A high‐resolution approach for the spatiotemporal analysis of forest canopy space using terrestrial laser scanning data

Hess, Carsten; Härdtle, Werner; Kunz, Matthias; Fichtner, Andreas; Oheimb, Goddert von

doi:10.1002/ece3.4193

Cited by 23 publications

(15 citation statements)

References 47 publications

(68 reference statements)

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“…size, shape and orientation) of the individuals of the community are available. Measuring these variables in a fully mapped community could appear as a challenge but the ever-growing development of remote sensing technologies such as LIDAR and digital photogrammetry (Lefsky, Cohen, Parker, & Harding, 2002;Morsdorf et al, 2004;Paris, Kelbe, van Aardt, & Bruzzone, 2017) or terrestrial laser scanning (Hess, Härdtle, Kunz, Fichtner, & von Oheimb, 2018) that enable to map the species canopy would render this a routine task in the near future. In addition, although a high number of simulations has been suggested to be necessary to get reliable inference in Monte Carlo tests (Ruxton & Neuhäuser, 2013), our OAA test could attain enough statistical power in most situations with just 199 simulations.…”

Section: Discussionmentioning

confidence: 99%

The shape is more important than we ever thought: Plant to plant interactions in a high mountain community

et al. 2019

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Plant to plant interactions are probably the most important driver of species coexistence at fine spatial scales, but their detection represents a challenge in Ecology. Spatial point pattern analysis (SPPA) is likely the approach most used to identify them, however, it suffers from some limitations related to the over‐simplification of individuals to points. Here, we propose a new approach called Overlapping Area Analysis (OAA) to test whether the consideration of the shape and orientation of the individuals reveal signs of interactions between species that would remain undetected with SPPA. We used this approach to analyse a fully mapped cryophilic grassland in the Sierra de Guadarrama National Park (Spain), where the crown of each individual plant (i.e. the species canopy) was approximated by a polygon. We then computed and compared the total overlapping area between the canopy of a focal species and that of any other species in the community with the expectations of a null model of random rotation of each plant around its centroid. We complemented the results of our new approach by comparing with that of SPPA of plants’ centroids. Results of OAA showed that up to 41% of species pairs had less canopy overlap than expected, suggesting that many interspecific canopy associations in this plant community were significantly negative at the finest spatial scale. Contrarily, SPPA estimated that 12% of species pairs were positively associated at spatial scales up to 20 cm, confirming the facilitative effect displayed by the main engineer in the community (Festuca curvifolia Lag.) and by some other dominant species. Our new approach quantifying canopy associations provides new insights into the processes guiding community assembly. While the results of SPPA suggested the prevalence of traditional ‘stress gradient hypothesis’ (i.e. prevalence of positive interactions under stressful abiotic conditions), OAA revealed that many interspecific canopy associations were significantly negative. Overall, most facilitated species optimized this positive effect by placing their centroids as close to the benefactor species as their foraging behaviour allowed while avoiding crown overlap. The method proposed is available in a dedicated r‐package that will facilitate its application by other ecologists.

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Section: Discussionmentioning

confidence: 99%

The shape is more important than we ever thought: Plant to plant interactions in a high mountain community

et al. 2019

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“…As mentioned in the previous section, the most important variable in the process of obtaining the DTM is voxel resolution. At this stage, the voxel resolution was discussed and defined to be 5 cm based on previous studies (Bienert et al, 2006;Hess et al, 2018) and field observations. According to the elevation analysis of raw point cloud data, the maximum tree height was calculated as 22.80 m ( Figure 6).…”

Section: 1extraction Of Terrain and Tree Datamentioning

confidence: 99%

Individual tree measurements in a planted woodland with terrestrial laser scanner

