Stochastic First-Order Learning for Large-Scale Flexibly Tied Gaussian Mixture Model
Abstract
Gaussian Mixture Models (GMMs) are one of the most potent parametric density models used extensively in many applications. Flexibly-tied factorization of the covariance matrices in GMMs is a powerful approach for coping with the challenges of common GMMs when faced with high-dimensional data and complex densities which often demand a large number of Gaussian components. However, the expectation-maximization algorithm for fitting flexibly-tied GMMs still encounters difficulties with streaming and very large dimensional data. To overcome these challenges, this paper suggests the use of first-order stochastic optimization algorithms. Specifically, we propose a new stochastic optimization algorithm on the manifold of orthogonal matrices. Through numerous empirical results on both synthetic and real datasets, we observe that stochastic optimization methods can outperform the expectation-maximization algorithm in terms of attaining better likelihood, needing fewer epochs for convergence, and consuming less time per each epoch.
Cite
@article{arxiv.2212.05402,
title = {Stochastic First-Order Learning for Large-Scale Flexibly Tied Gaussian Mixture Model},
author = {Mohammad Pasande and Reshad Hosseini and Babak Nadjar Araabi},
journal= {arXiv preprint arXiv:2212.05402},
year = {2023}
}