Vegetation canopy height estimation in dynamic tropical landscapes with TanDEM‐X supported by GEDI data

Schlund, Michael; Wenzel, Arne; Camarretta, Nicolò; Stiegler, Christian; Erasmi, Stefan

doi:10.1111/2041-210x.13933

Cited by 9 publications

(7 citation statements)

References 64 publications

(261 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…GEDI provides dense and well distributed lidar waveform measurements across Earths tropical and temperate forests and defines an ideal framework to explore the synergetic use of waveform lidar and interferometric X-band SAR measurements at local to global scales. Indeed, the synergies between TanDEM-X and waveform lidar data [34] have been confirmed by a number of studies using the TanDEM-X / GEDI framework [30][31], [37][38].…”

Section: Introductionmentioning

confidence: 73%

Large-Scale Forest Height Mapping by Combining TanDEM-X and GEDI Data

Choi

Cazcarra-Bes²,

Guliaev

et al. 2023

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

View full text Add to dashboard Cite

The present study addresses the development, implementation and validation of a forest height mapping scheme based on the combination of TanDEM-X interferometric coherence and GEDI waveform measurements. The very general case where only a single polarisation TanDEM-X interferogram, a set of spatially discrete GEDI waveform measurements and no DTM are available is assumed. The use of GEDI waveforms to invert the TanDEM-X interferometric measurements is described together with a set of performance criteria implemented to ensure a certain performance quality. The emphasis is set on developing a methodology able to invert forest height at large scales. Combining 595 TanDEM-X scenes and about 15 million GEDI waveforms, a spatially continuous 25 m resolution forest height map covering the whole of Tasmania Island is achieved. The derived forest height map is validated against an airborne lidarderived canopy height map available across the whole island.

show abstract

Section: Introductionmentioning

confidence: 73%

Large-Scale Forest Height Mapping by Combining TanDEM-X and GEDI Data

Choi

Cazcarra-Bes²,

Guliaev

et al. 2023

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

View full text Add to dashboard Cite

show abstract

“…Spaceborne RADAR data offer a complementary source of data, particularly across the tropics. Schlund et al (2022) suggested an approach to combine GEDI data with TanDEM‐X polarimetric SAR data via a semi‐empirical model for canopy height estimations over tropical forests and then validated the results with airborne LiDAR data. A higher and denser vegetation cover was shown to result in larger errors in the estimation of canopy height by the applied linear models.…”

Section: Thematic Groups Being Covered In the Sfmentioning

confidence: 99%

“…1. Stand-, canopy-and tree-level structural analysis by active RS data (Atkins et al, 2023;Blanchard et al, 2023;Coverdale & Davies, 2023;Hardenbol et al, 2022;Schlund et al, 2022;Singh et al, 2023;Tatsumi et al, 2022;Zhang & Liu, 2023).…”

Section: G Ener Al and S Pecific Trendsmentioning

confidence: 99%

“…Of the accepted papers, four are published in Journal of Animal Ecology , two in Journal of Applied Ecology , four in Journal of Ecology and eight in Methods in Ecology and Evolution . When assessing the general trends being covered by the contributions, a few general (and partly overlapping) trends can be distinguished, including: Stand‐, canopy‐ and tree‐level structural analysis by active RS data (Atkins et al, 2023; Blanchard et al, 2023; Boucher et al, 2023; Coverdale & Davies, 2023; Hardenbol et al, 2022; Schlund et al, 2022; Singh et al, 2023; Tatsumi et al, 2022; Zhang & Liu, 2023). Climate‐mediated response of animal populations (from insects to ungulates) as investigated by active RS data (Brlík et al, 2022; Hockridge et al, 2022).…”

Section: General and Specific Trendsmentioning

confidence: 99%

“…photon-counting, large footprint and transect pattern for data acquisition has offered precious sources of 3D information, though often insufficient for spatially explicit and consistent estimates or upscaling over large areas. Spaceborne RADAR data offer a complementary source of data, particularly across the tropics Schlund et al (2022). suggested an approach to combine GEDI data with TanDEM-X polarimetric SAR data via a semi-empirical model for canopy height estimations over tropical forests and then validated the results with airborne LiDAR data.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Towards complex applications of active remote sensing for ecology and conservation

2023

View full text Add to dashboard Cite

Remote sensing (RS) and geospatial sciences already amount to a long history of fostering research in topics related to ecology. Data and methods have mainly been subject to research and experiments, but trends are now emerging that suggest the use of RS in practical applications like nationwide monitoring programs and assisting global conservation goals. However, use of active remote sensing for ecological and conservation is in its infancy, and the implications of active sensor data, including light detection and ranging and radio detection and ranging that mostly deliver three‐dimensional (3D) information, are still relatively primitive and have largely been limited to indirect use of their extracted proxies for ecological modelling. This cross‐journal special feature between Methods in Ecology and Evolution, Journal of Animal Ecology, Journal of Applied Ecology and Journal of Ecology includes 18 papers that include full research papers, reviews and technical applications. They are mostly novel in either or both their interpretation of proxies derived from active RS data and the direct usage of 3D RS techniques (terrestrial, airborne, UAV borne and spaceborne) to address ecological topics. We categorized the published contributions into the following thematic groups, with some degree of overlap: (i) ecosystem structural analysis by active data (nine studies); (ii) response of animal populations to climate dynamics as shown by active data; (iii) interactive effects of forest structure and wildlife monitoring (five studies); (iv) forest inventories assisted by active data (one study) and (v) tree type classification by active data (one study). Synthesis. The studies in this Special Feature and trends shown by other recent works at the interface of ecology and active RS confirm the ongoing shift from indirect and solely proxy‐based approaches to direct and more data‐science driven methods in approaching ecology and conservation problems by means of active sensors. Relatively affordable and accessible drone and citizen science‐based on‐demand active RS data acquisition are becoming common practice, and the future of sensor development is hypothesized to go beyond the current domination of very high spatial resolution data and towards multiple spaceborne platforms. These tools and methods will support spatial upscaling, uncertainty analysis, large‐scale mapping and monitoring of wildlife dynamics, among other topics that can take advantage of multitemporal/time series data. Nevertheless, access to demanding and costly very high‐resolution data sources may still be maintained and optimized by establishing international and public–private partnered data pools.

show abstract