Yurtseven¹,

Çoban²,

Akgül³

et al. 2019

Turk J Agric For

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Introduction Forest structural diversity is considered to be one of the most important components of biological diversity because it affects the ecological factor beneath the canopy and creates suitable niches for fauna. Therefore, more complex structures indicate greater biodiversity (Szmyt, 2014). Forest structure is also accepted as one of the main naturalness traits, which may include tree density, vertical heterogeneity, canopy cover, and forest layering (Winter, 2012). Hence, quantitative tree and stand structural parameters must be accurately measured for ecosystem service assessment and state of stand development (Moskal and Zheng, 2012). Traditionally, some structural attributes have been measured in the context of forest inventories using field measurements. With the development of technology, the combination of forest inventory methods and new remote sensing technologies have become powerful integrated tools (Brack, 1997). The airborne laser scanning (ALS) technology, which offers high resolution data to derive structural forest parameters, has become notably popular (Means et al., 2000; Drake et al., 2002; Naesset and Økland, 2002; Morsdorf et al., 2004). However, the measurement of ground-truth data still remains in demand in addition to measurements for forest inventory. In the last decade, terrestrial laser scanner (TLS) based data have also become an alternative tool in forest management studies (Bienert et al., 2006). TLS systems can produce 3D point clouds that allow quantitative analysis of tree parameters (Raumonen et al., 2013). TLS has been used in many forestry studies, such as biomass estimation (

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“…CloudCompare has proved a useful tool in a number of scientific studies, including those mapping wild leek (77), habitat suitability modelling for insect conservation (78), spatial ecology studies of coral and megabenthic invertebrates (79), and forest canopy ecology (80).…”

Section: Cloudcomparementioning

confidence: 99%

Species and habitat mapping in two dimensions and beyond. Structure-from-Motion Multi-View Stereo photogrammetry for the Conservation Community

DeBell

McKinley

et al. 2019

Preprint

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15Structure-from-Motion Multi View Stereo (SfM-MVS) photogrammetry is a technique 16 by which volumetric data can be derived from overlapping image sets, using changes of an 17 objects position between images to determine its height and spatial structure. Whilst SfM-MVS 18 has fast become a powerful tool for scientific research, its potential lies beyond the scientific 19 setting, since it can aid in delivering information about habitat structure, biomass, landscape 20 topography, spatial distribution of species in both two and three dimensions, and aid in 21 mapping change over time -both actual and predicted. All of which are of strong relevance for 22 the conservation community, whether from a practical management perspective or 23 understanding and presenting data in new and novel ways from a policy perspective. 24 For practitioners outside of academia wanting to use SfM-MVS there are technical 25 barriers to its application. For example, there are many SfM-MVS software options, but 26 knowing which to choose, or how to get the best results from the software can be difficult for 27 the uninitiated. There are also free and open source software options (FOSS) for processing 28 data through a SfM-MVS pipeline that could benefit those in conservation management and 29 policy, especially in instances where there is limited funding (i.e. commonly within grassroots 30 or community-based projects). This paper signposts the way for the conservation community 31 to understand the choices and options for SfM-MVS implementation, its limitations, current 32 best practice guidelines and introduces applicable FOSS options such as OpenDroneMap, 33MicMac, CloudCompare, QGIS and speciesgeocodeR. It will also highlight why and where 34 this technology has the potential to become an asset for spatial, temporal and volumetric studies 35 of landscape and conservation ecology. 36 37 38 39 Relatively new technologies, such as drones (1,2), advances in computational power 40 (3,4), improvements in digital cameras (5), along with classic remote sensing platforms such 41 as kite aerial photography (KAP) and balloons (6,7), have all combined to help create a new 42 opportunity in remote sensing research utilising SfM-MVS photogrammetry. It is these 43 convergent developments that now position SfM-MVS as a cost-effective and democratic tool 44 for conservation research.45SfM-MVS approaches use parallax (i.e. minor displacements in similar images) in 46 conjunction with computer vision techniques, in order to derive 3D structures from 2D data moving object). Data such as overlapping digital photographs and GPS/GNSS (Global 49 Positioning System/Global Navigation Satellite System) information are stitched together, 50 adding distance (X and Y) and height (Z) values to pixels (points) in the combined data, 51 producing a "point cloud" (Figure 1). From this, SfM-MVS software is able to output two 52 dimensional orthographic images containing detailed geographical location information, 53 alongside 2.5 dimensional reconstruct...

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A high‐resolution approach for the spatiotemporal analysis of forest canopy space using terrestrial laser scanning data

Cited by 23 publications

References 47 publications

The shape is more important than we ever thought: Plant to plant interactions in a high mountain community

The shape is more important than we ever thought: Plant to plant interactions in a high mountain community

Individual tree measurements in a planted woodland with terrestrial laser scanner

Species and habitat mapping in two dimensions and beyond. Structure-from-Motion Multi-View Stereo photogrammetry for the Conservation Community

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