Your search keyword '"He, Kate S."' showing total 6 results

1. From local spectral species to global spectral communities: A benchmark for ecosystem diversity estimate by remote sensing

Author

Rocchini, Duccio, Salvatori, Nicole, Beierkuhnlein, Carl, Chiarucci, Alessandro, de Boissieu, Florian, Förster, Michael, Garzon-Lopez, Carol X., Gillespie, Thomas W., Hauffe, Heidi C., He, Kate S., Kleinschmit, Birgit, Lenoir, Jonathan, Malavasi, Marco, Moudrý, Vítĕzslav, Nagendra, Harini, Payne, Davnah, Šímová, Petra, Torresani, Michele, Wegmann, Martin, and Féret, Jean-Baptiste

Subjects

13. Climate action, 15. Life on land, 580 Plants (Botany)

Abstract

In the light of unprecedented change in global biodiversity, real-time and accurate ecosystem and biodiversity assessments are becoming increasingly essential. Nevertheless, estimation of biodiversity using ecological field data can be difficult for several reasons. For instance, for very large areas, it is challenging to collect data that provide reliable information. Some of these restrictions in Earth observation can be avoided through the use of remote sensing approaches. Various studies have estimated biodiversity on the basis of the Spectral Variation Hypothesis (SVH). According to this hypothesis, spectral heterogeneity over the different pixel units of a spatial grid reflects a higher niche heterogeneity, allowing more organisms to coexist. Recently, the spectral species concept has been derived, following the consideration that spectral heterogeneity at a landscape scale corresponds to a combination of subspaces sharing a similar spectral signature. With the use of high resolution remote sensing data, on a local scale, these subspaces can be identified as separate spectral entities, the so called “spectral species”. Our approach extends this concept over wide spatial extents and to a higher level of biological organization. We applied this method to MODIS imagery data across Europe. Obviously, in this case, a spectral species identified by MODIS is not associated to a single plant species in the field but rather to a species assemblage, habitat, or ecosystem. Based on such spectral information, we propose a straightforward method to derive α- (local relative abundance and richness of spectral species) and β-diversity (turnover of spectral species) maps over wide geographical areas.

2. Remotely sensed spatial heterogeneity as an exploratory tool for taxonomic and functional diversity study

Author

Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, Rugani, Benedetto, Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, and Rugani, Benedetto

Abstract

Assessing biodiversity from field-based data is difficult for a number of practical reasons: (i) establishing the total number of sampling units to be investigated and the sampling design (e.g. systematic, random, stratified) can be difficult; (ii) the choice of the sampling design can affect the results; and (iii) defining the focal population of interest can be challenging. Satellite remote sensing is one of the most cost-effective and comprehensive approaches to identify biodiversity hotspots and predict changes in species composition. This is because, in contrast to field-based methods, it allows for complete spatial coverages of the Earth's surface under study over a short period of time. Furthermore, satellite remote sensing provides repeated measures, thus making it possible to study temporal changes in biodiversity. While taxonomic diversity measures have long been established, problems arising from abundance related measures have not been yet disentangled. Moreover, little has been done to account for functional diversity besides taxonomic diversity measures. The aim of this manuscript is to propose robust measures of remotely sensed heterogeneity to perform exploratory analysis for the detection of hotspots of taxonomic and functional diversity of plant species.

3. Remotely sensed spatial heterogeneity as an exploratory tool for taxonomic and functional diversity study

Author

Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, Rugani, Benedetto, Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, and Rugani, Benedetto

Abstract

Assessing biodiversity from field-based data is difficult for a number of practical reasons: (i) establishing the total number of sampling units to be investigated and the sampling design (e.g. systematic, random, stratified) can be difficult; (ii) the choice of the sampling design can affect the results; and (iii) defining the focal population of interest can be challenging. Satellite remote sensing is one of the most cost-effective and comprehensive approaches to identify biodiversity hotspots and predict changes in species composition. This is because, in contrast to field-based methods, it allows for complete spatial coverages of the Earth's surface under study over a short period of time. Furthermore, satellite remote sensing provides repeated measures, thus making it possible to study temporal changes in biodiversity. While taxonomic diversity measures have long been established, problems arising from abundance related measures have not been yet disentangled. Moreover, little has been done to account for functional diversity besides taxonomic diversity measures. The aim of this manuscript is to propose robust measures of remotely sensed heterogeneity to perform exploratory analysis for the detection of hotspots of taxonomic and functional diversity of plant species.

