Vertical Vegetation Structure Analysis and Hydraulic Roughness Determination Using Dense Als Point Cloud Data - A Voxel Based Approach

Vetter, M.; Höfle, Bernhard; Hollaus, Markus; Gschöpf, Christine; Mandlburger, Gottfried; Pfeifer, Norbert; Wagner, Wolfgang

doi:10.5194/isprsarchives-xxxviii-5-w12-265-2011

Cited by 23 publications

(28 citation statements)

References 19 publications

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“…A voxel is defined as an array of 3-D cubes, in the form of either a regular or an irregular grid, separated by user-defined horizontal and vertical resolutions, which are associated with the concept of the horizontal slice and vertical slice (or height bin), respectively [28,29]. In this study, voxel and sub-voxel (SV) arrays were created with user-defined horizontal and vertical resolutions.…”

Section: Introductionmentioning

confidence: 99%

Estimation of Voxel-Based Above-Ground Biomass Using Airborne LiDAR Data in an Intact Tropical Rain Forest, Brunei

Kim

Lee

Yoon

et al. 2016

Forests

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Abstract:The advancement of LiDAR technology has enabled more detailed evaluations of forest structures. The so-called "Volumetric pixel (voxel)" has emerged as a new comprehensive approach. The purpose of this study was to estimate plot-level above-ground biomass (AGB) in different plot sizes of 20 m × 20 m and 30 m × 30 m, and to develop a regression model for AGB prediction. Both point cloud-based (PCB) and voxel-based (VB) metrics were used to maximize the efficiency of low-density LiDAR data within a dense forest. Multiple regression model AGB prediction performance was found to be greatest in the 30 m × 30 m plots, with R 2 , adjusted R 2 , and standard deviation values of 0.92, 0.87, and 35.13 Mg·ha −1 , respectively. Five out of the eight selected independent variables were derived from VB metrics and the other three were derived from PCB metrics. Validation of accuracy yielded RMSE and NRMSE values of 27.8 Mg·ha −1 and 9.2%, respectively, which is a reasonable estimate for this structurally complex intact forest that has shown high NRMSE values in previous studies. This voxel-based approach enables a greater understanding of complex forest structure and is expected to contribute to the advancement of forest carbon quantification techniques.

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Section: Introductionmentioning

confidence: 99%

Estimation of Voxel-Based Above-Ground Biomass Using Airborne LiDAR Data in an Intact Tropical Rain Forest, Brunei

Kim

Lee

Yoon

et al. 2016

Forests

View full text Add to dashboard Cite

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“…In that case, roughness is usually estimated from smaller floods or similar floodplains, where observations are available, but this procedure adds additional uncertainties. Roughness can also be estimated by alternative methods, such as interpreting high-resolution lidar data Vetter et al, 2011). However, due to the estimation procedure some level of calibration may still be needed.…”

Section: (Iii) Parametersmentioning

confidence: 99%

Understanding flood regime changes in Europe: a state-of-the-art assessment

Hall

Arheimer

Borga

et al. 2014

Hydrol. Earth Syst. Sci.

497

335

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Abstract. There is growing concern that flooding is becoming more frequent and severe in Europe. A better understanding of flood regime changes and their drivers is therefore needed. The paper reviews the current knowledge on flood regime changes in European rivers that has traditionally been obtained through two alternative research approaches. The first approach is the data-based detection of changes in observed flood events. Current methods are reviewed together with their challenges and opportunities. For example, observation biases, the merging of different data sources and accounting for nonlinear drivers and responses. The second approach consists of modelled scenarios of future floods. Challenges and opportunities associated with flood change scenarios are discussed such as fully accounting for uncertainties in the modelling cascade and feedbacks. To make progress in flood change research, we suggest that a synthesis of these two approaches is needed. This can be achieved by focusing on long duration records and flood-rich and flood-poor periods rather than on short duration flood trends only, by formally attributing causes of observed flood changes, by validating scenarios against observed flood regime dynamics, and by developing low-dimensional models of flood changes and feedbacks. The paper finishes with a call for a joint European flood change research network.

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“…Metrics for data represented as 3D rasters were presented in the past for plot and artificial data [5,38] and specific applications [12,20,43]. We present a general fragmentation index based on its 2D version [26] and apply it to a sample study area.…”

Section: Discussionmentioning

confidence: 99%

Generalized 3D fragmentation index derived from lidar point clouds

Petras

Newcomb

Mitášová

2017

Open geospatial data, softw. stand.

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Background: Point clouds with increased point densities create new opportunities for analyzing landscape structure in 3D space. Taking advantage of these dense point clouds we have extended a 2D forest fragmentation index developed for regional scale analyses into a 3D index for analyzing vegetation structure at a much finer scale. Methods: Based on the presence or absence of points in a 3D raster (voxel model) the 3D fragmentation index is used to evaluate the configuration of a cell's 3D neighborhood resulting in fragmentation classes such as interior, edge, or patch. In order to incorporate 3D fragmentation into subsequent conventional 2D analyses, we developed a transformation of this 3D fragmentation index into a series of 2D rasters based on index classes. Results: We applied this method to a point cloud obtained by airborne lidar capturing a suburban area with mixed forest cover. All processing and visualization was done in GRASS GIS, an open source, geospatial processing and remote sensing tool. The newly developed code is also publicly available and open source. The entire processing chain is available and executable through Docker for maximum reproducibility. Conclusions: We demonstrated that this proposed index can be used to describe different types of vegetation structure making it a promising tool for remote sensing and landscape ecology. Finally, we suggest that processing point clouds using 3D raster methods including 3D raster algebra is as straightforward as using well-established 2D raster and image processing methods.

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Vertical Vegetation Structure Analysis and Hydraulic Roughness Determination Using Dense Als Point Cloud Data - A Voxel Based Approach

Cited by 23 publications

References 19 publications

Estimation of Voxel-Based Above-Ground Biomass Using Airborne LiDAR Data in an Intact Tropical Rain Forest, Brunei

Estimation of Voxel-Based Above-Ground Biomass Using Airborne LiDAR Data in an Intact Tropical Rain Forest, Brunei

Understanding flood regime changes in Europe: a state-of-the-art assessment

Generalized 3D fragmentation index derived from lidar point clouds

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