基于图神经网络的多指标沉井下沉姿态预测

doi:10.19678/j.issn.1000-3428.0070141

计算机工程 ›› 2026, Vol. 52 ›› Issue (6): 307-313. doi: 10.19678/j.issn.1000-3428.0070141

基于图神经网络的多指标沉井下沉姿态预测

向以龙, 倪南, 邹越超, 袁同, 李博涵, 王铁鑫*()

南京航空航天大学计算机科学与技术学院, 江苏南京 211106

收稿日期:2024-07-17 修回日期:2024-09-02 出版日期:2026-06-15 发布日期:2026-06-02
通讯作者: 王铁鑫
作者简介:
向以龙(CCF学生会员)，男，硕士研究生，主研方向为多元时序数据预测
倪南，本科生
邹越超，硕士研究生
袁同，硕士研究生
李博涵，副教授、博士
王铁鑫(通信作者)，副教授、博士

Multi-Indicator Sinking Attitude Prediction of Open Caisson Based on Graph Neural Network

XIANG Yilong, NI Nan, ZOU Yuechao, YUAN Tong, LI Bohan, WANG Tiexin*()

College of Computer Science and Technology, Nanjing University of Aeronautics and Astronautics, Nanjing 211106, Jiangsu, China

Received:2024-07-17 Revised:2024-09-02 Online:2026-06-15 Published:2026-06-02
Contact: WANG Tiexin

摘要/Abstract

摘要：

桥梁作为重要的交通基础设施, 质量是其建造及使用的重中之重。沉井作为基础结构, 在桥梁建造中被广泛应用。在沉井建造过程中, 实时准确的下沉姿态预测有助于降低事故风险, 提高工程质量。常用的统计模型和机器学习模型等预测方法, 难以应对时序数据的非线性时空特征, 如结构应力、沉井下沉姿态等, 导致预测结果不准确。深度学习模型可以捕获数据时空特征, 已广泛应用于时序数据预测, 但尚未被应用于沉井下沉姿态预测等相关任务。因此, 提出基于图神经网络(GNN)的多指标预测模型(MiPM)。MiPM通过自注意力机制以及门控循环单元(GRU)动态建立时序数据序列间的图邻接矩阵, 并结合卷积神经网络提取时序数据的时间特征和空间特征。通过交错的网络结构融合时空特征, 映射预测结果。为验证MiPM的有效性, 以一个真实的桥梁沉井建造工程为实证研究案例。实验结果表明, 对比13个基线模型, MiPM在均方根误差指标上至少降低5.6%, 具有更好的预测结果表现。

关键词: 图神经网络, 图邻接矩阵, 沉井建造, 姿态预测, 时序数据

Abstract:

The quality of bridges, as crucial transportation infrastructure, is an important consideration during its construction and usage. Open caissons are widely used as basic structures in bridge construction. During the open caisson construction process, real-time and accurate prediction of the sinking attitude helps reduce accident risks and may improve project quality. Commonly used prediction methods, such as statistical models and machine learning models, have difficulty coping with the nonlinear spatiotemporal features of time series data, such as structural stress and open caisson sinking attitude, resulting in inaccurate prediction results. Deep learning models can capture the spatiotemporal features of data and have been widely used in time-series data prediction. However, they have not yet been applied to related tasks, such as open caisson sinking attitude prediction. In this study, we propose a Multi-indicator Prediction Model (MiPM) based on a Graph Neural Network (GNN). MiPM dynamically establishes the graph adjacency matrix between time-series data sequences using the self-attention mechanism and the Gate Recurrent Unit (GRU) and combines it with the convolutional neural network to extract the temporal and spatial features of time-series data. The spatiotemporal features are fused using an interleaved network structure, and the prediction results are mapped. To verify the effectiveness of the MiPM, a real open-caisson bridge construction project is used as an empirical case study. The results show that, compared with 13 baseline models, MiPM has a better prediction performance; for example, its Root Mean Square Error (RMSE) is at least 5.6% lower.

