A Geometric Approach to Monitoring Threshold Functions over Distributed Data Streams

Monitoring data streams in a distributed system is the focus of much research in recent years. Most of the proposed schemes, however, deal with monitoring simple aggregated values, such as the frequency of appearance of items in the streams. More involved challenges, such as the important task of feature selection (e.g., by monitoring the information gain of various features), still require very high communication overhead using naive, centralized algorithms. We present a novel geometric approach by which an arbitrary global monitoring task can be split into a set of constraints applied locally on each of the streams. The constraints are used to locally filter out data increments that do not affect the monitoring outcome, thus avoiding unnecessary communication. As a result, our approach enables monitoring of arbitrary threshold functions over distributed data streams in an efficient manner. We present experimental results on real-world data which demonstrate that our algorithms are highly scalable, and considerably reduce communication load in comparison to centralized algorithms.

[1]  Samuel Madden,et al.  Continuously adaptive continuous queries over streams , 2002, SIGMOD '02.

[2]  Christopher Olston,et al.  Finding (recently) frequent items in distributed data streams , 2005, 21st International Conference on Data Engineering (ICDE'05).

[3]  Dennis Shasha,et al.  StatStream: Statistical Monitoring of Thousands of Data Streams in Real Time , 2002, VLDB.

[4]  Samuel Madden,et al.  Fjording the stream: an architecture for queries over streaming sensor data , 2002, Proceedings 18th International Conference on Data Engineering.

[5]  Calton Pu,et al.  Continual Queries for Internet Scale Event-Driven Information Delivery , 1999, IEEE Trans. Knowl. Data Eng..

[6]  Yiming Yang,et al.  RCV1: A New Benchmark Collection for Text Categorization Research , 2004, J. Mach. Learn. Res..

[7]  Noga Alon,et al.  The space complexity of approximating the frequency moments , 1996, STOC '96.

[8]  Christos Faloutsos,et al.  Online data mining for co-evolving time sequences , 2000, Proceedings of 16th International Conference on Data Engineering (Cat. No.00CB37073).

[9]  Jennifer Widom,et al.  Models and issues in data stream systems , 2002, PODS.

[10]  Jennifer Widom,et al.  Query Processing, Resource Management, and Approximation ina Data Stream Management System , 2002 .

[11]  Graham Cormode,et al.  Holistic aggregates in a networked world: distributed tracking of approximate quantiles , 2005, SIGMOD '05.

[12]  Jennifer Widom,et al.  Continuous queries over data streams , 2001, SGMD.

[13]  Danny Raz,et al.  Efficient reactive monitoring , 2002, IEEE J. Sel. Areas Commun..

[14]  Douglas B. Terry,et al.  Continuous queries over append-only databases , 1992, SIGMOD '92.

[15]  Ambuj K. Singh,et al.  Distributed data streams indexing using content-based routing paradigm , 2005, 19th IEEE International Parallel and Distributed Processing Symposium.