sparse and low-rank tensor regression
Boosted Sparse and Low-Rank Tensor Regression
We propose a sparse and low-rank tensor regression model to relate a univariate outcome to a feature tensor, in which each unit-rank tensor from the CP decomposition of the coefficient tensor is assumed to be sparse. This structure is both parsimonious and highly interpretable, as it implies that the outcome is related to the features through a few distinct pathways, each of which may only involve subsets of feature dimensions. We take a divide-and-conquer strategy to simplify the task into a set of sparse unit-rank tensor regression problems. To make the computation efficient and scalable, for the unit-rank tensor regression, we propose a stagewise estimation procedure to efficiently trace out its entire solution path. We show that as the step size goes to zero, the stagewise solution paths converge exactly to those of the corresponding regularized regression. The superior performance of our approach is demonstrated on various real-world and synthetic examples.
Reviews: Boosted Sparse and Low-Rank Tensor Regression
This paper examines the problem of tensor regression and proposes a boosted sparse low-rank model that produces interpretable results. In their low-rank tensor regression model, unit-rank tensors from the CP decomposition of the coefficient tensor is assumed to be sparse. This assumption allows for an interpretable model where the outcome is related to only a subset of features. For model estimation, the authors use a divide-and-conquer strategy to learn the sparse CP decomposition, based on an existing sequential extraction method, where sparse unit-rank problems are sequentially solved. Instead of using an alternating convex search (ACS) approach, the authors use a stage-wise unit-rank tensor factorization algorithm to learn the model.
Boosted Sparse and Low-Rank Tensor Regression
He, Lifang, Chen, Kun, Xu, Wanwan, Zhou, Jiayu, Wang, Fei
We propose a sparse and low-rank tensor regression model to relate a univariate outcome to a feature tensor, in which each unit-rank tensor from the CP decomposition of the coefficient tensor is assumed to be sparse. This structure is both parsimonious and highly interpretable, as it implies that the outcome is related to the features through a few distinct pathways, each of which may only involve subsets of feature dimensions. We take a divide-and-conquer strategy to simplify the task into a set of sparse unit-rank tensor regression problems. To make the computation efficient and scalable, for the unit-rank tensor regression, we propose a stagewise estimation procedure to efficiently trace out its entire solution path. We show that as the step size goes to zero, the stagewise solution paths converge exactly to those of the corresponding regularized regression.