Key words: Graph Neural Network (GNN), graph adjacency matrix, open caisson construction, attitude prediction, time series data

向以龙, 倪南, 邹越超, 袁同, 李博涵, 王铁鑫. 基于图神经网络的多指标沉井下沉姿态预测[J]. 计算机工程, 2026, 52(6): 307-313.

XIANG Yilong, NI Nan, ZOU Yuechao, YUAN Tong, LI Bohan, WANG Tiexin. Multi-Indicator Sinking Attitude Prediction of Open Caisson Based on Graph Neural Network[J]. Computer Engineering, 2026, 52(6): 307-313.

https://www.ecice06.com/CN/Y2026/V52/I6/307

图/表 10

图1 MiPM模型结构

Fig.1 Structure of MiPM model

图2 图学习层结构

Fig.2 Structure of graph learning layer

图3 时间卷积层的结构

Fig.3 Structure of temporal convolution layer

图4 空间信息学习层结构

Fig.4 Structure of spatial information learning layer

图5 张靖皋长江大桥沉井

Fig.5 Zhangjinggao yangtze river bridge open caisson

图6 各传感器位置示意图

Fig.6 Schematic diagrams of the positions of each sensor

图7 超参数对预测精度的影响

Fig.7 Influence of hyper-parameters on prediction accuracy

参考文献 27

1	WU S S , ZHAO G F , WU B S . Real-time prediction of the mechanical behavior of suction caisson during installation process using GA-BP neural network. Engineering Applications of Artificial Intelligence, 2022, 116, 105475. doi: 10.1016/j.engappai.2022.105475
2	JIANG B N , YU T , PENG W M , et al. Analysis of mechanism of sand gushing and sudden sinking of ultra-large deep-water open caisson in sand via field and model tests. Applied Ocean Research, 2023, 130, 103436. doi: 10.1016/j.apor.2022.103436
3	PURI N , TURKAN Y . Bridge construction progress monitoring using lidar and 4D design models. Automation in Construction, 2020, 109, 102961. doi: 10.1016/j.autcon.2019.102961
4	徐鹏飞, 李耀良, 徐伟. 压入式沉井施工对环境影响的现场监测研究. 岩土力学, 2014, 35 (4): 1084- 1094.
	XU P F , LI Y L , XU W . Field measurement and analysis of influence of jacked open caisson construction on environments. Rock and Soil Mechanics, 2014, 35 (4): 1084- 1094.
5	刘帅, 乔颖, 罗雄飞, 等. 时序数据库关键技术综述. 计算机研究与发展, 2024, 61 (3): 614- 638.
	LIU X , QIAO Y , LUO X F , et al. Key techniques of time series databases: a survey. Journal of Computer Research and Development, 2024, 61 (3): 614- 638.
6	谢贵才, 段磊, 蒋为鹏. 多尺度时序依赖的校园公共区域人流量预测. 软件学报, 2021, 32 (3): 831- 844.
	XIE G C , DUAN L , JIANG W P . Pedestrian volume prediction for campus public area based on multi-scale temporal dependency. Journal of Software, 2021, 32 (3): 831- 844.
7	REN Q B , LI M C , LI H , et al. A novel deep learning prediction model for concrete dam displacements using interpretable mixed attention mechanism. Advanced Engineering Informatics, 2021, 50, 101407. doi: 10.1016/j.aei.2021.101407
8	ZHOU H Y , ZHANG S H , PENG J Q , et al. Informer: beyond efficient transformer for long sequence time-series forecasting. Artificial Intelligence, 2021, 35 (12): 11106- 11115.
9	ZHOU T, MA Z, WEN Q, et al. Fedformer: frequency enhanced decomposed transformer for long-term series forecasting[C]//Proceedings of the International Conference on Machine Learning. Washington D. C., USA: IEEE Press, 2022: 27268-27286.
10	DONG X C , GUO M W , WANG S L . Advanced prediction of the sinking speed of open caissons based on the spatial-temporal characteristics of multivariate structural stress data. Applied Ocean Research, 2022, 127, 103330. doi: 10.1016/j.apor.2022.103330
11	DONG X C , GUO M W , WANG S L . Inclination prediction of a giant open caisson during the sinking process using various machine learning algorithms. Ocean Engineering, 2023, 269, 113587. doi: 10.1016/j.oceaneng.2022.113587
