discrete RV that takes only the valuesx 1 ,x 2 ,...,xnwith probabilitiesp 1 ,p 2 ,...,pn


then we may describeXas a continuous RV with PDF


f(x)=

∑n

i=1

piδ(x−xi), (30.44)

whereδ(x) is the Dirac delta function discussed in subsection 13.1.3. From (30.42)


and the fundamental property of the delta function (13.12), we see that


Pr(a<X≤b)=

∫b

a

f(x)dx,

=

∑n

i=1

pi

∫b

a

δ(x−xi)dx=


i

pi,

where the final sum extends over those values ofifor whicha<xi≤b.


30.4.3 Sets of random variables

It is common in practice to consider two or more random variables simultane-


ously. For example, one might be interested in both the height and weight of


a person drawn at random from a population. In the general case, these vari-


ables may depend on one another and are described byjoint probability density


functions; these are discussed fully in section 30.11. We simply note here that if


we have (say) two random variablesXandYthen by analogy with the single-


variable case we define their joint probability density functionf(x, y)insucha


way that, ifXandYare discrete RVs,


Pr(X=xi,Y=yj)=f(xi,yj),

or, ifXandYare continuous RVs,


Pr(x<X≤x+dx, y < Y≤y+dy)=f(x, y)dx dy.
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