The Benefit of Using Random Matrix Theory to Fit High-Dimensional T-Copulas
19 Pages Posted: 19 Mar 2016 Last revised: 22 Mar 2016
Date Written: March 17, 2016
Abstract
In risk management, t-copulas are used to model dependencies beyond Gaussian copulas as they take into account tail dependencies. A t-copula has two parameters: the correlation matrix and the degree of freedom; they are usually estimated by maximizing the likelihood function of the observations. In risk modeling, the dimension of the copula is often high, making the maximization not tractable as the number of pairwise correlations to estimate is too high. McNeil et al. (2005) suggested a procedure that consists in using a correlation matrix estimated through Kendall’s rank correlation matrix estimate, likely transformed to be definite positive, as an input in the likelihood function to deduce a value for the degree of freedom. In this short paper, we exhibit the bias of this degree of freedom’s estimator due to the noise in the correlation matrix estimate. We address this problem using Random Matrix Theory-based denoising technique to improve the correlation estimate used as an input. On simulation studies, we show how this improved procedure gives an estimator of the degree of freedom of t-copulas with no bias and a smaller variance. Finally, we fit a t-copula on real operational risk data in a way to illustrate the necessity and the benefit of this procedure.
Keywords: Random Matrix Theory, Denoising technique, Student's t-copulas, Large Dimension, Risk Modeling, Operational Risk
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