A Systematic Review of Marine-Based Species Distribution Models (SDMs) with Recommendations for Best Practice

Robinson, Néstor M.; Nelson, Wendy A.; Costello, Mark J.; Sutherland, Judy E.; Lundquist, Carolyn J.

doi:10.3389/fmars.2017.00421

Cited by 201 publications

(184 citation statements)

References 38 publications

(44 reference statements)

Supporting

Mentioning

155

Contrasting

Unclassified

Order By: Relevance

“…Colors indicate whether transfers were considered successful (green, unbroken lines; 1-9) or not (dark red, dashed lines; [16][17][18][19][20], as reported by the authors and irrespective of the statistical methods chosen to build the models or the metrics used to evaluate them. Dual colors indicate scenarios in which the quality of transfers varied as a function of modeling algorithms (10-11), space (12), or species (13)(14)(15) contemporaneous sites at different positions along an environmental gradient can approximate temporal variability [72]. Such would be the case, for example, for areas subject to temperature regimes similar to those anticipated in the future, noting it will not be appropriate for species occupying small ranges or those not well-represented in the fossil record.…”

Section: Do Specific Modeling Approaches Results In Better Transferabimentioning

confidence: 99%

“…Assessments of transferability demand appropriate diagnostics of prediction accuracy and precision [73], yet there is still little consensus on which metrics are most appropriate [6,74]. All else being equal, true validation is possible only with independent data, which are often Figure 7 in Robinson et al [12]). Challenges were identified by a consortium of 50 experts.…”

Section: Do Specific Modeling Approaches Results In Better Transferabimentioning

confidence: 99%

“…Acknowledging significant overlap and linkages between these challenges (Figure 2), we explore each separately below. Attempts to understand and enhance transferability face many of the same hurdles as ecological modeling generally (e.g., data quality, stochasticity), and adhering to best practice recommendations (e.g., [12,13]) is thus imperative. We do not focus on these well-established standards, but concentrate on the additional challenges posed by transferring models.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Outstanding Challenges in the Transferability of Ecological Models

Yates

Bouchet

Caley

et al. 2018

Trends in Ecology & Evolution

463

456

View full text Add to dashboard Cite

Predictive models are central to many scientific disciplines and vital for informing management in a rapidly changing world. However, limited understanding of the accuracy and precision of models transferred to novel conditions (their 'transferability') undermines confidence in their predictions. Here, 50 experts identified priority knowledge gaps which, if filled, will most improve model transfers. These are summarized into six technical and six fundamental challenges, which underlie the combined need to intensify research on the determinants of ecological predictability, including species traits and data quality, and develop best practices for transferring models. Of high importance is the identification of a widely applicable set of transferability metrics, with appropriate tools to quantify the sources and impacts of prediction uncertainty under novel conditions. Predicting the UnknownPredictions facilitate the formulation of quantitative, testable hypotheses that can be refined and validated empirically [1]. Predictive models have thus become ubiquitous in numerous scientific disciplines, including ecology [2], where they provide means for mapping species distributions, explaining population trends, or quantifying the risks of biological invasions and disease outbreaks (e.g., [3,4]). The practical value of predictive models in supporting policy and decision making has therefore grown rapidly (Box 1) [5]. With that has come an increasing desire to predict (see Glossary) the state of ecological features (e.g., species, habitats) and our likely impacts upon them [5], prompting a shift from explanatory models to anticipatory predictions [2]. However, in many situations, severe data deficiencies preclude the development of specific models, and the collection of new data can be prohibitively costly or simply impossible [6]. It is in this context that interest in transferable models (i.e., those that can be legitimately projected beyond the spatial and temporal bounds of their underlying data [7]) has grown.Transferred models must balance the tradeoff between estimation and prediction bias and variance (homogenization versus nontransferability, sensu [8]). Ultimately, models that can Highlights Models transferred to novel conditions could provide predictions in data-poor scenarios, contributing to more informed management decisions.The determinants of ecological predictability are, however, still insufficiently understood.Predictions from transferred ecological models are affected by species' traits, sampling biases, biotic interactions, nonstationarity, and the degree of environmental dissimilarity between reference and target systems.We synthesize six technical and six fundamental challenges that, if resolved, will catalyze practical and conceptual advances in model transfers.We propose that the most immediate obstacle to improving understanding lies in the absence of a widely applicable set of metrics for assessing transferability, and that encouraging the development of models grounded in well-established mech...

show abstract

Section: Do Specific Modeling Approaches Results In Better Transferabimentioning

confidence: 99%

Section: Do Specific Modeling Approaches Results In Better Transferabimentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Outstanding Challenges in the Transferability of Ecological Models

