Trajectory Improves Data Delivery in Urban Vehicular Networks

Efficient data delivery is of great importance, but highly challenging for vehicular networks because of frequent network disruption, fast topological change and mobility uncertainty. The vehicular trajectory knowledge plays a key role in data delivery. Existing algorithms have largely made predictions on the trajectory with coarse-grained patterns such as spatial distribution or/and the inter-meeting time distribution, which has led to poor data delivery performance. In this paper, we mine the extensive data sets of vehicular traces from two large cities in China, i.e., Shanghai and Shenzhen, through conditional entropy analysis, we find that there exists strong spatiotemporal regularity with vehicle mobility. By extracting mobility patterns from historical vehicular traces, we develop accurate trajectory predictions by using multiple order Markov chains. Based on an analytical model, we theoretically derive packet delivery probability with predicted trajectories. We then propose routing algorithms taking full advantage of predicted probabilistic vehicular trajectories. Finally, we carry out extensive simulations based on three large data sets of real GPS vehicular traces, i.e., Shanghai taxi data set, Shanghai bus data set and Shenzhen taxi data set. The conclusive results demonstrate that our proposed routing algorithms can achieve significantly higher delivery ratio at lower cost when compared with existing algorithms.

[1]  Cecilia Mascolo,et al.  Extending Access Point Connectivity through Opportunistic Routing in Vehicular Networks , 2010, 2010 Proceedings IEEE INFOCOM.

[2]  Yunhao Liu,et al.  Exploiting Ubiquitous Data Collection for Mobile Users in Wireless Sensor Networks , 2013, IEEE Transactions on Parallel and Distributed Systems.

[3]  Jaehoon Jeong,et al.  TBD: Trajectory-Based Data Forwarding for Light-Traffic Vehicular Networks , 2009, 2009 29th IEEE International Conference on Distributed Computing Systems.

[4]  Timur Friedman,et al.  DTN routing in a mobility pattern space , 2005, WDTN '05.

[5]  H. T. Kung,et al.  Ad hoc relay wireless networks over moving vehicles on highways , 2001, MobiHoc '01.

[6]  Fan Bai,et al.  Toward understanding characteristics of dedicated short range communications (DSRC) from a perspective of vehicular network engineers , 2010, MobiCom.

[7]  Eric Horvitz,et al.  Predestination: Where Do You Want to Go Today? , 2007, Computer.

[8]  Brian Gallagher,et al.  MaxProp: Routing for Vehicle-Based Disruption-Tolerant Networks , 2006, Proceedings IEEE INFOCOM 2006. 25TH IEEE International Conference on Computer Communications.

[9]  Arun Venkataramani,et al.  DTN routing as a resource allocation problem , 2007, SIGCOMM '07.

[10]  Alexandre Proutière,et al.  Complexity in wireless scheduling: impact and tradeoffs , 2008, MobiHoc '08.

[11]  Minglu Li,et al.  Compressive Sensing Approach to Urban Traffic Sensing , 2011, 2011 31st International Conference on Distributed Computing Systems.

[12]  Srinivasan Seshan,et al.  IrisNet: An Architecture for a Worldwide Sensor Web , 2003, IEEE Pervasive Comput..

[13]  Marco Roccetti,et al.  Efficient vehicle-to-pedestrian exchange of medical data: an empirical model with preliminary results , 2011, MobileHealth '11.

[14]  Ryan Newton,et al.  The pothole patrol: using a mobile sensor network for road surface monitoring , 2008, MobiSys '08.

[15]  Vijay Erramilli,et al.  Delegation forwarding , 2008, MobiHoc '08.

[16]  Paolo Bellavista,et al.  Mobeyes: smart mobs for urban monitoring with a vehicular sensor network , 2006, IEEE Wireless Communications.

[17]  Nahid Shahmehri,et al.  A peer-to-peer approach to vehicular communication for the support of traffic safety applications , 2002, Proceedings. The IEEE 5th International Conference on Intelligent Transportation Systems.

[18]  Amarsinh Vidhate,et al.  Routing in Delay Tolerant Network , 2016 .

[19]  Cecilia Mascolo,et al.  GeOpps: Geographical Opportunistic Routing for Vehicular Networks , 2007, 2007 IEEE International Symposium on a World of Wireless, Mobile and Multimedia Networks.

[20]  Lionel M. Ni,et al.  SEER: Metropolitan-Scale Traffic Perception Based on Lossy Sensory Data , 2009, IEEE INFOCOM 2009.

[21]  Yunhao Liu,et al.  Rendered Path: Range-Free Localization in Anisotropic Sensor Networks With Holes , 2007, IEEE/ACM Transactions on Networking.

[22]  Injong Rhee,et al.  Max-Contribution: On Optimal Resource Allocation in Delay Tolerant Networks , 2010, 2010 Proceedings IEEE INFOCOM.

[23]  Richard E. Hansen,et al.  Prioritized epidemic routing for opportunistic networks , 2007, MobiOpp '07.