信息交通系统中的新兴应用

doi:10.1007/s11390-014-1450-9

Search
Browse by Issue
Fig/Tab
Adv Search

›› 2014,Vol. 29 ›› Issue (4): 562-575.doi: 10.1007/s11390-014-1450-9

• Special Section on Selected Paper from NPC 2011 • 上一篇下一篇

信息交通系统中的新兴应用

Aditya Wagh¹, Student Member, IEEE, Yunfei Hou¹ (侯云飞), Student Member, IEEE, Chunming Qiao¹ (乔春明), Fellow, IEEE, Longfei Zhang¹ (张龙飞), Xu Li¹ (李旭), Adel Sadek², Kevin Hulme³, Changxu Wu⁴ (吴昌旭), Member, IEEE, Hong-Li Xu⁵ (徐宏力), and Liu-Sheng Huang⁵ (黄刘生)

1. Department of Computer Science and Engineering, State University of New York at Buffalo, Buffalo, NY 14260-2000 U.S.A.;
2. Department of Civil, Structural and Environmental Engineering, State University of New York at Buffalo, Buffalo NY 14260-2000, U.S.A.;
3. The New York State Center for Engineering Design and Industrial Innovation, Buffalo, NY 14260, U.S.A.;
4. Department of Industrial and System Engineering, State University of New York at Buffalo, Buffalo NY 14260-2000, U.S.A.;
5. School of Computer Science and Technology, Suzhou Institute for Advanced Study, University of Science and Technology of China, Suzhou 215123, China

出版日期:2014-07-05 发布日期:2014-07-05
作者简介:Aditya Wagh is a Ph.D. student at the Department of Computer Science and Engineering at the State University of New York at Buffalo (SUNY Buffalo). He received his B.S. and M.S. degrees in computer science from the University of Mumbai in 2006 and 2008, respectively. His research is mainly focused on cyber transportation (CTS) and vehicular cyber physical systems (VCPS). Aditya is a student member of the IEEE.
基金资助:
This research was partially supported by the National Science Foundation of USA under Grant No. NSF-CPS-1035733, the Joint Research Fund for Overseas Chinese Scholars and Scholars in Hong Kong and Macao of the National Natural Science Foundation of China under Grant No. 61228207, and the Cisco University Research Program.

Emerging Applications for Cyber Transportation Systems

1. Department of Computer Science and Engineering, State University of New York at Buffalo, Buffalo, NY 14260-2000 U.S.A.;
2. Department of Civil, Structural and Environmental Engineering, State University of New York at Buffalo, Buffalo NY 14260-2000, U.S.A.;
3. The New York State Center for Engineering Design and Industrial Innovation, Buffalo, NY 14260, U.S.A.;
4. Department of Industrial and System Engineering, State University of New York at Buffalo, Buffalo NY 14260-2000, U.S.A.;
5. School of Computer Science and Technology, Suzhou Institute for Advanced Study, University of Science and Technology of China, Suzhou 215123, China

Online:2014-07-05 Published:2014-07-05
About author:Aditya Wagh is a Ph.D. student at the Department of Computer Science and Engineering at the State University of New York at Buffalo (SUNY Buffalo). He received his B.S. and M.S. degrees in computer science from the University of Mumbai in 2006 and 2008, respectively. His research is mainly focused on cyber transportation (CTS) and vehicular cyber physical systems (VCPS). Aditya is a student member of the IEEE.
Supported by:
This research was partially supported by the National Science Foundation of USA under Grant No. NSF-CPS-1035733, the Joint Research Fund for Overseas Chinese Scholars and Scholars in Hong Kong and Macao of the National Natural Science Foundation of China under Grant No. 61228207, and the Cisco University Research Program.

摘要/Abstract

车载网和自动驾驶技术的发展将极大地改变现有的交通系统。本文将介绍和评估CTS （Cyber Transportation System）系统中的一些新兴应用。在设计这些应用时使用了全局性方法，其中考虑了驾驶者，交通系统和通信网络各自的特性。这些应用将会提高驾驶的安全性，同时提供路上的信息娱乐服务。他们还会提高交通的控制和效率，在为旅客提供便利的同时也能吸引来自政府和私人企业的投资，进而促进信息交通系统的发展。

Abstract: Recent advances in connected vehicles and autonomous driving are going to change the face of ground transportation as we know it. This paper describes the design and evaluation of several emerging applications for such a Cyber Transportation System (CTS). These applications have been designed using holistic approaches, which consider the unique roles played by the human drivers, the transportation system, and the communication network. They can improve driver safety and provide on-road infotainment. They can also improve transportation operations and efficiency, thereby benefiting travelers and attracting investment from both government agencies and private businesses to deploy infrastructures and bootstrap the evolutionary process of CTS.

