Performance Analysis of Vehicle-to-Anything Operation of 5G under Different Propagation Environments and Mobility Levels

Show simple item record

dc.contributor.author Rafi, Hasib Ahmed
dc.contributor.author Fahad, Md. Saymon
dc.contributor.author Ahmed, Sakib
dc.contributor.author Sajjad, Syed Safwan
dc.date.accessioned 2020-12-26T05:12:51Z
dc.date.available 2020-12-26T05:12:51Z
dc.date.issued 2019-11-15
dc.identifier.citation 􀀾1􀁀 Francisco J. Martinez et al. “Emergency Services in Future Intelligent Transportation Systems Based on Vehicular Communication Networks”, IEEE Intelligent Transportation Systems Magazine, October 2010, vol. 2, issue. 2, pp. 6-20. 􀀾2􀁀 K. Zheng, Q. Zheng, P. Chatzimisios, W. Xiang, and Y. Zhou, “Heterogeneous Vehicular Networking: A Survey on Architecture, Challenges, and Solutions”, IEEE Commun. Surv. & Tutor., Fourth Quarter 2015, vol. 17, issue. 4, pp. 2377–2396. 􀀾3􀁀 R. F. Atallah, M. J. Khabbaz, and C. M. Assi, “Vehicular Networking: A Survey on Spectrum Access Technologies and Persisting Challenges”, Elsevier Vehic. Commun., July 2015, vol. 2, issue. 3, pp. 125–149. 􀀾4􀁀 Xuyu Yang, Shiwen Mao, and Michelle X. Chang, “An Overview of 3GPP Cellular Vehicle-to-Everything Standards”, GetMobile: Mobile Computing and Communications, September 2017, vol. 21, issue. 3, pp. 19-25. 􀀾5􀁀 3GPP TS 22.185, “Service requirements for V2X services”, Release 15, 2018. 􀀾6􀁀 “Radio Interface Standards of Vehicle-to-Vehicle and Vehicle-to-Infrastructure Communications for Intelligent Transport System Applications”, Recommendation ITU-R M.2084-0, September 2015. 􀀾7􀁀 Dr. Michaela Vanderveen, and Kunal Shukla, “Cellular V2X Communications Towards 5G”, 5G Americas (White Paper), March 2018. 􀀾8􀁀 3GPP TS 23.285, “Architecture enhancements for V2X services”, Release 15, 2018. 􀀾9􀁀 3GPP TS 33.185, “Security aspect for LTE support of V2X services”, Release 15, 2018. 􀀾10􀁀 Erik Dahlman, Stefan Parkvall, and Johan Sköld, “4G LTE - Advanced Pro and The Road to 5G”, Elsevier Ltd., pp. 461-486, ISBN: 978-0-12-804575-6. 􀀾11􀁀 Li Feng et al., “V2X White Paper by NGMN Alliance”, project. NGMN V2X Task Force, confidentiality class. P - Public, approved by / date. NGMN Board / 10th July 2018. 􀀾12􀁀 3GPP TS 22.186, “Enhancement of 3GPP support for V2X scenarios”, Release 16, 2018. 􀀾13􀁀 Ioannis Mavromatis, Andrea Tassi, Giovanni Rigazzi, Robert J. Piechocki, and Andrew Nix, “Multi-Radio 5G Architecture for Connected and Autonomous Vehicles: Application and Design Insights”, EAI Endorsed Trans. Indust. Netw. & Intellig. Syst., February 2018, DOI:10.4108/eai.20-3-2018.154368 􀀾14􀁀 “Accelerating C-V2X Commercialization”, Qualcomm (2017). 􀀾15􀁀 Andreas Festag, “Standards for Vehicular Communication􀂲from IEEE 802.11p to 5G”, e & i Elektrotechnik und Informationstechnik, November 2015, vol. 132, issue. 7, pp. 409-416 􀀾16􀁀 John B. Kenney, “Dedicated Short-Range Communications (DSRC) Standards in the United States”, Proceedings of the IEEE, July 2011, vol. 99, issue. 7, pp. 1162-1182. 􀀾17􀁀 ETSI TS 122 186 V15.3.0, Release 15, 2018. 