A false negative approach to mining frequent itemsets from high speed transactional data streams

Mining frequent itemsets from transactional data streams is challenging due to the nature of the exponential explosion of itemsets and the limit memory space required for mining frequent itemsets. Given a domain of I unique items, the possible number of itemsets can be up to 2^I-1. When the length of data streams approaches to a very large number N, the possibility of an itemset to be frequent becomes larger and difficult to track with limited memory. The existing studies on finding frequent items from high speed data streams are false-positive oriented. That is, they control memory consumption in the counting processes by an error parameter @e, and allow items with support below the specified minimum support s but above [email protected] counted as frequent ones. However, such false-positive oriented approaches cannot be effectively applied to frequent itemsets mining for two reasons. First, false-positive items found increase the number of false-positive frequent itemsets exponentially. Second, minimization of the number of false-positive items found, by using a small @e, will make memory consumption large. Therefore, such approaches may make the problem computationally intractable with bounded memory consumption. In this paper, we developed algorithms that can effectively mine frequent item(set)s from high speed transactional data streams with a bound of memory consumption. Our algorithms are based on Chernoff bound in which we use a running error parameter to prune item(set)s and use a reliability parameter to control memory. While our algorithms are false-negative oriented, that is, certain frequent itemsets may not appear in the results, the number of false-negative itemsets can be controlled by a predefined parameter so that desired recall rate of frequent itemsets can be guaranteed. Our extensive experimental studies show that the proposed algorithms have high accuracy, require less memory, and consume less CPU time. They significantly outperform the existing false-positive algorithms.

[1]  Mahesh Viswanathan,et al.  An Approximate L1-Difference Algorithm for Massive Data Streams , 2002, SIAM J. Comput..

[2]  Yossi Matias,et al.  Spectral bloom filters , 2003, SIGMOD '03.

[3]  H. Chernoff A Measure of Asymptotic Efficiency for Tests of a Hypothesis Based on the sum of Observations , 1952 .

[4]  Rajeev Motwani,et al.  Approximate Frequency Counts over Data Streams , 2012, VLDB.

[5]  Hannu Toivonen,et al.  Sampling Large Databases for Association Rules , 1996, VLDB.

[6]  Moses Charikar,et al.  Finding frequent items in data streams , 2002, Theor. Comput. Sci..

[7]  Piotr Indyk,et al.  Maintaining stream statistics over sliding windows: (extended abstract) , 2002, SODA '02.

[8]  Piotr Indyk,et al.  Maintaining Stream Statistics over Sliding Windows , 2002, SIAM J. Comput..

[9]  Marianne Durand,et al.  A Probabilistic Counting Algorithm , 2005 .

[10]  Hongjun Lu,et al.  False Positive or False Negative: Mining Frequent Itemsets from High Speed Transactional Data Streams , 2004, VLDB.

[11]  Ramakrishnan Srikant,et al.  Fast Algorithms for Mining Association Rules in Large Databases , 1994, VLDB.

[12]  Graham Cormode,et al.  What's hot and what's not: tracking most frequent items dynamically , 2003, TODS.

[13]  Jessica H. Fong,et al.  An Approximate Lp Difference Algorithm for Massive Data Streams , 1999, Discret. Math. Theor. Comput. Sci..

[14]  Philippe Flajolet,et al.  Probabilistic Counting Algorithms for Data Base Applications , 1985, J. Comput. Syst. Sci..

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

[16]  Johannes Gehrke,et al.  Querying and mining data streams: you only get one look a tutorial , 2002, SIGMOD '02.

[17]  Rakesh Agarwal,et al.  Fast Algorithms for Mining Association Rules , 1994, VLDB 1994.

[18]  Erik D. Demaine,et al.  Frequency Estimation of Internet Packet Streams with Limited Space , 2002, ESA.

[19]  Jeffrey Scott Vitter,et al.  Random sampling with a reservoir , 1985, TOMS.