Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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30.4 RANDOM VARIABLES AND DISTRIBUTIONS


Substituting this expression into (30.37) gives


W{ni}=N!

∏R


i=1

gi!
ni!(gi−ni)!

.


Such a system of particles has the names of no famous scientists attached to it, since it
appears that it never occurs in nature.


30.4 Random variables and distributions

Suppose an experiment has an outcome sample spaceS. A real variableXthat


is defined for all possible outcomes inS(so that a real number – not necessarily


unique – is assigned to each possible outcome) is called arandom variable(RV).


The outcome of the experiment may already be a real number and hence a random


variable, e.g. the number of heads obtained in 10 throws of a coin, or the sum of


the values if two dice are thrown. However, more arbitrary assignments are possi-


ble, e.g. the assignment of a ‘quality’ rating to each successive item produced by a


manufacturing process. Furthermore, assuming that a probability can be assigned


to all possible outcomes in a sample spaceS, it is possible to assign aprobability


distributionto any random variable. Random variables may be divided into two


classes, discrete and continuous, and we now examine each of these in turn.


30.4.1 Discrete random variables

A random variableXthat takes only discrete valuesx 1 ,x 2 ,...,xn, with proba-


bilitiesp 1 ,p 2 ,...,pn, is called a discrete random variable. The number of values


nfor whichXhas a non-zero probability is finite or at most countably infinite.


As mentioned above, an example of a discrete random variable is the number of


heads obtained in 10 throws of a coin. IfXis a discrete random variable, we can


define aprobability function(PF)f(x) that assigns probabilities to all the distinct


values thatXcan take, such that


f(x)=Pr(X=x)=

{
pi ifx=xi,
0otherwise.

(30.38)

A typical PF (see figure 30.6) thus consists of spikes, atvalid valuesofX, whose


height atxcorresponds to the probability thatX=x. Since the probabilities


must sum to unity, we require


∑n

i=1

f(xi)=1. (30.39)

We may also define thecumulative probability function(CPF) ofX,F(x), whose

value gives the probability thatX≤x,sothat


F(x)=Pr(X≤x)=


xi≤x

f(xi). (30.40)
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