量子图神经网络物理仿真

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY
Benjamin Collis, Saahil Patel, Daniel Koch, Massimiliano Cutugno, L. Wessing, P. Alsing
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引用次数: 0

摘要

我们开发并实现了量子图神经网络(QGNN)的两种实现,应用于粒子相互作用的模拟任务。第一个QGNN是一个推测性的量子-经典混合学习模型,它依赖于直接利用叠加态作为经典信息在粒子之间传播信息的能力。第二种是可实现的量子-经典混合学习模型,该模型通过RX旋转门的参数直接传播粒子信息。在相同的任务中也训练了一个经典的图神经网络(CGNN)。推测性QGNN和CGNN都是对可实现QGNN的控制。经典模型和量子模型的比较是基于每个模型的损失值和精度。总的来说,每个模型都具有很高的学习效率,在训练过程中损失值迅速趋近于零;然而,每个模型都有一定程度的不准确性。通过性能比较,我们的结果表明,可实现的QGNN比CGNN具有潜在的优势。此外,我们表明,CGNN中超参数的轻微改变显着提高了准确性,这表明进一步的微调可以减轻每个模型中中度不准确性的问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physics simulation via quantum graph neural network
We develop and implement two realizations of quantum graph neural networks (QGNN), applied to the task of particle interaction simulation. The first QGNN is a speculative quantum-classical hybrid learning model that relies on the ability to directly utilize superposition states as classical information to propagate information between particles. The second is an implementable quantum-classical hybrid learning model that propagates particle information directly through the parameters of RX rotation gates. A classical graph neural network (CGNN) is also trained in the same task. Both the Speculative QGNN and CGNN act as controls against the Implementable QGNN. Comparison between classical and quantum models is based on the loss value and accuracy of each model. Overall, each model had a high learning efficiency, in which the loss value rapidly approached zero during training; however, each model was moderately inaccurate. Comparing performances, our results show that the Implementable QGNN has a potential advantage over the CGNN. Additionally, we show that a slight alteration in hyperparameters in the CGNN notably improves accuracy, suggesting that further fine tuning could mitigate the issue of moderate inaccuracy in each model.
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CiteScore
9.90
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