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The VLDB Journal

, Volume 27, Issue 4, pp 445–470 | Cite as

Finding the optimal location and keywords in obstructed and unobstructed space

  • Farhana Murtaza Choudhury
  • J. Shane Culpepper
  • Zhifeng Bao
  • Timos Sellis
Regular Paper

Abstract

The problem of optimal location selection based on reverse k nearest neighbor (R \(k\) NN) queries has been extensively studied in spatial databases. In this work, we present a related query, denoted as a Maximized Bichromatic Reverse Spatial Textual k Nearest Neighbor (MaxST) query, that finds an optimal location and a set of keywords for an object so that the object is a \(k\) NN object for as many users as possible. Such a query has many practical applications including advertisements, where the query is to find the location and the text contents to include in an advertisement so that it is relevant to the maximum number of users. The visibility of the advertisements also has an important role in the users’ interests. In this work, we address two instances of the spatial relevance when ranking items: (1) the Euclidean distance and (2) the visibility. We carefully design a series of index structures and approaches to answer the MaxST for both instances. Specifically, we present (1) the Grp-topk approach that requires the computation of the top-k objects for all of the users first and then applies various pruning techniques to find the optimal location and keywords; (2) the Indiv-U approach, where we use similarity estimations to avoid computing the top-k objects of the users that cannot be a final result; and (3) the Index-U approach where we propose a hierarchical index structure over the users to improve pruning. We show that the keyword selection component in MaxST queries is NP-hard and present both approximate and exact solutions for the problem.

Keywords

Spatial–textual query Reverse kNN Efficiency 

Notes

Acknowledgements

This work was supported by the Australian Research Council’s Discovery Projects Scheme (Grants DP140101587, DP170102231, and DP170102726) and Google Faculty Research Award. This work was partially supported by the National Natural Science Foundation of China (NSFC) 91646204. Farhana Choudhury is the recipient of a scholarship from National ICT Australia. We thank Lisi Chen, Gao Cong, Christian S. Jensen, and Dingming Wu for providing the implementation of the IR-tree in [3].

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Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  1. 1.RMIT UniversityMelbourneAustralia
  2. 2.Swinburne University of TechnologyHawthornAustralia

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