Computing Immutable Regions for Subspace Top-k Queries

Computing Immutable Regions for Subspace Top-k Queries

Given a high-dimensional dataset, a top-k query can be used to shortlist the k tuples that best match the user’s preferences. Typically, these preferences regard a subset of the available dimensions (i.e., attributes) whose relative significance is expressed by user-specified weights. Along with the...

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Bibliographic Details
Main Authors: MOURATIDIS, Kyriakos, PANG, Hwee Hwa
Format: text
Language:English
Published: Institutional Knowledge at Singapore Management University 2013
Subjects:
Corresponding weights
Different domains
High dimensional data
High-dimensional dataset
Preference functions
Pruning techniques
Resource-efficient
User's preferences
Databases and Information Systems
Numerical Analysis and Scientific Computing
Online Access:https://ink.library.smu.edu.sg/sis_research/1624
https://ink.library.smu.edu.sg/context/sis_research/article/2623/viewcontent/p73_mouratidis_pv.pdf
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Institution: Singapore Management University
Language: English
Description
Summary:Given a high-dimensional dataset, a top-k query can be used to shortlist the k tuples that best match the user’s preferences. Typically, these preferences regard a subset of the available dimensions (i.e., attributes) whose relative significance is expressed by user-specified weights. Along with the query result, we propose to compute for each involved dimension the maximal deviation to the corresponding weight for which the query result remains valid. The derived weight ranges, called immutable regions, are useful for performing sensitivity analysis, for finetuning the query weights, etc. In this paper, we focus on top-k queries with linear preference functions over the queried dimensions. We codify the conditions under which changes in a dimension’s weight invalidate the query result, and develop algorithms to compute the immutable regions. In general, this entails the examination of numerous non-result tuples. To reduce processing time, we introduce a pruning technique and a thresholding mechanism that allow the immutable regions to be determined correctly after examining only a small number of non-result tuples. We demonstrate empirically that the two techniques combine well to form a robust and highly resource-efficient algorithm. We verify the generality of our findings using real high- dimensional data from different domains (documents, images, etc) and with different characteristics.

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