RV coefficient

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In statistics, the RV coefficient[1] is a multivariate generalization of the squared Pearson correlation coefficient (because the RV coefficient takes values between 0 and 1).[2] It measures the closeness of two set of points that may each be represented in a matrix.

The major approaches within statistical multivariate data analysis can all be brought into a common framework in which the RV coefficient is maximised subject to relevant constraints. Specifically, these statistical methodologies include:[1]

One application of the RV coefficient is in functional neuroimaging where it can measure the similarity between two subjects' series of brain scans[3] or between different scans of a same subject.[4]

Definitions

The definition of the RV-coefficient makes use of ideas[5] concerning the definition of scalar-valued quantities which are called the "variance" and "covariance" of vector-valued random variables. Note that standard usage is to have matrices for the variances and covariances of vector random variables. Given these innovative definitions, the RV-coefficient is then just the correlation coefficient defined in the usual way.

Suppose that X and Y are matrices of centered random vectors (column vectors) with covariance matrix given by

[math]\displaystyle{ \Sigma_{XY}=\operatorname{E}( XY^\top) \,, }[/math]

then the scalar-valued covariance (denoted by COVV) is defined by[5]

[math]\displaystyle{ \operatorname{COVV}(X,Y)= \operatorname{Tr}(\Sigma_{XY}\Sigma_{YX}) \, . }[/math]

The scalar-valued variance is defined correspondingly:

[math]\displaystyle{ \operatorname{VAV}(X)= \operatorname{Tr}(\Sigma_{XX}^2) \, . }[/math]

With these definitions, the variance and covariance have certain additive properties in relation to the formation of new vector quantities by extending an existing vector with the elements of another.[5]

Then the RV-coefficient is defined by[5]

[math]\displaystyle{ \mathrm{RV}(X,Y) = \frac { \operatorname{COVV}(X,Y) } { \sqrt{ \operatorname{VAV}(X) \operatorname{VAV}(Y) } } \, . }[/math]

Shortcoming of the coefficient and adjusted version

Even though the coefficient takes values between 0 and 1 by construction, it seldom attains values close to 1 as the denominator is often too large with respect to the maximal attainable value of the denominator.[6]

Given known diagonal blocks [math]\displaystyle{ \Sigma_{XX} }[/math] and [math]\displaystyle{ \Sigma_{YY} }[/math] of dimensions [math]\displaystyle{ p\times p }[/math] and [math]\displaystyle{ q\times q }[/math] respectively, assuming that [math]\displaystyle{ p \le q }[/math] without loss of generality, it has been proved[7] that the maximal attainable numerator is [math]\displaystyle{ \operatorname{Tr}(\Lambda_X \Pi \Lambda_Y), }[/math] where [math]\displaystyle{ \Lambda_X }[/math] (resp. [math]\displaystyle{ \Lambda_Y }[/math]) denotes the diagonal matrix of the eigenvalues of [math]\displaystyle{ \Sigma_{XX} }[/math](resp. [math]\displaystyle{ \Sigma_{YY} }[/math]) sorted decreasingly from the upper leftmost corner to the lower rightmost corner and [math]\displaystyle{ \Pi }[/math] is the [math]\displaystyle{ p \times q }[/math] matrix [math]\displaystyle{ (I_p \ 0_{p\times (q-p)} ) }[/math].

In light of this, Mordant and Segers[7] proposed an adjusted version of the RV coefficient in which the denominator is the maximal value attainable by the numerator. It reads

[math]\displaystyle{ \bar{\operatorname{RV}}(X,Y) = \frac{\operatorname{Tr}(\Sigma_{XY}\Sigma_{YX})}{\operatorname{Tr}(\Lambda_X \Pi \Lambda_Y)} = \frac{\operatorname{Tr}(\Sigma_{XY}\Sigma_{YX})}{\sum_{j=1}^{min(p,q)} (\Lambda_X)_{j,j} (\Lambda_Y)_{j,j}}. }[/math]

The impact of this adjustment is clearly visible in practice.[7]

See also

References

  1. 1.0 1.1 Robert, P.; Escoufier, Y. (1976). "A Unifying Tool for Linear Multivariate Statistical Methods: The RV-Coefficient". Applied Statistics 25 (3): 257–265. doi:10.2307/2347233. 
  2. Abdi, Hervé (2007). Salkind, Neil J. ed. RV coefficient and congruence coefficient. Thousand Oaks. ISBN 978-1-4129-1611-0. 
  3. Ferath Kherif; Jean-Baptiste Poline; Sébastien Mériaux; Habib Banali; Guillaume Plandin; Matthew Brett (2003). "Group analysis in functional neuroimaging: selecting subjects using similarity measures". NeuroImage 20 (4): 2197–2208. doi:10.1016/j.neuroimage.2003.08.018. PMID 14683722. https://hal-cea.archives-ouvertes.fr/cea-00371054/file/Kherifetal_NeuroImage.pdf. 
  4. Herve Abdi; Joseph P. Dunlop; Lynne J. Williams (2009). "How to compute reliability estimates and display confidence and tolerance intervals for pattern classiffers using the Bootstrap and 3-way multidimensional scaling (DISTATIS)". NeuroImage 45 (1): 89–95. doi:10.1016/j.neuroimage.2008.11.008. PMID 19084072. 
  5. 5.0 5.1 5.2 5.3 Escoufier, Y. (1973). "Le Traitement des Variables Vectorielles". Biometrics (International Biometric Society) 29 (4): 751–760. doi:10.2307/2529140. 
  6. Pucetti, G. (2019). "Measuring Linear Correlation Between Random Vectors". SSRN. http://dx.doi.org/10.2139/ssrn.3116066s. 
  7. 7.0 7.1 7.2 Mordant Gilles; Segers Johan (2022). "Measuring dependence between random vectors via optimal transport,". Journal of Multivariate Analysis 189.