Volume 50 Issue 4
Apr.  2024
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HAN Yibo, DONG Lihong, YE Ou. Construction of knowledge graph for fully mechanized coal mining equipment based on joint coding[J]. Journal of Mine Automation,2024,50(4):84-93.  doi: 10.13272/j.issn.1671-251x.2023100009
Citation: HAN Yibo, DONG Lihong, YE Ou. Construction of knowledge graph for fully mechanized coal mining equipment based on joint coding[J]. Journal of Mine Automation,2024,50(4):84-93.  doi: 10.13272/j.issn.1671-251x.2023100009

Construction of knowledge graph for fully mechanized coal mining equipment based on joint coding

doi: 10.13272/j.issn.1671-251x.2023100009
  • Received Date: 2023-10-03
  • Rev Recd Date: 2024-04-19
  • Available Online: 2024-05-10
  • Using knowledge graph technology for data management can achieve effective representation of fully mechanized coal mining equipment. The information with deep mining value can be obtained. The imbalanced data of fully mechanized coal mining equipment and the limited number of entities in certain categories of equipment affect the precision of entity recognition models. In order to solve the above problems, a knowledge graph construction method for fully mechanized coal mining equipment based on joint coding is proposed. Firstly, the fully mechanized coal mining equipment ontology model is constructed, determining the concepts and relationships. Secondly, the entity recognition model is designed. The model uses Token Embedding, Position Embedding, Sentence Embedding, and Task Embedding 4-layer Embedding structures and Transformer Encoder to encode fully mechanized coal mining equipment data, extract dependency relationships and contextual information features between words. The model introduces a Chinese character library, using the Word2vec model for encoding, extracting semantic rules between characters, and solving the problem of rare characters in fully mechanized coal mining equipment data. The model uses the GRU model to jointly encode the data of fully mechanized coal mining equipment and the character vectors encoded in the font library, and fuse vector features. The model uses the Lattice-LSTM model for character decoding to obtain entity recognition results. Finally, the model uses graph database technology to store and organize extracted knowledge in the form of graphs, completing the construction of knowledge graphs. Experimental verification is conducted on the dataset of fully mechanized coal mining equipment. The results show that the method improves the recognition accuracy of fully mechanized coal mining equipment entities by more than 1.26% compared to existing methods, which to some extent alleviates the low accuracy problem caused by insufficient data when constructing a knowledge graph of fully mechanized coal mining equipment in a small sample situation.

     

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  • [1]
    王国法,任怀伟 ,马宏伟,等. 煤矿智能化基础理论体系研究[J]. 智能矿山,2023,4(2):2-8.

    WANG Guofa,REN Huaiwei,MA Hongwei,et al. Research on the basic theoretical system of coal mine inteliigence[J]. Journal of Intelligent Mine,2023,4(2):2-8.
    [2]
    曹现刚,罗璇,张鑫媛,等. 煤矿机电设备运行状态大数据管理平台设计[J]. 煤炭工程,2020,52(2):22-26.

    CAO Xiangang,LUO Xuan,ZHANG Xinyuan,et al. Design of big data management platform for operation status of coal mine electromechanical equipment[J]. Coal Engineering,2020,52(2):22-26.
    [3]
    高晶,赵良君,吕旭阳. 基于数据挖掘的煤矿安全管理大数据平台[J]. 煤矿安全,2022,53(6):121-125.

    GAO Jing,ZHAO Liangjun,LYU Xuyang. Coal mine safety management big data platform based on data mining[J]. Safety in Coal Mines,2022,53(6):121-125.
    [4]
    QIAO Wanguan,CHEN Xue. Connotation,characteristics and framework of coal mine safety big data[J]. Heliyon,2022,8(11). DOI: 10.1016/j.heliyon.2022.e11834.
    [5]
    吴雪峰,赵志凯,王莉,等. 煤矿巷道支护领域知识图谱构建[J]. 工矿自动化,2019,45(6):42-46.

    WU Xuefeng,ZHAO Zhikai,WANG Li,et al. Construction of knowledge graph of coal mine roadway support field[J]. Industry and Mine Automation,2019,45(6):42-46.
    [6]
    刘鹏,叶帅,舒雅,等. 煤矿安全知识图谱构建及智能查询方法研究[J]. 中文信息学报,2020,34(11):49-59.

    LIU Peng,YE Shuai,SHU Ya,et al. Coalmine safety:knowledge graph construction and its QA approach[J]. Journal of Chinese Information Processing,2020,34(11):49-59.
    [7]
    李哲,周斌,李文慧,等. 煤矿机电设备事故知识图谱构建及应用[J]. 工矿自动化,2022,48(1):109-112.

