How to Mine Potentially Popular Items? A Reverse MIPS-based Approach
April 18, 2025 Β· Declared Dead Β· π International Conference on Statistical and Scientific Database Management
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Authors
Daichi Amagata, Kazuyoshi Aoayama, Keito Kido, Sumio Fujita
arXiv ID
2504.13445
Category
cs.DB: Databases
Citations
0
Venue
International Conference on Statistical and Scientific Database Management
Last Checked
4 months ago
Abstract
The $k$-MIPS ($k$ Maximum Inner Product Search) problem has been employed in many fields. Recently, its reverse version, the reverse $k$-MIPS problem, has been proposed. Given an item vector (i.e., query), it retrieves all user vectors such that their $k$-MIPS results contain the item vector. Consider the cardinality of a reverse $k$-MIPS result. A large cardinality means that the item is potentially popular, because it is included in the $k$-MIPS results of many users. This mining is important in recommender systems, market analysis, and new item development. Motivated by this, we formulate a new problem. In this problem, the score of each item is defined as the cardinality of its reverse $k$-MIPS result, and the $N$ items with the highest score are retrieved. A straightforward approach is to compute the scores of all items, but this is clearly prohibitive for large numbers of users and items. We remove this inefficiency issue and propose a fast algorithm for this problem. Because the main bottleneck of the problem is to compute the score of each item, we devise a new upper-bounding technique that is specific to our problem and filters unnecessary score computations. We conduct extensive experiments on real datasets and show the superiority of our algorithm over competitors.
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