Effective integration of morphological analysis and named entity recognition based on a recurrent neural network

•Integration of morphological analysis and named entity recognition models.•Effective alleviation of error propagation problems.•Performance improvements in both morphological analysis and named entity recognition. Morphological analysis (MA) and named entity recognition (NER) are essential steps in...

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Bibliographic Details
Published in:Pattern recognition letters 2018-09, Vol.112, p.361-365
Main Authors: Lee, Hyeon-gu, Park, Geonwoo, Kim, Harksoo
Format: Article
Language:English
Subjects:
Architecture
Error propagation problem
Information science
Integrated neural network model
Morphological analysis
Named entity recognition
Natural language processing
Neural networks
Pipelining (computers)
Propagation
Recognition
Recurrent neural networks
Training
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Summary:•Integration of morphological analysis and named entity recognition models.•Effective alleviation of error propagation problems.•Performance improvements in both morphological analysis and named entity recognition. Morphological analysis (MA) and named entity recognition (NER) are essential steps in natural language processing. Because NER is generally considered the next step after MA, many previous studies have adopted a pipeline architecture in which results of MA are used as inputs of NER. However, under this kind of pipeline architecture, MA errors lead to decreasing performance in NER models. To alleviate this error propagation problem, we propose an integrated neural network model that performs MA and NER simultaneously. The proposed model consists of two layers of bidirectional gated recurrent unit models with conditional random field layers: a lower layer for MA and an upper layer for NER. To optimize weighting parameters of the proposed model, we use a two-phase training scheme. The first phase trains all layers for NER, and the second trains the lower layer for MA. In our experiments, the proposed model outperforms both an independent MA model and independent NER model. Based on the experimental results, we conclude that the proposed model can effectively alleviate the error propagation problem that frequently occurs in the pipeline architecture.
ISSN:0167-8655
1872-7344
DOI:10.1016/j.patrec.2018.08.015