[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.3837/tiis.2021.10.020

Traffic Flow Sensing Using Wireless Signals

Duan, Xuting (Beijing Advanced Innovation Center for Big Data and Brain Computing, School of Transportation Science and Engineering, Beihang University)
Jiang, Hang (Beijing Advanced Innovation Center for Big Data and Brain Computing, School of Transportation Science and Engineering, Beihang University)
Tian, Daxin (Beijing Advanced Innovation Center for Big Data and Brain Computing, School of Transportation Science and Engineering, Beihang University)
Zhou, Jianshan (Beijing Advanced Innovation Center for Big Data and Brain Computing, School of Transportation Science and Engineering, Beihang University)
Zhou, Gang (Research Institute of Highway, Ministry of Transport of the People's Republic of China)
E, Wenjuan (School of Rail Transportation, Soochow University)
Sun, Yafu (China TransInfo Technology Co., Ltd)
Xia, Shudong (China TransInfo Technology Co., Ltd)

Publication Information

KSII Transactions on Internet and Information Systems (TIIS) / v.15, no.10, 2021 , pp. 3858-3874 More about this Journal

Abstract

As an essential part of the urban transportation system, precise perception of the traffic flow parameters at the traffic signal intersection ensures traffic safety and fully improves the intersection's capacity. Traditional detection methods of road traffic flow parameter can be divided into the micro and the macro. The microscopic detection methods include geomagnetic induction coil technology, aerial detection technology based on the unmanned aerial vehicles (UAV) and camera video detection technology based on the fixed scene. The macroscopic detection methods include floating car data analysis technology. All the above methods have their advantages and disadvantages. Recently, indoor location methods based on wireless signals have attracted wide attention due to their applicability and low cost. This paper extends the wireless signal indoor location method to the outdoor intersection scene for traffic flow parameter estimation. In this paper, the detection scene is constructed at the intersection based on the received signal strength indication (RSSI) ranging technology extracted from the wireless signal. We extracted the RSSI data from the wireless signals sent to the road side unit (RSU) by the vehicle nodes, calibrated the RSSI ranging model, and finally obtained the traffic flow parameters of the intersection entrance road. We measured the average speed of traffic flow through multiple simulation experiments, the trajectory of traffic flow, and the spatiotemporal map at a single intersection inlet. Finally, we obtained the queue length of the inlet lane at the intersection. The simulation results of the experiment show that the RSSI ranging positioning method based on wireless signals can accurately estimate the traffic flow parameters at the intersection, which also provides a foundation for accurately estimating the traffic flow state in the future era of the Internet of Vehicles.

Keywords

Internet of Vehicles; RSSI; Traffic Flow Sensing; Cooperative Vehicle Infrastructure System;

