Efficient Representative Subset Selection over Sliding Windows

Representative subset selection (RSS) is an important tool for users to draw insights from massive datasets. Existing literature models RSS as the submodular maximization problem to capture the “diminishing returns” property of the representativeness of selected subsets, but often only has a single...

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Bibliographic Details
Published inIEEE transactions on knowledge and data engineering Vol. 31; no. 7; pp. 1327 - 1340
Main Authors Wang, Yanhao, Li, Yuchen, Tan, Kian-Lee
Format Journal Article
LanguageEnglish
Published New York IEEE 01.07.2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
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Summary:Representative subset selection (RSS) is an important tool for users to draw insights from massive datasets. Existing literature models RSS as the submodular maximization problem to capture the “diminishing returns” property of the representativeness of selected subsets, but often only has a single constraint (e.g., cardinality), which limits its applications in many real-world problems. To capture the data recency issue and support different types of constraints, we formulate dynamic RSS in data streams as maximizing submodular functions subject to general dd-knapsack constraints (SMDK) over sliding windows. We propose a KnapWindow framework (KW) for SMDK. KW utilizes the KnapStream algorithm (KS) for SMDK in append-only streams as a subroutine. It maintains a sequence of checkpoints and KS instances over the sliding window. Theoretically, KW is \frac{1-\varepsilon }{1+d}1-ɛ1+d-approximate for SMDK. Furthermore, we propose a KnapWindowPlus framework (KW^{+}+) to improve upon KW. KW^{+}+ builds an index SubKnapChk to manage the checkpoints and KS instances. SubKnapChk deletes a checkpoint whenever it can be approximated by its successors. By keeping much fewer checkpoints, KW^{+}+ achieves higher efficiency than KW while still guaranteeing a \frac{1-\varepsilon ^{\prime }}{2+2d}1-ɛ'2+2d-approximate solution for SMDK. Finally, we evaluate the efficiency and solution quality of KW and KW^{+}+ in real-world datasets. The experimental results demonstrate that KW achieves more than two orders of magnitude speedups over the batch baseline and preserves high-quality solutions for SMDK over sliding windows. KW^{+}+ further runs 5-10 times faster than KW while providing solutions with equivalent or even better utilities.
ISSN:1041-4347
1558-2191
DOI:10.1109/TKDE.2018.2854182