未來工作

在本論文實驗模擬中證明藉由可應變式的接手節點挑選機制的好處，未來研 究也期望透過改善接手節點尋找範圍之角度，減少接手節點尋找時間，並減少控 制訊息成本。另外，對於 QoS 需求的評估項目，例如：資料封包生產量、Jitter 等實驗項目，皆是值得繼續研究的議題，以期可更深入了解本論文提出之研究方

62

法的特性，若能改善上述影響之因素，相信能使本論文成果更臻完善。

63

參考文獻

[1] T. Yasser, M. Paul, L. Anis, and D. L. F. Arnaud, “Vehicle Ad Hoc Networks-Applications and Related Technical Issues,” IEEE Communications Surveys & Tutorials magazine, vol. 10, no. 3, pp. 74-88, 2008.

[2] L. S. Mihail, and K. Maria, “Inter-Vehicle Communication Systems：A Survey,”

IEEE Communications Surveys & Tutorials Magazine, vol. 10, no. 2, pp.

88-105, 2008.

[3] 802.11p, Available at

http://grouper.ieee.org/groups/802/11/Reports/tgp_update.htm

[4] R. Mangharam, J. Meyers, R. Rajkumar, D. Stancil, J. Parikh, H. Krishnan, and C. Kellum, “A Multi-Hop Mobile Networking Test-Bed for Telematics,”

Proceedings of Society for Automotive Engineers (SAE) World Congress.

Detroit, USA. Apr. 2005.

[5] W. Sun, H. Y. chi, K. Yukimasa., and S. Kusumoto, “GvGrid：A Qos Routing Protocol for Vehicular Ad Hoc Networks,” Proceedings of IWQoS 14th IEEE International Workshop, pp. 130-139, Jun. 2006.

[6] R. B. Kalivaradhan, and A. Thangavelu, “A Simulated Modeling Approach towards Providing Adaptive QoS for Vehicular Safety Services over VANET,”

International Journal of Research and Reviews in Computer Science, vol. 1, no.

4, pp. 110, Dec. 2010.

[7] Z. Niu, W. Yao, Q. Ni, and Y. Song, “DeReQ：A Qos Routing Algorithm for Multimedia Communications in Vehicular Ad Hoc Networks,” Proceedings of the Wireless Communications and Mobile Computing, New York, USA, pp.

393-398, 2007.

64

[8] S. Yousefi, S. Bastani, and M. Fathy, “On the Performance of Safety Message Dissemination in Vehicular Ad Hoc Networks,” Proceedings of 4th European Conference on Universal Multiservice Networks ECUMN, Toulouse, France, pp.

377-390, 2007.

[9] M. Boban, G. Misek, and O. Tonguz, “What Is the Best Achievable QoS for Unicast Routing in VANETs?” Proceedings of the 3rd IEEE Workshop on Automotive Networking and Applications, pp. 1-10, Nov. 30-Dec. 4, 2008.

[10] Z. Niu, W. Yao, Q. Ni, and Y. Song, “Link Reliability Model for Vehicle Ad Hoc Network,” London Communications Symposium (LCS06), UCL, London, Sept.

14-15, 2006.

[11] J. Liu, and V. Issarny, “QoS-Aware Service Location in Mobile Ad Hoc Networks,” Proceedings of the 5th IEEE International Conference on Mobile Data Management, Berkeley, pp. 224-235, 2004.

[12] B. N. Park, W. Lee, and C. Lee, “QoS-Aware Internet Access Schemes for Wireless Mobile Ad Hoc Networks,” Computer Communications, vol. 30, no. 2, pp. 369-384, 2007.

[13] A. Agbaria, G. Gershinsky, N. Naaman, and K. Shagin, “Extrapolation-Based and QoS-Aware Real-Time Communication in Wireless Mobile Ad Hoc Networks,” Proceedings of 8th IFIP Annual Mediterranean, pp. 21-26, 2009.

[14] S. H. Shah, and K. Nahrstedt, “Guaranteeing Throughput for Real Time Traffic in Multi-hop IEEE 802.11 Wireless Networks,” Proceedings of IEEE International Conference on Military Communication, Atlantic City, NJ, pp.

21-26, Oct. 2005.

[15] S. H. Shah, and K. Nahrstedt, “Predictive Location-Based QoS Routing in

65

Mobile Ad Hoc Networks,” Proceedings of IEEE International Conference on Communications, New York, Apr. 2002.

[16] K. Abrougui, A. Boukerche, and S. Samarah, “Design and Performance Evaluation of QoS Aware and Location Based Service Discovery Protocol for Vehicular Networks,” Proceedings of the 13th ACM international conference on Modeling, Analysis, and Simulation of Wireless and Mobile Systems, pp. 73-80, Oct. 17-21, 2010.

