Extending the viability theory framework of resilience to uncertain dynamics, and application to lake eutrophication

Extending the viability theory framework of resilience to uncertain dynamics, and application to lake eutrophication

► A framework for the resilience of any stochastic dynamical system is presented. ► This is an extension of the deterministic viability-based framework of resilience. ► We distinguish strong and rare perturbations from weaker usual uncertainty. ► Resilience is recovering and keeping a property after...

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Bibliographic Details
Published in:Ecological indicators Vol. 29; pp. 420 - 433
Main Authors: Rougé, Charles, Mathias, Jean-Denis, Deffuant, Guillaume
Format: Journal Article
Language:English
Published: Amsterdam Elsevier Ltd 01-06-2013
Elsevier
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Dynamic programming
Environmental Sciences
eutrophication
Fresh water ecosystems
Fundamental and applied biological sciences. Psychology
lakes
probability
Probability of resilience
Resilience
seeds
Stochastic dynamics
Synecology
viability
Viability theory
Stochastic dynamics
Dynamic programming
Viability theory
Resilience
Probability of resilience
Freshwater environment
Dynamics
Theory
Lakes
Viability
Eutrophication
STOCHASTIC DYNAMICS
RESILIENCE ECOLOGIQUE
PROCESSUS STOCHASTIQUE
VIABILITY THEORY
DYNAMIC PROGRAMMING
RESILIENCE
THEORIE DE LA VIABILITE
EUTROPHISATION
CALCUL DE PROBABILITE
PROBABILITY OF RESILIENCE
LAC
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Summary:► A framework for the resilience of any stochastic dynamical system is presented. ► This is an extension of the deterministic viability-based framework of resilience. ► We distinguish strong and rare perturbations from weaker usual uncertainty. ► Resilience is recovering and keeping a property after a strong perturbation. ► Dynamic programming allows for maximizing the probability of being resilient. Resilience, the capacity for a system to recover from a perturbation so as to keep its properties and functions, is of growing concern to a wide range of environmental systems. The challenge is often to render this concept operational without betraying it, nor diluting its content. The focus here is on building on the viability theory framework of resilience to extend it to discrete-time stochastic dynamical systems. The viability framework describes properties of the system as a subset of its state space. This property is resilient to a perturbation if it can be recovered and kept by the system after a perturbation: its trajectory can come back and stay in the subset. This is shown to reflect a general definition of resilience. With stochastic dynamics, the stochastic viability kernel describes the robust states, in which the system has a high probability of staying in the subset for a long time. Then, probability of resilience is defined as the maximal probability that the system reaches a robust state within a time horizon. Management strategies that maximize the probability of resilience can be found through dynamic programming. It is then possible to compute a range of statistics on the time for restoring the property. The approach is illustrated on the example of lake eutrophication and shown to foster the use of different indicators that are adapted to distinct situations. Its relevance for the management of ecological systems is also discussed.
Bibliography:http://dx.doi.org/10.1016/j.ecolind.2012.12.032
ISSN:1470-160X
1872-7034
DOI:10.1016/j.ecolind.2012.12.032