English

Bayesian machine learning for Boltzmann machine in quantum-enhanced feature spaces

Quantum Physics 2019-12-24 v1 Machine Learning Data Analysis, Statistics and Probability

Abstract

Bayesian learning is ubiquitous for implementing classification and regression tasks, however, it is accompanied by computationally intractable limitations when the feature spaces become extremely large. Aiming to solve this problem, we develop a quantum bayesian learning framework of the restricted Boltzmann machine in the quantum-enhanced feature spaces. Our framework provides the encoding phase to map the real data and Boltzmann weight onto the quantum feature spaces and the training phase to learn an optimal inference function. Specifically, the training phase provides a physical quantity to measure the posterior distribution in quantum feature spaces, and this measure is utilized to design the quantum maximum a posterior (QMAP) algorithm and the quantum predictive distribution estimator (QPDE). It is shown that both quantum algorithms achieve exponential speed-up over their classical counterparts. Furthermore, it is interesting to note that our framework can figure out the classical bayesian learning tasks, i.e. processing the classical data and outputting corresponding classical labels. And a simulation, which is performed on an open-source software framework for quantum computing, illustrates that our algorithms show almost the same classification performance compared to their classical counterparts. Noting that the proposed quantum algorithms utilize the shallow circuit, our work is expected to be implemented on the noisy intermediate-scale quantum (NISQ) devices, and is one of the promising candidates to achieve quantum supremacy.

Keywords

Cite

@article{arxiv.1912.10857,
  title  = {Bayesian machine learning for Boltzmann machine in quantum-enhanced feature spaces},
  author = {Yusen Wu and Chao-hua Yu and Sujuan Qin and Qiaoyan Wen and Fei Gao},
  journal= {arXiv preprint arXiv:1912.10857},
  year   = {2019}
}

Comments

14 pages, 7 figures

R2 v1 2026-06-23T12:54:39.330Z