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http://dx.doi.org/10.3837/tiis.2019.08.017

A Deep Learning Part-diagnosis Platform(DLPP) based on an In-vehicle On-board gateway for an Autonomous Vehicle  

Kim, KyungDeuk (Department of Computer Engineering, College of Engineering, Catholic Kwandong University)
Son, SuRak (Department of Computer Engineering, College of Engineering, Catholic Kwandong University)
Jeong, YiNa (Department of Computer Engineering, College of Engineering, Catholic Kwandong University)
Lee, ByungKwan (Department of Computer Engineering, College of Engineering, Catholic Kwandong University)
Publication Information
KSII Transactions on Internet and Information Systems (TIIS) / v.13, no.8, 2019 , pp. 4123-4141 More about this Journal
Abstract
Autonomous driving technology is divided into 0~5 levels. Of these, Level 5 is a fully autonomous vehicle that does not require a person to drive at all. The automobile industry has been trying to develop Level 5 to satisfy safety, but commercialization has not yet been achieved. In order to commercialize autonomous unmanned vehicles, there are several problems to be solved for driving safety. To solve one of these, this paper proposes 'A Deep Learning Part-diagnosis Platform(DLPP) based on an In-vehicle On-board gateway for an Autonomous Vehicle' that diagnoses not only the parts of a vehicle and the sensors belonging to the parts, but also the influence upon other parts when a certain fault happens. The DLPP consists of an In-vehicle On-board gateway(IOG) and a Part Self-diagnosis Module(PSM). Though an existing vehicle gateway was used for the translation of messages happening in a vehicle, the IOG not only has the translation function of an existing gateway but also judges whether a fault happened in a sensor or parts by using a Loopback. The payloads which are used to judge a sensor as normal in the IOG is transferred to the PSM for self-diagnosis. The Part Self-diagnosis Module(PSM) diagnoses parts itself by using the payloads transferred from the IOG. Because the PSM is designed based on an LSTM algorithm, it diagnoses a vehicle's fault by considering the correlation between previous diagnosis result and current measured parts data.
Keywords
OBD-II; Sensor Fault Decision; Self-diagnosis; Loopback; On-board gateway;
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  • Reference
1 Long Short-Term Memory (LSTM). https://developer.nvidia.com/discover/lstm
2 Zhou Yuwen., Huang Changqin., Hu Qintai., Zhu Jia,, Tang Yong., "Personalized learning full-path recommendation model based on LSTM neural networks," Information Sciences, Vol. 444, pp135-152, 2018.   DOI
3 Rao Guozheng., Huang Weihang., Feng Zhiyong,, Cong Qiong., "LSTM with sentence representations for document-level sentiment classification," Neurocomputing, Vol. 308, pp.49-57, 2018.   DOI
4 Hong-In Kim., Rae-Hong Park., "Residual LSTM Attention Network for Object Tracking," IEEE Signal Processing Letters, Vol. 25, pp.1029-1033, 2018.   DOI
5 T. Le., K. Mayaram., T. Fiez., "Efficient Far-Field Radio Frequency Energy Harvesting for Passively Powered Sensor Networks," IEEE Journal of Solid-State Circuits, Vol. 43, pp.1287-1302, 2008.   DOI
6 N.E. Leonard., D.A. Paley., F. Lekien., R. Sepulchre., D.M. Fratantoni., R.E. Davis., "Collective Motion, Sensor Networks, and Ocean Sampling," Proceedings of the IEEE, Vol. 95, pp.48-74, 2007.   DOI
7 S. Bamberg., A.Y. Benbasat., D.M. Scarborough., D.E. Krebs., J.A. Paradiso., "Gait Analysis Using a Shoe-Integrated Wireless Sensor System," IEEE Transactions on Information Technology in Biomedicine, Vol. 12, Issue 4, pp..413-423, 2008.   DOI
8 Y.N. Jeong., S.R. Son., E.H. Jeong., B.K. Lee., "A Design of a Lightweight In-Vehicle Edge Gateway for the Self-Diagnosis of an Autonomous Vehicle," Applied Sciences, Vol. 8, 2018.
9 Y.N. Jeong., S.R. Son., B.K. Lee., "The Lightweight Autonomous Vehicle Self-Diagnosis (LAVS) Using Machine Learning Based on Sensors and Multi-Protocol IoT Gateway," Sensors, Vol. 19, 2019.
10 Suhasini Gadam, "Artificial Intelligence and Autonomous Vehicles," Data Driven Investor, 2018.
11 Zhao Yang., Liu Peng., Wang Zhenpo., Hong Jichao., "Electric Vehicle Battery Fault Diagnosis Based on Statistical Method," Energy Procedia, Vol. 105, pp.2366-2371, 2017.   DOI
12 Fong A.C.M., Hui S.C., "Neural expert system for vehicle fault diagnosis via the WWW," Computational Web Intelligence, pp..169-181, 2004.
13 Menhour L., Charara A., Lechner D., "Steering vehicle control and road bank angle estimation: application for diagnosis of vehicle limits in bend," Inderscience Publishers, Vol. 12, No. 4, pp334-366, 2014.
14 Guo Dingfei., Zhong Maiying., Ji Hongquan,, Liu Yang., Yang Rui., "A hybrid feature model and deep learning based fault diagnosis for unmanned aerial vehicle sensors," Neurocomputing, Vol. 319, pp.155-163, 2018.   DOI
15 Hongsik Choi., Suresh Subramaniam., Hyeong-Ah Choi., "Loopback recovery from double-link failures in optical mesh networks," IEEE/ACM Transactions on Networking, Vol. 12, Issue 6, pp1119-1130, 2004.   DOI
16 Xiaojing Huang., Y. Jay Guo., Jian A. Zhang., "Transceiver I/Q Imbalance Self-Calibration With Phase-Shifted Local Loopback for Multichannel Microwave Backhaul," IEEE Transactions on Wireless Communications, Vol. 15, pp.7657-7669, 2016.   DOI
17 Xuan-Lun Huang., Jiun-Lang Huang., "ADC/DAC Loopback Linearity Testing by DAC Output Offsetting and Scaling," IEEE Transactions on Very Large Scale Integration (VLSI) Systems, Vol. 19, pp.1765-1774, 2011.   DOI
18 Byoungho Kim., "Dithering Loopback-Based Prediction Technique for Mixed-Signal Embedded System Specifications," IEEE Transactions on Circuits and Systems II-Express Briefs, Vol. 63, pp.121-125, 2016.   DOI