融合欧氏空间邻近与拓扑邻接信息预训练模型的路网网格模式

doi:10.11947/j.AGCS.2026.20250350

测绘学报 ›› 2026, Vol. 55 ›› Issue (3): 415-424.doi: 10.11947/j.AGCS.2026.20250350

• 数智时代地图学新理论与新方法 • 上一篇下一篇

融合欧氏空间邻近与拓扑邻接信息预训练模型的路网网格模式

禹文豪¹^,²(), 曾子怡¹(), 张一帆¹^,³, 钱海忠⁴

^1.中国地质大学（武汉）地理与信息工程学院，湖北　武汉　430078
^2.自然资源部城市国土资源监测与仿真重点实验室，广东　深圳　518034
^3.中国矿业大学环境与测绘学院，江苏　徐州　221116
^4.信息工程大学地理空间信息学院，河南　郑州　450001

收稿日期:2025-09-01 修回日期:2026-03-02 出版日期:2026-04-16 发布日期:2026-04-16
通讯作者: 曾子怡 E-mail:yuwh@cug.edu.cn;zen@cug.edu.cn
作者简介:禹文豪（1987—），男，博士，教授，研究方向为大模型、地图智能与时空数据挖掘。E-mail：yuwh@cug.edu.cn
基金资助:
自然资源部城市国土资源监测与仿真重点实验室开放基金(KF-2025-09-07);国家自然科学基金(42371446);湖北省自然科学基金(2024AFD412);武汉市重点研发计划(2025051202030412)

Road network grid pattern analysis using a pre-trained model fusing spatial and topological information

Wenhao YU¹^,²(), Ziyi ZENG¹(), Yifan ZHANG¹^,³, Haizhong QIAN⁴

^1.School of Geography and Information Engineering, China University of Geosciences, Wuhan 430078, China
^2.Key Laboratory of Urban Land Resources Monitoring and Simulation, Ministry of Natural Resources, Shenzhen 518034, China
^3.School of Environment Science and Spatial Informatics, China University of Mining and Technology, Xuzhou 221116, China
^4.School of Geospatial Information, Information Engineering University, Zhengzhou 450001, China

Received:2025-09-01 Revised:2026-03-02 Online:2026-04-16 Published:2026-04-16
Contact: Ziyi ZENG E-mail:yuwh@cug.edu.cn;zen@cug.edu.cn
About author:YU Wenhao (1987—), male, PhD, professor, majors in large models, map intelligence and spatio-temporal data mining. E-mail: yuwh@cug.edu.cn
Supported by:
Open Fund of Key Laboratory of Urban Land Resources Monitoring and Simulation, Ministry of Natural Resources(KF-2025-09-07);The National Natural Science Foundation of China(42371446);The Natural Science Foundation of Hubei Province, China(2024AFD412);The Key Research and Development Program of Wuhan(2025051202030412)

摘要/Abstract

摘要：

路网网格模式识别是地图学与地理空间信息领域的经典问题，广泛应用于地图综合、空间认知、矢量数据更新等任务中。对路网模式特征的提取与分析，是反映城市景观特征以及实现智能化地图操作的关键步骤。然而现有方法面临两大挑战：一是依赖大量高质量标注数据，二是对路网空间-拓扑信息的表征不够完整。路网作为典型的非结构化图数据，难以直接应用为规则栅格数据设计的预训练方法。为解决上述问题，本文提出一种融合欧氏空间邻近与拓扑邻接信息的自监督预训练模型。在方法上，一方面通过图卷积核网络对局部路径结构进行编码，增强拓扑感知能力；另一方面设计空间注意力偏置机制，将欧氏距离信息融入图节点表示，实现双重空间信息的有效融合，从而更好地捕捉道路网络的特征。在学习范式上，采用预训练策略，仅利用无标注路网数据学习通用表征，降低对标注数据的依赖。在公开城市路网数据集上的试验结果表明，本文模型在路网模式分类任务中取得显著优势：准确率达到88.03%，相比最优基线方法（CRHD）提升2.29个百分点；精确率、召回率分别达到88.89%和87.47%，分别提升3.19、1.57个百分点；F₁值为0.878 0，提升了0.020 9。本文验证了融合架构与预训练策略的有效性，本文模型可学习到更具泛化性的路网内在表征，为下游任务提供基础模型支持。

