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Main Authors: Bury, Thomas M., Dylewsky, Daniel, Bauch, Chris T., Anand, Madhur, Glass, Leon, Shrier, Alvin, Bub, Gil
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2303.09669
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author Bury, Thomas M.
Dylewsky, Daniel
Bauch, Chris T.
Anand, Madhur
Glass, Leon
Shrier, Alvin
Bub, Gil
author_facet Bury, Thomas M.
Dylewsky, Daniel
Bauch, Chris T.
Anand, Madhur
Glass, Leon
Shrier, Alvin
Bub, Gil
contents Many natural and man-made systems are prone to critical transitions -- abrupt and potentially devastating changes in dynamics. Deep learning classifiers can provide an early warning signal (EWS) for critical transitions by learning generic features of bifurcations (dynamical instabilities) from large simulated training data sets. So far, classifiers have only been trained to predict continuous-time bifurcations, ignoring rich dynamics unique to discrete-time bifurcations. Here, we train a deep learning classifier to provide an EWS for the five local discrete-time bifurcations of codimension-1. We test the classifier on simulation data from discrete-time models used in physiology, economics and ecology, as well as experimental data of spontaneously beating chick-heart aggregates that undergo a period-doubling bifurcation. The classifier outperforms commonly used EWS under a wide range of noise intensities and rates of approach to the bifurcation. It also predicts the correct bifurcation in most cases, with particularly high accuracy for the period-doubling, Neimark-Sacker and fold bifurcations. Deep learning as a tool for bifurcation prediction is still in its nascence and has the potential to transform the way we monitor systems for critical transitions.
format Preprint
id arxiv_https___arxiv_org_abs_2303_09669
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Predicting discrete-time bifurcations with deep learning
Bury, Thomas M.
Dylewsky, Daniel
Bauch, Chris T.
Anand, Madhur
Glass, Leon
Shrier, Alvin
Bub, Gil
Quantitative Methods
Machine Learning
Dynamical Systems
Many natural and man-made systems are prone to critical transitions -- abrupt and potentially devastating changes in dynamics. Deep learning classifiers can provide an early warning signal (EWS) for critical transitions by learning generic features of bifurcations (dynamical instabilities) from large simulated training data sets. So far, classifiers have only been trained to predict continuous-time bifurcations, ignoring rich dynamics unique to discrete-time bifurcations. Here, we train a deep learning classifier to provide an EWS for the five local discrete-time bifurcations of codimension-1. We test the classifier on simulation data from discrete-time models used in physiology, economics and ecology, as well as experimental data of spontaneously beating chick-heart aggregates that undergo a period-doubling bifurcation. The classifier outperforms commonly used EWS under a wide range of noise intensities and rates of approach to the bifurcation. It also predicts the correct bifurcation in most cases, with particularly high accuracy for the period-doubling, Neimark-Sacker and fold bifurcations. Deep learning as a tool for bifurcation prediction is still in its nascence and has the potential to transform the way we monitor systems for critical transitions.
title Predicting discrete-time bifurcations with deep learning
topic Quantitative Methods
Machine Learning
Dynamical Systems
url https://arxiv.org/abs/2303.09669