On instabilities in neural network-based physics simulators

Daniel Floryan
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Abstract

When neural networks are trained from data to simulate the dynamics of physical systems, they encounter a persistent challenge: the long-time dynamics they produce are often unphysical or unstable. We analyze the origin of such instabilities when learning linear dynamical systems, focusing on the training dynamics. We make several analytical findings which empirical observations suggest extend to nonlinear dynamical systems. First, the rate of convergence of the training dynamics is uneven and depends on the distribution of energy in the data. As a special case, the dynamics in directions where the data have no energy cannot be learned. Second, in the unlearnable directions, the dynamics produced by the neural network depend on the weight initialization, and common weight initialization schemes can produce unstable dynamics. Third, injecting synthetic noise into the data during training adds damping to the training dynamics and can stabilize the learned simulator, though doing so undesirably biases the learned dynamics. For each contributor to instability, we suggest mitigative strategies. We also highlight important differences between learning discrete-time and continuous-time dynamics, and discuss extensions to nonlinear systems.
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论基于神经网络的物理模拟器的不稳定性
当神经网络通过数据训练来模拟物理系统的动力学时,它们会遇到一个长期存在的挑战:它们产生的长期动力学往往是非物理的或不稳定的。我们分析了学习线性动力学系统时这种不稳定性的根源,重点关注训练动力学。我们得出了几项分析结论,经验观察表明,这些结论也适用于非线性动力系统。首先,训练动力学的收敛速度是不均匀的,取决于数据中能量的分布。作为一种特例,在数据没有能量的方向上的动力学是无法学习的。其次,在无法学习的方向上,神经网络产生的动态取决于权重初始化,而普通的权重初始化方案会产生不稳定的动态。第三,在训练过程中向数据中注入合成噪声会增加训练动力学的阻尼,并能稳定学习到的模拟器,但这样做会对学习到的动力学产生不良影响。针对每种不稳定因素,我们都提出了应对策略。我们还强调了学习离散时间和连续时间动力学之间的重要区别,并讨论了对非线性系统的扩展。
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