Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing

Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing

The decline of biodiversity is one of the major current global issues. Still, there is a widespread lack of information about the spatial distribution of individual species and biodiversity as a whole. Remote sensing techniques are increasingly used for biodiversity monitoring and especially the com...

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Main Authors: Martin Wegmann, Stefan Dech, Jörg Müller, Carl Beierkuhnlein, Martin Bachmann, Björn Reineking, Benjamin F. Leutner
Format: Article
Language:English
Published: MDPI AG 2012-09-01
Series:Remote Sensing
Subjects:
minimum noise fraction transformation
Boruta feature selection
Shannon index
NMDS
full-waveform LiDAR
HyMap
herb layer
shrub layer
tree layer
Online Access:http://www.mdpi.com/2072-4292/4/9/2818
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spelling doaj-6ac57582bd2745e58832e5730d0067ad2020-11-25T00:02:30ZengMDPI AGRemote Sensing2072-42922012-09-01492818284510.3390/rs4092818Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote SensingMartin WegmannStefan DechJörg MüllerCarl BeierkuhnleinMartin BachmannBjörn ReinekingBenjamin F. LeutnerThe decline of biodiversity is one of the major current global issues. Still, there is a widespread lack of information about the spatial distribution of individual species and biodiversity as a whole. Remote sensing techniques are increasingly used for biodiversity monitoring and especially the combination of LiDAR and hyperspectral data is expected to deliver valuable information. In this study spatial patterns of vascular plant community composition and alpha-diversity of a temperate montane forest in Germany were analysed for different forest strata. The predictive power of LiDAR (LiD) and hyperspectral (MNF) datasets alone and combined (MNF+LiD) was compared using random forest regression in a ten-fold cross-validation scheme that included feature selection and model tuning. The final models were used for spatial predictions. Species richness could be predicted with varying accuracy (R2 = 0.26 to 0.55) depending on the forest layer. In contrast, community composition of the different layers, obtained by multivariate ordination, could in part be modelled with high accuracies for the first ordination axis (R2 = 0.39 to 0.78), but poor accuracies for the second axis (R2 ≤ 0.3). LiDAR variables were the best predictors for total species richness across all forest layers (R2 LiD = 0.3, R2 MNF = 0.08, R2 MNF+LiD = 0.2), while for community composition across all forest layers both hyperspectral and LiDAR predictors achieved similar performances (R2 LiD = 0.75, R2 MNF = 0.76, R2 MNF+LiD = 0.78). The improvement in R2 was small (≤0.07)—if any—when using both LiDAR and hyperspectral data as compared to using only the best single predictor set. This study shows the high potential of LiDAR and hyperspectral data for plant biodiversity modelling, but also calls for a critical evaluation of the added value of combining both with respect to acquisition costs.http://www.mdpi.com/2072-4292/4/9/2818minimum noise fraction transformationBoruta feature selectionShannon indexNMDSfull-waveform LiDARHyMapherb layershrub layertree layer
collection DOAJ
language English
format Article
sources DOAJ
author Martin Wegmann
Stefan Dech
Jörg Müller
Carl Beierkuhnlein
Martin Bachmann
Björn Reineking
Benjamin F. Leutner
spellingShingle Martin Wegmann
Stefan Dech
Jörg Müller
Carl Beierkuhnlein
Martin Bachmann
Björn Reineking
Benjamin F. Leutner
Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing
Remote Sensing
minimum noise fraction transformation
Boruta feature selection
Shannon index
NMDS
full-waveform LiDAR
HyMap
herb layer
shrub layer
tree layer
author_facet Martin Wegmann
Stefan Dech
Jörg Müller
Carl Beierkuhnlein
Martin Bachmann
Björn Reineking
Benjamin F. Leutner
author_sort Martin Wegmann
title Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing
title_short Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing
title_full Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing
title_fullStr Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing
title_full_unstemmed Modelling Forest α-Diversity and Floristic Composition — On the Added Value of LiDAR plus Hyperspectral Remote Sensing
title_sort modelling forest α-diversity and floristic composition — on the added value of lidar plus hyperspectral remote sensing
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2012-09-01
description The decline of biodiversity is one of the major current global issues. Still, there is a widespread lack of information about the spatial distribution of individual species and biodiversity as a whole. Remote sensing techniques are increasingly used for biodiversity monitoring and especially the combination of LiDAR and hyperspectral data is expected to deliver valuable information. In this study spatial patterns of vascular plant community composition and alpha-diversity of a temperate montane forest in Germany were analysed for different forest strata. The predictive power of LiDAR (LiD) and hyperspectral (MNF) datasets alone and combined (MNF+LiD) was compared using random forest regression in a ten-fold cross-validation scheme that included feature selection and model tuning. The final models were used for spatial predictions. Species richness could be predicted with varying accuracy (R2 = 0.26 to 0.55) depending on the forest layer. In contrast, community composition of the different layers, obtained by multivariate ordination, could in part be modelled with high accuracies for the first ordination axis (R2 = 0.39 to 0.78), but poor accuracies for the second axis (R2 ≤ 0.3). LiDAR variables were the best predictors for total species richness across all forest layers (R2 LiD = 0.3, R2 MNF = 0.08, R2 MNF+LiD = 0.2), while for community composition across all forest layers both hyperspectral and LiDAR predictors achieved similar performances (R2 LiD = 0.75, R2 MNF = 0.76, R2 MNF+LiD = 0.78). The improvement in R2 was small (≤0.07)—if any—when using both LiDAR and hyperspectral data as compared to using only the best single predictor set. This study shows the high potential of LiDAR and hyperspectral data for plant biodiversity modelling, but also calls for a critical evaluation of the added value of combining both with respect to acquisition costs.
topic minimum noise fraction transformation
Boruta feature selection
Shannon index
NMDS
full-waveform LiDAR
HyMap
herb layer
shrub layer
tree layer
url http://www.mdpi.com/2072-4292/4/9/2818
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