Your search keyword '"Li, Huazhi"' showing total 3 results

1. 3DSG: A 3D LiDAR-Based Object Detection Method for Autonomous Mining Trucks Fusing Semantic and Geometric Features.

Author

Li, Huazhi, Wang, Zhangyu, Yu, Guizhen, Gong, Ziren, Zhou, Bin, Chen, Peng, and Zhao, Fei

Subjects

OBJECT recognition (Computer vision), MINING methodology, TRUCKS, GRIDS (Cartography), POINT cloud, AUTONOMOUS vehicles

Abstract

Object detection is an essential task for autonomous vehicles to ensure safety. Due to the complexity of mining environments, it is difficult to detect objects accurately and robustly. To address these issues, this paper proposes a novel 3D LiDAR-based object detection method fusing semantic and geometric features for autonomous trucks in mining environments (3DSG). A road region extraction method is presented by establishing a semantic segmentation network with a region searching strategy to eliminate off-road point clouds. To deal with the complexity of unstructured road ground point-cloud segmentation, we propose a cascaded ground detection algorithm by performing semantic segmentation filtering and rectangular grid map filtering. A clustering method is proposed fusing adaptive distance thresholds of Euclidean clusters with semantic segmentation categories to solve the problem of the over- and undersegmentation of objects caused by the sparsity of point clouds. The performance of the proposed method is examined utilizing a real mining dataset named TG-Mine-3D. Compared with state-of-the-art methods, our method achieved higher precision of 66.39%. Moreover, for the truck and pedestrian categories, the performance of our method was significantly improved by 2.66% and 5.80%, respectively. The proposed method running at 51.35 ms achieved real-time performance. [ABSTRACT FROM AUTHOR]

Published

2022

2. A New Method for Haptic Shape Discriminability Detection

Author

Liu, Yulong, Yang, Jiajia, Yu, Yinghua, Yu, Yiyang, Wang, Wu, Li, Huazhi, Takahashi, Satoshi, Ejima, Yoshimichi, Wu, Qiong, Wu, Jinglong, Liu, Yulong, Yang, Jiajia, Yu, Yinghua, Yu, Yiyang, Wang, Wu, Li, Huazhi, Takahashi, Satoshi, Ejima, Yoshimichi, Wu, Qiong, and Wu, Jinglong

Abstract

Touch shape discrimination is not only closely related to tactile mechanoreceptors but also higher cognitive function. However, previous shape discrimination methods are difficult to complete in a short time, and the devices are complicated to operate and not user-friendly for nonprofessionals. Here, we propose a new method, the evaluation quantity of which is the angle discrimination threshold. In addition, to make this method easy to use for nonprofessionals, we designed a haptic angle sorting system, including the device and software. To evaluate this method, the angle sorting and two-angle discrimination experiments were compared, and it was found that participants spent significantly less time in the former experiment than in the latter. At the same time, there is a strong correlation between the performance of angle sorting and two-angle discrimination, which shows that the angle threshold obtained by the new method can also be used to evaluate the ability of touch discrimination. Moreover, the angle sorting results of different age groups also further demonstrate the feasibility of the method. The efficiency of this new method and the effectiveness of the system also provide a convenient means for evaluating haptic shape discrimination, which may have potential clinical application value in the early diagnosis of peripheral neuropathy and even in the evaluation of cognitive function.

Published

2021

3. A Novel MEMS Gyroscope In-Self Calibration Approach.

Author

Zhou, Qifan, Yu, Guizhen, Li, Huazhi, and Zhang, Na

Subjects

GYROSCOPES, OBSERVABILITY (Control theory), CALIBRATION, MICROELECTROMECHANICAL systems, KALMAN filtering, ALGORITHMS

Abstract

This paper presents a novel approach for hand-held low-cost MEMS (micro-electro-mechanical system) gyroscope in-self calibration. This method does not need the support of external high-precision equipment compared with traditional calibration scheme and can be accomplished by user hand rotation. In this approach, Kalman filter is designed to perform the calibration procedure and estimate gyroscope bias error, scale factor error and non-orthogonal error. The system observability is analyzed and the dynamic rotating conditions under which the sensor errors become observable are derived. The design principles of optimal calibration procedure are provided as well. Both simulated and practical experiments are carried out to test the validation of the proposed calibration algorithm. The achieved results demonstrate that the introduced approach can provide promising calibration scheme for the low-cost MEMS gyroscope. [ABSTRACT FROM AUTHOR]

Published

2020