Forecasting hypoxia events in north Atlantic ecosystems using chaotic dynamics

This paper introduces a novel approach for modeling dissolved oxygen (DO) time series data collected in Atlantic Canada. The primary objective is to propose a solution that can predict significant fluctuations in dissolved oxygen levels in estuaries, thereby improving our ability to manage and prote...

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Bibliographic Details
Published in:2024 International Joint Conference on Neural Networks (IJCNN)
Main Authors: Durand, Guillaume, Valdés, Julio J., Guyondet, Thomas, Rice, Olivia Gerry, Coffin, Michael
Format: Article in Journal/Newspaper
Language:English
Published: IEEE 2024
Subjects:
estuary ecosystems
dissolved oxygen time series
non-linear dynamic systems
chaos theory
modeling
machine learning
chaos
analytical models
fluctuations
computational modeling
biological system modeling
time series analysis
predictive models
Canada
North Atlantic
Online Access:https://doi.org/10.1109/IJCNN60899.2024.10651143
https://nrc-publications.canada.ca/eng/view/object/?id=7d255869-22c2-4497-b5d3-aba20a685a6a
https://nrc-publications.canada.ca/fra/voir/objet/?id=7d255869-22c2-4497-b5d3-aba20a685a6a
Description
Summary:This paper introduces a novel approach for modeling dissolved oxygen (DO) time series data collected in Atlantic Canada. The primary objective is to propose a solution that can predict significant fluctuations in dissolved oxygen levels in estuaries, thereby improving our ability to manage and protect these dynamic ecosystems. Dissolved oxygen serves as a crucial indicator of water quality and is influenced by various factors such as temperature, nutrient concentrations, and biological activities, resulting in a nonlinear dynamic system. By analyzing chaos-related metrics, we demonstrate that the inherent unpredictability and sensitivity of DO time series can be effectively captured. We show that the modeling of the magnitude and duration of DO fluctuations can be anticipated by studying features like bifurcation patterns. Our research effectively characterizes dissolved oxygen series as nonlinear dynamic systems, revealing the internal structure of these systems and enabling differentiation of sites based on their hypoxic behavior. We develop models using both classical and deep learning-based early warning/tipping point indicators, which successfully predict the occurrence of hypoxic events even in degraded sites. The presented results highlight the advantages of our proposed method in anticipating tipping points and predicting the duration of anoxic episodes, particularly in highly degraded sites. Peer reviewed: Yes NRC publication: Yes

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