Optical-RoI-Signaling for Vehicular Communications

This paper introduces a new hybrid waveform for optical wireless communication (OWC)/optical camera communication (OCC) systems and discusses the technical considerations of these systems. In a challenged vehicular communication environment, which requires high-speed, high-mobility, and long-distance communication support, implementing a hybrid waveform guarantees high-speed data transmission while reducing the cost of the OWC/OCC systems. The application of a hybrid waveform in the OWC/OCC systems is known as the region-of-interest (RoI)-signaling technique. This technique allows the OWC/OCC systems to simultaneously transmit low-rate and high-rate data streams. The low-rate data stream is used to detect and track the RoI of light sources for setting up the communication link, whereas the high-rate data stream is used for high-speed data transmission. Selection of proper modulation schemes for two simultaneous data streams is also discussed in this paper. A new modulation scheme, such as spatial-2-phase-shift-keying (S2-PSK), is proposed for the low-rate data stream. This scheme has been used to modify the IEEE 802.15.7-2018 standard, which is the revised version of the IEEE 802.15.7-2011 standard. For the high-rate data stream, single-carrier modulation or multiple-carrier modulation, such as the proposed hybrid-spatial-phase-shift-keying (HS-PSK) or variable pulse-position modulation (VPPM), can serve as viable solutions. Technical considerations for the modulation schemes of each type of data stream are analyzed to determine the feasibility of the proposed schemes. Finally, the experimental results and numerical parameters of the intended system are presented.

[1]  Trang Nguyen,et al.  Region-of-Interest Signaling Vehicular System Using Optical Camera Communications , 2017, IEEE Photonics Journal.

[2]  Trang Nguyen,et al.  Current Status and Performance Analysis of Optical Camera Communication Technologies for 5G Networks , 2017, IEEE Access.

[3]  Xiaohu Ge,et al.  Vehicular Communications for 5G Cooperative Small-Cell Networks , 2016, IEEE Transactions on Vehicular Technology.

[4]  Parth H. Pathak,et al.  Visible Light Communication, Networking, and Sensing: A Survey, Potential and Challenges , 2015, IEEE Communications Surveys & Tutorials.

[5]  Xiaohu Ge,et al.  5G Software Defined Vehicular Networks , 2017, IEEE Communications Magazine.

[6]  Chin-Teng Lin,et al.  Internet of Vehicles: Motivation, Layered Architecture, Network Model, Challenges, and Future Aspects , 2016, IEEE Access.

[7]  Takaya Yamazato,et al.  Technical Issues on IEEE 802.15.7m Image Sensor Communication Standardization , 2018, IEEE Communications Magazine.

[8]  Thomas D. C. Little,et al.  Impact of lighting requirements on VLC systems , 2013, IEEE Communications Magazine.

[9]  Sridhar Rajagopal,et al.  IEEE 802.15.7 visible light communication: modulation schemes and dimming support , 2012, IEEE Communications Magazine.

[10]  Richard D. Roberts,et al.  Undersampled frequency shift ON-OFF keying (UFSOOK) for camera communications (CamCom) , 2013, 2013 22nd Wireless and Optical Communication Conference.

[11]  Toshiaki Fujii,et al.  Improved Decoding Methods of Visible Light Communication System for ITS Using LED Array and High-Speed Camera , 2010, 2010 IEEE 71st Vehicular Technology Conference.

[12]  Alin-Mihai Căilean,et al.  Current Challenges for Visible Light Communications Usage in Vehicle Applications: A Survey , 2017, IEEE Communications Surveys & Tutorials.

[13]  Xuan Tang,et al.  Undersampled phase shift ON-OFF keying for camera communication , 2014, 2014 Sixth International Conference on Wireless Communications and Signal Processing (WCSP).

[14]  Latif Ullah Khan,et al.  Visible light communication: Applications, architecture, standardization and research challenges , 2017, Digit. Commun. Networks.