中文    English

Journal of Library and Information Science in Agriculture ›› 2023, Vol. 35 ›› Issue (8): 66-77.doi: 10.13998/j.cnki.issn1002-1248.23-0300

Previous Articles     Next Articles

Representation Model of Agricultural Knowledge Graph Based on the HARP Framework

CHEN Caiming1, FENG Jianzhong1,*, BAI Linyan2,3, WANG Jian1, XIE Nengfu1, ZOU Jun1   

  1. 1. Agricultural Information Institute of CAAS, Beijing 100081;
    2. Institute of Remote Sensing and Digital Earth, Chinese Academy of Sciences, Beijing 100094;
    3. International Research Center of Big Data for Sustainable Development Goals, Beijing 100094
  • Received:2023-05-16 Online:2023-08-05 Published:2023-12-04

PDF (PC)

68

Abstract: [Purpose/Significance] In the era of big data, the volume of data is growing at an exponential rate. One of the most prominent areas affected by this growth is the field of agriculture. The use of agricultural knowledge graphs, which serve as key infrastructures for managing agricultural knowledge, has expanded significantly. However, as the number of nodes and relationships within these graphs increase, so too does their complexity. This complexity gives rise to new challenges in training and representing such large-scale knowledge graphs. It is therefore of great significance to investigate methods for speeding up the embedding process of agricultural knowledge graphs, while preserving their structural integrity and minimizing resource consumption. This research embarks on a novel exploration to address this issue. It stands out from previous studies by concentrating on a hierarchical representation model for agricultural knowledge graphs. The potential impacts of this research on propelling the advancement of the field and on addressing significant real-world problems are substantial. [Method/Process] To confront this challenge, we propose a hierarchical representation model for agricultural knowledge graphs rooted in the HARP framework. Our model leverages the inherent hierarchical features of the agricultural knowledge graph. It incorporates an improved random walk strategy based on relational paths to semantically model relationship objects within the agricultural knowledge graph. This innovative approach effectively retains the hierarchy and asymmetrical relationship structure of the nodes in the graph, setting our work apart from previous research. The validity of our proposed model is fortified by a strong foundation of theoretical and empirical evidence. [Results/Conclusions] Our experimental results reveal several key findings. First, the hierarchical random walk with path (HRWP) model using the LEIDEN algorithm can preserve the spatial structure more effectively and converge more quickly to the maximum modularity, in comparison to the HARP framework. Second, the fusion model employing HRWP takes less training time than the total training time of both models combined, without significantly affecting the time complexity of the original algorithm. Third, we observed that when traditional algorithms are integrated with HRWP, there is an average improvement of 2% across various indicators, with a substantial enhancement in non-neural network models. Therefore, our proposed model not only accurately represents the agricultural knowledge graph but also effectively reduces the training time. Despite the promising outcomes of our study, there remain areas of potential improvement. One such area is the need for a more detailed discussion on the hierarchical nature of relationship objects in future research. This provides potential avenues for future exploration in this field. The findings of this research carry profound implications for the development of agricultural knowledge management systems, offering an effective approach to handle the burgeoning complexity of knowledge graphs.

Key words: knowledge graph, walk, representation learning, the hierarchical random walk with path (HRWP) framework

CLC Number: 

