Abstract
With the wide application of Light Detection and Ranging (LiDAR) in the collection of high-precision environmental point cloud information, three-dimensional (3D) object classification from point clouds has become an important research topic. However, the characteristics of LiDAR point clouds, such as unstructured distribution, disordered arrangement, and large amounts of data, typically result in high computational complexity and make it very difficult to classify 3D objects. Thus, this paper proposes a Convolutional Neural Network (CNN)-based 3D object classification method using the Hough space of LiDAR point clouds to overcome these problems. First, object point clouds are transformed into Hough space using a Hough transform algorithm, and then the Hough space is rasterized into a series of uniformly sized grids. The accumulator count in each grid is then computed and input to a CNN model to classify 3D objects. In addition, a semi-automatic 3D object labeling tool is developed to build a LiDAR point clouds object labeling library for four types of objects (wall, bush, pedestrian, and tree). After initializing the CNN model, we apply a dataset from the above object labeling library to train the neural network model offline through a large number of iterations. Experimental results demonstrate that the proposed method achieves object classification accuracy of up to 93.3% on average.
Highlights
Object classification is a significant research task in artificial intelligence (AI) and computer vision domain and has been applied to scene understanding, domestic/service robots, and smart factory systems [1, 2]
Light detection and ranging (LiDAR) sensors have been employed increasingly for object classification because such sensors can obtain a large amount of high-resolution and accurate 3D point clouds from the surrounding environment [4, 5]
3D object classification based on LiDAR point clouds remains a challenging problem
Summary
Object classification is a significant research task in artificial intelligence (AI) and computer vision domain and has been applied to scene understanding, domestic/service robots, and smart factory systems [1, 2]. High-precision object classification results enable an intelligent driving system to identify obstacles and achieve safe autonomous route planning [3]. High-precision object classification results are vital as a preliminary step for subsequent work. Light detection and ranging (LiDAR) sensors have been employed increasingly for object classification because such sensors can obtain a large amount of high-resolution and accurate 3D point clouds from the surrounding environment [4, 5]. Traditional classification methods from point clouds primarily analyze and extract features, such as geometric attributes, shape attributes, or structural attributes, and classify objects by training a model [6, 7]. 3D object classification based on LiDAR point clouds remains a challenging problem
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