关键词: 路网模式, 空间认知, 地图分析, 图预训练, 图结构学习

Abstract:

Road network pattern recognition is a classical problem in the fields of cartography and geospatial information science, and is widely applied in tasks such as map generalization, spatial cognition, and vector data updating. The extraction and analysis of road network pattern features constitute a crucial step in reflecting urban landscape characteristics and enabling intelligent map operations. However, existing methods face two major challenges: first, a heavy reliance on large amounts of high-quality labeled data; second, an incomplete representation of the spatial-topological information of road networks. As typical unstructured graph data, road networks cannot be directly processed by pre-training methods designed for regular grid data. To address these issues, this paper proposes a self-supervised pre-training model that integrates Euclidean spatial proximity and topological adjacency information. Method ologically, on one hand, a graph convolutional kernel network is employed to encode local path structures, enhancing topological awareness; on the other hand, a spatial attention bias mechanism is designed to incorporate Euclidean distance information into graph node representations, achieving an effective fusion of dual spatial information and thus better capturing the characteristics of road networks. In terms of the learning paradigm, a pre-training strategy is adopted, learning universal representations using only unlabeled road network data, thereby reducing dependence on labeled data. Experimental results on public urban road network datasets demonstrate that the proposed model achieves significant advantages in the road network pattern classification task: an accuracy of 88.03%, surpassing the optimal baseline method (CRHD) by 2.29 percentage points; precision and recall reach 88.89% and 87.47%, respectively, with improvements of 3.19 and 1.57 percentage points; and anF₁ score of 0.878 0, an increase of 0.020 9. This paper validates the effectiveness of the fusion architecture and the pre-training strategy. The proposed model can learn more generalizable intrinsic representations of road networks, providing foundational model support for downstream tasks.

Key words: road network pattern, spatial cognition, map analysis, graph pre-training, graph structure learning

中图分类号:

P208

禹文豪, 曾子怡, 张一帆, 钱海忠. 融合欧氏空间邻近与拓扑邻接信息预训练模型的路网网格模式[J]. 测绘学报, 2026, 55(3): 415-424.

Wenhao YU, Ziyi ZENG, Yifan ZHANG, Haizhong QIAN. Road network grid pattern analysis using a pre-trained model fusing spatial and topological information[J]. Acta Geodaetica et Cartographica Sinica, 2026, 55(3): 415-424.

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路网结构	微调数据集	测试数据集	合计
网格型	2702	676	3378
非网格型	4016	1063	5079
合计	6718	1739	—

方法	准确率/（%）	精确率/（%）	召回率/（%）	F₁值
CRHD	85.74	85.70	85.90	0.857 1
SECA	53.08	51.46	51.06	0.483 3
K-means	71.30	71.34	71.47	0.712 7
GMM	49.63	50.97	50.87	0.488 4
SVM	67.28	67.13	66.72	0.667 7
本文模型	88.03	88.89	87.47	0.878 0

方法	是否预训练	拓扑编码	空间编码	准确率/（%）	精确率/（%）	召回率/（%）	F₁值
无预训练方法	否	否	否	66.76	74.59	68.75	0.652 7
预训练方法	是	否	否	80.68	82.63	81.60	0.806 1
拓扑编码方法	是	是	否	81.31	83.73	80.22	0.805 0
空间编码方法	是	否	是	81.77	82.75	81.03	0.813 0
本文模型	是	是	是	88.03	88.89	87.47	0.878 0

融合欧氏空间邻近与拓扑邻接信息预训练模型的路网网格模式

Road network grid pattern analysis using a pre-trained model fusing spatial and topological information

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