Sparse Nonnegative Tensor Factorization and Completion with Noisy Observations
This work addresses tensor completion and denoising for applications like image or data analysis, but it is incremental as it extends existing matrix methods to tensors with sparsity and nonnegativity constraints.
The paper tackles the problem of sparse nonnegative tensor factorization and completion from noisy partial observations, proposing a model that minimizes maximum likelihood estimation with nonnegativity constraints and tensor ℓ₀ norm, and shows that error bounds for the estimator are established under general noise, with minimax lower bounds matching upper bounds up to a logarithmic factor, demonstrating better results than matrix-based methods.
In this paper, we study the sparse nonnegative tensor factorization and completion problem from partial and noisy observations for third-order tensors. Because of sparsity and nonnegativity, the underlying tensor is decomposed into the tensor-tensor product of one sparse nonnegative tensor and one nonnegative tensor. We propose to minimize the sum of the maximum likelihood estimation for the observations with nonnegativity constraints and the tensor $\ell_0$ norm for the sparse factor. We show that the error bounds of the estimator of the proposed model can be established under general noise observations. The detailed error bounds under specific noise distributions including additive Gaussian noise, additive Laplace noise, and Poisson observations can be derived. Moreover, the minimax lower bounds are shown to be matched with the established upper bounds up to a logarithmic factor of the sizes of the underlying tensor. These theoretical results for tensors are better than those obtained for matrices, and this illustrates the advantage of the use of nonnegative sparse tensor models for completion and denoising. Numerical experiments are provided to validate the superiority of the proposed tensor-based method compared with the matrix-based approach.