Directionally constrained fully convolutional neural network for airborne LiDAR point cloud classification

Wen, Congcong; Yang, Lina; Li, Xiang; Peng, Ling; Chi, Tianhe

doi:10.1016/j.isprsjprs.2020.02.004

Cited by 97 publications

(77 citation statements)

References 44 publications

(62 reference statements)

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“…To address these problems of the information lost in the translation process, a CNN-like network called PointNet was proposed to handle 3D point clouds. Additionally, some studies have applied CNN based techniques to irregular point clouds [ 37 , 38 , 39 , 40 , 41 , 42 ] after PointNet was proposed. These methods offer an integrated architecture that avoids high computational costs coming with high resolution voxels and allows point cloud data to be entered directly for semantic segmentation tasks.…”

Section: Related Studiesmentioning

confidence: 99%

FWNet: Semantic Segmentation for Full-Waveform LiDAR Data Using Deep Learning

Shinohara

Xiu

Matsuoka

2020

Sensors

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In the computer vision field, many 3D deep learning models that directly manage 3D point clouds (proposed after PointNet) have been published. Moreover, deep learning-based-techniques have demonstrated state-of-the-art performance for supervised learning tasks on 3D point cloud data, such as classification and segmentation tasks for open datasets in competitions. Furthermore, many researchers have attempted to apply these deep learning-based techniques to 3D point clouds observed by aerial laser scanners (ALSs). However, most of these studies were developed for 3D point clouds without radiometric information. In this paper, we investigate the possibility of using a deep learning method to solve the semantic segmentation task of airborne full-waveform light detection and ranging (lidar) data that consists of geometric information and radiometric waveform data. Thus, we propose a data-driven semantic segmentation model called the full-waveform network (FWNet), which handles the waveform of full-waveform lidar data without any conversion process, such as projection onto a 2D grid or calculating handcrafted features. Our FWNet is based on a PointNet-based architecture, which can extract the local and global features of each input waveform data, along with its corresponding geographical coordinates. Subsequently, the classifier consists of 1D convolutional operational layers, which predict the class vector corresponding to the input waveform from the extracted local and global features. Our trained FWNet achieved higher scores in its recall, precision, and F1 score for unseen test data—higher scores than those of previously proposed methods in full-waveform lidar data analysis domain. Specifically, our FWNet achieved a mean recall of 0.73, a mean precision of 0.81, and a mean F1 score of 0.76. We further performed an ablation study, that is assessing the effectiveness of our proposed method, of the above-mentioned metric. Moreover, we investigated the effectiveness of our PointNet based local and global feature extraction method using the visualization of the feature vector. In this way, we have shown that our network for local and global feature extraction allows training with semantic segmentation without requiring expert knowledge on full-waveform lidar data or translation into 2D images or voxels.

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Section: Related Studiesmentioning

confidence: 99%

FWNet: Semantic Segmentation for Full-Waveform LiDAR Data Using Deep Learning

Shinohara

Xiu

Matsuoka

2020

Sensors

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“…The framework achieves the highest overall accuracy among the existing methods. Wen C et al [49] proposed a directionally constrained point convolution (D-Conv) module and a directionally constrained fully convolutional neural network (D-FCN) to directly process large-scale point clouds.…”

Section: Tionsmentioning

confidence: 99%

A Graph-Voxel Joint Convolution Neural Network for ALS Point Cloud Segmentation

Zhang

Dai

2020

IEEE Access

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A deep convolution neural network is frequently used in airborne laser scanning (ALS) point cloud segmentation. In this study, we propose a joint graph-voxel convolution network to recognize on-ground objects accurately. In our network, the spatial context features of an input point cloud are first extracted by a designed U-Net via sparse convolution neural networks (SU-Net). Next, the extracted features are used as input features of a designed graph convolution network. We design a graph convolution module called the G-Net to extract the local spatial structure of each point. To enhance the representation of spatial context information, we initialize a graph based on a horizontal direction to enhance the difference between objects and the ground. The output probabilities of SU-Net and the graph convolution model are weighted as the input of the conditional random field optimizing model. The framework proposed in this study exhibits high processing efficiency. Experiments on the semantic 3D labeling dataset of the International Society for Photogrammetry and Remote Sensing (ISPRS) and 2019 IEEE Data Fusion Contest Dataset demonstrate that the proposed model significantly improve the highest F1 score and outperforms various previous networks.

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“…Finally, another MLP layer was used to classify each layer. Wen et al [41] proposed a multiscale FCN that considered direction. Winiwarter et al [42] investigated the applicability of PointNet++ for semantic classification of not only benchmark data but also actual airborne LiDAR point clouds.…”

Section: Related Study 21 3d Deep Learningmentioning

confidence: 99%

“…In this case, when point clouds are converted to voxels, classification performance is adversely affected because of information loss. However, some studies have applied CNN techniques on irregular point clouds [39,41,44,49]. These methods have shown state-of-the-art performance on several point cloud semantic segmentation benchmarks.…”

Section: Introductionmentioning

confidence: 99%

Semantic Segmentation for Full-Waveform LiDAR Data Using Local and Hierarchical Global Feature Extraction

Shinohara

Xiu

Matsuoka

2020

Proceedings of the 28th International Conference on Advances in Geographic Information Systems

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During the last few years, in the field of computer vision, sophisticated deep learning methods have been developed to accomplish semantic segmentation tasks of 3D point cloud data. Additionally, many researchers have extended the applicability of these methods, such as PointNet or PointNet++, beyond semantic segmentation tasks of indoor scene data to large-scale outdoor scene data observed using airborne laser scanning systems equipped with light detection and ranging (LiDAR) technology. Most extant studies have only investigated geometric information (x, y, and z or longitude, latitude, and height) and have omitted rich radiometric information. Therefore, we aim to extend the applicability of deep learning-based model from the geometric data into radiometric data acquired with airborne full-waveform LiDAR without converting the waveform into 2D images or 3D voxels. We simultaneously train two models: a local module for local feature extraction and a global module for acquiring wide receptive fields for the waveform. Furthermore, our proposed model is based on waveform-aware convolutional techniques. We evaluate the effectiveness of the proposed method using benchmark large-scale outdoor scene data. By integrating the two outputs from the local module and the global module, our proposed model had achieved higher mean recall value 0.92 than previous methods and higher F1 scores for all six classes than the other 3D Deep Learning method. Therefore, our proposed network consisting of the local and global module successfully resolves the semantic segmentation task of full-waveform LiDAR data without requiring expert knowledge. CCS CONCEPTS • Computing methodologies → Scene understanding.

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Directionally constrained fully convolutional neural network for airborne LiDAR point cloud classification

Cited by 97 publications

References 44 publications

FWNet: Semantic Segmentation for Full-Waveform LiDAR Data Using Deep Learning

FWNet: Semantic Segmentation for Full-Waveform LiDAR Data Using Deep Learning

A Graph-Voxel Joint Convolution Neural Network for ALS Point Cloud Segmentation

Semantic Segmentation for Full-Waveform LiDAR Data Using Local and Hierarchical Global Feature Extraction

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