[17] C. J. Huang, Y. T. Chuang, Y. J. Chen, D. X. Yang, and I. F. Chen, “QoS-Aware Roadside Base Station Assisted Routing in Vehicular Networks,” The Engineering Applications of Artificial Intelligence, NY, USA, pp. 1292-1301, Dec. 2009.

[18] C. J. Huang, Y. T. Chuang, and D. X. Yang, “An Adaptive QoS-Aware Roadside Base Station Assisted Routing in Vehicular Networks,” Proceedings of 2007 Taiwan Academic Network Conference, pp. 386-391, Oct. 2007

[19] T. A. Ramrekha, and C. Politis, “An Adaptive QoS Routing Solution for MANET Based Multimedia Communications in Emergency Cases,”

Proceedings of 1st ICST International Conference on Mobile Lightweight Wireless Systems (MobiLight), May 18-20, Athens, Greece., 2009.

[20] M. Chegin, and M. Fathy, “Optimized Routing Based on Mobility Prediction in Wireless Mobile Ad hoc Networks for Urban Area,” Proceedings of Information Technology：New Generations, Fifth International Conference on, pp. 390-395, 2008.

[21] H. Menouar, F. Filali, and M. Lenardi., “Movement Prediction-Based Routing (MOPR) Concept for Position-Based Routing in Vehicular Networks,”

66

Proceedings of IEEE International Conference on Vehicular Technology Conference., Baltimore, MD, USA, Sept. 2007.

[22] N. N. Saneiah Kamaruzaman, and H. Hasbullah, “Silent Alarm ： Path Optimization Route Lifetime for VANET Multi-Hop Routing Protocol,”

Proceedings of NETAPPS'2009, Nov. 2008.

[23] Y. C. Wei, Y. M. Chen, and H. L. Shan, “RSSI-Based User Centric Anonymization for Location Privacy in Vehicular Networks,” Security in Emerging Wireless Communication and Networking Systems, Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering 42, pp. 39-51, 2010.

[24] W. S. Choi, J. W. Nam, and S. G. Choi, “Hop State Prediction Method Using Distance Differential of RSSI on VANET,” Proceedings of Networked Computing and Advanced Information Management, Fourth International Conference on, pp. 426-431, 2008.

[25] K. Balachandran, S. Nanda, and S. R. Kadaba, “Channel Quality Estimation and Rate Adaptation for Cellular Mobile Radio,” IEEE Journal on Selected Areas in Communications, vol. 17, no. 7, pp. 1244-1256, Jul. 1999.

[26] R. Meireles, M. Boban, P. Steenkiste, O. Tonguz, and J. Barros, “Experimental Study on the Impact of Vehicular Obstructions in VANETs,” Proceedings of 2nd IEEE Vehicular Networking Conference, VNC 2010.

[27] C. Perkins, E. Belding-Royer, and S. Das, “Ad Hoc On-Demand Distance Vector (AODV) Routing,” Network Working Group, RFC 3561, Jul. 2003.

[28] B. Karp and H. T. Kung., “GPSR:Greedy Perimeter Stateless Routing for Wireless Networks,” Proceedings of the ACM/IEEE International Conference

67

on Mobile Computing and Networking, pp. 243-254, Boston, Mass., USA, Aug.

2000.

[29] J. Gong, C. Z. Xu and J. Holle, “Predictive Directional Greedy Routing in Vehicular Ad hoc Networks,” Proceedings of the 27th International Conference on Distributed Computing Systems Workshops, 2007.

[30] W. Su, S. Lee, and M. Gerla., “Mobility Prediction and Routing in Ad Hoc Wireless Networks,” International Journal of Network Management, vol. 11, no.

1, pp. 3-30, Jan. 2001.

[31] L. Loyola, H. S. Lichte, I. Aad, J. Widmer and S. Valentin., “Increasing the Capacity of IEEE 802.11 Wireless LAN through Cooperative Coded Retransmissions,” Proceedings of the IEEE Vehicular Technology Conference, pp. 1746-1750, May 2008.

[32] The Network Simulator (NS-2), http://www.isi.edu/nsnam/ns, release 2.1b9a, Jul. 2002.

[33] F. Bai, N. Sadagopan, and A. Helmy, “IMPORTANT ： A Framework to Systematically Analyze the Impact of Mobility on Performance of RouTing Protocols for Adhoc NeTworks,” Proceedings of IEEE INFOCOM, vol. 2, pp.

825-835, 2003.