Enhancing Computational Efficiency in Multiscale Systems Using Deep Learning of Coordinates and Flow Maps

arXiv - PHYS - Chaotic Dynamics Pub Date : 2024-04-28 DOI:arxiv-2407.00011

Asif Hamid, Danish Rafiq, Shahkar Ahmad Nahvi, Mohammad Abid Bazaz

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Abstract

Complex systems often show macroscopic coherent behavior due to the interactions of microscopic agents like molecules, cells, or individuals in a population with their environment. However, simulating such systems poses several computational challenges during simulation as the underlying dynamics vary and span wide spatiotemporal scales of interest. To capture the fast-evolving features, finer time steps are required while ensuring that the simulation time is long enough to capture the slow-scale behavior, making the analyses computationally unmanageable. This paper showcases how deep learning techniques can be used to develop a precise time-stepping approach for multiscale systems using the joint discovery of coordinates and flow maps. While the former allows us to represent the multiscale dynamics on a representative basis, the latter enables the iterative time-stepping estimation of the reduced variables. The resulting framework achieves state-of-the-art predictive accuracy while incurring lesser computational costs. We demonstrate this ability of the proposed scheme on the large-scale Fitzhugh Nagumo neuron model and the 1D Kuramoto-Sivashinsky equation in the chaotic regime.

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利用坐标和流图深度学习提高多尺度系统的计算效率

由于分子、细胞或群体中的个体等微观主体与其环境的相互作用，复杂系统通常表现出宏观的一致性行为。然而，在模拟过程中，由于底层动力学会发生变化，且跨越的时空尺度较宽，因此模拟这类系统会给计算带来诸多挑战。为了捕捉快速变化的特征，需要更细的时间步长，同时确保模拟时间足够长以捕捉慢尺度行为，这使得分析计算变得难以管理。本文展示了如何利用深度学习技术，通过坐标和流图的联合发现，为多尺度系统开发精确的时间步进方法。前者允许我们在表征基础上表征多尺度动力学，后者则能对缩小的变量进行迭代时间步进估计。由此产生的框架既能达到最先进的预测精度，又能降低计算成本。我们在大规模 Fitzhugh Nagumo 神经元模型和混沌状态下的一维 Kuramoto-Sivashinsky 方程上演示了所提方案的这种能力。

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arXiv - PHYS - Chaotic Dynamics

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