Training Classical Neural Networks by Quantum Machine Learning
Abstract
In recent years, advanced deep neural networks have required a large number of parameters for training. Therefore, finding a method to reduce the number of parameters has become crucial for achieving efficient training. This work proposes a training scheme for classical neural networks (NNs) that utilizes the exponentially large Hilbert space of a quantum system. By mapping a classical NN with parameters to a quantum neural network (QNN) with rotational gate angles, we can significantly reduce the number of parameters. These gate angles can be updated to train the classical NN. Unlike existing quantum machine learning (QML) methods, the results obtained from quantum computers using our approach can be directly used on classical computers. Numerical results on the MNIST and Iris datasets are presented to demonstrate the effectiveness of our approach. Additionally, we investigate the effects of deeper QNNs and the number of measurement shots for the QNN, followed by the theoretical perspective of the proposed method. This work opens a new branch of QML and offers a practical tool that can greatly enhance the influence of QML, as the trained QML results can benefit classical computing in our daily lives.
Cite
@article{arxiv.2402.16465,
title = {Training Classical Neural Networks by Quantum Machine Learning},
author = {Chen-Yu Liu and En-Jui Kuo and Chu-Hsuan Abraham Lin and Sean Chen and Jason Gemsun Young and Yeong-Jar Chang and Min-Hsiu Hsieh},
journal= {arXiv preprint arXiv:2402.16465},
year = {2024}
}
Comments
7 pages, 3 figures