Abstract
The current roadmaps and surveys for future wireless networking typically focus on communication and networking technologies and use representative applications to derive future network requirements. Such a benchmarking approach, however, does not cover the application integration challenge that arises from the many distributed applications sharing a network infrastructure, each with their individual topology and data structure. The paper addresses V2X networks as an important example. Crucial end-to-end application constraints including real-time and safety encourage a closer look at application interference and systematic integration. This perspective paper proposes a two-layer resource management that divides the problem into an application integration and a network management task. Valet parking with high-resolution infrastructure camera support is elaborated as a use case that overarches vehicle network and wireless network management. Experiments demonstrate the benefits of complementing the current network-centric management by an application-centric integration.
- [1] 2018. IEEE standard for local and metropolitan area network–bridges and bridged networks. IEEE Std. 802.1Q-2018 (Revision of IEEE Std. 802.1Q-2014) (2018), 1–1993. Google Scholar
Cross Ref
- [2] . 2018. 3GPP TR 22.886-3rd Generation Partnership Project; Technical Specification Group Services and System Aspects; Study on Enhancement of 3GPP Support for 5G V2X Services (Release 16).Google Scholar
- [3] . 2021. 3GPP TR 21.916-3rd Generation Partnership Project; Technical Specification Group Services and System Aspects; Release 16 Description; Summary of Rel-16 Work Items (Release 16).Google Scholar
- [4] . 2020. A visionary roadmap for advanced driving use cases, connectivity technologies, and radio spectrum needs. (
September 2020).Google Scholar - [5] . 2020. Driving Data to the Edge: The Challenge of Traffic Distribution. (
July 2020). https://aecc.org/resources/publicationsaccessed: 21.9.2021. Google Scholar - [6] . 2021. Connected Cars: On The Edge Of A Breakthrough. (
May 2021). https://aecc.org/resources/publicationsaccessed: 20.12.2021. Google Scholar - [7] . 2021. Next generation intra-vehicle backbone network architectures. In 2021 IEEE 22nd International Conference on High Performance Switching and Routing (HPSR’21). 1–7. Google Scholar
Cross Ref
- [8] . 2018. Connected Vehicles and the Cloud Enabling the Future of the Mobility User Experience. (2018). https://d1.awsstatic.com/Industries/Automotive/V2/Navigant%20Research%20-%20Amazon%20White%20Paper%20Full%20-%204-24-2018.pdf
accessed: 21.9.2021. Google Scholar - [9] . 1990. Algorithms and complexity concerning the preemptive scheduling of periodic, real-time tasks on one processor. Real-Time Syst. 2, 4 (
Oct. 1990), 301–324. Google ScholarDigital Library
- [10] . 2020. 6G wireless communication systems: Applications, requirements, technologies, challenges, and research directions. IEEE Open Journal of the Communications Society 1 (2020), 957–975. Google Scholar
Cross Ref
- [11] . 2020. A2D2: Audi autonomous driving dataset. CoRR abs/2004.06320 (2020).
arXiv:2004.06320 https://arxiv.org/abs/2004.06320.Google Scholar - [12] . 2020. Toward 6G networks: Use cases and technologies. IEEE Communications Magazine 58, 3 (2020), 55–61. Google Scholar
Cross Ref
- [13] . 2017. Cellular Vehicle-To-Everything. (2017). https://www.gsma.com/iot/wp-content/uploads/2017/12/C-2VX-Enabling-Intelligent-Transport_2.pdf.
accessed: 21.9.2021. Google Scholar - [14] . 2020. The apolloscape open dataset for autonomous driving and its application. IEEE Transactions on Pattern Analysis and Machine Intelligence 42, 10 (2020), 2702–2719. Google Scholar
Digital Library
- [15] . 2017. Connected Car on The Road to 5G. (
June 2017). https://www.huawei.com/en/technology-insights/industry-insights/outlook/mobile-broadband/xlabs/insights-whitepapers/huawei-whitepaper-connected-car-on-the-road-to-5g.accessed: 21.9.2021. Google Scholar - [16] . 2018. IEEE Standard for Local and Metropolitan Area Networks–Bridges and Bridged Networks – Amendment 31: Stream Reservation Protocol (SRP’18) Enhancements and Performance Improvements. Vol. 2018. 1–208 pages. Google Scholar
Cross Ref
- [17] . 2021. Road vehicles – Cybersecurity engineering.Google Scholar
- [18] . 2019. Road vehicles – Safety of the intended functionality.Google Scholar
- [19] . 2011. Road vehicles – Functional safety.Google Scholar
- [20] . 2020. Taxonomy and Definitions for Terms Related to Cooperative Driving Automation for On-Road Motor Vehicles J3216 202107.Google Scholar
- [21] . 2020. Fast failover in ethernet-based automotive networks. In 2020 IEEE 23rd International Symposium on Real-Time Distributed Computing (ISORC’20). 134–139. Google Scholar
Cross Ref
- [22] . 2021. Achieving safety and performance with reconfiguration protocol for ethernet TSN in automotive systems. Journal of Systems Architecture 118 (2021), 102208. Google Scholar
Cross Ref
- [23] . 2015. Dynamic control for mixed-critical networks-on-chip. In 2015 IEEE Real-Time Systems Symposium. 317–326. Google Scholar
Digital Library
- [24] . 2015. Software-defined networking: A comprehensive survey. Proc. IEEE 103, 1 (2015), 14–76. Google Scholar
Cross Ref
- [25] . 2017. Empowering automotive innovation. (
January 2017). https://download.microsoft.com/download/6/9/D/69D92EB1-F1EE-4893-ABE1-C005D7F9FF57/Microsoft_Connected_Vehicle_Platform_Whitepaper_EN_US.pdf.accessed: 21.9.2021. Google Scholar - [26] . 2015. Data Distribution Service, Version 1.4. OMG Document Number formal/2015-04-10. (
March 2015).Google Scholar - [27] . 2021. A middleware protocol for time-critical wireless communication of large data samples. In 2021 IEEE Real-Time Systems Symposium (RTSS’21). 1–13. Google Scholar
Cross Ref
- [28] . 2020. A vision of 6G wireless systems: Applications, trends, technologies, and open research problems. IEEE Network 34, 3 (2020), 134–142. Google Scholar
Cross Ref
- [29] . 2021. 6G wireless systems: Vision, requirements, challenges, insights, and opportunities. Proc. IEEE 109, 7 (2021), 1166–1199. Google Scholar
Cross Ref
- [30] . 2016. Formal analysis based evaluation of software defined networking for time-sensitive ethernet. In 2016 Design, Automation Test in Europe Conference Exhibition (DATE’16). 31–36.Google Scholar
Digital Library
- [31] . 2019. Standardization Roadmap for Automated Driving. (
March 2019). https://en.vda.de/en/services/Publications/standardization-roadmap-for-automatic-driving.html.accessed: 21.9.2021. Google Scholar - [32] . 2019. 6G Wireless networks: Vision, requirements, architecture, and key technologies. IEEE Vehicular Technology Magazine 14, 3 (2019), 28–41. Google Scholar
Cross Ref
Index Terms
Application-centric Network Management - Addressing Safety and Real-time in V2X Applications
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