Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

31.2 SAMPLE STATISTICS


moments of the sample. For example,


n 3 =

1
N

∑N

i=1

(xi−m 1 )^3

=

1
N

∑N

i=1

(x^3 i− 3 m 1 x^2 i+3m^21 xi−m^31 )

=m 3 − 3 m 1 m 2 +3m^21 m 1 −m^31

=m 3 − 3 m 1 m 2 +2m^31 , (31.11)

which may be compared with equation (30.53) in the previous chapter.


Mirroring our discussion of the normalised central momentsγrof a population

in subsection 30.5.5, we can also describe a sample in terms of the dimensionless


quantities


gk=

nk

nk/ 22

=

nk
sk

;

g 3 andg 4 are called the sample skewness and kurtosis. Likewise, it is common to


define theexcesskurtosis of a sample byg 4 −3.


31.2.4 Covariance and correlation

So far we have assumed that each data item of the sample consists of a single


number. Now let us suppose that each item of data consists of a pair of numbers,


so that the sample is given by (xi,yi),i=1, 2 ,...,N.


We may calculate the sample means,x ̄and ̄y, and sample variances,s^2 xand

s^2 y,ofthexiandyivalues individually but these statistics do not provide any


measure of the relationship between thexiandyi. By analogy with our discussion


in subsection 30.12.3 we measure any interdependence between thexiandyiin


terms of thesample covariance, which is given by


Vxy=

1
N

∑N

i=1

(xi− ̄x)(yi− ̄y)

=(x− ̄x)(y−y ̄)

=xy− ̄x ̄y. (31.12)

Writing out the last expression in full, we obtain the form most useful for


calculations, which reads


Vxy=

1
N

(N

i=1

xiyi

)


1
N^2

(N

i=1

xi

)(N

i=1

yi

)

.
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