Yates

Bouchet

Caley

et al. 2018

Trends in Ecology & Evolution

463

456

View full text Add to dashboard Cite

show abstract

“…Species distribution models (SDMs) are key tools for describing species habitats and distributions across marine and terrestrial systems (Elith & Leathwick, ; Robinson, Nelson, Costello, Sutherland, & Lundquist, ). Species distribution modelling involves using statistical tools to relate species occurrence or abundance to spatiotemporal patterns of environmental variation (Elith & Leathwick, ).…”

Section: Introductionmentioning

confidence: 99%

“…First, while marine SDMs have typically used a single‐model type (Robinson et al, ), determining an appropriate modelling approach can be challenging given inherent trade‐offs in the statistical methods available (Elith et al, ; Qiao, Soberón, & Peterson, ). Multi‐model ensembles can reduce uncertainty by overcoming biases inherent in any one model type and providing a “consensus” approach to predictions (Araújo & New, ; Gritti, Duputié, Massol, & Chuine, ).…”

Section: Introductionmentioning

confidence: 99%

Dynamic ensemble models to predict distributions and anthropogenic risk exposure for highly mobile species

Abrahms

Welch

Brodie

et al. 2019

Diversity and Distributions

106

View full text Add to dashboard Cite

Aim Advances in ecological and environmental modelling offer new opportunities for estimating dynamic habitat suitability for highly mobile species and supporting management strategies at relevant spatiotemporal scales. We used an ensemble modelling approach to predict daily, year‐round habitat suitability for a migratory species, the blue whale (Balaenoptera musculus), and demonstrate an application for evaluating the spatiotemporal dynamics of their exposure to ship strike risk. Location The California Current Ecosystem (CCE) and the Southern California Bight (SCB), USA. Methods We integrated a long‐term (1994–2008) satellite tracking dataset on 104 blue whales with data‐assimilative ocean model output to assess year‐round habitat suitability. We evaluated the relative utility of ensembling multiple model types compared to using single models, and selected and validated candidate models using multiple cross‐validation metrics and independent observer data. We quantified the spatial and temporal distribution of exposure to ship strike risk within shipping lanes in the SCB. Results Multi‐model ensembles outperformed single‐model approaches. The final ensemble model had high predictive skill (AUC = 0.95), resulting in daily, year‐round predictions of blue whale habitat suitability in the CCE that accurately captured migratory behaviour. Risk exposure in shipping lanes was highly variable within and among years as a function of environmental conditions (e.g., marine heatwave). Main conclusions Daily information on three‐dimensional oceanic habitats was used to model the daily distribution of a highly migratory species with high predictive power and indicated that management strategies could benefit by incorporating dynamic environmental information. This approach is readily transferable to other species. Dynamic, high‐resolution species distribution models are valuable tools for assessing risk exposure and targeting management needs.

show abstract

Comparison of spatial distribution models to predict subtidal burying habitat of the forage fish Ammodytes personatus in the Strait of Georgia, British Columbia, Canada

Robinson

Proudfoot

Rooper

et al. 2021

Aquatic Conservation

View full text Add to dashboard Cite

The Pacific sand lance (Ammodytes personatus) is a key forage species for many commercially important fish (e.g. salmon and groundfish), marine birds, and whales found in nearshore coastal waters of British Columbia, Canada. Sand lance lack a swim bladder and have a requirement for low‐silt, medium‐coarse sandy sea‐bed habitat for burying. Little information is available describing the distribution of burying habitat, partly because there are no commercial fisheries for A. personatus in British Columbia. This information is required by habitat and wildlife managers to identify and protect uncommon patches of burying habitats from detrimental activities, including dredging, infilling, and oil spills. In this study, habitat distribution results from five suitability modelling algorithms were evaluated: maximum entropy, generalized linear model, generalized additive model, random forest, and an ensemble model of the latter three. The maximum entropy model had the highest performance score (area under the receiver operator characteristic curve was 0.78) and was selected as the model that most accurately identified the presence of suitable A. personatus burying habitat. Model results indicate that suitable burying habitat is primarily influenced by derived sea‐bed substrate, distance to estuary, distance to sand‐gravel beaches, and bottom sea temperature. Overall, the spatial modelling identified only 105 km2 of highly suitable sand lance burying habitat, or 2.6% of the study area (0–150 m), primarily in Haro Strait, along the east coast of Vancouver Island, and in northern regions of the strait near Cortes, Savary, and Harwood islands. Identification of this uncommon and patchy burying habitat will contribute to the ongoing conservation of an important coastal prey species.

show abstract

A Systematic Review of Marine-Based Species Distribution Models (SDMs) with Recommendations for Best Practice

Cited by 201 publications

References 38 publications

Outstanding Challenges in the Transferability of Ecological Models

Outstanding Challenges in the Transferability of Ecological Models

Dynamic ensemble models to predict distributions and anthropogenic risk exposure for highly mobile species

Comparison of spatial distribution models to predict subtidal burying habitat of the forage fish Ammodytes personatus in the Strait of Georgia, British Columbia, Canada

Contact Info

Product

Resources

About