Abstract
In this paper, we study the problem of low-rank tensor completion with the purpose of recovering a low-rank tensor from a tensor with partial observed items. To date, there are several different definitions of tensor ranks. We focus the study on the low tubal rank tensor completion task. Previous works solve the low tubal rank tensor completion/recovery problems by convex tensor nuclear norm minimization. However, this kind of tensor nuclear norm is orientation dependent, which is originally due to the definition of tensor-tensor product. Based on the convex tensor nuclear norm minimization, the tensor recovery performance varies when the orientation of the input data is different. However, in practice, it is generally hard to choose the best way of the data input. To address this issue, we propose a new convex model which is based on the sum of tensor nuclear norm minimization. It includes the existing tensor nuclear norm minimization model as a special case which is corresponding to an orientation of the input data. The proposed model is convex and thus can be solved efficiently. Numerical experiments on images and video sequences demonstrate the effectiveness of our proposed method.
Highlights
With the increasing human demands and the rapid development of information science, the collection, storage and processing of data become a crucial problem to address
TENSOR COMPLETION BY SUM OF TENSOR NUCLEAR NORM MINIMIZATION In this chapter, we propose a simple sum of tensor nuclear norm based tensor completion model to avoid the orientation dependent issue of Tensor Nuclear Norm (TNN)
We propose the Sum of Tensor Nuclear Norm (STNN) to avoid this issue
Summary
Though real tensor data usually have high-dimensional structure, the tensor of interest is usually low-rank or approximate low-rank [5], and generally has low-dimensional structure This promote the development of the low-rank tensor estimation and recovery problem, which has been well applied in many different areas: e.g., classifying audio [6], estimating latent variable graphical models [7], image and video completion [8], motion segmentation [9], [10], and so forth. The work [23] studies the low tubal rank tensor completion problem by tensor nuclear norm minimization, i.e., min X ∗, s.t. P (X ) = P (M).
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