􀀾18􀁀 Laurens Hobert, Andreas Festag, Ignacio Llatser, Luciano Altomare, Filippo Visintainer, and Andras Kovacs, “Enhancements of V2X Communication in Support of Cooperative Autonomous Driving”, IEEE Communications Magazine, December 2015, vol. 53, issue. 12, pp. 64-70. 75 􀀾19􀁀 “Radio Interface Standards of Vehicle-to-Vehicle and Vehicle-to-Infrastructure Communications for Intelligent Transport System Applications”, Recommendation ITU-R M.2084-0, September 2015. 􀀾20􀁀 3GPP TR 22.885, “Study on LTE support for V2X Services”, Release 14, 2015. 􀀾21􀁀 Georgios Karagiannis et al., “Vehicular Networking: A Survey and Tutorial on Requirements, Architectures, Challenges, Standards and Solutions”, IEEE Communications Surveys & Tutorials, July 2011, vol. 13, issue. 4, pp. 584-616. 􀀾22􀁀 Donghoon Shin, Kangmun Park, and Manbok Park, “Effects of Vehicular Communication on Risk Assessment in Automated Driving Vehicles”, MDPI applied sciences, December 2018, vol. 8, issue. 12, EISSN 2076-3417. 􀀾23􀁀 Muntaser A. Salman, Suat Ozdemir, and Fatih V. Celebi, “Fuzzy Traffic Control with Vehicle-to-Everything Communication”, MDPI sensors, January 2018, vol. 18, issue. 2, EISSN 1424-8220. 􀀾24􀁀 Jian Wang, Yameng Shao, Yuming Ge, and Rundong Yu, “A Survey of Vehicle to Everything (V2X) Testing”, MDPI sensors, January 2019, vol. 19, issue. 2, EISSN 1424-8220. 􀀾25􀁀 Kwonjong Lee et al., “Latency of Cellular-Based V2X: Perspectives on TTI-Proportional Latency and TTI-Independent Latency”, IEEE Access, July 2017, vol. 5, Electronic ISSN: 2169-3536, DOI: 10.1109/ACCESS.2017.2731777 3GPP TR 33.885, “Study on security aspects for LTE support of vehicle-to-everything (V2X) services”, Release 14, 2017. 􀀾26􀁀 ITU-R, Detailed specifications of the radio interfaces of international mobile telecommunications-2000 (IMT-2000), Recommendation ITU-R M.1457e11, February 2013. 􀀾27􀁀 ITU-R, Framework and overall objectives of the future development of IMT-2000 and systems beyond IMT-2000, Recommendation ITU-R M.1645, June 2003. 􀀾28􀁀 ITU-R, ITU paves way for next-generation 4G mobile technologies; ITU-R IMT-advanced 4G standards to usher new era of mobile broadband communications, ITU Press Release, 21 October 2010. 􀀾29􀁀 ITU-RWP5D, Recommendation ITU-R M.2012. Detailed specifications of the terrestrial radio interfaces of International Mobile Telecommunications Advanced (IMT-Advanced), January 2012 􀀾30􀁀 M. Olsson, S. Sultana, S. Rommer, L. Frid, C. Mulligan, SAE and the Evolved Packet CoreeDriving the Mobile Broadband Revolution, Academic Press, 2009. 􀀾31􀁀 3GPP, 3rd generation partnership project; Technical specification group radio access network; Requirements for Evolved UTRA (E-UTRA) and Evolved UTRAN (E-UTRAN) (Release 7), 3GPP TR 25.913. 􀀾32􀁀 C.E. Shannon, A mathematical theory of communication, Bell System Tech. J 27 (July and October 1948) 379e423, 623e656. 􀀾33􀁀 J. Tellado and J.M. Cioffi, PAR reduction in multi-carrier transmission systems, ANSI T1E1.4/97e367. 􀀾34􀁀 W. Zirwas, Single frequency network concepts for cellular OFDM radio systems, International OFDM Workshop, Hamburg, Germany, September 2000. 􀀾35􀁀 Motorola, Comparison of PAR and Cubic Metric for Power De-rating, Tdoc R1-040642, 3GPP TSG-RAN WG1, May 2004. 