Analysis of Mobile Edge Computing for Vehicular Networks †

Vehicular ad-hoc Networks (VANETs) are an integral part of intelligent transportation systems (ITS) that facilitate communications between vehicles and the internet. More recently, VANET communications research has strayed from the antiquated DSRC standard and favored more modern cellular technologies, such as fifth generation (5G). The ability of cellular networks to serve highly mobile devices combined with the drastically increased capacity of 5G, would enable VANETs to accommodate large numbers of vehicles and support range of applications. The addition of thousands of new connected devices not only stresses the cellular networks, but also the computational and storage requirements supporting the applications and software of these devices. Autonomous vehicles, with numerous on-board sensors, are expected to generate large amounts of data that must be transmitted and processed. Realistically, on-board computing and storage resources of the vehicle cannot be expected to handle all data that will be generated over the vehicles lifetime. Cloud computing will be an essential technology in VANETs and will support the majority of computation and long-term data storage. However, the networking overhead and latency associated with remote cloud resources could prove detrimental to overall network performance. Edge computing seeks to reduce the overhead by placing computational resources nearer to the end users of the network. The geographical diversity and varied hardware configurations of resource in a edge-enabled network would require careful management to ensure efficient resource utilization. In this paper, we introduce an architecture which evaluates available resources in real-time and makes allocations to the most logical and feasible resource. We evaluate our approach mathematically with the use of a multi-criteria decision analysis algorithm and validate our results with experiments using a test-bed of cloud resources. Results demonstrate that an algorithmic ranking of physical resources matches very closely with experimental results and provides a means of delegating tasks to the best available resource.

[1]  Shiwen Mao,et al.  An Overview of 3GPP Cellular Vehicle-to-Everything Standards , 2017, GETMBL.

[2]  Dharma P. Agrawal,et al.  Context-Aware Mobile Edge Computing in Vehicular Ad-Hoc Networks , 2018, 2018 28th International Telecommunication Networks and Applications Conference (ITNAC).

[3]  Raja Lavanya,et al.  Fog Computing and Its Role in the Internet of Things , 2019, Advances in Computer and Electrical Engineering.

[4]  Fan Yang,et al.  Data Gathering Framework Based on Fog Computing Paradigm in VANETs , 2017, APWeb/WAIM Workshops.

[5]  Falko Dressler,et al.  Vehicular Micro Clouds as Virtual Edge Servers for Efficient Data Collection , 2017, CarSys@MobiCom.

[6]  Barbara M. Masini,et al.  A Survey on the Roadmap to Mandate on Board Connectivity and Enable V2V-Based Vehicular Sensor Networks , 2018, Sensors.

[7]  Pengfei Wang,et al.  Cellular V2X in Unlicensed Spectrum: Harmonious Coexistence with VANET in 5G systems , 2017, 1712.04639.

[8]  Roger J. Green Optical wireless with application in automotives , 2010, 2010 12th International Conference on Transparent Optical Networks.

[9]  Kapil Gulati,et al.  A comparison of cellular vehicle-to-everything and dedicated short range communication , 2017, 2017 IEEE Vehicular Networking Conference (VNC).

[10]  Yuanguo Bi,et al.  Toward 5G Spectrum Sharing for Immersive-Experience-Driven Vehicular Communications , 2017, IEEE Wireless Communications.

[11]  Xuemin Shen,et al.  Toward Efficient Content Delivery for Automated Driving Services: An Edge Computing Solution , 2018, IEEE Network.

[12]  Serge Fdida,et al.  Navigo: Interest forwarding by geolocations in vehicular Named Data Networking , 2015, 2015 IEEE 16th International Symposium on A World of Wireless, Mobile and Multimedia Networks (WoWMoM).

[13]  Paolo Pagano,et al.  Free space optical communication in the visible bandwidth for V2V safety critical protocols , 2012, 2012 8th International Wireless Communications and Mobile Computing Conference (IWCMC).

[14]  Matthew D. Higgins,et al.  Optical Wireless for Intravehicle Communications: A Channel Viability Analysis , 2012, IEEE Transactions on Vehicular Technology.

[15]  Sergio Barbarossa,et al.  Joint Optimization of Radio and Computational Resources for Multicell Mobile-Edge Computing , 2014, IEEE Transactions on Signal and Information Processing over Networks.

[16]  Li Zhao,et al.  Vehicle-to-Everything (v2x) Services Supported by LTE-Based Systems and 5G , 2017, IEEE Communications Standards Magazine.

[17]  Qiang Zheng,et al.  Software-Defined and Fog-Computing-Based Next Generation Vehicular Networks , 2018, IEEE Communications Magazine.

[18]  C. Robusto The Cosine-Haversine Formula , 1957 .