Physics-informed generator-encoder adversarial networks with latent space matching for stochastic differential equations

IF 3.1 3区计算机科学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Journal of Computational Science Pub Date : 2024-05-07 DOI:10.1016/j.jocs.2024.102318

Ruisong Gao , Min Yang , Jin Zhang

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Abstract

We propose a new class of physics-informed neural networks, called Physics-Informed Generator-Encoder Adversarial Networks, to effectively address the challenges posed by forward, inverse, and mixed problems in stochastic differential equations (SDEs). In these scenarios, while governing equations are known, the available data consist of only a limited set of snapshots for system parameters. Our model consists of two key components: the generator and the encoder, both updated alternately by gradient descent. In contrast to previous approaches that directly match approximated solutions with real snapshots, we employ an indirect matching operating within the lower-dimensional latent feature space. This method circumvents challenges associated with high-dimensional inputs and complex data distributions in solving SDEs. Numerical experiments indicate that, compared to existing deep learning solvers, our proposed approach not only demonstrates superior accuracy but also exhibits advantages in both computational efficiency and model complexity.

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针对随机微分方程的具有潜空间匹配的物理信息生成器-编码器对抗网络

我们提出了一类新的物理信息神经网络，称为物理信息生成器-编码器对抗网络（Physics-Informed Generator-Encoder Adversarial Networks），以有效解决随机微分方程（SDE）中的正向、逆向和混合问题所带来的挑战。在这些情况下，虽然治理方程是已知的，但可用数据仅包括一组有限的系统参数快照。我们的模型由两个关键部分组成：生成器和编码器，两者通过梯度下降交替更新。与以往直接将近似解与真实快照进行匹配的方法不同，我们采用的是在低维潜在特征空间内进行间接匹配的方法。这种方法规避了在求解 SDE 时与高维输入和复杂数据分布相关的挑战。数值实验表明，与现有的深度学习求解器相比，我们提出的方法不仅精度更高，而且在计算效率和模型复杂度方面都有优势。

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来源期刊

Journal of Computational Science COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-COMPUTER SCIENCE, THEORY & METHODS

CiteScore

5.50

自引率

3.00%

发文量

227

审稿时长

41 days

期刊介绍： Computational Science is a rapidly growing multi- and interdisciplinary field that uses advanced computing and data analysis to understand and solve complex problems. It has reached a level of predictive capability that now firmly complements the traditional pillars of experimentation and theory. The recent advances in experimental techniques such as detectors, on-line sensor networks and high-resolution imaging techniques, have opened up new windows into physical and biological processes at many levels of detail. The resulting data explosion allows for detailed data driven modeling and simulation. This new discipline in science combines computational thinking, modern computational methods, devices and collateral technologies to address problems far beyond the scope of traditional numerical methods. Computational science typically unifies three distinct elements: • Modeling, Algorithms and Simulations (e.g. numerical and non-numerical, discrete and continuous); • Software developed to solve science (e.g., biological, physical, and social), engineering, medicine, and humanities problems; • Computer and information science that develops and optimizes the advanced system hardware, software, networking, and data management components (e.g. problem solving environments).