Intelligent Context-Aware Communication Paradigm Design for IoVs Based on Data Analytics

IoVs have been envisioned to improve road safety and efficiency, and provide Internet access on the move, by providing a myriad of safety and infotainment applications to drivers and passengers. However, with limited spectrum resource, harsh wireless channel, and variable vehicle density, IoV communication faces severe challenges to achieve scalability, efficiency, and reliability. In this article, we propose a context-aware IoV paradigm design to enhance the communication performance, where the high-level contextual information is utilized to bring intelligence in the design. Specifically, through big data analytics on large-scale IoV communication traces collected from an extensive experiment conducted in Shanghai, we investigate the impacts of different contextual information on V2V communication performance. We reveal that among many types of contextual information, the NLoS link condition is a major one that significantly affects V2V link performance. Based on that observation, we discuss three critical but challenging communication paradigm designs with context awareness of V2V link conditions: smart medium resource allocation, efficient routing establishment, and reliable safety message broadcasting. Furthermore, we present a case study of a cooperative beaconing scheme, where machine learning methods are utilized to learn the real-time link contextual information, and vehicles in deep NLoS condition choose helpers to enhance the overall beaconing reliability.

[1]  Weihua Zhuang,et al.  Software Defined Space-Air-Ground Integrated Vehicular Networks: Challenges and Solutions , 2017, IEEE Communications Magazine.

[2]  Shahrokh Valaee,et al.  Congestion Control for Vehicular Networks With Safety-Awareness , 2016, IEEE/ACM Transactions on Networking.

[3]  Fan Bai,et al.  Toward understanding characteristics of dedicated short range communications (DSRC) from a perspective of vehicular network engineers , 2010, MobiCom.

[4]  Mianxiong Dong,et al.  Synthesizing Vehicle-to-Vehicle Communication Trace for VANET Research , 2017, 2017 IEEE International Conference on Smart Computing (SMARTCOMP).

[5]  Wenchao Xu,et al.  Big Data Driven Vehicular Networks , 2018, IEEE Network.

[6]  Hongke Zhang,et al.  Enhancing Crowd Collaborations for Software Defined Vehicular Networks , 2017, IEEE Communications Magazine.

[7]  Ivan Stojmenovic,et al.  Acknowledgment-Based Broadcast Protocol for Reliable and Efficient Data Dissemination in Vehicular Ad Hoc Networks , 2012, IEEE Transactions on Mobile Computing.

[8]  Zhu Han,et al.  V2X Meets NOMA: Non-Orthogonal Multiple Access for 5G-Enabled Vehicular Networks , 2017, IEEE Wireless Communications.

[9]  Muhammad Ali Imran,et al.  Challenges in 5G: how to empower SON with big data for enabling 5G , 2014, IEEE Network.

[10]  Mohsen Guizani,et al.  Software-Defined Networking for RSU Clouds in Support of the Internet of Vehicles , 2015, IEEE Internet of Things Journal.

[11]  Li Li,et al.  VeMAC: A TDMA-Based MAC Protocol for Reliable Broadcast in VANETs , 2013, IEEE Transactions on Mobile Computing.

[12]  Liviu Iftode,et al.  CARS: Context-Aware Rate Selection for vehicular networks , 2008, 2008 IEEE International Conference on Network Protocols.

[13]  Nei Kato,et al.  Space-Air-Ground Integrated Network: A Survey , 2018, IEEE Communications Surveys & Tutorials.

[14]  Yuanguo Bi,et al.  TV White Space Enabled Connected Vehicle Networks: Challenges and Solutions , 2017, IEEE Network.

[15]  Rahim Tafazolli,et al.  Analytical Study of the IEEE 802.11p MAC Sublayer in Vehicular Networks , 2012, IEEE Transactions on Intelligent Transportation Systems.