Data-driven discovery of self-similarity using neural networks.

IF 2.2 3区物理与天体物理 Q2 PHYSICS, FLUIDS & PLASMAS

Physical Review E Pub Date : 2025-02-01 DOI:10.1103/PhysRevE.111.024301

Ryota Watanabe, Takanori Ishii, Yuji Hirono, Hirokazu Maruoka

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引用次数: 0

Abstract

Finding self-similarity is a key step for understanding the governing law behind complex physical phenomena. Traditional methods for identifying self-similarity often rely on specific models, which can introduce significant bias. In this paper, we present a neural network-based approach that discovers self-similarity directly from observed data, without presupposing any models. The presence of self-similar solutions in a physical problem signals that the governing law contains a function whose arguments are given by power-law monomials of physical parameters, which are characterized by power-law exponents. The basic idea is to enforce such particular forms structurally in a neural network in a parametrized way. We train the neural network model using the observed data, and when the training is successful, we can extract the power exponents that characterize scale-transformation symmetries of the physical problem. We demonstrate the effectiveness of our method with both synthetic and experimental data, validating its potential as a robust, model-independent tool for exploring self-similarity in complex systems.

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使用神经网络的数据驱动的自相似性发现。

寻找自相似性是理解复杂物理现象背后支配规律的关键一步。传统的识别自相似性的方法往往依赖于特定的模型，这可能会引入显著的偏差。在本文中，我们提出了一种基于神经网络的方法，可以直接从观测数据中发现自相似性，而不需要预先假设任何模型。物理问题中自相似解的存在表明支配律包含一个函数，其参数由物理参数的幂律单项式给出，其特征为幂律指数。基本思想是在神经网络中以参数化的方式在结构上强制执行这些特定的形式。我们使用观察到的数据训练神经网络模型，当训练成功时，我们可以提取表征物理问题尺度变换对称性的幂指数。我们用合成和实验数据证明了我们方法的有效性，验证了它作为一种鲁棒的、独立于模型的工具在复杂系统中探索自相似性的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physical Review E PHYSICS, FLUIDS & PLASMASPHYSICS, MATHEMAT-PHYSICS, MATHEMATICAL

CiteScore

4.50

自引率

16.70%

发文量

2110

期刊介绍： Physical Review E (PRE), broad and interdisciplinary in scope, focuses on collective phenomena of many-body systems, with statistical physics and nonlinear dynamics as the central themes of the journal. Physical Review E publishes recent developments in biological and soft matter physics including granular materials, colloids, complex fluids, liquid crystals, and polymers. The journal covers fluid dynamics and plasma physics and includes sections on computational and interdisciplinary physics, for example, complex networks.