MSNet: Multi-Scale Convolutional Network for Point Cloud Classification

Point cloud classification is quite challenging due to the influence of noise, occlusion, and the variety of types and sizes of objects. Currently, most methods mainly focus on subjectively designing and extracting features. However, the features rely on prior knowledge, and it is also difficult to...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2018-04, Vol.10 (4), p.612
Main Authors: Wang, Lei, Huang, Yuchun, Shan, Jie, He, Liu
Format: Article
Language:English
Subjects:
Airborne lasers
Classification
conditional random field (CRF)
Datasets
Feature extraction
Lasers
multi-scale convolutional network (MSNet)
Object recognition
Occlusion
point cloud
Scanning
Urban environments
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Summary:Point cloud classification is quite challenging due to the influence of noise, occlusion, and the variety of types and sizes of objects. Currently, most methods mainly focus on subjectively designing and extracting features. However, the features rely on prior knowledge, and it is also difficult to accurately characterize the complex objects of point clouds. In this paper, we propose a concise multi-scale convolutional network (MSNet) for adaptive and robust point cloud classification. Both the local feature and global context are incorporated for this purpose. First, around each point, the spatial contexts of different sizes are partitioned as voxels of different scales. A voxel-based MSNet is then simultaneously applied at multiple scales to adaptively learn the discriminative local features. The class probability of a point cloud is predicted by fusing the features together across multiple scales. Finally, the predicted class probabilities of MSNet are optimized globally using the conditional random field (CRF) with a spatial consistency constraint. The proposed method was tested with data sets of mobile laser scanning (MLS), terrestrial laser scanning (TLS), and airborne laser scanning (ALS) point clouds. The experimental results show that the proposed method was able to achieve appreciable classification accuracies of 83.18%, 98.24%, and 97.02% on the MLS, TLS, and ALS data sets, respectively. The results also demonstrate that the proposed network has a strong generalization capability for classifying different kinds of point clouds under complex urban environments.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs10040612