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Main Authors: Jiang, Jian, Chen, Long, ke, Lu, Dou, Bozheng, Zhu, Yueying, Shi, Yazhou, Qiu, Huahai, Zhang, Bengong, Zhou, Tianshou, Wei, Guo-Wei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.14956
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author Jiang, Jian
Chen, Long
ke, Lu
Dou, Bozheng
Zhu, Yueying
Shi, Yazhou
Qiu, Huahai
Zhang, Bengong
Zhou, Tianshou
Wei, Guo-Wei
author_facet Jiang, Jian
Chen, Long
ke, Lu
Dou, Bozheng
Zhu, Yueying
Shi, Yazhou
Qiu, Huahai
Zhang, Bengong
Zhou, Tianshou
Wei, Guo-Wei
contents Chaos is omnipresent in nature, and its understanding provides enormous social and economic benefits. However, the unpredictability of chaotic systems is a textbook concept due to their sensitivity to initial conditions, aperiodic behavior, fractal dimensions, nonlinearity, and strange attractors. In this work, we introduce, for the first time, chaotic learning, a novel multiscale topological paradigm that enables accurate predictions from chaotic systems. We show that seemingly random and unpredictable chaotic dynamics counterintuitively offer unprecedented quantitative predictions. Specifically, we devise multiscale topological Laplacians to embed real-world data into a family of interactive chaotic dynamical systems, modulate their dynamical behaviors, and enable the accurate prediction of the input data. As a proof of concept, we consider 28 datasets from four categories of realistic problems: 10 brain waves, four benchmark protein datasets, 13 single-cell RNA sequencing datasets, and an image dataset, as well as two distinct chaotic dynamical systems, namely the Lorenz and Rossler attractors. We demonstrate chaotic learning predictions of the physical properties from chaos. Our new chaotic learning paradigm profoundly changes the textbook perception of chaos and bridges topology, chaos, and learning for the first time.
format Preprint
id arxiv_https___arxiv_org_abs_2503_14956
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Machine learning predictions from unpredictable chaos
Jiang, Jian
Chen, Long
ke, Lu
Dou, Bozheng
Zhu, Yueying
Shi, Yazhou
Qiu, Huahai
Zhang, Bengong
Zhou, Tianshou
Wei, Guo-Wei
Chaotic Dynamics
Biomolecules
Chaos is omnipresent in nature, and its understanding provides enormous social and economic benefits. However, the unpredictability of chaotic systems is a textbook concept due to their sensitivity to initial conditions, aperiodic behavior, fractal dimensions, nonlinearity, and strange attractors. In this work, we introduce, for the first time, chaotic learning, a novel multiscale topological paradigm that enables accurate predictions from chaotic systems. We show that seemingly random and unpredictable chaotic dynamics counterintuitively offer unprecedented quantitative predictions. Specifically, we devise multiscale topological Laplacians to embed real-world data into a family of interactive chaotic dynamical systems, modulate their dynamical behaviors, and enable the accurate prediction of the input data. As a proof of concept, we consider 28 datasets from four categories of realistic problems: 10 brain waves, four benchmark protein datasets, 13 single-cell RNA sequencing datasets, and an image dataset, as well as two distinct chaotic dynamical systems, namely the Lorenz and Rossler attractors. We demonstrate chaotic learning predictions of the physical properties from chaos. Our new chaotic learning paradigm profoundly changes the textbook perception of chaos and bridges topology, chaos, and learning for the first time.
title Machine learning predictions from unpredictable chaos
topic Chaotic Dynamics
Biomolecules
url https://arxiv.org/abs/2503.14956