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Uncertainty Quantification for Nonconvex Tensor Completion: Confidence Intervals, Heteroscedasticity and Optimality

Author(s): Cai, Changxiao; Poor, H Vincent; Chen, Yuxin

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Abstract: We study the distribution and uncertainty of nonconvex optimization for noisy tensor completion—the problem of estimating a low-rank tensor given incomplete and corrupted observations of its entries. Focusing on a two-stage estimation algorithm proposed by Cai et al. , we characterize the distribution of this nonconvex estimator down to fine scales. This distributional theory in turn allows one to construct valid and short confidence intervals for both the unseen tensor entries and the unknown tensor factors. The proposed inferential procedure enjoys several important features: (1) it is fully adaptive to noise heteroscedasticity, and (2) it is data-driven and automatically adapts to unknown noise distributions. Furthermore, our findings unveil the statistical optimality of nonconvex tensor completion: it attains un-improvable ℓ2 accuracy—including both the rates and the pre-constants—when estimating both the unknown tensor and the underlying tensor factors.
Publication Date: 12-Sep-2022
Citation: Cai, Changxiao, Poor, H Vincent, Chen, Yuxin. (2023). Uncertainty Quantification for Nonconvex Tensor Completion: Confidence Intervals, Heteroscedasticity and Optimality. IEEE Transactions on Information Theory, 69 (1), 407 - 452. doi:10.1109/tit.2022.3205781
DOI: doi:10.1109/tit.2022.3205781
ISSN: 0018-9448
EISSN: 1557-9654
Pages: 407 - 452
Type of Material: Journal Article
Journal/Proceeding Title: IEEE Transactions on Information Theory
Version: Final published version. This is an open access article.



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