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The accuracy of target distance obtained by a frequency modulated continuous wave (FMCW) laser ranging system is often affected by factors such as white Gaussian noise (WGN), spectrum leakage, and the picket fence effect. There are some traditional spectrum correction algorithms to solve the problem above, but the results are unsatisfactory. In this article, a decomposition filtering-based dual-window correction (DFBDWC) algorithm is proposed to alleviate the problem caused by these factors. This algorithm reduces the influence of these factors by utilizing a decomposition filtering, dual-window in time domain and two phase values of spectral peak in the frequency domain, respectively. With the comparison of DFBDWC and these traditional algorithms in simulation and experiment on a built platform, the results show a superior performance of DFBDWC based on this platform. The maximum absolute error of target distance calculated by this algorithm is reduced from 0.7937 m of discrete Fourier transform (DFT) algorithm to 0.0407 m, which is the best among all mentioned spectrum correction algorithms. A high performance FMCW laser ranging system can be realized with the proposed algorithm, which has attractive potential in a wide scope of applications.
Yi Hao; Ping Song; Xuanquan Wang; Zhikang Pan. A Spectrum Correction Algorithm Based on Beat Signal of FMCW Laser Ranging System. Sensors 2021, 21, 5057 .
AMA StyleYi Hao, Ping Song, Xuanquan Wang, Zhikang Pan. A Spectrum Correction Algorithm Based on Beat Signal of FMCW Laser Ranging System. Sensors. 2021; 21 (15):5057.
Chicago/Turabian StyleYi Hao; Ping Song; Xuanquan Wang; Zhikang Pan. 2021. "A Spectrum Correction Algorithm Based on Beat Signal of FMCW Laser Ranging System." Sensors 21, no. 15: 5057.
To solve the poor real-time performance of the existing fault diagnosis algorithms on transmission system rotating components, this paper proposes a novel high-dimensional OT-Caps (Optimal Transport–Capsule Network) model. Based on the traditional capsule network algorithm, an auxiliary loss is introduced during the offline training process to improve the network architecture. Simultaneously, an optimal transport theory and a generative adversarial network are introduced into the auxiliary loss, which accurately depicts the error distribution of the fault characteristic. The proposed model solves the low real-time performance of the capsule network algorithm due to complex architecture, long calculation time, and oversized hardware resource consumption. Meanwhile, it ensures the high precision, early prediction, and transfer aptitude of fault diagnosis. Finally, the model’s effectiveness is verified by the public data sets and the actual faults data of the transmission system, which provide technical support for the application.
Xuanquan Wang; Xiongjun Liu; Ping Song; Yifan Li; Youtian Qie. A Novel Deep Learning Model for Mechanical Rotating Parts Fault Diagnosis Based on Optimal Transport and Generative Adversarial Networks. Actuators 2021, 10, 146 .
AMA StyleXuanquan Wang, Xiongjun Liu, Ping Song, Yifan Li, Youtian Qie. A Novel Deep Learning Model for Mechanical Rotating Parts Fault Diagnosis Based on Optimal Transport and Generative Adversarial Networks. Actuators. 2021; 10 (7):146.
Chicago/Turabian StyleXuanquan Wang; Xiongjun Liu; Ping Song; Yifan Li; Youtian Qie. 2021. "A Novel Deep Learning Model for Mechanical Rotating Parts Fault Diagnosis Based on Optimal Transport and Generative Adversarial Networks." Actuators 10, no. 7: 146.
As a typical application of indirect-time-of-flight (ToF) technology, photonic mixer device (PMD) solid-state array Lidar has gained rapid development in recent years. With the advantages of high resolution, frame rate and accuracy, the equipment is widely used in target recognition, simultaneous localization and mapping (SLAM), industrial inspection, etc. The PMD Lidar is vulnerable to several factors such as ambient light, temperature and the target feature. To eliminate the impact of such factors, a proper calibration is needed. However, the conventional calibration methods need to change several distances in large areas, which result in low efficiency and low accuracy. To address the problems, this paper presents an improved calibration method based on electrical analog delay. The method firstly eliminates the lens distortion using a self-adaptive interpolation algorithm, meanwhile it calibrates the grayscale image using an integral time simulating based method. Then, the grayscale image is used to estimate the parameters of ambient light compensation in depth calibration. Finally, by combining four types of compensation, the method effectively improves the performance of depth calibration. Through several experiments, the proposed method is more adaptive to multiscenes with targets of different reflectivities, which significantly improves the ranging accuracy and adaptability of PMD Lidar.
Xuanquan Wang; Ping Song; Wuyang Zhang. An Improved Calibration Method for Photonic Mixer Device Solid-State Array Lidars Based on Electrical Analog Delay. Sensors 2020, 20, 7329 .
AMA StyleXuanquan Wang, Ping Song, Wuyang Zhang. An Improved Calibration Method for Photonic Mixer Device Solid-State Array Lidars Based on Electrical Analog Delay. Sensors. 2020; 20 (24):7329.
Chicago/Turabian StyleXuanquan Wang; Ping Song; Wuyang Zhang. 2020. "An Improved Calibration Method for Photonic Mixer Device Solid-State Array Lidars Based on Electrical Analog Delay." Sensors 20, no. 24: 7329.