Convex Parameter Estimation of Perturbed Multivariate Generalized
Gaussian Distributions
- URL: http://arxiv.org/abs/2312.07479v1
- Date: Tue, 12 Dec 2023 18:08:04 GMT
- Title: Convex Parameter Estimation of Perturbed Multivariate Generalized
Gaussian Distributions
- Authors: Nora Ouzir and Fr\'ed\'eric Pascal and Jean-Christophe Pesquet
- Abstract summary: We propose a convex formulation with well-established properties for MGGD parameters.
The proposed framework is flexible as it combines a variety of regularizations for the precision matrix, the mean and perturbations.
Experiments show a more accurate precision and covariance matrix estimation with similar performance for the mean vector parameter.
- Score: 18.95928707619676
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The multivariate generalized Gaussian distribution (MGGD), also known as the
multivariate exponential power (MEP) distribution, is widely used in signal and
image processing. However, estimating MGGD parameters, which is required in
practical applications, still faces specific theoretical challenges. In
particular, establishing convergence properties for the standard fixed-point
approach when both the distribution mean and the scatter (or the precision)
matrix are unknown is still an open problem. In robust estimation, imposing
classical constraints on the precision matrix, such as sparsity, has been
limited by the non-convexity of the resulting cost function. This paper tackles
these issues from an optimization viewpoint by proposing a convex formulation
with well-established convergence properties. We embed our analysis in a noisy
scenario where robustness is induced by modelling multiplicative perturbations.
The resulting framework is flexible as it combines a variety of regularizations
for the precision matrix, the mean and model perturbations. This paper presents
proof of the desired theoretical properties, specifies the conditions
preserving these properties for different regularization choices and designs a
general proximal primal-dual optimization strategy. The experiments show a more
accurate precision and covariance matrix estimation with similar performance
for the mean vector parameter compared to Tyler's M-estimator. In a
high-dimensional setting, the proposed method outperforms the classical GLASSO,
one of its robust extensions, and the regularized Tyler's estimator.
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