Predicting species distributions from checklist data using site‐occupancy models

Kéry, Marc; Gardner, Beth; Monnerat, Christian

doi:10.1111/j.1365-2699.2010.02345.x

Cited by 190 publications

(233 citation statements)

References 52 publications

(68 reference statements)

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“…Also, further work is needed to ascertain the factors determining smaller-scale habitat selection, using site occupancy models that account for imperfect detectability (Johnson et al 2009, Kery et al 2010, Rota et al 2011 …”

Section: Resultsmentioning

confidence: 99%

Predicted distributions and conservation status of two threatened Southeast Asian small carnivores: the banded civet and Hose’s civet

et al. 2013

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Knowledge of the distribution and habitat preferences of a species is of paramount importance when assessing its conservation status. We used accurately recorded occurrence records and ecological niche modelling to predict the distribution of two threatened and poorly known small carnivore species that occur in Southeast Asia, the banded civet ( Hemigalus derbyanus ) and Hose ' s civet ( Diplogale hosei ), and analysed their spatial niche differentiation for habitat and elevation. We then identified possible anthropogenic threats, and used our modelling predictions to recommend surveying priorities. The predicted distribution of the banded civet was principally in lowland evergreen forest in southern Myanmar/Thailand, Peninsular Malaysia, Sumatra, Borneo and three Mentawai Islands (Siberut, Sipora and South Pagai), and for Hose ' s civet in evergreen forest across the higher elevation regions of Borneo. Our niche analyses suggested that there is a tendency for these two species to separate spatially along an elevation gradient: the banded civet is mainly found in lowland areas, whereas Hose ' s civet primarily occurs at higher elevations. Our study strongly indicated that these two viverrids are forest-dependent species that may be threatened by forest loss, degradation and fragmentation. Field surveys should be prioritised in areas where each species is predicted to occur and no records currently exist.

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Section: Resultsmentioning

confidence: 99%

Predicted distributions and conservation status of two threatened Southeast Asian small carnivores: the banded civet and Hose’s civet

et al. 2013

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“…Large-scale analyses often assume that the absence of a species in the data represents a true absence (i.e., that its detection probability is 1, Kéry et al 2010, Monk 2014. Clearly, this is rarely the case.…”

Section: Hardisty Et Al 2013)mentioning

confidence: 99%

New Approaches to Marine Conservation Through the Scaling Up of Ecological Data

Edgar

Bates

Bird

et al. 2016

Annu. Rev. Mar. Sci.

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In an era of rapid global change, conservation managers urgently need improved tools to track and counter declining ecosystem conditions. This need is particularly acute in the marine realm, where threats are out of sight, inadequately mapped, cumulative, and often poorly understood, thereby generating impacts that are inefficiently managed. Recent advances in macroecology, statistical analysis, and the compilation of global data will play a central role in improving conservation outcomes, provided that global, regional, and local data streams can be integrated to produce locally relevant and interpretable outputs. Progress will be assisted by (a) expanded rollout of systematic surveys that quantify species patterns, including some carried out with help from citizen scientists; (b) coordinated experimental research networks that utilize large-scale manipulations to identify mechanisms underlying these patterns; (c) improved understanding of consequences of threats through the application of recently developed statistical techniques to analyze global species' distributional data and associated environmental and socioeconomic factors; (d) development of reliable ecological indicators for accurate and comprehensible tracking of threats; and (e) improved data-handling and communication tools.

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“…These citizen science data naturally present several analysis-related challenges relating to sampling bias, observer variability, and measurement errors (see, e.g., Yoccoz et al, 2001, Jeppsson et al, 2010, Kery et al, 2010. None the less, novel statistical and computational approaches exist to account for possible biases (see, e.g., Kelling et al, 2009, Jeppsson et al, 2010, Kery et al, 2010, Hochachka et al, 2012, Bird et al, 2013. Initial analyses based on SOS bird data have shown good potential for birds (Snäll et al, 2011) and longhorn beetles (Jeppsson et al, 2010, Snäll et al, 2013.…”

Section: Integrating and Reusing Large Heterogeneous Biodiversity Datmentioning

confidence: 99%

“…When structured monitoring data are not available, or are limited in space or time, citizen science data represent an alternative or complementary source of information. These citizen science data naturally present several analysis-related challenges relating to sampling bias, observer variability, and measurement errors (see, e.g., Yoccoz et al, 2001, Jeppsson et al, 2010, Kery et al, 2010. None the less, novel statistical and computational approaches exist to account for possible biases (see, e.g., Kelling et al, 2009, Jeppsson et al, 2010, Kery et al, 2010, Hochachka et al, 2012, Bird et al, 2013.…”

Section: Integrating and Reusing Large Heterogeneous Biodiversity Datmentioning

confidence: 99%

Swedish LifeWatch ─ a biodiversity infrastructure integrating and reusing data from citizen science, monitoring and research

Gärdenfors

Jönsson

Obst

et al. 2014

HCj

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With continued pressure on biodiversity and ever-growing conflicts with human development, qualified systems for scenario modelling, impact assessment and decision support are urgently needed. Such systems must be able to integrate complex models and information from many sources and do so in a flexible and transparent way. To that end, as well as for other complicated and data-intensive biodiversity research purposes, the concept of LifeWatch has emerged. The idea of LifeWatch is to construct e-infrastructure and virtual laboratories by integrating large data sources, computational capacities, and tools for analysis and modelling in an open, serviceoriented architecture. To be efficient and accurate, a continuous inflow of large quantities of data is essential. However, even with new techniques, government-funded monitoring data and research data will not feed the system with up-to-date species information of sufficient scale and resolution. To fill this void, skilled amateur observers (citizen scientists) can contribute to a very valuable extent.

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Predicting species distributions from checklist data using site‐occupancy models

Cited by 190 publications

References 52 publications

Predicted distributions and conservation status of two threatened Southeast Asian small carnivores: the banded civet and Hose’s civet

Predicted distributions and conservation status of two threatened Southeast Asian small carnivores: the banded civet and Hose’s civet

New Approaches to Marine Conservation Through the Scaling Up of Ecological Data

Swedish LifeWatch ─ a biodiversity infrastructure integrating and reusing data from citizen science, monitoring and research

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