NetNCSP: Nonoverlapping closed sequential pattern mining

Sequential pattern mining (SPM) has been applied in many fields. However, traditional SPM neglects the pattern repetition in sequence. To solve this problem, gap constraint SPM was proposed and can avoid finding too many useless patterns. Nonoverlapping SPM, as a branch of gap constraint SPM, means...

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Bibliographic Details
Published in:Knowledge-based systems 2020-05, Vol.196, p.105812-105812, Article 105812
Main Authors: Wu, Youxi, Zhu, Changrui, Li, Yan, Guo, Lei, Wu, Xindong
Format: Article
Language:English
Subjects:
Algorithms
Closed pattern mining
Compressibility
COVID-19
Data mining
Mathematical analysis
Mining
Nettree
Nonoverlapping sequence pattern
Pattern analysis
Periodic wildcard gaps
Redundancy
Sequential pattern mining
Severe acute respiratory syndrome coronavirus 2
Viruses
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Summary:Sequential pattern mining (SPM) has been applied in many fields. However, traditional SPM neglects the pattern repetition in sequence. To solve this problem, gap constraint SPM was proposed and can avoid finding too many useless patterns. Nonoverlapping SPM, as a branch of gap constraint SPM, means that any two occurrences cannot use the same sequence letter in the same position as the occurrences. Nonoverlapping SPM can make a balance between efficiency and completeness. The frequent patterns discovered by existing methods normally contain redundant patterns. To reduce redundant patterns and improve the mining performance, this paper adopts the closed pattern mining strategy and proposes a complete algorithm, named Nettree for Nonoverlapping Closed Sequential Pattern (NetNCSP) based on the Nettree structure. NetNCSP is equipped with two key steps, support calculation and closeness determination. A backtracking strategy is employed to calculate the nonoverlapping support of a pattern on the corresponding Nettree, which reduces the time complexity. This paper also proposes three kinds of pruning strategies, inheriting, predicting, and determining. These pruning strategies are able to find the redundant patterns effectively since the strategies can predict the frequency and closeness of the patterns before the generation of the candidate patterns. Experimental results show that NetNCSP is not only more efficient but can also discover more closed patterns with good compressibility. Furtherly, in biological experiments NetNCSP mines the closed patterns in SARS-CoV-2 and SARS viruses. The results show that the two viruses are of similar pattern composition with different combinations.
ISSN:0950-7051
1872-7409
DOI:10.1016/j.knosys.2020.105812