Dynamic minimum set problem for reserve design: Heuristic solutions for large problems

Conversion of wild habitats to human dominated landscape is a major cause of biodiversity loss. An approach to mitigate the impact of habitat loss consists of designating reserves where habitat is preserved and managed. Determining the most valuable areas to preserve in a landscape is called the res...

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Veröffentlicht in:PloS one 2018-03, Vol.13 (3), p.e0193093-e0193093
Hauptverfasser: Bonneau, Mathieu, Sabbadin, Régis, Johnson, Fred A, Stith, Bradley
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Sabbadin, Régis
Johnson, Fred A
Stith, Bradley
description Conversion of wild habitats to human dominated landscape is a major cause of biodiversity loss. An approach to mitigate the impact of habitat loss consists of designating reserves where habitat is preserved and managed. Determining the most valuable areas to preserve in a landscape is called the reserve design problem. There exists several possible formulations of the reserve design problem, depending on the objectives and the constraints. In this article, we considered the dynamic problem of designing a reserve that contains a desired area of several key habitats. The dynamic case implies that the reserve cannot be designed in one time step, due to budget constraints, and that habitats can be lost before they are reserved, due for example to climate change or human development. We proposed two heuristics strategies that can be used to select sites to reserve each year for large reserve design problem. The first heuristic is a combination of the Marxan and site-ordering algorithms and the second heuristic is an augmented version of the common naive myopic heuristic. We evaluated the strategies on several simulated examples and showed that the augmented greedy heuristic is particularly interesting when some of the habitats to protect are particularly threatened and/or the compactness of the network is accounted for.
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subjects Algorithms
Animal genetics
Applied mathematics
Biodiversity
Biodiversity loss
Biology and Life Sciences
Climate change
Computer Science
Computer simulation
Design
Ecology
Ecology and Environmental Sciences
Environmental aspects
Environmental protection
Environmental research
Formulations
Genetics
Habitat loss
Habitat modification
Habitats
Heuristic
Life Sciences
Mathematical programming
Mathematics
Native species
Physical Sciences
Problem solving
Research and Analysis Methods
Social Sciences
Trends
Wildlife conservation
title Dynamic minimum set problem for reserve design: Heuristic solutions for large problems
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