2007
DOI: 10.1071/wf06003
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Estimation of shrub height for fuel-type mapping combining airborne LiDAR and simultaneous color infrared ortho imaging

Abstract: A fuel-type map of a predominantly shrub-land area in central Portugal was generated for a fire research experimental site, by combining airborne light detection and ranging (LiDAR), and simultaneous color infrared ortho imaging. Since the vegetation canopy and the ground are too close together to be easily discerned by LiDAR pulses, standard methods of processing LiDAR data did not provide an accurate estimate of shrub height. It was demonstrated that the standard process to generate the digital ground model … Show more

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Cited by 103 publications
(84 citation statements)
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“…However, with the onset of full waveform recording and later radiometric calibration, it was proven that vegetation classification relying only on LIDAR data is possible [65]. LIDAR was first used for such purposes in forests, where vegetation height and canopy structure are more diverse [66], but applications in shrublands [67,68] and wetlands were also successful [69][70][71][72]. LIDAR is increasingly used for mapping conservation relevant variables, including coverage of different species or associations for biodiversity assessment [73,74], but also human activities or natural environmental variables relevant for habitat quality [46].…”
Section: Lidar For Ecological Mappingmentioning
confidence: 99%
“…However, with the onset of full waveform recording and later radiometric calibration, it was proven that vegetation classification relying only on LIDAR data is possible [65]. LIDAR was first used for such purposes in forests, where vegetation height and canopy structure are more diverse [66], but applications in shrublands [67,68] and wetlands were also successful [69][70][71][72]. LIDAR is increasingly used for mapping conservation relevant variables, including coverage of different species or associations for biodiversity assessment [73,74], but also human activities or natural environmental variables relevant for habitat quality [46].…”
Section: Lidar For Ecological Mappingmentioning
confidence: 99%
“…The AMS3D assigns every plant crown to a forest layer, namely ground vegetation, understory and overstory (green, red and randomly-colored ellipsoids). Therefore, the individual crown map shown in Figure 2b readily provides single layer forest metrics: tree density (number of ellipsoids within the forest plot normalized by its area), tree height (z coordinate of the highest lidar point assigned to a given 3D cluster), individual crown length (distance between the tree height and the lowest lidar point of the 3D cluster) and the forest layers mean height (the 50th height percentile of the lidar points assigned to juvenile overstory and understory and the 90th height percentile regarding the ground vegetation [22]). According to Ferraz et al [15], the cc is computed for single layers using the lidar returns assigned to juvenile overstory, understory and ground vegetation.…”
Section: Forest Metrics Extractionmentioning
confidence: 99%
“…ALS mapping of vegetation structure is operational in forests [37][38][39], rapidly developing in shrublands [40][41][42][43][44] but applications to riparian vegetation types remain rare [45,46] …”
Section: Passive Remote Sensing Of Wetland Vegetationmentioning
confidence: 99%