衔接自动编码器和动态模式分解,实现 PDE 的降阶建模和控制

Priyabrata Saha, Saibal Mukhopadhyay
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摘要

由偏微分方程(PDEs)驱动的复杂时空动力系统的建模与控制通常需要降维技术来构建低阶模型,以提高计算效率。本文探讨了一种深度自动编码学习方法,用于对由时空 PDEs 驱动的动态系统进行降维建模和控制。我们首先通过分析表明,学习线性自动编码降阶模型的优化目标可以通过动态模式分解与控制算法得到近似的解。然后,我们将这种线性自动编码架构扩展到深度自动编码框架,从而开发出非线性降阶模型。此外,我们还利用学习到的降阶模型,使用稳定性受限的深度神经网络设计控制器。通过数值实验,我们以反应扩散系统为例,验证了我们的方法在建模和控制方面的有效性。
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Bridging Autoencoders and Dynamic Mode Decomposition for Reduced-order Modeling and Control of PDEs
Modeling and controlling complex spatiotemporal dynamical systems driven by partial differential equations (PDEs) often necessitate dimensionality reduction techniques to construct lower-order models for computational efficiency. This paper explores a deep autoencoding learning method for reduced-order modeling and control of dynamical systems governed by spatiotemporal PDEs. We first analytically show that an optimization objective for learning a linear autoencoding reduced-order model can be formulated to yield a solution closely resembling the result obtained through the dynamic mode decomposition with control algorithm. We then extend this linear autoencoding architecture to a deep autoencoding framework, enabling the development of a nonlinear reduced-order model. Furthermore, we leverage the learned reduced-order model to design controllers using stability-constrained deep neural networks. Numerical experiments are presented to validate the efficacy of our approach in both modeling and control using the example of a reaction-diffusion system.
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