Citations & Related Records

Reference

1	X.L. Zheng and J.L. Wang, "Design and Implementation of a CSI-Based Ubiquitous Smoking Detection System," IEEE-ACM TRANSACTIONS ON NETWORKING, Vol.25(6), pp. 3781-3793, 2017. DOI
2	J.C. Wang, Z.S. Tian and X.L. Yang, "CSI Component Reconstruction-Based AoA Estimation for Subtle Human-Induced Reflection Under the TTW Scenario," IEEE Communications Letters, Vol.23(8), pp. 1393-1396, 2019. DOI
3	S. Guha, K. Plarre, D. Lissner, S. Mitra, B. Krishna, P. Dutta, S. Kumar, "Auto Witness: Locating and tracking stolen property while tolerating GPS and radio outages," ACM Transactions on Sensor Networks, vol. 8(4), pp. 1-28, 2012.
4	Y.S.MA et al., "Wi-Fi Sensing with Channel State Information: A Survey," ACM Computing Surveys, Vol.52(3), pp. 1-36, 2019.
5	M. Waqas, S. Tu, S. U. Rehman, Z. Halim, S. Anwar et al., "Authentication of vehicles and road side units in intelligent transportation system," Computers, Materials & Continua, vol. 64, no. 1, pp. 359-371, 2020. DOI
6	J. Su, Z. G. Sheng, A. X. Liu and Y. R. Chen, "A group-based binary splitting algorithm for UHF RFID anti-collision systems," IEEE Transactions on Communications, vol. 68, no. 2, pp. 998-1012, 2020. DOI
7	J. Su, Z. Sheng, A. X. Liu, and Y. Chen, "A partitioning approach to RFID identification," IEEE/ACM Transactions on Networking, vol. 28, no. 5, pp. 2160-2173, 2020. DOI
8	I. Constandache, R.R. Choudhury and I. Rhee, "Towards Mobile Phone Localization without WarDriving," in Proc. of INFOCOM, 2010
9	A. Abdi, "On the estimation of the K parameter for the Rice fading distribution," IEEE Communications Letters, Vol.5(3), pp. 92-94, 2001. DOI
10	J. Su, R. Xu, S. Yu, B. Wang, and J. Wang, "Idle slots skipped mechanism based tag identification algorithm with enhanced collision detection," KSII Transactions on Internet and Information Systems, vol. 14, no. 5, pp. 2294-2309, 2020. DOI
11	Z.H. Chen and L. Zhang, "Wi-Fi CSI Based Passive Human Activity Recognition Using Attention Based BLSTM," IEEE Transactions on Mobile Computing, Vol.18(11), pp. 2714-2724, 2019. DOI
12	H. Liu, L. Qi and S. Rong, "Deterministic vessel automatic collision avoidance strategy evaluation modeling," Intelligent Automation & Soft Computing, vol. 25, no.4, pp. 789-804, 2019.
13	S. Chao, "Road Traffic Operation Assessment Based on Multi-source Floating Car Data Fusion," Journal of Tongji University, Vol.46(1), pp. 46-52, 2017.
14	H. Li, and M.X. Dong, "Learning Human Activities through Wi-Fi Channel State Information with Multiple Access Points," IEEE Communications Magazine, Vol.56(5), pp. 124-129, 2018. DOI
15	Q.H. Gao, J. Wang and X.R. Ma, "CSI-Based Device-Free Wireless Localization and Activity Recognition Using Radio Image Features," IEEE Transactions on Vehicular Technology, Vol.66(11), pp. 10346-10356, 2017. DOI
16	G. Swathi, "A frame work for categorize the innumerable vulnerable nodes in mobile adhoc network," Computer Systems Science and Engineering, vol. 35, no.5, pp. 335-345, 2020. DOI
17	C. Li, G. Wu, L. Xing, F. Zhu and L. Zhao, "An efficient certificateless aggregate signature scheme designed for Vanet," Computers, Materials & Continua, vol. 63, no. 2, pp. 725-742, 2020.
18	Mohanty, " VEPSD: A novel velocity estimation algorithm for next-generation wireless systems," IEEE Transactions on Wireless Communications, Vol.4(6), pp. 2655-2660, 2005. DOI
19	P. Bahl, "RADAR: An In-Building RF-Based User Location and Tracking System," in Proc. of INFOCOM 2000. Nineteenth Annual Joint Conference of the IEEE Computer and Communications Societies, 2000.
20	Y. Mao, K. Li and D. Mao, "Application of wireless network positioning technology based on gps in geographic information measurement," Journal of New Media, vol. 2, no.3, pp. 131-135, 2020. DOI
21	C.X. Ma, W. Hao, A.B. Wang and H.X. Zhao, "Developing a Coordinated Signal Control System for Urban Ring Road Under the Vehicle-Infrastructure Connected Environment," IEEE Access, Vol. 6, pp. 52471-52478, 2018. DOI
22	S. Zhang, H. Luo, Z. Wu, Y. Sun, Y. Wang et al., "Efficient heavy hitters identification over speed traffic streams," Computers, Materials & Continua, vol. 63, no. 1, pp. 213-222, 2020.
23	K.Y.Jin et al., "A Single Node Vehicle Detection System Using an Adaptive Signal Adjustment Technique," in Proc. of 2017 20TH INTERNATIONAL SYMPOSIUM ON WIRELESS PERSONAL MULTIMEDIA COMMUNICATIONS (WPMC), pp. 349-353, 2017.
24	H.P. Yin et al., "A Vision-Based Traffic Flow Detection Approach," in Proc. of PROCEEDINGS OF THE 2015 CHINESE INTELLIGENT SYSTEMS CONFERENCE, Vol. 359, pp. 143-152, 2015.
