Page 358 - 《软件学报》2024年第6期

P. 358

2934 软件学报 2024 年第 35 卷第 6 期

2021.3122301]
[5] Sun J, Zhou Y, Zong CQ. One-shot relation learning for knowledge graphs via neighborhood aggregation and paths encoding. ACM
Trans. on Asian and Low-resource Language Information Processing, 2021, 21(3): 52. [doi: 10.1145/3484729]
[6] Zhou YH. About modern Chinese morphemes. Journal of Southwest University for Nationalities (Philosophy and Social Sciences), 2001,
22(7): 202–205 (in Chinese with English abstract).
[7] Chiu JPC, Nichols E. Named entity recognition with bidirectional LSTM-CNNs. Trans. of the Association for Computational Linguistics,
2016, 4: 357–370. [doi: 10.1162/tacl_a_00104]
[8] Lample G, Ballesteros M, Subramanian S, Kawakami K, Dyer C. Neural architectures for named entity recognition. In: Proc. of the 2016
Conf. of the North American Chapter of the Association for Computational Linguistics: Human Language Technologies. San Diego:
ACL, 2016. 260–270. [doi: 10.18653/v1/N16-1030]
[9] Dong CH, Zhang JJ, Zong CQ, Hattori M, Di H. Character-based LSTM-CRF with radical-level features for Chinese named entity
recognition. In: Proc. of th 5th CCF Conf. on Natural Language Processing and Chinese Computing (NLPCC 2016), and the 24th Int’l
Conf. on Computer Processing of Oriental Languages. Kunming: Springer, 2016. 239–250. [doi: 10.1007/978-3-319-50496-4_20]
[10] Huang ZH, Xu W, Yu K. Bidirectional LSTM-CRF models for sequence tagging. arXiv:1508.01991, 2015.
[11] Sheikhshab G, Birol I, Sarkar A. In-domain context-aware token embeddings improve biomedical named entity recognition. In: Proc. of

the 9th Int’l Workshop on Health Text Mining and Information Analysis. Brussels: ACL, 2018. 160–164. [doi: 10.18653/v1/W18-5618]
[12] Li XN, Yan H, Qiu XP, Huang XJ. FLAT: Chinese ner using flat-lattice transformer. In: Proc. of the 58th Annual Meeting of the
Association for Computational Linguistics. Online: ACL, 2020. 6836–6842. [doi: 10.18653/v1/2020.acl-main.611]
[13] Bekoulis G, Deleu J, Demeester T, Develder C. Joint entity recognition and relation extraction as a multi-head selection problem. Expert
Systems with Applications, 2018, 114: 34–45. [doi: 10.1016/j.eswa.2018.07.032]
[14] Yu JT, Bohnet B, Poesio M. Named entity recognition as dependency parsing. In: Proc. of the 58th Annual Meeting of the Association for
Computational Linguistics. ACL, 2020. 6470–6476. [doi: 10.18653/v1/2020.acl-main.577]
[15] Shen YL, Ma XY, Tan ZQ, Zhang S, Wang W, Lu WM. Locate and label: A two-stage identifier for nested named entity recognition. In:
Proc. of the 59th Annual Meeting of the Association for Computational Linguistics and the 11th Int’l Joint Conf. on Natural Language
Processing (Vol. 1: Long Papers). ACL, 2021. 2782–2794. [doi: 10.18653/v1/2021.acl-long.216]
[16] Isozaki H, Kazawa H. Efficient support vector classifiers for named entity recognition. In: Proc. of the 19th Int’l Conf. on Computational
Linguistics. Taipei: ACL, 2002. 1–7. [doi: 10.3115/1072228.1072282]
[17] Lee KJ, Hwang YS, Kim S, Rim HC. Biomedical named entity recognition using two-phase model based on SVMs. Journal of
Biomedical Informatics, 2004, 37(6): 436–447. [doi: 10.1016/j.jbi.2004.08.012]
[18] Ju ZF, Wang J, Zhu F. Named entity recognition from biomedical text using SVM. In: Proc. of the 5th Int’l Conf. on Bioinformatics and
Biomedical Engineering. Wuhan: IEEE, 2011. 1–4. [doi: 10.1109/icbbe.2011.5779984]
[19] Zhou GD, Su J. Named entity recognition using an HMM-based chunk tagger. In: Proc. of the 40th Annual Meeting of the Association for
Computational Linguistics. Philadelphia: ACL, 2002. 473–480. [doi: 10.3115/1073083.1073163]
[20] Zhao SJ. Named entity recognition in biomedical texts using an HMM model. In: Proc. of the 2004 Int’l Joint Workshop on Natural
Language Processing in Biomedicine and its Applications. Geneva: COLING, 2004. 87–90.
[21] Zhang J, Shen D, Zhou GD, Su J, Tan CL. Enhancing HMM-based biomedical named entity recognition by studying special phenomena.
Journal of Biomedical Informatics, 2004, 37(6): 411–422. [doi: 10.1016/j.jbi.2004.08.005]
[22] McCallum A, Li W. Early results for named entity recognition with conditional random fields, feature induction and Web-enhanced
lexicons. In: Proc. of the 7th Conf. on Natural Language Learning at HLT-NAACL 2003. Edmonton: ACL, 2003. 188–191. [doi: 10.3115/
1119176.1119206]
[23] Settles B. Biomedical named entity recognition using conditional random fields and rich feature sets. In: Proc. of the 2004 Int’l Joint
Workshop on Natural Language Processing in Biomedicine and its Applications. Geneva: COLING, 2004. 107–110.
[24] Collobert R, Weston J, Bottou L, Karlen M, Kavukcuoglu K, Kuksa P. Natural language processing (almost) from scratch. Journal of
Machine Learning Research, 2011, 12: 2493–2537.
[25] Peters ME, Neumann M, Iyyer M, Gardner M, Clark C, Lee K, Zettlemoyer L. Deep contextualized word representations. In: Proc. of the
2018 Conf. of the North American Chapter of the Association for Computational Linguistics: Human Language Technologies, Vol. 1
(Long Papers). New Orleans: ACL, 2018. 2227–2237. [doi: 10.18653/v1/N18-1202]
[26] Hakala K, Pyysalo S. Biomedical named entity recognition with multilingual BERT. In: Proc. of the 5th Workshop on BioNLP Open
Shared Tasks. Hong Kong: ACL, 2019. 56–61. [doi: 10.18653/v1/D19-5709]
[27] Shen D, Zhang J, Zhou GD, Su J, Tan CL. Effective adaptation of hidden markov model-based named entity recognizer for biomedical

353 354 355 356 357 358 359 360 361 362 363