Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

31.4 SOME BASIC ESTIMATORS


a 1

a 2

ˆa 1

aˆ 2

atrue atrue

aˆobs ˆaobs

(a) (b)

Figure 31.4 (a) The ellipseQ(aˆ,a)=cinaˆ-space. (b) The ellipseQ(a,aˆobs)=c
ina-space that corresponds to a confidence regionRat the level 1−α,when
csatisfies (31.39).

confidence level 1−αis given byQ(a,aˆobs)=c,wheretheconstantcsatisfies
∫c


0

P(χ^2 M)d(χ^2 M)=1−α, (31.39)

andP(χ^2 M) is the chi-squared PDF of orderM, discussed in subsection 30.9.4. This


integral may be evaluated numerically to determine the constantc. Alternatively,


some reference books tabulate the values ofccorresponding to given confidence


levels and various values ofM. A representative selection of values ofcis given


in table 31.2; there the number of degrees of freedom is denoted by the more


usualn, rather thanM.


31.4 Some basic estimators

In many cases, one does not know the functional form of the population from


which a sample is drawn. Nevertheless, in a case where the sample values


x 1 ,x 2 ,...,xNare each drawnindependentlyfrom a one-dimensional population


P(x), it is possible to construct some basic estimators for the moments and central


moments ofP(x). In this section, we investigate the estimating properties of the


common sample statistics presented in section 31.2. In fact, expectation values


and variances of these sample statistics can be calculatedwithoutprior knowledge


of the functional form of the population; they depend only on the sample sizeN


and certain moments and central moments ofP(x).


31.4.1 Population meanμ

Let us suppose that the parent populationP(x) has meanμand varianceσ^2 .An


obvious estimatorμˆof the population mean is the sample meanx ̄. Providedμ


andσ^2 are both finite, we may apply the central limit theorem directly to obtain

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