Spearman rho metric
Spearman rho
The non-parametric correlation coefficient (or measure of association) known as Spearman's rho was first discussed by the psychologist C. Spearman in 1904 [a4] as a coefficient of correlation on ranks (cf. also Correlation coefficient; Rank statistic). In modern use, the term "correlation" refers to a measure of a linear relationship between variates (such as the Pearson product-moment correlation coefficient), while "measure of association" refers to a measure of a monotone relationship between variates (such as the Kendall tau metric and Spearman's rho). For an historical review of Spearman's rho and related coefficients, see [a2].
Spearman's rho, denoted 
, is computed by applying the Pearson product-moment correlation coefficient procedure to the ranks associated with a sample 
. Let 
and 
; then computing the sample (Pearson) correlation coefficient 
for 
yields
 |
 |
where 
. When ties exist in the data, the following adjusted formula for 
is used:
 |
where 
for 
the number of 
observations that are tied at a given rank, and 
for 
the number of 
observations that are tied at a given rank. For details on the use of 
in hypothesis testing, and for large-sample theory, see [a1].
If 
and 
are random variables (cf. Random variable) with respective distribution functions 
and 
, then the population parameter estimated by 
, usually denoted 
, is defined to be the Pearson product-moment correlation coefficient of the random variables 
and 
:
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 |
Spearman's 
is occasionally referred to as the grade correlation coefficient, since 
and 
are sometimes called the "grades" of 
and 
.
Like Kendall's tau, 
is a measure of association based on the notion of concordance. One says that two pairs 
and 
of real numbers are concordant if 
and 
or if 
and 
(i.e., if 
); and discordant if 
and 
or if 
and 
(i.e., if 
). Now, let 
, 
and 
be independent random vectors with the same distribution as 
. Then
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 |
that is, 
is proportional to the difference between the probabilities of concordance and discordance between the random vectors 
and 
(clearly, 
can be replaced by 
).
When 
and 
are continuous,
 |
 |
where 
is the copula of 
and 
. Consequently, 
is invariant under strictly increasing transformations of 
and 
, a property 
shares with Kendall's tau but not with the Pearson product-moment correlation coefficient. Note that 
is proportional to the signed volume between the graphs of the copula 
and the "product" copula 
, the copula of independent random variables. For a survey of copulas and their relationship with measures of association, see [a3].
Spearman [a5] also proposed an 
version of 
, known as Spearman's footrule, based on absolute differences 
in ranks rather than squared differences:
 |
The population parameter 
estimated by 
is given by
 |
 |
References
| [a1] | J.D. Gibbons, "Nonparametric methods for quantitative analysis" , Holt, Rinehart & Winston (1976) |
| [a2] | W.H. Kruskal, "Ordinal measures of association" J. Amer. Statist. Assoc. , 53 (1958) pp. 814–861 |
| [a3] | R.B. Nelsen, "An introduction to copulas" , Springer (1999) |
| [a4] | C. Spearman, "The proof and measurement of association between two things" Amer. J. Psychol. , 15 (1904) pp. 72–101 |
| [a5] | C. Spearman, "A footrule for measuring correlation" Brit. J. Psychol. , 2 (1906) pp. 89–108 |
Spearman rho metric. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Spearman_rho_metric&oldid=15466