Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

STATISTICS



P(aˆ|a)

aˆα(a) aˆβ(a)

α β

Figure 31.2 The sampling distributionP(aˆ|a)ofsomeestimatorˆafor a given
value ofa. The shaded regions indicate the two probabilities Pr(a<ˆ aˆα(a)) =α
and Pr(a>ˆ ˆaβ(a)) =β.

ofaˆbyP(aˆ|a). For any particular value ofa, one can determine the two values


aˆα(a)andaˆβ(a) such that


Pr(a<ˆ aˆα(a)) =

∫ˆaα(a)

−∞

P(aˆ|a)dˆa=α, (31.25)

Pr(a>ˆ aˆβ(a)) =

∫∞

aˆβ(a)

P(ˆa|a)daˆ=β. (31.26)

This is illustrated in figure 31.2. Thus, for any particular value ofa, the probability


that the estimatoraˆlies within the limitsaˆα(a)andaˆβ(a) is given by


Pr(ˆaα(a)<a<ˆ aˆβ(a)) =

∫ˆaβ(a)

ˆaα(a)

P(aˆ|a)daˆ=1−α−β.

Now, let us suppose that from our samplex 1 ,x 2 ,...,xN, we actually obtain the

valueaˆobsfor our estimator. Ifˆais a good estimator ofathen we would expect


aˆα(a)andˆaβ(a) to be monotonically increasing functions ofa(i.e.ˆaαandaˆβboth


change in thesamesense asawhen the latter is varied). Assuming this to be the


case, we can uniquely define the two numbersa−anda+by the relationships


aˆα(a+)=aˆobs and aˆβ(a−)=ˆaobs.

From (31.25) and (31.26) it follows that


Pr(a+<a)=α and Pr(a−>a)=β,

which when taken together imply


Pr(a−<a<a+)=1−α−β. (31.27)

Thus, from our estimateaˆobs, we have determined two valuesa−anda+such that


this interval contains the true value ofawith probability 1−α−β. It should be


emphasised thata−anda+are random variables. If a large number of samples,

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