短轨迹就是你所需要的:基于变压器的长时耗散量子动力学模型

Luis E. Herrera Rodríguez, Alexei A. Kananenka
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摘要

在这篇论文中,我们证明了基于具有自注意层的变压器架构的深度人工神经网络可以预测与耗散环境耦合的量子系统的长时种群动态,前提是系统的短时种群动态是已知的。从弱系统-水浴耦合到强耦合-非马尔科夫状态,这项研究开发的变压器神经网络模型可以高效、准确地预测自旋玻色子模型的长时动态。我们的模型比经典预测模型(如递归神经网络)更精确,可与基于核岭回归的量子耗散系统动力学模拟的最新模型相媲美。
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A short trajectory is all you need: A transformer-based model for long-time dissipative quantum dynamics
In this communication we demonstrate that a deep artificial neural network based on a transformer architecture with self-attention layers can predict the long-time population dynamics of a quantum system coupled to a dissipative environment provided that the short-time population dynamics of the system is known. The transformer neural network model developed in this work predicts the long-time dynamics of spin-boson model efficiently and very accurately across different regimes, from weak system-bath coupling to strong coupling non-Markovian regimes. Our model is more accurate than classical forecasting models, such as recurrent neural networks and is comparable to the state-of-the-art models for simulating the dynamics of quantum dissipative systems, based on kernel ridge regression.
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