Whitening transformation

A whitening transformation or sphering transformation is a linear transformation that transforms a vector of random variables with a known covariance matrix into a set of new variables whose covariance is the identity matrix, meaning that they are uncorrelated and each have variance 1.[1] The transformation is called "whitening" because it changes the input vector into a white noise vector.

Several other transformations are closely related to whitening:

  1. the decorrelation transform removes only the correlations but leaves variances intact,
  2. the standardization transform sets variances to 1 but leaves correlations intact,
  3. a coloring transformation transforms a vector of white random variables into a random vector with a specified covariance matrix.[2]

Definition

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Suppose   is a random (column) vector with non-singular covariance matrix   and mean  . Then the transformation   with a whitening matrix   satisfying the condition   yields the whitened random vector   with unit diagonal covariance.

If   has non-zero mean  , then whitening can be performed by  .

There are infinitely many possible whitening matrices   that all satisfy the above condition. Commonly used choices are   (Mahalanobis or ZCA whitening),   where   is the Cholesky decomposition of   (Cholesky whitening),[3] or the eigen-system of   (PCA whitening).[4]

Optimal whitening transforms can be singled out by investigating the cross-covariance and cross-correlation of   and  .[3] For example, the unique optimal whitening transformation achieving maximal component-wise correlation between original   and whitened   is produced by the whitening matrix   where   is the correlation matrix and   the diagonal variance matrix.

Whitening a data matrix

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Whitening a data matrix follows the same transformation as for random variables. An empirical whitening transform is obtained by estimating the covariance (e.g. by maximum likelihood) and subsequently constructing a corresponding estimated whitening matrix (e.g. by Cholesky decomposition).

High-dimensional whitening

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This modality is a generalization of the pre-whitening procedure extended to more general spaces where   is usually assumed to be a random function or other random objects in a Hilbert space  . One of the main issues of extending whitening to infinite dimensions is that the covariance operator has an unbounded inverse in  . Nevertheless, if one assumes that Picard condition holds for   in the range space of the covariance operator, whitening becomes possible.[5] A whitening operator can be then defined from the factorization of the Moore–Penrose inverse of the covariance operator, which has effective mapping on Karhunen–Loève type expansions of  . The advantage of these whitening transformations is that they can be optimized according to the underlying topological properties of the data, thus producing more robust whitening representations. High-dimensional features of the data can be exploited through kernel regressors or basis function systems.[6]

R implementation

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An implementation of several whitening procedures in R, including ZCA-whitening and PCA whitening but also CCA whitening, is available in the "whitening" R package [7] published on CRAN. The R package "pfica"[8] allows the computation of high-dimensional whitening representations using basis function systems (B-splines, Fourier basis, etc.).

See also

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References

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  1. ^ Koivunen, A.C.; Kostinski, A.B. (1999). "The Feasibility of Data Whitening to Improve Performance of Weather Radar". Journal of Applied Meteorology. 38 (6): 741–749. Bibcode:1999JApMe..38..741K. doi:10.1175/1520-0450(1999)038<0741:TFODWT>2.0.CO;2. ISSN 1520-0450.
  2. ^ Hossain, Miliha. "Whitening and Coloring Transforms for Multivariate Gaussian Random Variables". Project Rhea. Retrieved 21 March 2016.
  3. ^ a b Kessy, A.; Lewin, A.; Strimmer, K. (2018). "Optimal whitening and decorrelation". The American Statistician. 72 (4): 309–314. arXiv:1512.00809. doi:10.1080/00031305.2016.1277159. S2CID 55075085.
  4. ^ Friedman, J. (1987). "Exploratory Projection Pursuit" (PDF). Journal of the American Statistical Association. 82 (397): 249–266. doi:10.1080/01621459.1987.10478427. ISSN 0162-1459. JSTOR 2289161. OSTI 1447861.
  5. ^ Vidal, M.; Aguilera, A.M. (2022). "Novel whitening approaches in functional settings". STAT. 12 (1): e516. doi:10.1002/sta4.516. hdl:1854/LU-8770510.
  6. ^ Ramsay, J.O.; Silverman, J.O. (2005). Functional Data Analysis. Springer New York, NY. doi:10.1007/b98888. ISBN 978-0-387-40080-8.
  7. ^ "whitening R package". Retrieved 2018-11-25.
  8. ^ "pfica R package". Retrieved 2023-02-11.
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