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Autores principales: Zhang, Juping, Zheng, Gan, Koike-Akino, Toshiaki, Wong, Kai-Kit, Burton, Fraser
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2408.04747
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author Zhang, Juping
Zheng, Gan
Koike-Akino, Toshiaki
Wong, Kai-Kit
Burton, Fraser
author_facet Zhang, Juping
Zheng, Gan
Koike-Akino, Toshiaki
Wong, Kai-Kit
Burton, Fraser
contents This paper investigates quantum machine learning to optimize the beamforming in a multiuser multiple-input single-output downlink system. We aim to combine the power of quantum neural networks and the success of classical deep neural networks to enhance the learning performance. Specifically, we propose two hybrid quantum-classical neural networks to maximize the sum rate of a downlink system. The first one proposes a quantum neural network employing parameterized quantum circuits that follows a classical convolutional neural network. The classical neural network can be jointly trained with the quantum neural network or pre-trained leading to a fine-tuning transfer learning method. The second one designs a quantum convolutional neural network to better extract features followed by a classical deep neural network. Our results demonstrate the feasibility of the proposed hybrid neural networks, and reveal that the first method can achieve similar sum rate performance compared to a benchmark classical neural network with significantly less training parameters; while the second method can achieve higher sum rate especially in presence of many users still with less training parameters. The robustness of the proposed methods is verified using both software simulators and hardware emulators considering noisy intermediate-scale quantum devices.
format Preprint
id arxiv_https___arxiv_org_abs_2408_04747
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hybrid Quantum-Classical Neural Networks for Downlink Beamforming Optimization
Zhang, Juping
Zheng, Gan
Koike-Akino, Toshiaki
Wong, Kai-Kit
Burton, Fraser
Information Theory
This paper investigates quantum machine learning to optimize the beamforming in a multiuser multiple-input single-output downlink system. We aim to combine the power of quantum neural networks and the success of classical deep neural networks to enhance the learning performance. Specifically, we propose two hybrid quantum-classical neural networks to maximize the sum rate of a downlink system. The first one proposes a quantum neural network employing parameterized quantum circuits that follows a classical convolutional neural network. The classical neural network can be jointly trained with the quantum neural network or pre-trained leading to a fine-tuning transfer learning method. The second one designs a quantum convolutional neural network to better extract features followed by a classical deep neural network. Our results demonstrate the feasibility of the proposed hybrid neural networks, and reveal that the first method can achieve similar sum rate performance compared to a benchmark classical neural network with significantly less training parameters; while the second method can achieve higher sum rate especially in presence of many users still with less training parameters. The robustness of the proposed methods is verified using both software simulators and hardware emulators considering noisy intermediate-scale quantum devices.
title Hybrid Quantum-Classical Neural Networks for Downlink Beamforming Optimization
topic Information Theory
url https://arxiv.org/abs/2408.04747