Quantum Divide-and-Conquer Anchoring for Separable Non-negative Matrix Factorization
Abstract
It is NP-complete to find non-negative factors and with fixed rank from a non-negative matrix by minimizing . Although the separability assumption (all data points are in the conical hull of the extreme rows) enables polynomial-time algorithms, the computational cost is not affordable for big data. This paper investigates how the power of quantum computation can be capitalized to solve the non-negative matrix factorization with the separability assumption (SNMF) by devising a quantum algorithm based on the divide-and-conquer anchoring (DCA) scheme. The design of quantum DCA (QDCA) is challenging. In the divide step, the random projections in DCA is completed by a quantum algorithm for linear operations, which achieves the exponential speedup. We then devise a heuristic post-selection procedure which extracts the information of anchors stored in the quantum states efficiently. Under a plausible assumption, QDCA performs efficiently, achieves the quantum speedup, and is beneficial for high dimensional problems.
Cite
@article{arxiv.1802.07828,
title = {Quantum Divide-and-Conquer Anchoring for Separable Non-negative Matrix Factorization},
author = {Yuxuan Du and Tongliang Liu and Yinan Li and Runyao Duan and Dacheng Tao},
journal= {arXiv preprint arXiv:1802.07828},
year = {2018}
}