Searching Trajectories by Regions of Interest

With the increasing availability of moving-object tracking data, trajectory search is increasingly important. We propose and investigate a novel query type named trajectory search by regions of interest (TSR query). Given an argument set of trajectories, a TSR query takes a set of regions of interest as a parameter and returns the trajectory in the argument set with the highest spatial-density correlation to the query regions. This type of query is useful in many popular applications such as trip planning and recommendation, and location based services in general. TSR query processing faces three challenges: how to model the spatial-density correlation between query regions and data trajectories, how to effectively prune the search space, and how to effectively schedule multiple so-called query sources. To tackle these challenges, a series of new metrics are defined to model spatial-density correlations. An efficient trajectory search algorithm is developed that exploits upper and lower bounds to prune the search space and that adopts a query-source selection strategy, as well as integrates a heuristic search strategy based on priority ranking to schedule multiple query sources. The performance of TSR query processing is studied in extensive experiments based on real and synthetic spatial data.

[1]  B. Yegnanarayana,et al.  Artificial Neural Networks , 2004 .

[2]  Lei Chen,et al.  Robust and fast similarity search for moving object trajectories , 2005, SIGMOD '05.

[3]  Jiajie Xu,et al.  Effective map-matching on the most simplified road network , 2012, SIGSPATIAL/GIS.

[4]  Tetsuji Satoh,et al.  Shape-Based Similarity Query for Trajectory of Mobile Objects , 2003, Mobile Data Management.

[5]  Eamonn Keogh Exact Indexing of Dynamic Time Warping , 2002, VLDB.

[6]  Heng Tao Shen,et al.  Searching trajectories by locations: an efficiency study , 2010, SIGMOD Conference.

[7]  Hua Lu,et al.  Planning unobstructed paths in traffic-aware spatial networks , 2015, GeoInformatica.

[8]  Nicholas Jing Yuan,et al.  Towards efficient search for activity trajectories , 2013, 2013 IEEE 29th International Conference on Data Engineering (ICDE).

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

[10]  Antonin Guttman,et al.  R-trees: a dynamic index structure for spatial searching , 1984, SIGMOD '84.

[11]  Ernesto Damiani,et al.  Guest editorial: large-scale Web virtualized environment , 2015, World Wide Web.

[12]  A. Roli Artificial Neural Networks , 2012, Lecture Notes in Computer Science.

[13]  Panos Kalnis,et al.  Discovery of Path Nearby Clusters in Spatial Networks , 2015, IEEE Transactions on Knowledge and Data Engineering.

[14]  Christian S. Jensen,et al.  Stochastic skyline route planning under time-varying uncertainty , 2014, 2014 IEEE 30th International Conference on Data Engineering.

[15]  Christos Faloutsos,et al.  Efficient Similarity Search In Sequence Databases , 1993, FODO.

[16]  Jiajie Xu,et al.  Popularity-aware spatial keyword search on activity trajectories , 2016, World Wide Web.

[17]  Edsger W. Dijkstra,et al.  A note on two problems in connexion with graphs , 1959, Numerische Mathematik.

[18]  Bradford W. Parkinson,et al.  Global positioning system : theory and applications , 1996 .

[19]  Panos Kalnis,et al.  User oriented trajectory search for trip recommendation , 2012, EDBT '12.

[20]  Jianwen Su,et al.  Shapes based trajectory queries for moving objects , 2005, GIS '05.

[21]  Christian S. Jensen,et al.  EcoMark: evaluating models of vehicular environmental impact , 2012, SIGSPATIAL/GIS.

[22]  Kai Zheng,et al.  PNN query processing on compressed trajectories , 2011, GeoInformatica.

[23]  Dimitrios Gunopulos,et al.  Discovering similar multidimensional trajectories , 2002, Proceedings 18th International Conference on Data Engineering.

[24]  Jiawei Han,et al.  Adaptive Fastest Path Computation on a Road Network: A Traffic Mining Approach , 2007, VLDB.

[25]  Christos Faloutsos,et al.  Efficient retrieval of similar time sequences under time warping , 1998, Proceedings 14th International Conference on Data Engineering.

[26]  Yannis Theodoridis,et al.  Index-based Most Similar Trajectory Search , 2007, 2007 IEEE 23rd International Conference on Data Engineering.

[27]  Panos Kalnis,et al.  Personalized trajectory matching in spatial networks , 2014, The VLDB Journal.

[28]  Nikos Pelekis,et al.  Algorithms for Nearest Neighbor Search on Moving Object Trajectories , 2007, GeoInformatica.

[29]  Panos Kalnis,et al.  Collective Travel Planning in Spatial Networks , 2016, IEEE Transactions on Knowledge and Data Engineering.

[30]  Dieter Pfoser,et al.  On Map-Matching Vehicle Tracking Data , 2005, VLDB.

[31]  Lei Chen,et al.  On The Marriage of Lp-norms and Edit Distance , 2004, VLDB.