[1] 李克强,戴一凡,李升波,等.智能网联汽车(ICV)技术的发展现状及趋势[J].汽车安全与节能学报,2017,8(1):1-14. LI Keqiang, DAI Yifan, LI Shengbo, et al. State-of-the-art and technical trends of intelligent and connected vehicles[J]. Journal of Automotive Safety and Energy, 2017,8(1):1-14. [2] DESJARDINS C, CHAIB-DRAA B. Cooperative adaptive cruise control: a reinforcement learning approach[J]. IEEE Transactions on Intelligent Transportation Systems, 2011, 12(4):1248-1260. [3] 魏磊,王云鹏,秦洪懋,等.车联网环境下CACC车辆信息传播安全性研究[J].汽车工程,2019,41(3):252-258. WEI Lei, WANG Yunpeng, QIN Hongmao, et al. A research on security of information propagation of CACC vehicles under internet of vehicles environment[J]. Automotive Engineering, 2019, 41(3): 252-258. [4] HARTENSTEIN H, LABERTEAUX L P. A tutorial survey on vehicular ad hoc networks[J]. IEEE Communications Magazine, 2008, 46(6):164-171. [5] 常雪阳,许庆,李克强,等.通信时延与丢包下智能网联汽车控制性能分析[J].中国公路学报,2019,32(6):216-225. CHANG Xueyang, XU Qing, LI Keqiang, et al. Analysis of intelligent and connected vehicle control under communication delay and packet loss[J]. China Journal of Highway and Transport, 2019,32(6):216-225. [6] 刘宗巍, 匡旭, 赵福全. V2X关键技术应用与发展综述[J]. 电讯技术, 2019, 59(1):121-128. LIU Zongwei, KUANG Xu, ZHAO Fuquan. A survey on applications and development of V2X key technologies[J]. Telecommunication Engineering, 2019, 59(1):121-128. [7] 秦晓辉,王建强,谢伯元,等.非匀质车辆队列的分布式控制[J].汽车工程,2017,39(1):73-78,106. QIN Xiaohui, WANG Jianqiang, XIE Boyuan, et al. Distributed control of heterogeneous vehicular platoons[J]. Automotive Engineering, 2017,39(1):73-78,106. [8] LEI C, EENENNAAN E M, WOLTERINK W K, et al. Impact of packet loss on CACC string stability performance[C]. International Conference on Its Telecommunications. IEEE, 2011. [9] ZENG T, SEMIARI O, SAAD W, et al. Integrated communic-ations and control co-design for wireless vehicular platoon systems[C]. 2018 IEEE International Conference on Communications (ICC 2018). IEEE, 2018. [10] LIU X, GOLDSMITH A, MAHAL S S, et al. Effects of communication delay on string stability in vehicle platoons[C]. 2001 IEEE International Conference on Intelligent Transportation Systems (ITSC). New Jersey: IEEE, 2001: 625-630. [11] PLÖGER D, KRÜGER L, TIMM-GIEL A. Analysis of communication demands of networked control systems for autonomous platooning[C]. 19th International Symposium on “A World of Wireless, Mobile and Multimedia Networks”(WoWMoM). New Jersey: IEEE, 2018: 14-19. [12] FRIIS H T. A note on a simple transmission formula[J]. Proc Ire, 1946, 34(5):254-256. [13] MAHLER K, PASCHALIDIS P C, KORTKE A, et al. Modeling and simulation of small-scale fading for vehicle-to-vehicle communication[C]. Proceedings of the Second IEEE Vehicular Networking Conference. IEEE, 2010:72-77. [14] ANNADURAI C, NAGARAJAN V. Performance analysis for cooperative ad-hoc networks in the presence of correlated nakagami fading[J]. Wireless Personal Communications, 2017, 92(4):1443-1458. [15] SOMMER C, ECKHOFF D, GERMAN R, et al. A computationally inexpensive empirical model of IEEE 802.11p radio shadowing in urban environments[C]. Eighth International Conference on Wireless On-demand Network Systems and Services. IEEE, 2011:84-90. [16] MURRAY T, MURRAY T, COJOCARI M, et al. Measuring the performance of IEEE 802.11p using NS-2 simulator for vehicular networks[C]. IEEE International Conference on Electro/information Technology. IEEE, 2008:498-503.[17] KIOKES G, AMDITIS A, UZUNOGLU N K. Simulation-based performance analysis and improvement of orthogonal frequency division multiplexing-802.11p system for vehicular communications[J]. Intelligent Transport Systems Iet, 2009, 3 (4) :429-436. [18] TCHOUANKEM H, ZINCHENKO T, SCHUMACHER H. Impact of buildings on vehicle-to-vehicle communication at urban intersections[C]. Consumer Communications and Networking Conference. IEEE, 2015:206-212. [19] KRUPANEK B, BOGACZ R. Mathematical model of communication delays in wireless networks[J]. International Journal of Electronics and Telecommunications, 2016, 62(1):61-64. [20] TALIWAL V, JIANG D, MANGOLD H, et al. Empirical determination of channel characteristics for DSRC vehicle-to-vehicle communication[C]. International Workshop on Vehicular Ad Hoc Networks. DBLP, 2004:88-94. |