The Schatten-p quasi-norm (0<p<1) is usually used to replace the standard
nuclear norm in order to approximate the rank function more accurately.
However, existing Schatten-p quasi-norm minimization algorithms involve
singular value decomposition (SVD) or eigenvalue decomposition (EVD) in each
iteration, and thus may become very slow and impractical for large-scale
problems. In this paper, we first define two tractable Schatten quasi-norms,
i.e., the Frobenius/nuclear hybrid and bi-nuclear quasi-norms, and then prove
that they are in essence the Schatten-2/3 and 1/2 quasi-norms, respectively,
which lead to the design of very efficient algorithms that only need to update
two much smaller factor matrices. We also design two efficient proximal
alternating linearized minimization algorithms for solving representative
matrix completion problems. Finally, we provide the global convergence and
performance guarantees for our algorithms, which have better convergence
properties than existing algorithms. Experimental results on synthetic and
real-world data show that our algorithms are more accurate than the
state-of-the-art methods, and are orders of magnitude faster.Comment: 16 pages, 5 figures, Appears in Proceedings of the 30th AAAI
Conference on Artificial Intelligence (AAAI), Phoenix, Arizona, USA, pp.
2016--2022, 201
