UAS Imagery-Based Mapping of Coarse Wood Debris in a Natural Deciduous Forest in Central Germany (Hainich National Park)

Thiel, Christian; Mueller, Marlin M.; Epple, Lea; Thau, Christian; Hese, S.; Voltersen, M.; Henkel, Andreas

doi:10.3390/rs12203293

Cited by 13 publications

(16 citation statements)

References 52 publications

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“…A total of 4215 images, covering an area of 1.16 km 2 , were collected via parallel flights on five days during January 2019, resulting in a ground resolution of 1.63 cm per pixel. The images were processed with the software Agisoft Metashape Professional 1.5 (Agisoft, 2019a ) to reconstruct 3D-information from 2D-images (Kabiri et al, 2020 ; Kienholz et al, 2020 ; Thiel et al, 2020 ). This resulted in a digital surface model (DSM), a digital terrain model (DTM), and consequently in a normalized digital surface model (nDSM), showing the height of any object on the ground (for more detailed information see SI 1 and Fig.…”

Section: Methodsmentioning

confidence: 99%

Using an unmanned aerial system to analyse environmental impacts of charcoal production on tropical savanna ecosystems in northwestern Kenya

Petersen

Nüsser

2022

Environ Monit Assess

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In many regions of Sub-Saharan Africa, charcoal plays an important role as energy source but is widely perceived as a major driver of deforestation and forest degradation. This narrative, however, is mostly based on research within primary production regions. Though space-borne remote sensing applications can be useful in monitoring such large-scale production modes, environmental effects of household-level production are less easy to assess. Therefore, the present study employs an unmanned aerial system (UAS) to assess the impact of small-scale charcoal production on the vegetation density in the immediate vicinity of production sites. The UAS data was complemented by field measurements and very high-resolution WordView-2 satellite imagery. This approach revealed only small differences between charcoal production sites and reference plots which were usually evened out after 20–25-m distance to the plot centre using a concentric ring analysis. Results further show that a distinction between different land-use practices is difficult, even with the high spatial resolution provided by a UAS. Thus, more research and new approaches are needed to evaluate the role of small-scale charcoal production in deforestation and forest degradation processes against the background of other human activities. However, to exploit the full potential of UAS for monitoring environmental effects in charcoal producing areas, official regulations need to be clearer and more reliable.

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Section: Methodsmentioning

confidence: 99%

Using an unmanned aerial system to analyse environmental impacts of charcoal production on tropical savanna ecosystems in northwestern Kenya

Petersen

Nüsser

2022

Environ Monit Assess

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“…From an application standpoint, the two approaches conceptually most similar to ours use the Hough transform to fit lines representing individual stems in binarized images of target class posterior probabilities obtained on the basis of hand-crafted textural features (Duan et al, 2017) or spectral thresholding (Panagiotidis et al, 2019). Thiel et al (2020) performed generic line detection within RGB orthomosaics derived from very-high resolution unmanned aerial system-acquired imagery to find approximate fallen stem shapes.Lopes Queiroz et al ( 2019) used a generic segmentation procedure on the spectral bands of the aerial image combined with the normalized difference vegetation index (Tucker, 1979), and subsequently classified the resulting clusters based on spectral/textural features augmented with LiDAR derived information (canopy height model). Einzmann et al (2017) applied a similar approach, using large-scale mean shift in the role of the segmentation algorithm and augmenting the set of spectral bands with linear transformations of raw bands, textural features and multiple vegetation indices.…”

Section: Related Workmentioning

confidence: 99%

Instance segmentation of fallen trees in aerial color infrared imagery using active multi-contour evolution with fully convolutional network-based intensity priors

Polewski

Shelton

Yao

et al. 2021

ISPRS Journal of Photogrammetry and Remote Sensing

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“…Santos et al (2019) made a comparison of three different deep learning frameworks, namely YOLOv3, Faster Region Based Convolutional Neural Networks (Faster R-CNN), and RetinaNet to assess a time series of RGB images in the context of tree crown detection achieving an overall average precision (AP) of 92%. Other studies have used object-based image analysis approach to detect coarse wood debris (CWD) from unmanned aerial systems in conjunction with LiDAR point clouds (Thiel et al, 2020). The authors reported an overall average precision (mAP) of 85% and a recall of 69.2%.…”

Section: Introductionmentioning

confidence: 99%

Detection of Degraded Acacia Tree Species Using Deep Neural Networks on Uav Drone Imagery

Osio

Le²,

Ayugi³

et al. 2022

ISPRS Ann. Photogramm. Remote Sens. Spatial Inf. Sci.

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Abstract. Deep-learning-based image classification and object detection has been applied successfully to tree monitoring. However, studies of tree crowns and fallen trees, especially on flood inundated areas, remain largely unexplored. Detection of degraded tree trunks on natural environments such as water, mudflats, and natural vegetated areas is challenging due to the mixed colour image backgrounds. In this paper, Unmanned Aerial Vehicles (UAVs), or drones, with embedded RGB cameras were used to capture the fallen Acacia Xanthophloea trees from six designated plots around Lake Nakuru, Kenya. Motivated by the need to detect fallen trees around the lake, two well-established deep neural networks, i.e. Faster Region-based Convolution Neural Network (Faster R-CNN) and Retina-Net were used for fallen tree detection. A total of 7,590 annotations of three classes on 256×256 image patches were used for this study. Experimental results show the relevance of deep learning in this context, with Retina-Net model achieving 38.9% precision and 57.9% recall.

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UAS Imagery-Based Mapping of Coarse Wood Debris in a Natural Deciduous Forest in Central Germany (Hainich National Park)

Cited by 13 publications

References 52 publications

Using an unmanned aerial system to analyse environmental impacts of charcoal production on tropical savanna ecosystems in northwestern Kenya

Using an unmanned aerial system to analyse environmental impacts of charcoal production on tropical savanna ecosystems in northwestern Kenya

Instance segmentation of fallen trees in aerial color infrared imagery using active multi-contour evolution with fully convolutional network-based intensity priors

Detection of Degraded Acacia Tree Species Using Deep Neural Networks on Uav Drone Imagery

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