Recurrent neural networks for dynamical systems: Applications to ordinary differential equations, collective motion, and hydrological modeling

Classical methods of solving spatiotemporal dynamical systems include statistical approaches such as autoregressive integrated moving average, which assume linear and stationary relationships between systems’ previous outputs. Development and implementation of linear methods are relatively simple, b...

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Published in:Chaos (Woodbury, N.Y.) N.Y.), 2023-01, Vol.33 (1), p.013109-013109
Main Authors: Gajamannage, K., Jayathilake, D. I., Park, Y., Bollt, E. M.
Format: Article
Language:English
Subjects:
Artificial neural networks
Differential equations
Dynamical systems
Error correction
Forecasting
Hydrology
Mathematical models
Modelling
Neural networks
Ordinary differential equations
Process variables
Reconstruction
Recurrent neural networks
Regular
Sequences
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cited_by cdi_FETCH-LOGICAL-c473t-be8813b3095438ed3bd0af6ae3f48e675bc5573dbb2ae29df81c99ad99e5f70a3
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description Classical methods of solving spatiotemporal dynamical systems include statistical approaches such as autoregressive integrated moving average, which assume linear and stationary relationships between systems’ previous outputs. Development and implementation of linear methods are relatively simple, but they often do not capture non-linear relationships in the data. Thus, artificial neural networks (ANNs) are receiving attention from researchers in analyzing and forecasting dynamical systems. Recurrent neural networks (RNNs), derived from feed-forward ANNs, use internal memory to process variable-length sequences of inputs. This allows RNNs to be applicable for finding solutions for a vast variety of problems in spatiotemporal dynamical systems. Thus, in this paper, we utilize RNNs to treat some specific issues associated with dynamical systems. Specifically, we analyze the performance of RNNs applied to three tasks: reconstruction of correct Lorenz solutions for a system with a formulation error, reconstruction of corrupted collective motion trajectories, and forecasting of streamflow time series possessing spikes, representing three fields, namely, ordinary differential equations, collective motion, and hydrological modeling, respectively. We train and test RNNs uniquely in each task to demonstrate the broad applicability of RNNs in the reconstruction and forecasting the dynamics of dynamical systems.
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source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list)
subjects Artificial neural networks
Differential equations
Dynamical systems
Error correction
Forecasting
Hydrology
Mathematical models
Modelling
Neural networks
Ordinary differential equations
Process variables
Reconstruction
Recurrent neural networks
Regular
Sequences
title Recurrent neural networks for dynamical systems: Applications to ordinary differential equations, collective motion, and hydrological modeling
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