Habitat-partitioning improves regional distribution models in multi-habitat species: a case study with the European bilberry

Suárez‐Seoane, Susana; Jíménez-Alfaro, Borja; Obeso, José Ramón

doi:10.1007/s10531-019-01922-5

Cited by 8 publications

(9 citation statements)

References 94 publications

(93 reference statements)

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“…At the plant-community level, the typology studied ranged from plant associations [49,50] to natural habitats [5,[51][52][53]. Interestingly, Bradter et al [49] and Fenske et al [50] indicated that increasing the vegetation hierarchical level (i.e., from habitat to plant association or species) decreases OCC accuracy, while Suárez-Seoane et al [54] demonstrated the opposite. In addition, Suárez-Seoane et al [54] and Connor et al [55] showed that vegetation classes with a narrow ecological niche had higher classification accuracy than that with a wider niche.…”

Section: From Plant Species To Land Covermentioning

confidence: 99%

“…Interestingly, Bradter et al [49] and Fenske et al [50] indicated that increasing the vegetation hierarchical level (i.e., from habitat to plant association or species) decreases OCC accuracy, while Suárez-Seoane et al [54] demonstrated the opposite. In addition, Suárez-Seoane et al [54] and Connor et al [55] showed that vegetation classes with a narrow ecological niche had higher classification accuracy than that with a wider niche. To improve the classification accuracy of plant communities, Tang et al [56] developed an approach that groups species into spectrally discriminating phenological groups based on a k-means classification applied to PCA axes of MODIS spectral variables.…”

Section: From Plant Species To Land Covermentioning

confidence: 99%

“…The vegetation variable (i.e., spectral values) is used most often (n = 99) and comes exclusively from RS data. Specifically, several studies showed the utility of variables that characterize vegetation phenology derived from multispectral satellite data to map natural vegetation, such as MODIS [82,83], Landsat [54], ASTER [84], RapidEye [51], or hyperspectral airborne data [85]. Although Sentinel-2 data are increasingly relevant for OCCs, their use remained limited to a few acquisitions [45,[71][72][73].…”

Section: Underused Rs-based Environmental Variablesmentioning

confidence: 99%

“…Conversely, many studies have reported not only that adding a spectral variable to environmental variables increases OCC accuracy [82,[110][111][112], particularly when classifying climate-unstructured plant species [59], but also that the spectral variable often contributes the most [36,46]. Two other studies reported that adding spectral variables did enhance the spatial scale of the map substantially [54,106]. Only 25 studies used at least four variable types.…”

Section: Combining Variables Improves Occ Performancementioning

confidence: 99%

“…Regarding reference data, their quality is also an issue for OCC performance [54]. Although new reference plots can be collected according to a specific protocol suitable for classifying actual area of vegetation classes at local or regional scales, using field reference databases is inevitable when classifying larger sites and/or performing temporal monitoring.…”

Section: Data Quality Influences Occ Performancementioning

confidence: 99%

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One-Class Classification of Natural Vegetation Using Remote Sensing: A Review

Rapinel

Hubert‐Moy

2021

Remote Sensing

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Advances in remote sensing (RS) technology in recent years have increased the interest in including RS data into one-class classifiers (OCCs). However, this integration is complex given the interdisciplinary issues involved. In this context, this review highlights the advances and current challenges in integrating RS data into OCCs to map vegetation classes. A systematic review was performed for the period 2013–2020. A total of 136 articles were analyzed based on 11 topics and 30 attributes that address the ecological issues, properties of RS data, and the tools and parameters used to classify natural vegetation. The results highlight several advances in the use of RS data in OCCs: (i) mapping of potential and actual vegetation areas, (ii) long-term monitoring of vegetation classes, (iii) generation of multiple ecological variables, (iv) availability of open-source data, (v) reduction in plotting effort, and (vi) quantification of over-detection. Recommendations related to interdisciplinary issues were also suggested: (i) increasing the visibility and use of available RS variables, (ii) following good classification practices, (iii) bridging the gap between spatial resolution and site extent, and (iv) classifying plant communities.

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Section: From Plant Species To Land Covermentioning

confidence: 99%

Section: From Plant Species To Land Covermentioning

confidence: 99%

Section: Underused Rs-based Environmental Variablesmentioning

confidence: 99%

Section: Combining Variables Improves Occ Performancementioning

confidence: 99%

Section: Data Quality Influences Occ Performancementioning

confidence: 99%

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One-Class Classification of Natural Vegetation Using Remote Sensing: A Review

Rapinel

Hubert‐Moy

2021

Remote Sensing

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Large‐scale and fine‐grained mapping of heathland habitats using open‐source remote sensing data

Hubert‐Moy

Rozo

Perrin³

et al. 2022

Remote Sens Ecol Conserv

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Mapping natural habitats remains challenging, especially at a national scale. Although new open-access variables for vegetation and its environment and increased spatial resolution derived from satellite remote sensing data are available at the global scale, the relevance of these new variables for fine-grained mapping of natural habitats at a national scale remains underexplored. This study aimed to map the fine-grained pattern of four heathland habitats throughout France (550 000 km 2 ). Environmental (bioclimatic, soil and topographic) and spectral (vegetation) variables derived from MODerate resolution Imaging Spectroradiometer, Advanced Spaceborne Thermal Emission and Reflection Radiometer, and Sentinel-2 satellite data were analyzed using the MaxEnt classifier. Open-access field databases were used to calibrate and validate the classification, based on the threshold-independent area under the curve (AUC) index and the conventional F1-score. For each heathland habitat, potential and actual areas were mapped using environmental and spectral variables, respectively. The results showed high classification accuracy for potential (AUC 0.92-0.99) and actual (AUC 0.88-0.99) suitability maps of the four heathland habitats. Visual interpretation of maps of the probability of occurrence indicated that the fine-grained distribution of heathland habitat was detected satisfactorily. However, although the accuracy of the crisp map of combined classifications of actual heathland habitats was high (overall accuracy 0.72), estimated producer's accuracies in terms of proportion of area were low (<0.25). This study provides the first fine-grained pattern maps of heathland habitats at a national scale, thus highlighting the value of combining environmental and spectral variables derived from open-remote sensing data and open-source field databases. These suitability maps could support the identification of heathland habitats in the framework of national conservation policies.

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