Abstract
This paper describes a flexible framework for generalized low-rank tensor estimation problems that includes many important instances arising from applications in computational imaging, genomics, and network analysis. The proposed estimator consists of finding a low-rank tensor fit to the data under generalized parametric models. To overcome the difficulty of nonconvexity in these problems, we introduce a unified approach of projected gradient descent that adapts to the underlying low-rank structure. Under mild conditions on the loss function, we establish both an upper bound on statistical error and the linear rate of computational convergence through a general deterministic analysis. Then we further consider a suite of generalized tensor estimation problems, including sub-Gaussian tensor PCA, tensor regression, and Poisson and binomial tensor PCA. We prove that the proposed algorithm achieves the minimax optimal rate of convergence in estimation error. Finally, we demonstrate the superiority of the proposed framework via extensive experiments on both simulated and real data.
Funding Statement
The research of R. H. and A. R. Z. was supported in part by NSF Grants DMS-1811868, NSF CAREER-1944904, and NIH R01-GM131399. The research of R. W. was supported in part by AFOSR Grants FA9550-18-1-0166, DOE DE-AC02-06CH11357, NSF OAC-1934637, and NSF DMS-2023109. The research of R.H. was also supported in part by a RAship from Institute for Mathematics of Data Science at UW-Madison.
Acknowledgments
The authors thank Paul Voyles and Chenyu Zhang for providing the 4D-STEM dataset and for helpful discussions.
Citation
Rungang Han. Rebecca Willett. Anru R. Zhang. "An optimal statistical and computational framework for generalized tensor estimation." Ann. Statist. 50 (1) 1 - 29, February 2022. https://doi.org/10.1214/21-AOS2061
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