Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

STATISTICS


Using (31.113) to substitute for ̄x−μ 0 in (31.116), and noting thatdx ̄=


(s/



N−1)dt, we find

P( ̄x, s|H 0 )d ̄xds=AsN−^1 exp

[

Ns^2
2 σ^2

(
1+

t^2
N− 1

)]
dt ds,

whereAis another normalisation constant. In order to obtain the sampling


distribution oftalone, we must integrateP(t, s|H 0 ) with respect tosover its


allowed range, from 0 to∞. Thus, the required distribution oftalone is given by


P(t|H 0 )=

∫∞

0

P(t, s|H 0 )ds=A

∫∞

0

sN−^1 exp

[

Ns^2
2 σ^2

(
1+

t^2
N− 1

)]
ds.
(31.117)

To carry out this integration, we sety=s{1+[t^2 /(N−1)]}^1 /^2 , which on substi-


tution into (31.117) yields


P(t|H 0 )=A

(
1+

t^2
N− 1

)−N/ 2 ∫∞

0

yN−^1 exp

(

Ny^2
2 σ^2

)
dy.

Since the integral overydoes not depend ont, it is simply a constant. We thus


find that that the sampling distribution of the variabletis


P(t|H 0 )=

1

(N−1)π

Γ

( 1
2 N

)

Γ

( 1
2 (N−1)

)

(
1+

t^2
N− 1

)−N/ 2
,
(31.118)

wherewehaveusedthecondition


∫∞
−∞P(t|H^0 )dt= 1 to determine the normali-
sation constant (see exercise 31.18).


The distribution (31.118) is calledStudent’st-distribution withN− 1 degrees of

freedom. A plot of Student’st-distribution is shown in figure 31.11 for various


values ofN. For comparison, we also plot the standard Gaussian distribution,


to which thet-distribution tends for largeN. As is clear from the figure, the


t-distribution is symmetric aboutt= 0. In table 31.3 we list some critical points


of the cumulative probability functionCn(t)ofthet-distribution, which is defined


by


Cn(t)=

∫t

−∞

P(t′|H 0 )dt′,

wheren=N−1 is the number of degrees of freedom. Clearly,Cn(t) is analogous


to the cumulative probability function Φ(z) of the Gaussian distribution, discussed


in subsection 30.9.1. For comparison purposes, we also list the critical points of


Φ(z), which corresponds to thet-distribution forN=∞.

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