25	W. Hao, Y.J. Lin and Y. Cheng, "Signal Progression Model for Long Intersection Grouping and Coordination," IEEE Access, Vol. 6, pp. 30128-30136, 2018. DOI
26	Y. Wang, J. Yang, H.B. Liu and Y.Y. Chen, "Measuring Human Queues Using Wi-Fi Signals," in Proc. of MobiCom: International Conference on Mobile Computing & Networking, pp. 235-238, 2013.
27	J. Liu, X. Kang, C. Dong and F. Zhang, "Simulation of real-time path planning for large-scale transportation network using parallel computation," Intelligent Automation & Soft Computing, vol. 25, no.1, pp. 65-77, 2019.
28	J.Sanguesa, "SensingTraffic Density Combining V2V and V2I Wireless Communications," Sensors, Vol.15(12), pp. 31794-31810, 2015. DOI
29	H.Q. Liu, "A New Approach for Real-Time Traffic Delay Estimation Based on Cooperative Vehicle-Infrastructure Systems at the Signal Intersection," Arabian Journal for Science & Engineering, Vol.44(3), pp. 2613-2625, 2019. DOI
30	W.Xu et al., "Online Method to Impute Missing Loop Detector Data for Urban Freeway Traffic Control," TRANSPORTATION RESEARCH RECORD, Vol.2593(2593), pp. 37-46, 2016. DOI
31	Z. Gao et al., "Synergizing Appearance and Motion With Low Rank Representation for Vehicle Counting and Traffic Flow Analysis," IEEE Transactions on Intelligent Transportation Systems, Vol.19(8), pp. 2675-2685, 2018. DOI
32	H. Zhao, Y.F. Li, W. Hao, Sr. Peeta, Y.B. Wang, "Evaluating the Effects of Switching Period of Communication Topologies and Delays on Electric Connected Vehicles Stream with Car-following Theory," IEEE Transactions on Intelligent Transportation Systems, pp. 1-11, 2020.
33	X.H. Tian, S.J. Zhu, and S.J. Xiong, "Performance Analysis of Wi-Fi Indoor Localization with Channel State Information," IEEE Transactions on Mobile Computing, Vol.18(8), pp. 1870-1884, 2019. DOI
34	Y. Tang, W. Liu, Y. He, Y. Zhang and F. Zhang, "The development of generalized public bicycles in China and its role in the urban transportation system," Journal of Internet of Things, vol. 2, no. 3, pp. 101-107, 2020. DOI
35	W. Hao, L. Liu, X.F. Yang, Y.F. Li, Y.J. Byon, "Reducing CACC Platoon Disturbances Caused by State Jitters by Combining Two Stages Driving State Recognition with Multiple Platoons Strategies and Risk Prediction," IEEE Transactions on Intelligent Transportation Systems, pp. 1-11, 2020.
36	W. Hao, Z. Zhang, Z. Gao, K. Yi, J. Wang, "Research on mandatory lane-changing behavior in highway weaving sections," Journal of advanced transportation, Vol. 2020(6), pp. 1-9, 2020.
37	D. Kim and S. Kim, "Network-aided intelligent traffic steering in 5g mobile networks," Computers, Materials & Continua, vol. 65, no. 1, pp. 243-261, 2020. DOI
38	C. R. Tang, "Research and Analysis of WSN Node Location in Highway Traffic Based on Priority," Journal of Quantum Computing, vol. 2, no. 1, pp. 1-9, 2020. DOI
39	J. Su, R. Xu, S. Yu, B. Wang, and J. Wang, "Redundant rule detection for software-defined networking," KSII Transactions on Internet and Information Systems, vol. 14, no. 6, pp. 2735-2751, 2020. DOI
40	H. Chen, "Video Detection System of Traffic Flow toward Urban Roads," in Proc. of CSAI '18 Proceedings of the 2018 2nd International Conference on Computer Science and Artificial Intelligence, 2018
41	X.Y. Wang, L.J. Gao and S.W. Mao, "CSI-Based Fingerprinting for Indoor Localization: A Deep Learning Approach," IEEE Transactions on Vehicular Technology, Vol.66(1), pp. 763-776, 2017. DOI
42	J. Su, Z. Sheng, A. X. Liu, Y. Han, and Y. Chen, "Capture-aware identification of mobile RFID tags with unreliable channels," IEEE Transactions on Mobile Computing, pp. 1-1, 2020.
43	C. Ergen, T.H. Serhat and Kontik, "RSSI-Fingerprinting-Based Mobile Phone Localization with Route Constraints," IEEE Transactions on Vehicular Technology, Vol.63(1), pp. 423-428, 2014. DOI
44	W. Yan, Y.Y. Chen, and M. Richard, "Leveraging Wi-Fi Signals to Monitor Human Queues," IEEE Pervasive Computing, Vol.13(2), pp. 14-17, 2014. DOI
45	H.Q.Liu et al., "Data Feature Analysis of Non-Scanning Multi Target Millimeter-Wave Radar in Traffic Flow Detection Applications," SENSORS, Vol.18(9), pp. 2756, 2018. DOI
46	S.Li et al., "Vehicle counting and traffic flow parameter estimation for dense traffic scenes," IET Intelligent Transport Systems, Vol.14(12), pp. 1517-1523, 2020. DOI
47	Z. YANG, Z.M. ZHOU, Y.H. LIU, "From RSSI to CSI: Indoor Localization via Channel Response," ACM Computing Surveys, Vol.46(2), pp. 1-32, 2013.
48	R. Zhou, and X. Lu, "Device-Free Presence Detection and Localization With SVM and CSI Fingerprinting," IEEE Sensors Journal, Vol.17(23), pp. 7990-7999, 2017. DOI