  • TP391.1
[1] 孙坦, 丁培, 黄永文, 等. 文本挖掘技术在农业知识服务中的应用述评[J]. 农业图书情报学报, 2021, 33(1): 4-16.
SUN T, DING P, HUANG Y W, et al.Review on the application and development strategies of text mining in agriculture knowledge services[J]. Journal of library and information science in agriculture, 2021, 33(1): 4-16.
[2] 曹树金, 吴育冰, 韦景竹, 等. 知识图谱研究的脉络、流派与趋势——基于SSCI与CSSCI期刊论文的计量与可视化[J]. 中国图书馆学报, 2015, 41(5): 16-34.
CAO S J, WU Y B, WEI J Z, et al.History, schools and trend in knowledge map: Investigation and visualization based on SSCI and CSSCI[J]. Journal of library science in China, 2015, 41(5): 16-34.
[3] 徐有为, 张宏军, 程恺, 等. 知识图谱嵌入研究综述[J]. 计算机工程与应用, 2022, 58(9): 30-50.
XU Y W, ZHANG H J, CHENG K, et al.Comprehensive survey on knowledge graph embedding[J]. Computer engineering and applications, 2022, 58(9): 30-50.
[4] 徐增林, 盛泳潘, 贺丽荣, 等. 知识图谱技术综述[J]. 电子科技大学学报, 2016, 45(4): 589-606.
XU Z L, SHENG Y P, HE L R, et al.Review on knowledge graph techniques[J]. Journal of university of electronic science and technology of China, 2016, 45(4): 589-606.
[5] ZHOU C, LIU Y Q, LIU X F, et al.Scalable graph embedding for asymmetric proximity[C]//Proceedings of the AAAI Conference on Artificial Intelligence, 2017, 31(1): 456-545.
[6] LI E Z, LE Z Y.Frustrated random walks: A faster algorithm to evaluate node distances on connected and undirected graphs[J]. Physical review E, 2020, 102: 052135.
[7] QIAO L, JIANG L, HAN M, et al.Hierarchical random walk infer-ence in knowledge graphs[C]// The 39th International ACM SIGIR Conference on Research and Development in Information Retrieval. Pisa, Italy: Association for Computing Machinery, 2016.
[8] 赵卓翔, 王轶彤, 田家堂, 等. 社会网络中基于标签传播的社区发现新算法[J]. 计算机研究与发展, 2011, 48(S3): 8-15.
ZHAO Z X, WANG Y T, TIAN J T, et al.A novel algorithm for com-munity discovery in social networks based on label propagation[J]. Journal of computer research and development, 2011, 48(S3): 8-15.
[9] 孙光福, 吴乐, 刘淇, 等. 基于时序行为的协同过滤推荐算法[J]. 软件学报, 2013, 24(11): 2721-2733.
SUN G F, WU L, LIU Q, et al.Recommendations based on collaborative filtering by exploiting sequential behaviors[J]. Journal of software, 2013, 24(11): 2721-2733.
[10] BORDES A, USUNIER N, GARCIA-DURáN A, et al. Translating embeddings for modeling multi-relational data[C]// Proceedings of
the 26th International Conference on Neural Information Processing Systems - Volume 2. New York: ACM, 2013: 2787-2795.
[11] FENG J, ZHOU M T, HAO Y, et al. Knowlege graph embedding by flexible translation[J]. arXiv:1505.05253, 2015.
[12] XIAO H, HUANG M L, HAO Y, et al. TransA: An adaptive approach for knowledge graph embedding[J]. arXiv:1509.05490, 2015.
[13] SUN Z Q, DENG Z H, NIE J Y, et al.RotatE: Knowledge graph embedding by relational rotation in complex space[J]. arXiv: 1902.10197, 2019.
[14] NICKEL M, TRESP V, KRIEGEL H P.A three-way model for collective learning on multi-relational data[C]// Proceedings of the 28th International Conference on International Conference on Machine Learning. New York: ACM, 2011: 809-816.
[15] YANG B, YUH W T, HE X D, et al. Embedding entities and relations for learning and inference in knowledge bases[J]. arXiv preprint arXiv:1412.6575, 2014.
[16] SCHLICHTKRULL M, KIPF T N, BLOEM P, et al.Modeling relational data with graph convolutional networks[C]//European semantic web conference. Cham: Springer, 2018: 593-607.
[17] SHANG C, TANG Y, HUANG J, et al.End-to-end structure-aware convolutional networks for knowledge base completion[J]. Proceedings of the AAAI conference on artificial intelligence AAAI conference on artificial intelligence, 2019, 33: 3060-3067.
[18] MITCHELL T, FREDKIN E.Never-ending language learning[C]// 2014 IEEE International Conference on Big Data(Big Data). Piscataway, New Jersey: IEEE, 2015: 1.
[19] DONG X, GABRILOVICH E, HEITZ G, et al.Knowledge vault: A web-scale approach to probabilistic knowledge fusion[C]// Proceedings of the 20th ACM SIGKDD international conference on Knowledge discovery and data mining. New York, NY, USA: ACM, 2014.
[20] 李小凤, 肖帅, 刘希艳, 等. 我国农业类国家标准分类检索浅析[J]. 中国标准化, 2020(7): 67-71, 75.