􀀾36􀁀 S.T. Chung, A.J. Goldsmith, Degrees of freedom in adaptive modulation: A unified view, IEEE T, Commun. 49 (9) (September 2001) 1561e1571. 􀀾37􀁀 A.J. Goldsmith, P. Varaiya, Capacity of fading channels with channel side information, IEEE T. Inform. Theory 43 (November 1997) 1986e1992. 76 􀀾38􀁀 R. Knopp, P.A. Humblet, Information capacity and power control in single-cell multi-user communications, Proceedings of the IEEE International Conference on Communications, Seattle, WA, USA, Vol. 1, 1995, 331e335. 􀀾39􀁀 D. Tse, Optimal power allocation over parallel Gaussian broadcast channels, Proceedings of the International Symposium on Information Theory, Ulm, Germany, June 1997, p. 7. 􀀾40􀁀 M.L. Honig and U. Madhow, Hybrid intra-cell TDMA/inter-cell CDMA with inter-cell interference suppression for wireless networks, Proceedings of the IEEE Vehicular Technology Conference, Secaucus, NJ, USA, 1993, pp. 309e312. 􀀾41􀁀 S. Ramakrishna, J.M. Holtzman, A scheme for throughput maximization in a dual-class CDMA system, IEEE J. Sel. Area Comm. 16 (6) (1998) 830e844. 􀀾42􀁀 C. Schlegel, Trellis and Turbo Coding, WileyeIEEE Press, Chichester, UK, March 2004. 􀀾43􀁀 J.M. Wozencraft, M. Horstein, Digitalised Communication Over Two-way Channels, Fourth London Symposium on Information Theory, London, UK, September 1960. 􀀾44􀁀 D. Chase, Code combining - a maximum-likelihood decoding approach for combining and arbitrary number of noisy packets, IEEE T. Commun. 33 (May1985) 385e393. 􀀾45􀁀 M.B. Pursley, S.D. Sandberg, Incremental-redundancy transmission for meteor-burst communications, IEEE T. Commun. 39 (May 1991) 689e702. 􀀾46􀁀 S.B. Wicker, M. Bartz, Type-I hybrid ARQ protocols using punctured MDS codes, IEEE T. Commun. 42 (April 1994) 1431-1440. en_US
dc.identifier.uri http://hdl.handle.net/123456789/740
dc.description Supervised by Dr. Mohammad Tawhid Kawser Associate Professor Electrical and Electronic Engineering (EEE) Islamic University of Technology (IUT) en_US
dc.description.abstract Our thesis topic is related to V2X ,its applications and its performance analysis. This thesis book contains an in-depth study of V2X technologies which has been carried out by our team. It also contains the analysis of BLER and throughput for varying numbers of frames, Doppler frequencies and modulation schemes. Performance analysis is done for multiple mobility factors in two different propagation environments namely- EVA and ETU. EPA was avoided in this case because mobility factor doesn’t play a huge role due to absence of high speed entities in this particular propagation model. en_US
dc.language.iso en en_US
dc.publisher Department of Electrical and Electronic Engineering, Islamic University of Technology,Board Bazar, Gazipur, Bangladesh en_US
dc.title Performance Analysis of Vehicle-to-Anything Operation of 5G under Different Propagation Environments and Mobility Levels en_US
dc.type Thesis en_US


Files in this item

This item appears in the following Collection(s)

Show simple item record

Search IUT Repository


Advanced Search

Browse

My Account

Statistics