TMS-RFID: Temporal management of large-scale RFID applications

In coming years, there will be billions of RFID tags living in the world tagging almost everything for tracking and identification purposes. This phenomenon will impose a new challenge not only to the network capacity but also to the scalability of event processing of RFID applications. Since most RFID applications are time sensitive, we propose a notion of Time To Live (TTL), representing the period of time that an RFID event can legally live in an RFID data management system, to manage various temporal event patterns. TTL is critical in the “Internet of Things” for handling a tremendous amount of partial event-tracking results. Also, TTL can be used to provide prompt responses to time-critical events so that the RFID data streams can be handled timely. We divide TTL into four categories according to the general event-handling patterns. Moreover, to extract event sequence from an unordered event stream correctly and handle TTL constrained event sequence effectively, we design a new data structure, namely Double Level Sequence Instance List (DLSIList), to record intermediate stages of event sequences. On the basis of this, an RFID data management system, namely Temporal Management System over RFID data streams (TMS-RFID), has been developed. This system can be constructed as a stand-alone middleware component to manage temporal event patterns. We demonstrate the effectiveness of TMS-RFID on extracting complex temporal event patterns through a detailed performance study using a range of high-speed data streams and various queries. The results show that TMS-RFID has a very high throughput, namely 170,000–870,000 events per second for different highly complex continuous queries. Moreover, the experiments also show that the main structure to record the intermediate stages in TMS-RFID does not increase exponentially with the number of events. These results demonstrate that TMS-RFID not only supports high processing speeds, but is also highly scalable.

[1]  Narain H. Gehani,et al.  Composite Event Specification in Active Databases: Model & Implementation , 1992, VLDB.

[2]  Hendrik Segers,et al.  Composite event specification in active databases: model and implementation , 1992 .

[3]  Sharma Chakravarthy,et al.  Composite Events for Active Databases: Semantics, Contexts and Detection , 1994, VLDB.

[4]  Morris Sloman,et al.  GEM: a generalized event monitoring language for distributed systems , 1997, Distributed Syst. Eng..

[5]  Guangtian Liu,et al.  A unified approach for specifying timing constraints and composite events in active real-time database systems , 1998, Proceedings. Fourth IEEE Real-Time Technology and Applications Symposium (Cat. No.98TB100245).

[6]  Rainer Unland,et al.  On the semantics of complex events in active database management systems , 1999, Proceedings 15th International Conference on Data Engineering (Cat. No.99CB36337).

[7]  Sudarshan S. Chawathe,et al.  Managing RFID Data , 2004, VLDB.

[8]  Jennifer Widom,et al.  Flexible time management in data stream systems , 2004, PODS.

[9]  Martha Palmer Seven Principles of Effective RFID Data Management , 2004 .

[10]  Michael J. Franklin,et al.  Events on the edge , 2005, SIGMOD '05.

[11]  J. Landt,et al.  The history of RFID , 2005, IEEE Potentials.

[12]  Frederick Reiss,et al.  Design Considerations for High Fan-In Systems: The HiFi Approach , 2005, CIDR.

[13]  Fusheng Wang,et al.  Temporal Management of RFID Data , 2005, VLDB.

[14]  Johannes Gehrke,et al.  Towards Expressive Publish/Subscribe Systems , 2006, EDBT.

[15]  Yanlei Diao,et al.  High-performance complex event processing over streams , 2006, SIGMOD Conference.

[16]  Fusheng Wang,et al.  Bridging Physical and Virtual Worlds: Complex Event Processing for RFID Data Streams , 2006, EDBT.

[17]  Fusheng Wang,et al.  RFID Data Processing with a Data Stream Query Language , 2007, 2007 IEEE 23rd International Conference on Data Engineering.

[18]  Johannes Gehrke,et al.  Cayuga: a high-performance event processing engine , 2007, SIGMOD '07.

[19]  Sherali Zeadally,et al.  Enabling Next-Generation RFID Applications: Solutions and Challenges , 2008, Computer.