Early warning signals of regime shifts for aquatic systems: Can experiments help to bridge the gap between theory and real-world application?

In complex systems, a critical transition is a shift in a system’s dynamical regime from its current state to a strongly contrasting state as external conditions move beyond a tipping point. These transitions are often preceded by characteristic early warning signals such as increased system variability. However, early warning signals in complex, coupled human–environment systems (HESs) remain little studied. Here, we compare critical transitions and their early warning signals in a coupled HES model to an equivalent environment model uncoupled from the human system. We parameterize the HES model, using social and ecological data from old-growth forests in Oregon. We find that the coupled HES exhibits a richer variety of dynamics and regime shifts than the uncoupled environment system. Moreover, the early warning signals in the coupled HES can be ambiguous, heralding either an era of ecosystem conservationism or collapse of both forest ecosystems and conservationism. The presence of human feedback in the coupled HES can also mitigate the early warning signal, making it more difficult to detect the oncoming regime shift. We furthermore show how the coupled HES can be “doomed to criticality”: Strategic human interactions cause the system to remain perpetually in the vicinity of a collapse threshold, as humans become complacent when the resource seems protected but respond rapidly when it is under immediate threat. We conclude that the opportunities, benefits, and challenges of modeling regime shifts and early warning signals in coupled HESs merit further research.

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Data-driven identification of reliable sensor species to predict regime shifts in ecological networks

Royal Society Open Science ◽

10.1098/rsos.200896 ◽

2020 ◽

Vol 7 (8) ◽

pp. 200896 ◽

Cited By ~ 1

Author(s):

Amin Ghadami ◽

Shiyang Chen ◽

Bogdan I. Epureanu

Keyword(s):

Indicator Species ◽

Early Warning ◽

Regime Shifts ◽

Data Driven ◽

Warning Signals ◽

Early Warning Signals ◽

Critical Transitions ◽

Spatially Distributed ◽

Data Driven Approach ◽

Interacting Components

Signals of critical slowing down are useful for predicting impending transitions in ecosystems. However, in a system with complex interacting components not all components provide the same quality of information to detect system-wide transitions. Identifying the best indicator species in complex ecosystems is a challenging task when a model of the system is not available. In this paper, we propose a data-driven approach to rank the elements of a spatially distributed ecosystem based on their reliability in providing early-warning signals of critical transitions. The proposed method is rooted in experimental modal analysis techniques traditionally used to identify structural dynamical systems. We show that one could use natural system fluctuations and the system responses to small perturbations to reveal the slowest direction of the system dynamics and identify indicator regions that are best suited for detecting abrupt transitions in a network of interacting components. The approach is applied to several ecosystems to demonstrate how it successfully ranks regions based on their reliability to provide early-warning signals of regime shifts. The significance of identifying the indicator species and the challenges associated with ranking nodes in networks of interacting components are also discussed.

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Deep learning for early warning signals of regime shifts

10.1101/2021.03.28.437429 ◽

2021 ◽

Author(s):

Thomas Bury ◽

Raman Sujith ◽

Induja Pavithran ◽

Marten Scheffer ◽

Timothy Lenton ◽

...

Keyword(s):

Deep Learning ◽

Early Warning ◽

Normal Forms ◽

Learning Algorithm ◽

Tipping Point ◽

Regime Shifts ◽

Tipping Points ◽

Warning Signals ◽

Early Warning Signals ◽

Deep Learning Algorithm

Many natural systems exhibit regime shifts where slowly changing environmental conditions suddenly shift the system to a new and sometimes very different state. As the tipping point is approached, the dynamics of complex and varied systems all simplify down to a small number of possible 'normal forms' that determine how the new regime will look. Indicators such as increasing lag-1 autocorrelation and variance provide generic early warning signals (EWS) by detecting how dynamics slow down near the tipping point. But they do not indicate what type of new regime will emerge. Here we develop a deep learning algorithm that can detect EWS in systems it was not explicitly trained on, by exploiting information about normal forms and scaling behaviour of dynamics near tipping points that are common to many dynamical systems. The algorithm detects EWS in 268 empirical and model time series from ecology, thermoacoustics, climatology, and epidemiology with much greater sensitivity and specificity than generic EWS. It can also predict the normal form that will characterize the oncoming regime shift. Such approaches can help humans better manage regime shifts. The algorithm also illustrates how a universe of possible models can be mined to recognize naturally-occurring tipping points.

