Video Streaming Over Vehicular Networks
As one of the most important enabling technologies in the envisioned intelligent transportation system (ITS), vehicular networks are designed to provide information exchange via vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communications.
With the explosive growth of information technology, vehicular networks contribute to a more efficient driving experience by acting as a promising medium to provide a number of innovation applications, such as traffic monitoring, driving assistance, and multimedia services (Belanović et al., 2010; Ren et al., 2015; Wu et al., 2018).
Vehicular networks employ two different transmission categories, i.e., vehicle-to-infrastructure (V2I) communications, which enable vehicles to communicate with a roadside unit (RSU), and vehicular-to-vehicle (V2V) communications, which enable vehicles to communicate with each other. In 1999, FCC allocated 75 MHz (from 5.850...
- 3GPP TR 22885 (2015) Technical specification group services and system aspects; Study on LTE support for V2X services, Rel. 14Google Scholar
- Atallah RF, Assi CM, Khabbaz MJ (2018) Scheduling the operation of a connected vehicular network using deep reinforcement learning. IEEE Trans Intell Transp Syst 1–14, http://doi.org/10.1109/TITS.2018.2832219
- Belyaev E, Vinel A, Surak A, Gabbouj M, Jonsson M, Egiazarian K (2015) Robust vehicle-to-infrastructure video transmission for road surveillance applications. IEEE Trans Veh Technol 64(7):2991–3003Google Scholar
- Chang J et al (2017) An overview of US DOT connected vehicle roadside unit research activities. Technical report, United States. Department of Transportation. ITS Joint Program OfficeGoogle Scholar
- IEEE Std 80211p (2010) Part 11, Amendment 6: wireless access in vehicular environments (WAVE)Google Scholar
- Park JS, Lee U, Oh SY, Gerla M, Lun DS (2006) Emergency related video streaming in vanet using network coding. In: Proceedings of the 3rd international workshop on vehicular ad hoc networks. ACM, pp 102–103Google Scholar
- Rezende C, Ramos HS, Pazzi RW, Boukerche A, Frery AC, Loureiro AA (2012) Virtus: a resilient location-aware video unicast scheme for vehicular networks. In: 2012 IEEE international conference on communications (ICC). IEEE, pp 698–702Google Scholar
- Sheng Z, Pressas A, Ocheri V, Ali F, Rudd R, Nekovee M (2018) Intelligent 5G vehicular networks: an integration of DSRC and mmwave communications. In: 2018 international conference on information and communication technology convergence (ICTC). IEEE, pp 571–576Google Scholar
- Xing M, Cai L (2012) Adaptive video streaming with inter-vehicle relay for highway vanet scenario. In: 2012 IEEE international conference on communications (ICC). IEEE, pp 5168–5172Google Scholar
- Xu Y, Zhou H, Wang X, Zhao B (2015) Resource allocation for scalable video streaming in highway vanet. In: 2015 international conference on wireless communications & signal processing (WCSP). IEEE, pp 1–5Google Scholar
- Zhou H, Ji Y, Wang X, Zhao B (2015) ADMM based algorithm for eICIC configuration in heterogeneous cellular networks. In: 2015 IEEE conference on computer communications (INFOCOM). IEEE, pp 343–351Google Scholar
- Zhou H, Wang X, Liu Z, Zhao X, Ji Y, Yamada S (2016) Qos-aware resource allocation for multicast service over vehicular networks. In: 2016 8th international conference on wireless communications & signal processing (WCSP). IEEE, pp 1–5Google Scholar