LeWoS: A universal leaf‐wood classification method to facilitate the 3D modelling of large tropical trees using terrestrial LiDAR

Wang, Di; Takoudjou, Stéphane Momo; Casella, Eric

doi:10.1111/2041-210x.13342

Cited by 82 publications

(64 citation statements)

References 53 publications

(146 reference statements)

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“…and needle clusters with near-vertical leaf inclination angles were always classified as woody materials. Previous studies obtained similar results when using geometric-based classification models [10,32]. When combining the LRI-and geometric-based features to separate the foliagewoody components from TLS data, the OA increased at least 5%.…”

Section: Lri Correctionsupporting

confidence: 64%

“…where P 0 means the relative observed agreement among N samples in error matrices with r rows, which is equal to the ratio of the sum of the correct identification samples of all samples belonging to the same type; the P c is the hypothetical probability of chance agreement; X i+ and X +i are the row probabilities and the column probabilities, respectively. To assess the contribution of combining the LRI and geometrical information in distinguishing TLS data, we used the LeWoS model [32] and LWCLF model [15], which are only based on geometrical features, to classify the TLS datasets, and evaluated their classification accuracy for foliage and woody components. Additionally, we compared the FWCNN-based results with those obtained using the Random Forest (RF) algorithm [48], Gaussian Mixed Model (GMM) [30], and Support Vector Machine (SVM) algorithm [49] in terms of classification accuracy and running efficiency.…”

Section: Accuracy Assessmentmentioning

confidence: 99%

“…Some supervised classification models have been successfully developed, such as the Random Forest (RF) algorithm [11], Gaussian Mixed Model (GMM) [30], and Support Vector Machine (SVM) algorithm [31], and have achieved high classification accuracy. In the meantime, unsupervised clustering methods, such as the DBSCAN algorithm [10] and LeWoS model [32], have been proposed for separating foliage and woody points in TLS datasets collected in forests.…”

Section: Introductionmentioning

confidence: 99%

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An Improved Convolution Neural Network-Based Model for Classifying Foliage and Woody Components from Terrestrial Laser Scanning Data

Zheng

Yang

2020

Remote Sensing

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Separating foliage and woody components can effectively improve the accuracy of simulating the forest eco-hydrological processes. It is still challenging to use deep learning models to classify canopy components from the point cloud data collected in forests by terrestrial laser scanning (TLS). In this study, we developed a convolution neural network (CNN)-based model to separate foliage and woody components (FWCNN) by combing the geometrical and laser return intensity (LRI) information of local point sets in TLS datasets. Meanwhile, we corrected the LRI information and proposed a contribution score evaluation method to objectively determine hyper-parameters (learning rate, batch size, and validation split rate) in the FWCNN model. Our results show that: (1) Correcting the LRI information could improve the overall classification accuracy (OA) of foliage and woody points in tested broadleaf (from 95.05% to 96.20%) and coniferous (from 93.46% to 94.98%) TLS datasets (Kappa ≥ 0.86). (2) Optimizing hyper-parameters was essential to enhance the running efficiency of the FWCNN model, and the determined hyper-parameter set was suitable to classify all tested TLS data. (3) The FWCNN model has great potential to classify TLS data in mixed forests with OA > 84.26% (Kappa ≥ 0.67). This work provides a foundation for retrieving the structural features of woody materials within the forest canopy.

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Section: Lri Correctionsupporting

confidence: 64%

Section: Accuracy Assessmentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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An Improved Convolution Neural Network-Based Model for Classifying Foliage and Woody Components from Terrestrial Laser Scanning Data

Zheng

Yang

2020

Remote Sensing

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“…In the case of this paper, we are focused on separating parts of a forest into terrain, vegetation, coarse woody debris, and stem categories from a point cloud. There have been many different approaches to the segmentation of forest point clouds [20][21][22][23][24][25][26][27][28][29][30][31][32][33][34] so far. Some approaches use heuristics [20,22,25,28,29] or morphological operations [27], while others use supervised [23,26,[30][31][32][33] or unsupervised [21,34] machine learning techniques.…”

