Formula test

edit

Formula from AppQM:

 

Sections to replace Covariance matrix#Block matrices

Block matrices

edit

The joint mean   and joint covariance matrix   of   and   can be written in block form

 

where  ,   and  .

  and   can be identified as the variance matrices of the marginal distributions for   and   respectively.

If   and   are jointly normally distributed,

 

then the conditional distribution for   given   is given by

 [1]

defined by conditional mean

 

and conditional variance

 

The matrix   is known as the matrix of regression coefficients, while in linear algebra   is the Schur complement of   in  .

The matrix of regression coefficients may often be given in transpose form,  , suitable for post-multiplying a row vector of explanatory variables   rather than pre-multiplying a column vector  . In this form they correspond to the coefficients obtained by inverting the matrix of the normal equations of ordinary least squares (OLS).

Partial covariance matrix

edit

A covariance matrix with all non-zero elements tells us that all the individual random variables are interrelated. This means that the variables are not only directly correlated, but also correlated via other variable indirectly. Often such indirect, common-mode correlations are trivial and uninteresting. They can be suppressed by calculating the partial covariance matrix, that is the part of covariance matrix that shows only the interesting part of correlations.

If two vectors of random variables   and   are correlated via another vector  , the latter correlations are suppressed in a matrix[2]

 

The partial covariance matrix   is effectively the simple covariance matrix   as if the uninteresting random variables   were held constant.

Covariance matrix as a parameter of a distribution

edit

If a column vector   of   possibly correlated random variables is jointly normally distributed, or more generally elliptically distributed, then its probability density function   can be expressed in terms of the covariance matrix   as follows[2]

 

where   and   is the determinant of  .


Sections to insert at the end of Covariance matrix#Applications

Covariance mapping

edit

In covariance mapping the values of the   or   matrix are plotted as a 2-dimensional map. When vectors   and   are discrete random functions, the map shows statistical relations between different regions of the random functions. Statistically independent regions of the functions show up on the map as zero-level flatland, while positive or negative correlations show up, respectively, as hills or valleys.

In practice the column vectors  , and   are acquired experimentally as rows of   samples, e.g.

 

where   is the i-th descrete value in sample j of the random function  . The expected values needed in the covariance formula are estimated using the sample mean, e.g.

 

and the covariance matrix is estimated by the sample covariance matrix

 

where the angular brackets denote sample averaging as before except that the Bessel's correction should be made to avoid bias. Using this estimation the partial covariance matrix can be calculated as

 

where the backslash denotes the left matrix division operator, which bypasses the requirement to invert a matrix and is available in some computational packages such as Matlab.[3]

 
Figure 1: Construction of a partial covariance map of N2 molecules undergoing Coulomb explosion induced by a free-electron laser.[4] Panels a and b map the two terms of the covariance matrix, which is shown in panel c. Panel d maps common-mode correlations via intensity fluctuations of the laser. Panel e maps the partial covariance matrix that is corrected for the intensity fluctuations. Panel f shows that 10% overcorrection improves the map and makes ion-ion correlations clearly visible. Owing to momentum conservation these correlations appear as lines approximately perpendicular to the autocorrelation line (and to the periodic modulations which are caused by detector ringing).

Fig. 1 illustrates how a partial covariance map is constructed on an example of an experiment performed at the FLASH free-electron laser in Hamburg.[4] The random function   is the time-of-flight spectrum of ions from a Coulomb explosion of nitrogen molecules multiply ionised by a laser pulse. Since only a few hundreds of molecules are ionised at each laser pulse, the single-shot spectra are highly fluctuating. However, collecting typically   such spectra,  , and averaging them over   produces a smooth spectrum  , which is shown in red at the bottom of Fig. 1. The average spectrum   reveals several nitrogen ions in a form of peaks broadened by their kinetic energy, but to find the correlations between the ionisation stages and the ion momenta requires calculating a covariance map.

In the example of Fig. 1 spectra   and   are the same, except that the range of the time-of-flight   differs. Panel a shows  , panel b shows   and panel c shows their difference, which is   (note a change in the colour scale). Unfortunately, this map is overwhelmed by uninteresting, common-mode correlations induced by laser intensity fluctuating from shot to shot. To suppress such correlations the laser intensity   is recorded at every shot, put into   and   is calculated as panels d and e show. The suppression of the uninteresting correlations is, however, imperfect because there are other sources of common-mode fluctuations than the laser intensity and in principle all these sources should be monitored in vector  . Yet in practice it is often sufficient to overcompensate the partial covariance correction as panel f shows, where interesting correlations of ion momenta are now clearly visible as straight lines centred on ionisation stages of atomic nitrogen.

Two-dimensional infrared spectroscopy

edit

Two-dimensional infrared spectroscopy employs correlation analysis to obtain 2D spectra of the condensed phase. There are two versions of this analysis: synchronous and asynchronous. Mathematically, the former is expressed in terms of the sample covariance matrix and the technique is equivalent to covariance mapping.[5]

  1. ^ Eaton, Morris L. (1983). Multivariate Statistics: a Vector Space Approach. John Wiley and Sons. pp. 116–117. ISBN 0-471-02776-6.
  2. ^ a b W J Krzanowski "Principles of Multivariate Analysis" (Oxford University Press, New York, 1988), Chap. 14.4; K V Mardia, J T Kent and J M Bibby "Multivariate Analysis (Academic Press, London, 1997), Chap. 6.5.3; T W Anderson "An Introduction to Multivariate Statistical Analysis" (Wiley, New York, 2003), 3rd ed., Chaps. 2.5.1 and 4.3.1.
  3. ^ L J Frasinski "Covariance mapping techniques" J. Phys. B: At. Mol. Opt. Phys. 49 152004 (2016), open access
  4. ^ a b O Kornilov, M Eckstein, M Rosenblatt, C P Schulz, K Motomura, A Rouzée, J Klei, L Foucar, M Siano, A Lübcke, F. Schapper, P Johnsson, D M P Holland, T Schlatholter, T Marchenko, S Düsterer, K Ueda, M J J Vrakking and L J Frasinski "Coulomb explosion of diatomic molecules in intense XUV fields mapped by partial covariance" J. Phys. B: At. Mol. Opt. Phys. 46 164028 (2013), open access
  5. ^ I Noda "Generalized two-dimensional correlation method applicable to infrared, Raman, and other types of spectroscopy" Appl. Spectrosc. 47 1329–36 (1993)