4. Remotely sensed spatial heterogeneity as an exploratory tool for taxonomic and functional diversity study

Author

Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, Rugani, Benedetto, Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, and Rugani, Benedetto

Abstract

Assessing biodiversity from field-based data is difficult for a number of practical reasons: (i) establishing the total number of sampling units to be investigated and the sampling design (e.g. systematic, random, stratified) can be difficult; (ii) the choice of the sampling design can affect the results; and (iii) defining the focal population of interest can be challenging. Satellite remote sensing is one of the most cost-effective and comprehensive approaches to identify biodiversity hotspots and predict changes in species composition. This is because, in contrast to field-based methods, it allows for complete spatial coverages of the Earth's surface under study over a short period of time. Furthermore, satellite remote sensing provides repeated measures, thus making it possible to study temporal changes in biodiversity. While taxonomic diversity measures have long been established, problems arising from abundance related measures have not been yet disentangled. Moreover, little has been done to account for functional diversity besides taxonomic diversity measures. The aim of this manuscript is to propose robust measures of remotely sensed heterogeneity to perform exploratory analysis for the detection of hotspots of taxonomic and functional diversity of plant species.

5. Remotely sensed spatial heterogeneity as an exploratory tool for taxonomic and functional diversity study

Author

Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, Rugani, Benedetto, Rocchini, Duccio, Bacaro, Giovanni, Chirici, Gherado, Da Re, Daniele, Feilhauer, Hannes, Foody, Giles M., Galluzzi, Marta, Garzon-Lopez, Carol X., Gillespie, Thomas W., He, Kate S., Lenoir, Jonathan, Marcantonio, Matteo, Nagendra, Harini, Ricotta, Carlo, Rommel, Edvinas, Schmidtlein, Sebastian, Skidmore, Andrew K., Van de Kerchove, Ruben, Wegmann, Martin, and Rugani, Benedetto

Abstract

Assessing biodiversity from field-based data is difficult for a number of practical reasons: (i) establishing the total number of sampling units to be investigated and the sampling design (e.g. systematic, random, stratified) can be difficult; (ii) the choice of the sampling design can affect the results; and (iii) defining the focal population of interest can be challenging. Satellite remote sensing is one of the most cost-effective and comprehensive approaches to identify biodiversity hotspots and predict changes in species composition. This is because, in contrast to field-based methods, it allows for complete spatial coverages of the Earth's surface under study over a short period of time. Furthermore, satellite remote sensing provides repeated measures, thus making it possible to study temporal changes in biodiversity. While taxonomic diversity measures have long been established, problems arising from abundance related measures have not been yet disentangled. Moreover, little has been done to account for functional diversity besides taxonomic diversity measures. The aim of this manuscript is to propose robust measures of remotely sensed heterogeneity to perform exploratory analysis for the detection of hotspots of taxonomic and functional diversity of plant species.

6. Anticipating species distributions: Handling sampling effort bias under a Bayesian framework.

Author

Rocchini D, Garzon-Lopez CX, Marcantonio M, Amici V, Bacaro G, Bastin L, Brummitt N, Chiarucci A, Foody GM, Hauffe HC, He KS, Ricotta C, Rizzoli A, and Rosà R

Abstract

Anticipating species distributions in space and time is necessary for effective biodiversity conservation and for prioritising management interventions. This is especially true when considering invasive species. In such a case, anticipating their spread is important to effectively plan management actions. However, considering uncertainty in the output of species distribution models is critical for correctly interpreting results and avoiding inappropriate decision-making. In particular, when dealing with species inventories, the bias resulting from sampling effort may lead to an over- or under-estimation of the local density of occurrences of a species. In this paper we propose an innovative method to i) map sampling effort bias using cartogram models and ii) explicitly consider such uncertainty in the modeling procedure under a Bayesian framework, which allows the integration of multilevel input data with prior information to improve the anticipation species distributions., (Copyright © 2016. Published by Elsevier B.V.)

Published

2017