<div class="csl-bib-body">
<div class="csl-entry">Pfeiffer, P., Alfons, A., & Filzmoser, P. (2022, August 24). <i>Efficient computation of robust multivariate maximum association</i> [Conference Presentation]. 24th International Conference on Computational Statistics, Bologna, Italy. http://hdl.handle.net/20.500.12708/152955</div>
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dc.identifier.uri
http://hdl.handle.net/20.500.12708/152955
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dc.description.abstract
Methods to measure association between multivariate datasets become increasingly
important as more multimodal data is acquired. Canonical Correlation
Analysis (CCA) is widely applied for this task, but is neither robust in
the presence of atypical observations nor well-defined in the high-dimensional
case, when more variables than samples are collected. Let R denote a bivariate
measure of association. A measure of maximum association between two
multivariate variables X and Y is defined via maximization of R between linear
combinations of sets of variables: ρ = max||α||=1,||β||=1 R(αTX, βT Y ). Using the
Pearson correlation for the association measure R results in the first canonical
correlation coefficient, while a robust choice of R yields a more robust estimator.
These estimators have desirable theoretical properties, but computation
can be a limiting factor: Methods that require the computation of covariance
matrices, or are based on pairwise comparison, or grid-search do not scale well
to high-dimensional data. We present an algorithm based on adaptive gradient
descent and M-association derived from a bivariate M-scatter matrix for
the computation of robust multivariate maximum association. Simulations illustrate
the robustness properties of our approach, as well as its suitability for
high-dimensional data. The presented algorithm can also be applied to other
robust methods in the context of high-dimensional data analysis.
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dc.description.sponsorship
FFG - Österr. Forschungsförderungs- gesellschaft mbH