Aditya Wagh, Yunfei Hou, Chunming Qiao, Longfei Zhang, Xu Li, Adel Sadek, Kevin . 信息交通系统中的新兴应用[J]. , 2014, 29(4): 562-575.

Aditya Wagh, Yunfei Hou, Chunming Qiao, Longfei Zhang, Xu Li, Adel Sadek, Kevin Hulme, Changxu Wu, Hong-Li Xu, and Liu-Sheng Huang. Emerging Applications for Cyber Transportation Systems[J]. , 2014, 29(4): 562-575.

参考文献

[1] Slavik M, Mahgoub I. Spatial distribution and channel quality adaptive protocol for multihop wireless broadcast routing in VANET. IEEE Transactions on Mobile Computing, 2013, 12(4): 722-734.

[2] Guo L, Huang S, Sadek A W. An evaluation of likely environmental benefits of a time-dependent green routing system in the greater Buffalo-Niagara region. Journal of Intelligent Transportation Systems: Technology, Planning, and Operations, 2013, 17(1): 18-30.

[3] Barnum D T, Karlaftis M G, Tandon S. Improving the efficiency of metropolitan area transit by joint analysis of its multiple providers. Transportation Research Part E: Logistics and Transportation Review, 2011, 47(6): 1160-1176.

[4] U.S. Department of Transportation. Safety pilot program overview, www.its.dot.gov/safety pilot/spmd.htm, May 2014.

[5] Markoff J. Google cars drive themselves in traffic. The New York Times, October 2010. http://www.nytimes.com/2010/ 10/10/science/10google.html?pagewanted=all, May 2014.

[6] Zhang Y, Wu C, Wan J, Qiao C. Development and validation of warning message utility scale (WMUS). Proceedings of the Human Factors and Ergonomics Society Annual Meeting, 2013, 57(1): 1179-1183.

[7] Farah H, Koutsopoulos H N, Saifuzzaman H et al. Evaluation of the effect of cooperative infrastructure-to-vehicle systems on driver behavior. Transportation Research Part C: Emerging Technologies, 2012, 21(1): 42-56.

[8] Marshall D, Lee J D, Austria R A. Alerts for in-vehicle information systems: Annoyance, urgency, and appropriateness. Human Factors, 2007, 49(1): 145-157.

[9] Jamson A H, Merat N. Surrogate in-vehicle information systems and driver behavior: Effects of visual and cognitive load in rural driving. Transportation Research Part F: Traffic Psychology and Behaviour, 2005, 8(2): 79-96.

[10] Donmez B, Boyle L N, Lee J D. The impact of distraction mitigation strategies on driving performance. Human Factors, 2006, 48(4): 785-804.

[11] Verwey W B. On-line driver workload estimation: Effects of road situation and age on secondary task measures. Ergonomics, 2000, 43(2): 187-209.

[12] SAE International. Its in-vehicle message priority. Standard, J2395, 2002. http://subscriptions.sae.org/content/j2395 200202, May 2014.

[13] Sohn H, Lee J D, Bricker D L et al. A dynamic programming algorithm for scheduling in-vehicle messages. IEEE Trans. Intelligent Transportation Systems, 2008, 9(2): 226-234.

[14] Wu C, Liu Y. Queuing network modeling of driver workload and performance. IEEE Trans. Intelligent Transportation Systems, 2007, 8(3): 528-537.

[15] Li X, Yu X, Wagh A, Qiao C. Human factors-aware service scheduling in vehicular cyber-physical systems. In Proc. IEEE International Conference on Computer Communications, April 2011, pp.2174-2182.

[16] Guo M, Ammar M H, Zegura E W. V3: A vehicle-to-vehicle live video streaming architecture. In Proc. the 3rd Int. Conf. Pervasive Computing and Communications, March 2005, pp.171-180.

[17] Yoon S, Ha D T, Ngo H Q, Qiao C. MoPADS: A mobility profile aided file downloading service in vehicular networks. IEEE Trans. Vehicular Technology, 2009, 58(9): 5235-5246.

[18] Chu Y, Huang N. Delivering of live video streaming for vehicular communication using peer-to-peer approach. In Proc. Mobile Networking for Vehicular Environments, May 2007, pp.16.

[19] Cheng H T, Shan H, Zhuang W. Infotainment and road safety service support in vehicular networking: From a communication perspective. Mechanical Systems and Signal Processing, 2011, 25(6): 2020-2038.