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Implications of being discrete and spatial for detecting early warning signals of regime shifts

Ecological Indicators ◽

10.1016/j.ecolind.2017.11.040 ◽

2018 ◽

Vol 94 ◽

pp. 503-511 ◽

Cited By ~ 7

Author(s):

Sumithra Sankaran ◽

Sabiha Majumder ◽

Sonia Kéfi ◽

Vishwesha Guttal

Keyword(s):

Early Warning ◽

Regime Shifts ◽

Warning Signals ◽

Early Warning Signals

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Long‐term empirical evidence, early warning signals and multiple drivers of regime shifts in a lake ecosystem

Journal of Ecology ◽

10.1111/1365-2745.13544 ◽

2020 ◽

Author(s):

Haojie Su ◽

Rong Wang ◽

Yuhao Feng ◽

Yanling Li ◽

Yun Li ◽

...

Keyword(s):

Empirical Evidence ◽

Early Warning ◽

Regime Shifts ◽

Lake Ecosystem ◽

Warning Signals ◽

Early Warning Signals

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Spatial Correlation as an Early Warning Signal of Regime Shifts in a Multiplex Disease-Behaviour Network

10.1101/195388 ◽

2017 ◽

Author(s):

Peter C. Jentsch ◽

Madhur Anand ◽

Chris T. Bauch

Keyword(s):

Spatial Correlation ◽

Early Warning ◽

Regime Shift ◽

Tipping Point ◽

Regime Shifts ◽

Critical Slowing Down ◽

Warning Signals ◽

Early Warning Signals ◽

Network Layer ◽

Slowing Down

AbstractEarly warning signals of sudden regime shifts are a widely studied phenomenon for their ability to quantify a system’s proximity to a tipping point to a new and contrasting dynamical regime. However, this effect has been little studied in the context of the complex interactions between disease dynamics and vaccinating behaviour. Our objective was to determine whether critical slowing down (CSD) occurs in a multiplex network that captures opinion propagation on one network layer and disease spread on a second network layer. We parameterized a network simulation model to represent a hypothetical self-limiting, acute, vaccine-preventable infection with shortlived natural immunity. We tested five different network types: random, lattice, small-world, scale-free, and an empirically derived network. For the first four network types, the model exhibits a regime shift as perceived vaccine risk moves beyond a tipping point from full vaccine acceptance and disease elimination to full vaccine refusal and disease endemicity. This regime shift is preceded by an increase in the spatial correlation in non-vaccinator opinions beginning well before the bifurcation point, indicating CSD. The early warning signals occur across a wide range of parameter values. However, the more gradual transition exhibited in the empirically-derived network underscores the need for further research before it can be determined whether trends in spatial correlation in real-world social networks represent critical slowing down. The potential upside of having this monitoring ability suggests that this is a worthwhile area for further research.

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Robustness of early warning signals for catastrophic and non-catastrophic transitions

10.1101/218297 ◽

2017 ◽

Author(s):

Partha Sharathi Dutta ◽

Yogita Sharma ◽

Karen C. Abbott

Keyword(s):

Early Warning ◽

Regime Shift ◽

Regime Shifts ◽

Stable Equilibrium Point ◽

Perturbation Scheme ◽

Correlated Noise ◽

Warning Signals ◽

Saddle Node Bifurcation ◽

Early Warning Signals ◽

Saddle Node

AbstractEarly warning signals (EWS) are statistical indicators that a rapid regime shift may be forthcoming. Their development has given ecologists hope of predicting rapid regime shifts before they occur. Accurate predictions, however, rely on the signals being appropriate to the system in question. Most of the EWS commonly applied in ecology have been studied in the context of one specific type of regime shift (the type brought on by a saddle-node bifurcation, at which one stable equilibrium point collides with an unstable equilibrium and disappears) under one particular perturbation scheme (temporally uncorrelated noise that perturbs the net population growth rate in a density independent way). Whether and when these EWS can be applied to other ecological situations remains relatively unknown, and certainly underappreciated. We study a range of models with different types of dynamical transitions (including rapid regime shifts) and several perturbation schemes (density-dependent uncorrelated or temporally-correlated noise) and test the ability of EWS to warn of an approaching transition. We also test the sensitivity of our results to the amount of available pre-transition data and various decisions that must be made in the analysis (i.e. the rolling window size and smoothing bandwidth used to compute the EWS). We find that EWS generally work well to signal an impending saddle-node bifurcation, regardless of the autocorrelation or intensity of the noise. However, EWS do not reliably appear as expected for other types of transition. EWS were often very sensitive to the length of the pre-transition time series analyzed, and usually less sensitive to other decisions. We conclude that the EWS perform well for saddle-node bifurcation in a range of noise environments, but different methods should be used to predict other types of regime shifts. As a consequence, knowledge of the mechanism behind a possible regime shift is needed before EWS can be used to predict it.

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