New approaches for delineating <i>n</i>‐dimensional hypervolumes

Blonder, Benjamin; Morrow, Cecina Babich; Maitner, Brian S.; Harris, David J.; Lamanna, Christine; Violle, Cyrille; Enquist, Brian J.; Kerkhoff, Andrew J.

doi:10.1111/2041-210x.12865

Cited by 232 publications

(342 citation statements)

References 48 publications

(91 reference statements)

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“…We can use hypervolume concepts to analyse patterns of overlap between sets of point data in multidimensional space (e.g. Blonder et al, ). Current hypervolume approaches first map each observation in an n ‐dimensional space, where the dimensions are the chosen variables.…”

Section: Introductionmentioning

confidence: 99%

“…MaxEnt; Phillips, Anderson, & Schapire, ); to classify points in ecological space as ‘in’ or ‘out’ of the modelled niche (e.g. hypervolume_exclusion_test; Blonder et al, ); or to define the boundary of the niche in n‐dimensional space (e.g. hypervolume_svm; Blonder et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…hypervolume_exclusion_test; Blonder et al, ); or to define the boundary of the niche in n‐dimensional space (e.g. hypervolume_svm; Blonder et al, ). Once described by an appropriate model, two hypervolumes may be compared and the volumes of the overlapping and unique regions can be measured (see hypervolume_set, hypervolume_overlap_statistics functions; Blonder et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…Because many biological variables are strongly correlated, this method is limited in the variables that can be analysed. Blonder's hypervolume package (Blonder, Lamanna, Violle, & Enquist, ; Blonder et al, ) includes a range of functions for hypervolume modelling and comparison. In both hypervolume and hyperoverlap the shape of the hypervolume is not defined by a priori expectations, so we have used hypervolume as a standard to evaluate the performance of hyperoverlap .…”

Section: Introductionmentioning

confidence: 99%

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hyperoverlap: Detecting biological overlap in n‐dimensional space

2020

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Comparative biological studies often investigate the morphological, physiological or ecological divergence (or overlap) between entities such as species or populations. Here we discuss the weaknesses of using existing methods to analyse patterns of phenotypic overlap and present a novel method to analyse co‐occurrence in multidimensional space. We propose a ‘hyperoverlap’ framework to detect qualitative overlap (or divergence) between point datasets and present the hyperoverlap r package which implements this framework, including functions for visualization. hyperoverlap uses support vector machines (SVMs) to train a classifier based on point data (such as morphological or ecological data) for two entities. This classifier finds the optimal boundary between the two sets of data and compares the predictions to the original labels. Misclassification is an evidence of overlap between the two entities. We demonstrate the theoretical and practical advantages of this method compared to existing approaches (e.g. single‐entity hypervolume models) using the bioclimatic data extracted from global occurrence records of conifers. We find that there are instances where single‐entity hypervolume models predict overlap, but there are no observations of either entity in the shared hypervolume. In these instances, hyperoverlap reports nonoverlap. We show that our method is stable and less likely to be affected by sampling biases than current approaches. We also find that hyperoverlap is particularly effective for situations involving entities with a small number of data points (e.g. narrowly endemic species) for which single‐entity models cannot be reliably constructed. We argue that overlap can be reliably detected using hyperoverlap, particularly for descriptive studies. The method proposed here is a valuable tool for studying patterns of overlap in a multidimensional space.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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hyperoverlap: Detecting biological overlap in n‐dimensional space

2020

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“…Accounting for data structure is possible in non‐parametric approaches by incorporating a weighting structure (Breunig , Blonder et al. ) so that observations do not all contribute equally to the calculated hypervolume. We aim to demonstrate that multidimensional parametric approaches can be generalized to account for complex data structures in an analogous way to incorporating data structure into univariate models.…”

Section: Introductionmentioning

confidence: 99%

Model‐based hypervolumes for complex ecological data

Jarvis

Henrys

Keith

et al. 2019

Ecology

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Developing a holistic understanding of the ecosystem impacts of global change requires methods that can quantify the interactions among multiple response variables. One approach is to generate high dimensional spaces, or hypervolumes, to answer ecological questions in a multivariate context. A range of statistical methods has been applied to construct hypervolumes but have not yet been applied in the context of ecological data sets with spatial or temporal structure, for example, where the data are nested or demonstrate temporal autocorrelation. We outline an approach to account for data structure in quantifying hypervolumes based on the multivariate normal distribution by including random effects. Using simulated data, we show that failing to account for structure in data can lead to biased estimates of hypervolume properties in certain contexts. We then illustrate the utility of these “model‐based hypervolumes” in providing new insights into a case study of afforestation effects on ecosystem properties where the data has a nested structure. We demonstrate that the model‐based generalization allows hypervolumes to be applied to a wide range of ecological data sets and questions.

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What makes a weed a weed? A large‐scale evaluation of arable weeds through a functional lens

Bourgeois

Munoz

Fried

et al. 2019

American J of Botany

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Premise of the Study Despite long‐term research efforts, a comprehensive perspective on the ecological and functional properties determining plant weediness is still lacking. We investigated here key functional attributes of arable weeds compared to non‐weed plants, at large spatial scale. Methods We used an intensive survey of plant communities in cultivated and non‐cultivated habitats to define a pool of plants occurring in arable fields (weeds) and one of plants occurring only in open non‐arable habitats (non‐weeds) in France. We compared the two pools based on nine functional traits and three functional spaces (LHS, reproductive and resource requirement hypervolumes). Within the weed pool, we quantified the trait variation of weeds along a continuum of specialization to arable fields. Key Results Weeds were mostly therophytes and had higher specific leaf area, earlier and longer flowering, and higher affinity for nutrient‐rich, sunny and dry environments compared to non‐weeds, although functional spaces of weeds and non‐weeds largely overlapped. When fidelity to arable fields increased, the spectrum of weed ecological strategies decreased as did the overlap with non‐weeds, especially for the resource requirement hypervolume. Conclusions Arable weeds constitute a delimited pool defined by a trait syndrome providing tolerance to the ecological filters of arable fields (notably, regular soil disturbances and fertilization). The identification of such a syndrome is of great interest to predict the weedy potential of newly established alien plants. An important reservoir of plants may also become weeds after changes in agricultural practices, considering the large overlap between weeds and non‐weeds.

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New approaches for delineating n‐dimensional hypervolumes

Cited by 232 publications

References 48 publications

hyperoverlap: Detecting biological overlap in n‐dimensional space

hyperoverlap: Detecting biological overlap in n‐dimensional space

Model‐based hypervolumes for complex ecological data

What makes a weed a weed? A large‐scale evaluation of arable weeds through a functional lens

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