Ontology-guided knowledge graph construction for mineral prediction

doi:10.13745/j.esf.sf.2024.5.4

Abstract

Abstract:

Knowledge graph construction is an effective means of acquiring and representing knowledge in data-driven research, however, existing knowledge graphs have many problems and limitations in mineral resource prediction. Firstly, relevant studies are few while existing knowledge graphs lack spatiotemporal semantics, which limits the effective representation and analysis of the spatiotemporal characteristics of mineral resources. Secondly, existing graph construction methods emphasize text extraction at the data level, but lack ontology construction involving complex logical relationships and lack effective association between ontology and data layers. As a result, existing knowledge graphs lack in-depth and sufficient semantic information to meet the requirement of mineral resource prediction in expressing complex geoscience concepts and relationships. To address this issue, this study takes an ontology-guided approach to construct a knowledge graph suitable for mineral prediction tasks. We first construct the initial domain ontology on the basis of in-depth understanding of mineral prediction theories and methods; we then integrate the domain ontology with selected mature geological time ontology and geographical space ontology to expand the initial ontology—by embedding spatiotemporal semantics we can effectively express the spatiotemporal characteristics of mineral resources. We also pay attention to the association between ontology and data layers—by establishing rich semantic relationships we can achieve effective inter-node connection and information sharing in the knowledge graph. Experimental results show that the knowledge graph outperformed other existing graphs in terms of knowledge richness and confidence. This study provides a methodology for multi-ontology based knowledge graph construction for mineral prediction, thereby promoting further development of this field.

Key words: mineral resources, knowledge graph, ontology engineering, mineral prediction theory

CLC Number:

P628

YE Yuxin, LIU Jiawen, ZENG Wanxin, YE Shuisheng. Ontology-guided knowledge graph construction for mineral prediction[J]. Earth Science Frontiers, 2024, 31(4): 16-25.

Figures/Tables 9

Fig.1 A multi-ontology based approach to knowledge graph construction

Fig.2 Initial ontology

Fig.3 Geologic time ontology

Fig.4 Flowchart for extracting geological map features

Fig.5 BERT-BiLSTM-CRF model

Fig.6 Simplified geological and mineral resources map

Table 1 Some knowledge graph concepts and instances

概念	实体
地层	渐新统-中新统桃树园组、长城系星星峡岩群和中- 下侏罗统煤沟窑组等
岩体	中粒暗色辉长岩、二长花岗岩和灰色片麻状花岗闪长岩等
岩脉	酸性岩脉、中性岩脉和基性岩脉等
地质时间	全新世、侏罗纪、晚石炭世和新元古代等

Table 2 Comparison of knowledge graph metrics between different construction methods

	平均度	置信度
Fact	32	0.69
Fact+Onto	19	0.73
Fact+Onto+RelOnt	23	0.88

Fig.7 Comparison of knowledge graphs with and without ontology

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