    LI Zhe,ZHOU Bin,LI Wenhui,et al. Construction and application of mine electromechanical equipment accident knowledge graph[J]. Industry and Mine Automation,2022,48(1):109-112.
    [8]
    ZHANG Guozhen,CAO Xiangang,ZHANG Mengyuan. A knowledge graph system for the maintenance of coal mine equipment[J]. Mathematical Problems in Engineering,2021,2021:1-13.
    [9]
    OSIPOVA I,GOSPODINOVA V. Representation of the process of sudden outbursts of coal and gas using a knowledge graph[C]. E3S Web of Conferences,2020. DOI: 10.1051/e3sconf/202019204022.
    [10]
    ETZIONI O,BANKO M,SODERLAND S,et al. Open information extraction from the web[J]. Communications of the ACM,2008,51(12):68-74. doi: 10.1145/1409360.1409378
    [11]
    施昭,曾鹏,于海斌. 基于本体的制造知识建模方法及其应用[J]. 计算机集成制造系统,2018,24(11):2653-2664.

    SHI Zhao,ZENG Peng,YU Haibin. Ontology-based modeling method for manufacturing knowledge and its application[J]. Computer Integrated Manufacturing Systems,2018,24(11):2653-2664.
    [12]
    封红旗,孙杨,杨森,等. 基于BERT的中文电子病历命名实体识别[J]. 计算机工程与设计,2023,44(4):1220-1227.

    FENG Hongqi,SUN Yang,YANG Sen,et al. Chinese electronic medical record named entity recognition based on BERT methods[J]. Computer Engineering and Design,2023,44(4):1220-1227.
    [13]
    蔡安江,张妍,任志刚. 煤矿综采设备故障知识图谱构建[J]. 工矿自动化,2023,49(5):46-51.

    CAI Anjiang,ZHANG Yan,REN Zhigang. Fault knowledge graph construction for coal mine fully mechanized mining equipment[J]. Journal of Mine Automation,2023,49(5):46-51.
    [14]
    COLLARANA D,GALKIN M,TRAVERSO-RIBóN I,et al. Semantic data integration for knowledge graph construction at query time[C]. IEEE 11th International Conference on Semantic Computing,San Diego,2017:109-116.
    [15]
    SUN Yu,WANG Shuohuan,LI Yukun,et al. Ernie 2.0:a continual pre-training framework for language understanding[C]. The AAAI Conference on Artificial Intelligence,New York,2019. DOI: 10.1609/aaai.v34i05.6428.
    [16]
    CHURCH K W. Word2Vec[J]. Natural Language Engineering,2017,23(1):155-162. doi: 10.1017/S1351324916000334
    [17]
    丁辰晖,夏鸿斌,刘渊. 融合知识图谱与注意力机制的短文本分类模型[J]. 计算机工程,2021,47(1):94-100.

    DING Chenhui,XIA Hongbin,LIU Yuan. Short text classification model combining knowledge graph and attention mechanism[J]. Computer Engineering,2021,47(1):94-100.
    [18]
    ZHANG Yue,YANG Jie. Chinese NER using lattice LSTM[Z/OL]. [2023-09-10]. https://doi.org/10.48550/arXiv.1805.02023.
    [19]
    宫法明,李翛然. 基于Neo4j的海量石油领域本体数据存储研究[J]. 计算机科学,2018,45(增刊1):549-554.

    GONG Faming,LI Xiaoran. Research on ontology data storage of massive oil field based on Neo4j[J]. Computer Science,2018,45(S1):549-554.
    [20]
    马良荔,李陶圆,刘爱军,等. 基于迁移学习的小数据集命名实体识别研究[J]. 华中科技大学学报(自然科学版),2022,50(2):118-123.

    MA Liangli,LI Taoyuan,LIU Aijun,et al. Research on named entity recognition method based on transfer learning for small data sets[J]. Journal of Huazhong University of Science and Technology(Natural Science Edition),2022,50(2):118-123.
    [21]
    秦健,侯建新,谢怡宁,等. 医疗文本的小样本命名实体识别[J]. 哈尔滨理工大学学报,2021,26(4):94-101.

    QIN Jian,HOU Jianxin,XIE Yining,et al. Few-shot named entity recognition for medical text[J]. Journal of Harbin University of Science and Technology,2021,26(4):94-101.
    [22]
    于韬,张英,拥措. 基于小样本学习的藏文命名实体识别[J]. 计算机与现代化,2023(5):13-19.

    YU Tao,ZHANG Ying,YONG T. Tibetan named entity recognition based on small sample learning[J]. Computer and Modernization,2023(5):13-19.
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