research-article

Learning expressive linkage rules using genetic programming

Authors:

Christian BizerAuthors Info & Claims

Proceedings of the VLDB Endowment, Volume 5, Issue 11

Pages 1638 - 1649

https://doi.org/10.14778/2350229.2350276

Published: 01 July 2012 Publication History

Abstract

A central problem in data integration and data cleansing is to find entities in different data sources that describe the same real-world object. Many existing methods for identifying such entities rely on explicit linkage rules which specify the conditions that entities must fulfill in order to be considered to describe the same real-world object. In this paper, we present the GenLink algorithm for learning expressive linkage rules from a set of existing reference links using genetic programming. The algorithm is capable of generating linkage rules which select discriminative properties for comparison, apply chains of data transformations to normalize property values, choose appropriate distance measures and thresholds and combine the results of multiple comparisons using non-linear aggregation functions. Our experiments show that the GenLink algorithm outperforms the state-of-the-art genetic programming approach to learning linkage rules recently presented by Carvalho et. al. and is capable of learning linkage rules which achieve a similar accuracy as human written rules for the same problem.

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O’hare KJurek-Loughrey ADe Campos C(2021)High-Value Token-Blocking: Efficient Blocking Method for Record LinkageACM Transactions on Knowledge Discovery from Data10.1145/345052716:2(1-17)Online publication date: 21-Jul-2021
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cover image Proceedings of the VLDB Endowment

Proceedings of the VLDB Endowment Volume 5, Issue 11

July 2012

608 pages

ISSN:2150-8097

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VLDB Endowment

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Published: 01 July 2012

Published in PVLDB Volume 5, Issue 11

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Cited By

Bornemann LBleifuß TKalashnikov DNargesian FNaumann FSrivastava D(2023)Matching Roles from Temporal Data: Why Joe Biden is not only President, but also Commander-in-ChiefProceedings of the ACM on Management of Data10.1145/35889191:1(1-26)Online publication date: 30-May-2023
(2023)Geospatial Data ScienceundefinedOnline publication date: 9-Jun-2023
O’hare KJurek-Loughrey ADe Campos C(2021)High-Value Token-Blocking: Efficient Blocking Method for Record LinkageACM Transactions on Knowledge Discovery from Data10.1145/345052716:2(1-17)Online publication date: 21-Jul-2021
Petrovski PBizer C(2020)Learning expressive linkage rules from sparse dataSemantic Web10.3233/SW-19035611:3(549-567)Online publication date: 1-Jan-2020
Sun ZZhang QHu WWang CChen MAkrami FLi C(2020)A benchmarking study of embedding-based entity alignment for knowledge graphsProceedings of the VLDB Endowment10.14778/3407790.340782813:12(2326-2340)Online publication date: 14-Sep-2020
Debruyne C(2020)Introducing Context and Context-awareness in Data IntegrationProceedings of the 22nd International Conference on Information Integration and Web-based Applications & Services10.1145/3428757.3429116(178-183)Online publication date: 30-Nov-2020
Christophides VEfthymiou VPalpanas TPapadakis GStefanidis K(2020)An Overview of End-to-End Entity Resolution for Big DataACM Computing Surveys10.1145/341889653:6(1-42)Online publication date: 6-Dec-2020
Papadakis GTsekouras LThanos EGiannakopoulos GPalpanas TKoubarakis M(2020)Domain- and Structure-Agnostic End-to-End Entity Resolution with JedAIACM SIGMOD Record10.1145/3385658.338566448:4(30-36)Online publication date: 25-Feb-2020
Rivero CRuiz DHung CCerny TShin DBechini A(2020)Selecting suitable configurations for automated link discoveryProceedings of the 35th Annual ACM Symposium on Applied Computing10.1145/3341105.3373882(907-914)Online publication date: 30-Mar-2020
Primpeli ABizer CAkerkar RJung J(2019)Robust Active Learning of Expressive Linkage RulesProceedings of the 9th International Conference on Web Intelligence, Mining and Semantics10.1145/3326467.3326484(1-7)Online publication date: 26-Jun-2019
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