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arxiv: 2312.03438 · v1 · pith:X75UPUGRnew · submitted 2023-12-06 · 🧮 math.OC · eess.SP· stat.ML

On the Estimation Performance of Generalized Power Method for Heteroscedastic Probabilistic PCA

classification 🧮 math.OC eess.SPstat.ML
keywords estimationperformancedatamethodproblemassociatedconstraintemph
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The heteroscedastic probabilistic principal component analysis (PCA) technique, a variant of the classic PCA that considers data heterogeneity, is receiving more and more attention in the data science and signal processing communities. In this paper, to estimate the underlying low-dimensional linear subspace (simply called \emph{ground truth}) from available heterogeneous data samples, we consider the associated non-convex maximum-likelihood estimation problem, which involves maximizing a sum of heterogeneous quadratic forms over an orthogonality constraint (HQPOC). We propose a first-order method -- generalized power method (GPM) -- to tackle the problem and establish its \emph{estimation performance} guarantee. Specifically, we show that, given a suitable initialization, the distances between the iterates generated by GPM and the ground truth decrease at least geometrically to some threshold associated with the residual part of certain "population-residual decomposition". In establishing the estimation performance result, we prove a novel local error bound property of another closely related optimization problem, namely quadratic optimization with orthogonality constraint (QPOC), which is new and can be of independent interest. Numerical experiments are conducted to demonstrate the superior performance of GPM in both Gaussian noise and sub-Gaussian noise settings.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Benign Landscape of Quadratic Programs with Orthogonality Constraints and Its Application to Heteroscedastic Probabilistic PCA

    math.OC 2026-06 unverdicted novelty 6.0

    Proves that QPOC problems have a benign landscape with all critical points being global optima or strict saddles, and shows the population and large-sample HePPCA inherit this with local geodesic strong concavity.