On Discovery of Traveling Companions from Streaming Trajectories

The advance of object tracking technologies leads to huge volumes of spatio-temporal data collected in the form of trajectory data stream. In this study, we investigate the problem of discovering object groups that travel together (i.e., traveling companions) from trajectory stream. Such technique has broad applications in the areas of scientific study, transportation management and military surveillance. To discover traveling companions, the monitoring system should cluster the objects of each snapshot and intersect the clustering results to retrieve moving-together objects. Since both clustering and intersection steps involve high computational overhead, the key issue of companion discovery is to improve the algorithm's efficiency. We propose the models of closed companion candidates and smart intersection to accelerate data processing. A new data structure termed traveling buddy is designed to facilitate scalable and flexible companion discovery on trajectory stream. The traveling buddies are micro-groups of objects that are tightly bound together. By only storing the object relationships rather than their spatial coordinates, the buddies can be dynamically maintained along trajectory stream with low cost. Based on traveling buddies, the system can discover companions without accessing the object details. The proposed methods are evaluated with extensive experiments on both real and synthetic datasets. The buddy-based method is an order of magnitude faster than existing methods. It also outperforms other competitors with higher precision and recall in companion discovery.

[1]  Christian S. Jensen,et al.  Discovery of convoys in trajectory databases , 2008, Proc. VLDB Endow..

[2]  Beng Chin Ooi,et al.  Continuous Clustering of Moving Objects , 2007, IEEE Transactions on Knowledge and Data Engineering.

[3]  Cyrus Shahabi,et al.  Accurate Discovery of Valid Convoys from Moving Object Trajectories , 2009, 2009 IEEE International Conference on Data Mining Workshops.

[4]  Marios Hadjieleftheriou,et al.  Time relaxed spatiotemporal trajectory joins , 2005, GIS '05.

[5]  Yunhao Liu,et al.  Mining Frequent Trajectory Patterns for Activity Monitoring Using Radio Frequency Tag Arrays , 2012, IEEE Transactions on Parallel and Distributed Systems.

[6]  Jiawei Han,et al.  Swarm: Mining Relaxed Temporal Moving Object Clusters , 2010, Proc. VLDB Endow..

[7]  Hans-Peter Kriegel,et al.  Incremental Clustering for Mining in a Data Warehousing Environment , 1998, VLDB.

[8]  Padhraic Smyth,et al.  A general probabilistic framework for clustering individuals and objects , 2000, KDD '00.

[9]  Matthew O. Ward,et al.  Neighbor-based pattern detection for windows over streaming data , 2009, EDBT '09.

[10]  Xing Xie,et al.  T-drive: driving directions based on taxi trajectories , 2010, GIS '10.

[11]  Philip S. Yu,et al.  Mining Colossal Frequent Patterns by Core Pattern Fusion , 2007, 2007 IEEE 23rd International Conference on Data Engineering.

[12]  Panos Kalnis,et al.  On Discovering Moving Clusters in Spatio-temporal Data , 2005, SSTD.

[13]  Sariel Har-Peled Clustering Motion , 2004, Discret. Comput. Geom..

[14]  Teofilo F. GONZALEZ,et al.  Clustering to Minimize the Maximum Intercluster Distance , 1985, Theor. Comput. Sci..

[15]  Lars Kulik,et al.  The V*-Diagram: a query-dependent approach to moving KNN queries , 2008, Proc. VLDB Endow..

[16]  Sangkyum Kim,et al.  Tru-Alarm: Trustworthiness Analysis of Sensor Networks in Cyber-Physical Systems , 2010, 2010 IEEE International Conference on Data Mining.

[17]  Jae-Gil Lee,et al.  Trajectory clustering: a partition-and-group framework , 2007, SIGMOD '07.

[18]  Bettina Speckmann,et al.  Efficient detection of motion patterns in spatio-temporal data sets , 2004, GIS '04.

[19]  Yifan Li,et al.  Clustering moving objects , 2004, KDD.

[20]  Padhraic Smyth,et al.  Trajectory clustering with mixtures of regression models , 1999, KDD '99.

[21]  Mong-Li Lee,et al.  Supporting Frequent Updates in R-Trees: A Bottom-Up Approach , 2003, VLDB.

[22]  Hans-Peter Kriegel,et al.  A Density-Based Algorithm for Discovering Clusters in Large Spatial Databases with Noise , 1996, KDD.

[23]  Xing Xie,et al.  Retrieving k-Nearest Neighboring Trajectories by a Set of Point Locations , 2011, SSTD.

[24]  Dino Pedreschi,et al.  Trajectory pattern mining , 2007, KDD '07.

[25]  Jae-Gil Lee,et al.  Traffic Density-Based Discovery of Hot Routes in Road Networks , 2007, SSTD.

[26]  Jian Pei,et al.  Data Mining: Concepts and Techniques, 3rd edition , 2006 .

[27]  Xing Xie,et al.  GeoLife: A Collaborative Social Networking Service among User, Location and Trajectory , 2010, IEEE Data Eng. Bull..

[28]  Jiawei Han,et al.  Data Mining: Concepts and Techniques, Second Edition , 2006, The Morgan Kaufmann series in data management systems.

[29]  Joachim Gudmundsson,et al.  Computing longest duration flocks in trajectory data , 2006, GIS '06.

[30]  Elisa Bertino,et al.  Continuous Intersection Joins Over Moving Objects , 2008, 2008 IEEE 24th International Conference on Data Engineering.

[31]  Joachim Gudmundsson,et al.  Reporting flock patterns , 2006, Comput. Geom..

[32]  Jeffrey Considine,et al.  Spatio-temporal aggregation using sketches , 2004, Proceedings. 20th International Conference on Data Engineering.

[33]  Shashi Shekhar,et al.  A partial join approach for mining co-location patterns , 2004, GIS '04.

[34]  Xuemin Lin,et al.  Clustering Moving Objects for Spatio-temporal Selectivity Estimation , 2004, ADC.