Extracting Ground-Level DEM From SRTM DEM in Forest Environments Based on Mathematical Morphology

Liu, Jung-kuan; Liu, Desheng; Alsdorf, Douglas

doi:10.1109/tgrs.2013.2296232

Cited by 14 publications

(8 citation statements)

References 23 publications

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“…Similar to urban-like vegetation, the ability to compare both DTMs to the outcome quality of other studies is limited because few studies deal with DTM filtering in dense forested areas using mathematical morphology and low-resolution raster data. Liu et al [53] used a sequence of morphological operators combined with segmentation to derive a DTM using SRTM data for two forest areas. The authors were able to reduce the RMSE from 23.58 m to 12.59 m and 14.32 m to 7.55 m, respectively, using the outcome compared to a national elevation dataset (NED).…”

Section: Discussionmentioning

confidence: 99%

TanDEM-X for Large-Area Modeling of Urban Vegetation Height: Evidence from Berlin, Germany

Schreyer

Geis

Lakes

2016

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

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Large-area urban ecology studies often miss information on vertical parameters of vegetation, even though they represent important constituting properties of complex urban ecosystems. The new globally available digital elevation model (DEM) of the spaceborne TanDEM-X mission has an unprecedented spatial resolution (12 × 12 m) that allows us to derive such relevant information. So far, suitable approaches using a TanDEM-X DEM for the derivation of a normalized canopy model (nCM) are largely absent. Therefore, this paper aims to obtain digital terrain models (DTMs) for the subsequent computation of two nCMs for urban-like vegetation (e.g., street trees) and forest-like vegetation (e.g., parks), respectively, in Berlin, Germany, using a TanDEM-X DEM and a vegetation mask derived from UltraCam-X data. Initial comparisons between morphological DTM-filter confirm the superior performance of a novel disaggregated progressive morphological filter (DPMF). For improved assessment of a DTM for urban-like vegetation, a modified DPMF and image enhancement methods were applied. For forest-like vegetation, an interpolation and a weighted DPMF approach were compared. Finally, all DTMs were used for nCM calculation. The nCM for urban-like vegetation revealed a mean height of 4.17 m compared to 9.61 m of a validation nCM. For forest-like vegetation, the mean height for the nCM of the weighted filtering approach (9.16 m) produced the best results (validation nCM: 13.55 m). It is concluded that an nCM from TanDEM-X can capture vegetation heights in their appropriate dimension, which can be beneficial for automated height-related vegetation analysis such as comparisons of vegetation carbon storage between several cities. Index Terms-Digital elevation model (DEM), digital terrain model (DTM), morphological filters (MFs), normalized digital surface model (nDSM), Tandem-X, trees, UltraCamX, urban vegetation. I. INTRODUCTION U RBAN vegetation is known to positively regulate urban ecological processes through air purification, noise reduction, urban cooling, and runoff mitigation, as well as to provide aesthetic and environmental benefits that are commonly characterized as urban ecosystem services [1]. In recent Manuscript

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Section: Discussionmentioning

confidence: 99%

TanDEM-X for Large-Area Modeling of Urban Vegetation Height: Evidence from Berlin, Germany

Schreyer

Geis

Lakes

2016

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

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“…The elevation was computed based on the third version of the Shuttle Radar Topography Mission (SRTM in m) provided by NASA JPL with a spatial resolution of 30 m (Farr et al 2007; Liu et al 2014). The SRTM mission occurred in February 2000 and collected data during ten days of operations.…”

Section: Methodsmentioning

confidence: 99%

Forest structure and degradation drive canopy gap sizes across the Brazilian Amazon

Reis

Jackson

et al. 2021

Preprint

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Canopy gaps are openings in the forest canopy resulting from branch fall and tree mortality events. Light reaches the lower layers of the canopy through these gaps, enabling understory trees to grow and maintaining the high heterogeneity and biodiversity of tropical forests. The size-frequency distribution of canopy gaps follows a power-law distribution, and the slope of this power-law (α) is a key indicator of forest structure and dynamics.We detected canopy gaps using a unique LiDAR data set consisting of 650 transects randomly distributed across the Brazilian Amazon Forest providing an unprecedented perspective on forest structural variation over 2500 km2 of forest. We then investigated how α varied with forest structure, elevation, soil fertility, water deficit, wind gust speed and lightning intensity.We found that human modified forests had more large gaps than intact forests. Within the intact forests we observed a large-scale Northwest to Southeast pattern in α (more large gaps in the Southeast), which aligns with recent work on tree mortality rates. The two most important variables in predicting α were median canopy height and maximum modeled height, which had opposite effects on the number of large gaps. Forests with higher median canopy height contain fewer large gaps but the presence of very tall trees was associated with more large gaps. Environmental variables were of secondary importance in our model, with larger gaps occurring in drier forests with high soil fertility, wind speed, and lightning intensity.The distribution of large gaps in the forest canopy varies substantially over the Brazilian Amazon as a result of canopy structure and mortality rates. We mapped this variation and found more large gaps in human modified forests, forests on fertile soils and those exposed to higher wind, lightning and drought stress. Increasing extreme weather events due to climate change may therefore increase the number of large gaps in currently intact forests, causing them to resemble human modified forests.

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“…The elevation was based on the third version of the Shuttle Radar Topography Mission (SRTM) provided by the National Aeronautics and Space Administration Jet Propulsion Laboratory (NASA JPL) (Farr et al., 2007; Liu et al., 2014). The SRTM mission collected data during 10 days of operations, using two synthetic aperture radars: NASA’s C‐band system (5.6 cm wavelength) and an X band system supplied by DLR (3.1 cm).…”

Section: Methodsmentioning

confidence: 99%

Resource availability and disturbance shape maximum tree height across the Amazon

Görgens

Nunes

Jackson

et al. 2020

Global Change Biology

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Tall trees are key drivers of ecosystem processes in tropical forest, but the controls on the distribution of the very tallest trees remain poorly understood. The recent discovery of grove of giant trees over 80 meters tall in the Amazon forest requires a reevaluation of current thinking. We used high-resolution airborne laser surveys to measure canopy height across 282,750 ha of old-growth and second-growth forests randomly sampling the entire Brazilian Amazon. We investigated how resources and disturbances shape the maximum height distribution across the Brazilian Amazon through the relations between the occurrence of giant trees and environmental factors. Common drivers of height development are fundamentally different from those influencing the occurrence of giant trees. We found that changes in wind and light availability drive giant tree distribution as much as precipitation and temperature, together shaping the forest structure of the Brazilian Amazon. The location of giant trees should be carefully considered by policymakers when identifying important hot spots for the conservation of biodiversity in the Amazon.

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Extracting Ground-Level DEM From SRTM DEM in Forest Environments Based on Mathematical Morphology

Cited by 14 publications

References 23 publications

TanDEM-X for Large-Area Modeling of Urban Vegetation Height: Evidence from Berlin, Germany

TanDEM-X for Large-Area Modeling of Urban Vegetation Height: Evidence from Berlin, Germany

Forest structure and degradation drive canopy gap sizes across the Brazilian Amazon

Resource availability and disturbance shape maximum tree height across the Amazon

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