Section: Introductionmentioning

confidence: 99%

Sensor Agnostic Semantic Segmentation of Structurally Diverse and Complex Forest Point Clouds Using Deep Learning

et al. 2021

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Forest inventories play an important role in enabling informed decisions to be made for the management and conservation of forest resources; however, the process of collecting inventory information is laborious. Despite advancements in mapping technologies allowing forests to be digitized in finer granularity than ever before, it is still common for forest measurements to be collected using simple tools such as calipers, measuring tapes, and hypsometers. Dense understory vegetation and complex forest structures can present substantial challenges to point cloud processing tools, often leading to erroneous measurements, and making them of less utility in complex forests. To address this challenge, this research demonstrates an effective deep learning approach for semantically segmenting high-resolution forest point clouds from multiple different sensing systems in diverse forest conditions. Seven diverse point cloud datasets were manually segmented to train and evaluate this model, resulting in per-class segmentation accuracies of Terrain: 95.92%, Vegetation: 96.02%, Coarse Woody Debris: 54.98%, and Stem: 96.09%. By exploiting the segmented point cloud, we also present a method of extracting a Digital Terrain Model (DTM) from such segmented point clouds. This approach was applied to a set of six point clouds that were made publicly available as part of a benchmarking study to evaluate the DTM performance. The mean DTM error was 0.04 m relative to the reference with 99.9% completeness. These approaches serve as useful steps toward a fully automated and reliable measurement extraction tool, agnostic to the sensing technology used or the complexity of the forest, provided that the point cloud has sufficient coverage and accuracy. Ongoing work will see these models incorporated into a fully automated forest measurement tool for the extraction of structural metrics for applications in forestry, conservation, and research.

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“…Within each voxel, the interaction of laser pulses with material is interpreted to derive two types of information: the nature of the material present (leaf or wood) and the leaf area density (in m 2 /m 3 ). The former can be obtained using different methods like reflectance threshold (Béland, Baldocchi, et al., 2014), semantic segmentation (Wang et al., 2020) or machine learning (Krishna Moorthy et al., 2019). The latter relies on theoretical approaches using the contact frequency (Béland et al., 2011; Hosoi & Omasa, 2006; Warren Wilson, 1959), maximum likelihood estimation (Pimont et al., 2018), or the Beer‐Lambert law (Béland et al., 2014; Ross, 1981).…”

Section: Introductionmentioning

confidence: 99%

Mapping forest leaf area density from multiview terrestrial lidar

Béland

Kobayashi

2021

Methods Ecol Evol

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Terrestrial lidar data are known to be useful for estimating the three‐dimensional (3D) distribution of leaf area in forests. This type of product holds great potential for modelling canopy reflectance and light interception to study the links between structure and function. However, little is currently known about its potential and limits in dense forests. Higher leaf area density implies that more laser pulses emitted by the ground‐based instrument are intercepted in lower canopy levels, and the implications of such occlusion effects on radiative transfer simulations are unknown. Occlusion effects can be minimized by increasing the number of locations lidar data is acquired from; how many locations are required for a forest with a given structure? This paper aims to address these knowledge gaps. We acquired terrestrial lidar data using a very high density of scanning positions (5 m between positions) over four dense forest 60 m × 60 m plots along a structural gradient. Occlusion effects were quantified, and the 3D distribution of leaf area density was mapped using voxels (cubic volumes) for four different scan densities (one original and three downsampled). The voxel arrays were then input into a radiative transfer model to simulate bidirectional reflectance factors and vertical fraction of absorbed radiation. We found that the summation of leaf area estimates for all voxels within the plot provided leaf area index (LAI) values close to LAI values estimated using traditional methods at each site. Occluded areas occurred mostly at the top of bottom heavy canopies. Radiative transfer simulations suggest that modelling small scale (<1 m) bidirectional reflectance factors (BRF) and light interception requires the highest scan position density used (5 m between scan positions), particularly at bottom heavy sites, and that 10 m between scan positions can be used for plot scale BRF simulations in forests with foliage density and vertical profiles similar to those tested here. This work establishes some initial guidelines for establishing terrestrial lidar survey protocols for mapping leaf area density in forests. The leaf area density voxel arrays derived are among the most accurate plot‐level 3D characterizations of foliage arrangement produced to date.

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LeWoS: A universal leaf‐wood classification method to facilitate the 3D modelling of large tropical trees using terrestrial LiDAR

Cited by 82 publications

References 53 publications

An Improved Convolution Neural Network-Based Model for Classifying Foliage and Woody Components from Terrestrial Laser Scanning Data

An Improved Convolution Neural Network-Based Model for Classifying Foliage and Woody Components from Terrestrial Laser Scanning Data

Sensor Agnostic Semantic Segmentation of Structurally Diverse and Complex Forest Point Clouds Using Deep Learning

Mapping forest leaf area density from multiview terrestrial lidar

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