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Main Authors: Mayora-Cebollero, Carmen, Fenton, Flavio H., Halprin, Molly, Herndon, Conner, Toye, Mikael J., Barrio, Roberto
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.13027
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author Mayora-Cebollero, Carmen
Fenton, Flavio H.
Halprin, Molly
Herndon, Conner
Toye, Mikael J.
Barrio, Roberto
author_facet Mayora-Cebollero, Carmen
Fenton, Flavio H.
Halprin, Molly
Herndon, Conner
Toye, Mikael J.
Barrio, Roberto
contents The study of experimental data is a relevant task in several physical, chemical and biological applications. In particular, the analysis of chaotic dynamics in cardiac systems is crucial as it can be related to some pathological arrhythmias. When working with short and noisy experimental time series, some standard techniques for chaos detection cannot provide reliable results because of such data characteristics. Moreover, when small datasets are available, Deep Learning techniques cannot be applied directly (that is, using part of the data to train the network, and using the trained network to analyze the remaining dataset). To avoid all these limitations, we propose an automatic algorithm that combines Deep Learning and some selection strategies based on a mathematical model of the same nature of the experimental data. To show its performance, we test it with experimental data obtained from ex-vivo frog heart experiments, obtaining highly accurate results.
format Preprint
id arxiv_https___arxiv_org_abs_2509_13027
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Deep Learning for Analyzing Chaotic Dynamics in Biological Time Series: Insights from Frog Heart Signals
Mayora-Cebollero, Carmen
Fenton, Flavio H.
Halprin, Molly
Herndon, Conner
Toye, Mikael J.
Barrio, Roberto
Chaotic Dynamics
The study of experimental data is a relevant task in several physical, chemical and biological applications. In particular, the analysis of chaotic dynamics in cardiac systems is crucial as it can be related to some pathological arrhythmias. When working with short and noisy experimental time series, some standard techniques for chaos detection cannot provide reliable results because of such data characteristics. Moreover, when small datasets are available, Deep Learning techniques cannot be applied directly (that is, using part of the data to train the network, and using the trained network to analyze the remaining dataset). To avoid all these limitations, we propose an automatic algorithm that combines Deep Learning and some selection strategies based on a mathematical model of the same nature of the experimental data. To show its performance, we test it with experimental data obtained from ex-vivo frog heart experiments, obtaining highly accurate results.
title Deep Learning for Analyzing Chaotic Dynamics in Biological Time Series: Insights from Frog Heart Signals
topic Chaotic Dynamics
url https://arxiv.org/abs/2509.13027