Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

31.5 MAXIMUM-LIKELIHOOD METHOD


By substitutingσ=1/u(so thatdσ=−du/u^2 ) and integrating by parts either (N−2)/ 2
or (N−3)/2 times, we find


P(μ|x,H)∝

[


N( ̄x−μ)^2 +Ns^2

]−(N−1)/ 2


,


where we have used the fact that



i(xi−μ)

(^2) =N( ̄x−μ) (^2) +Ns (^2) , ̄xbeing the sample mean
ands^2 the sample variance. We may now obtain the 95% central confidence interval by
finding the valuesμ−andμ+for which
∫μ−
−∞
P(μ|x,H)dμ=0. 025 and


∫∞


μ+

P(μ|x,H)dμ=0. 025.

The normalisation of the posterior distribution and the valuesμ−andμ+are easily
obtained by numerical integration. Substituting in the appropriate valuesN= 10, ̄x=1. 11
ands=1.01, we find the required confidence interval to be [0. 29 , 1 .97].
To obtain a confidence interval onσ, we must first obtain the corresponding marginal
posterior distribution. From (31.87), again using the fact that



i(xi−μ)

(^2) =N( ̄x−μ) (^2) +Ns (^2) ,
this is given by
P(σ|x,H)∝


1


σN

exp

(



Ns^2
2 σ^2

)∫∞


−∞

exp

[



N( ̄x−μ)^2
2 σ^2

]


dμ.

Noting that the integral of a one-dimensional Gaussian is proportional toσ, we conclude
that


P(σ|x,H)∝

1


σN−^1

exp

(



Ns^2
2 σ^2

)


.


The 95% central confidence interval onσcan then be found in an analogous manner to
that onμ, by solving numerically the equations
∫σ−


0

P(σ|x,H)dσ=0. 025 and

∫∞


σ+

P(σ|x,H)dσ=0. 025.

We find the required interval to be [0. 76 , 2 .16].


31.5.6 Behaviour of ML estimators for largeN

As mentioned in subsection 31.3.6, in the large-sample limitN→∞, the sampling


distribution of a set of (consistent) estimatorsaˆ, whether ML or not, will tend,


in general, to a multivariate Gaussian centred on the true valuesa.Thisisa


direct consequence of the central limit theorem. Similarly, in the limitN→∞the


likelihood functionL(x;a)alsotends towards a multivariate Gaussian but one


centred on the ML estimate(s)ˆa. Thus ML estimators are alwaysasymptotically


consistent. This limiting process was illustrated for the one-dimensional case by


figure 31.5.


Thus, asNbecomes large, the likelihood function tends to the form

L(x;a)=Lmaxexp

[
−^12 Q(a,ˆa)

]
,

whereQdenotes the quadratic form


Q(a,ˆa)=(a−aˆ)TV−^1 (a−aˆ)
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