LI X F, XIAO S, LIU X Y, et al.A brief analysis of the classification retrieval of Chinese national standards for agriculture[J]. China standardization, 2020(7): 67-71, 75.
[21] CHEN H C, PEROZZI B, HU Y F, et al.HARP: Hierarchical representation learning for networks[C]//Proceedings of the AAAI conference on artificial intelligence. 2018, 32(1): 336-341.
[22] TRAAG V A, WALTMAN L, VAN ECK N J. From Louvain to Leiden: Guaranteeing well-connected communities[J]. Scientific reports, 2019, 9: 5233.
[23] TOUTANOVA K, CHEN D, PANTEL P, et al.Representing text for joint embedding of text and knowledge bases[C]. Proceedings of the 2015 Conference on Empirical Methods in Natural Language Processing, 2015: 1499-1509.
[24] DETTMERS T, MINERVINI P, STENETORP P, et al.Convolutional 2D knowledge graph embeddings[C].Proceedings of the AAAI conference on artificial intelligence, 2018, 32(1): 241-249.
[25] VOORHEES E.The TREC-8 question answering track report[C]. Gaithersburg: Proceedings of TREC-8, 2000.
[26] HERLOCKER J L, KONSTAN J A, TERVEEN L G, et al.Evaluating collaborative filtering recommender systems[J]. ACM transactions on
information systems, 2004, 22(1): 5-53.
[1] FAN KeXin, SUN Tan, ZHAO RuiXue, KOU YuanTao, XIAN GuoJian. Comparison and Enlightenment of Crop Germplasm Resource Knowledge Service Platforms [J]. Journal of Library and Information Science in Agriculture, 2023, 35(5): 64-73.
[2] MA Weilu, XIAN Guojian, ZHAO Ruixue, LI Jiao, HUANG Yongwen, SUN Tan. Comparative Study and Optimization Strategies of Knowledge Graph Construction Management Systems [J]. Journal of Library and Information Science in Agriculture, 2023, 35(4): 19-31.
[3] CHANG ZhiJun, XU LiYuan, YU QianQian, ZHANG JianYong, WANG YongJi. Scientific and Technical Literature Data Management System Based on Life Cycle Model [J]. Journal of Library and Information Science in Agriculture, 2022, 34(6): 36-49.
[4] YANG Siluo, TIAN Peilin, ZHU Chuanyu, QIU Junping. Characteristics of UNESCO's Humanities and Social Sciences Research: Topic, Evolution and Cooperation [J]. Journal of Library and Information Science in Agriculture, 2021, 33(6): 6-17.
[5] XU Yongle, CHEN Yuanyuan, YANG Tingting, WAN Xiangli. Comparative Analysis of the Research on the Influence of Chinese and International Think Tanks [J]. Journal of Library and Information Science in Agriculture, 2021, 33(11): 50-62.
[6] LYU Lucheng, HAN Tao. Artificial Intelligence Empowers Library and Information Service ——Review of Forums about Information Technology for Library 2019 [J]. Journal of Library and Information Science in Agriculture, 2020, 32(5): 13-18.
[7] LI Zhongjun, SUN Ruiying, ZHANG Tao. Analysis of the Research Status of Public Opinion Ecology in China Based on Bibliometrics (2004-2019) [J]. Journal of Library and Information Science in Agriculture, 2020, 32(2): 5-13.
[8] ZHANG Tao, SUN Ruiying, LI Zhongjun. Subject Clustering and Evolutionary Trend of Public Opinion Documents in China [J]. Journal of Library and Information Science in Agriculture, 2020, 32(2): 14-21.
[9] CHEN Qingyun, CAO Jianfei, CHEN Rongzhen. Research and Practices From the Thesaurus to Knowledge Graph [J]. Agricultural Library and Information, 2019, 31(1): 44-53.
[10] ZHI Yingying. Exploration on the Application of Machine Learning in Library Discover System —Taking the Discover Tool Yewno Based on Knowledge Graph as Example [J]. , 2018, 30(7): 47-50.
[11] CHEN Fen, ZHU Tianxiu. Research on University Library's Subject Service Based on Bibliometrics and Knowledge Graph Analysis [J]. , 2018, 30(1): 99-103.
[12] TIAN Tian. Analysis of Information Service Visualization Graph Based on CiteSpace Ⅲ [J]. , 2015, 27(8): 52-56.
[13] ZHAO Lai-juan. Visualized Analysis on the Research Hotspots of Mobile Library in China [J]. , 2015, 27(8): 46-51.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Editorial Board of Journal of Library and Information Science in Agriculture
Tel:(010)82109667 Fax:(010)82109667 E-mail:xuekan@caas.cn
Powered by Beijing Magtech Co., Ltd.
知识共享许可协议