It is NP-complete to find non-negative factors W and H with fixed rank r from a non-negative matrix X by minimizing ||X - WH~T||~2_F. 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 [Zhou et al., 2013]. 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.
展开▼
机译:通过最小化|| x - wh〜t ||〜2_f,找到从非负矩阵x与非负矩阵x的固定等级r的非负因子w和h是np的完整。虽然可分离的假设(所有数据点都处于极端行的锥形船体),但是对于大数据来说,计算成本不能实惠。本文研究了量子计算的功率如何利用分离性假设(SNMF)来利用基于分裂和征收锚定(DCA)方案[Zhou等人来解决这些量子计算的功率如何利用可分子矩阵分解(SNMF)。 ,2013]。量子DCA(QDCA)的设计是具有挑战性的。在划分步骤中,DCA中的随机投影通过量子算法来完成用于线性操作,这实现了指数加速。然后,我们设计了启发式后选择程序,其有效地提取存储在量子状态中的锚点的信息。在合理的假设下,QDCA有效地执行,实现量子加速,有利于高维问题。
展开▼
