Exact Tensor Completion Powered by Arbitrary Linear Transforms

In this work, a tensor completion problem is studied, which aims to perfectly recover the tensor from partial observations. Existing theoretical guarantee requires the involved transform to be orthogonal, which hinders its applications. In this paper, jumping out of the constraints of isotropy or self-adjointness, the theoretical guarantee of exact tensor completion with arbitrary linear transforms is established. To that end, we define a new tensor-tensor product, which leads us to a new definition of the tensor nuclear norm. Equipped with these tools, an efficient algorithm based on alternating direction of multipliers is designed to solve the transformed tensor completion program and the theoretical bound is obtained. Our model and proof greatly enhance the flexibility of tensor completion and extensive experiments validate the superiority of the proposed method.