[20] Bucciol P, Masala E, Kawaguchi N, Takeda K, De Martin J. Performance evaluation of H. 264 video streaming over intervehicular 802.11 ad hoc networks. In Proc. the 16th Int. Symp. Personal, Indoor and Mobile Radio Communications, Sept. 2005, pp.1936-1940.

[21] Xue J, Chen C W. A new perceptual quality metric for video transrating for mobile devices. In Proc. the 2010 ACM Multimedia Workshop on Mobile Cloud Media Computing, Oct. 2010, pp.35-40.

[22] Song W, Tjondronegoro D W, Wang S et al. Impact of zooming and enhancing region of interests for optimizing user experience on mobile sports video. In Proc. the 18th ACM Int. Conf. Multimedia, Oct. 2010, pp.321-330.

[23] Dobrian F, Sekar V, Awan A et al. Understanding the impact of video quality on user engagement. In Proc. the ACM SIGCOMM Conference, Aug. 2011, pp.362-373.

[24] Tan W L, Lau W C, Yue O, Hui T H. Analytical models and performance evaluation of drive-thru internet systems. IEEE Journal on Selected Areas in Communications, 2011, 29(1): 207-222.

[25] He K, Li X, Schick B, Qiao C, Sudhaakar R, Addepalli S, Chen X. On-road video delivery with integrated heterogeneous wireless networks. Ad Hoc Networks, 2013, 11(7): 1992-2001.

[26] Morwitza V G, Steckela J H, Guptab A. When do purchase intentions predict sales? International Journal of Forecasting, 2007, 23(3): 347-364.

[27] Sun B, Morwitz V G. Stated intentions and purchase behavior: A unified model. International Journal of Research in Marketing, 2010, 27(4): 356-366.

[28] Goldfarb A, Tucker C. Online advertising. Advances in Computers, 2011, 81: 289-315.

[29] Liu N, Liu M, Cao J et al. When transportation meets communication: V2P over VANETs. In Proc. the 30th IEEE Int. Conf. Distributed Computing Systems, Jun. 2010, pp.567-576.

[30] Deshpande P, Kashyap A, Sung C, Das S R. Predictive methods for improved vehicular WiFi access. In Proc. the 7th International Conference on Mobile Systems, Applications, and Services, June 2009, pp.263-276.

[31] Ge Y, Liu C, Xiong H, Chen J. A taxi business intelligence system. In Proc. the 17th ACM SIGKDD Int. Conf. Knowledge Discovery and Data Mining, Aug. 2011, pp.735-738.

[32] Yuan J, Zheng Y, Zhang C et al. T-drive: Driving directions based on taxi trajectories. In Proc. the 18th SIGSPATIAL Int. Conf. Advances in Geographic Information Systems, Nov. 2010, pp.99-108.

[33] Seow K T, Dang N H, Lee D. A collaborative multiagent taxi-dispatch system. IEEE Trans. Automation Science and Engineering, 2010, 7(3): 607-616.

[34] Alshamsi A, Abdallah S, Rahwan I. Multiagent selforganization for a taxi dispatch system. In Proc. the 8th Int. Conf. Autonomous Agents and Multiagent Systems, May 2009, pp.21-28.

[35] Hou Y, Li X, Zhao Y et al. Towards efficient vacant taxis cruising guidance. In Proc. IEEE Global Communications Conference, Dec. 2013.

[36] Zhang D, Li Y, Zhang F, Lu M, Liu Y, He T. coRide: Carpool service with a win-win fare model for large-scale taxicab networks. In Proc. the 11th ACM Conference on Embedded Networked Sensor Systems, Nov. 2013, Article No.9.

[37] Chen P, Liu J, Chen W. A fuel-saving and pollution-reducing dynamic taxi-sharing protocol in VANETs. In Proc. the 72nd IEEE Vehicular Technology Conference Fall, Sept. 2010, pp.1-5.

[38] Chen C, Shallcross D, Shih Y et al. Smart ride share with flexible route matching. In Proc. the 13th Int. Conf. Advanced Communication Technology, Feb. 2011, pp.1506-1510.

[39] Hou Y, Li X, Qiao C. TicTac: From transfer-incapable carpooling to transfer-allowed carpooling. In Proc. IEEE Global Communications Conference, Dec. 2012, pp. 268-273.

[40] Zhao Y, Wagh A, Hulme K et al. Integrated traffic-drivingnetworking simulator: A unique R&D tool for connected vehicles. In Proc. Int. Conf. Connected Vehicles and Expo, Dec. 2012, pp.203-204.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

信息交通系统中的新兴应用

Emerging Applications for Cyber Transportation Systems

PDF (PC)

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

Metrics

本文评价

推荐阅读 10