12	LI Z W , LIANG J D , ZHANG X H , et al. Study on soil parameter evolution during ultra-large caisson sinking based on artificial neural network back analysis. Sustainability, 2023, 15 (13): 10627.
13	HUANG C , ZHU H , LI K Y , et al. Data-driven method for predicting soil pressure of foot blades within a large underwater caisson. Geofluids, 2022, 2022, 1983303.
14	HOCHREITER S , SCHMIDHUBER J . Long short-term memory. Neural Computation, 1997, 9 (8): 1735- 1780. doi: 10.1162/neco.1997.9.8.1735
15	CHO K, VAN MERRI ENBOER B, GULCEHRE C, et al. Learning phrase representations using RNN encoder-decoder for statistical machine translation[EB/OL]. [2024-06-10]. https://arxiv.org/abs/1406.1078.
16	QIN Y, SONG D, CHEN H, et al. A dual-stage attention-based recurrent neural network for time series prediction[EB/OL]. [2024-06-10]. https://arxiv.org/abs/1704.02971.
17	SUN C C, GUO H X, SHEN D R, et al. Temporal convolution and multi-attention jointly enhanced electricity load forecasting[C]//Proceedings of the International Conference on Web Information Systems and Applications. Berlin, Germany: Springer, 2023: 39-51.
18	LAI G K, CHANG W C, YANG Y M, et al. Modeling long- and short-term temporal patterns with deep neural networks[C]//Proceedings of the 41st International ACM SIGIR Conference on Research & Development in Information Retrieval. New York, USA: ACM Press, 2018: 95-104.
19	WANG X Y, MA Y, WANG Y Q, et al. Traffic flow prediction via spatial temporal graph neural network[C]//Proceedings of the Web Conference. New York, USA: ACM Press, 2020: 1082-1092.
20	YANG F H , LI X , WANG M , et al. WaveForM: graph enhanced wavelet learning for long sequence forecasting of multivariate time series. Artificial Intelligence, 2023, 37 (9): 10754- 10761.
21	CAI W L , LIANG Y X , LIU X G , et al. MSGNet: learning multi-scale inter-series correlations for multivariate time series forecasting. Artificial Intelligence, 2024, 38 (10): 11141- 11149.
22	YI K, ZHANG Q, FAN W, et al. FourierGNN: rethinking multivariate time series forecasting from a pure graph perspective[C]//Proceedings of the Advances in Neural Information Processing Systems. Cambridge, USA: MIT Press, 2024: 545-556.
23	LI Y, YU R, SHAHABI C, et al. Diffusion convolutional recurrent neural network: data-driven traffic forecasting[EB/OL]. [2024-06-10]. https://arxiv.org/abs/1707.01926.
24	WU Z H, PAN S R, LONG G D, et al. Connecting the dots: multivariate time series forecasting with graph neural networks[C]//Proceedings of the 26th ACM SIGKDD International Conference on Knowledge Discovery & Data Mining. New York, USA: ACM Press, 2020: 753-763.
25	YU F, KOLTUN V. Multi-scale context aggregation by dilated convolutions[EB/OL]. [2024-06-10]. https://arxiv.org/abs/1511.07122.
26	LI Q M , HAN Z C , WU X M . Deeper insights into graph convolutional networks for semi-supervised learning. Artificial Intelligence, 2018, 32 (1): 10356- 10364.
27	CHEN T Q, GUESTRIN C. XGBoost: a scalable tree boosting system[C]//Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining. New York, USA: ACM Press, 2016: 785-794.

[1]	罗恒, 万良. 基于动态时空图神经网络的网络流量入侵检测方法[J]. 计算机工程, 2026, 52(6): 202-213.
[2]	周丽君, 张俊然, 王开元, 向军莲. 融合患者临床体征的图增强注意力药物推荐[J]. 计算机工程, 2026, 52(6): 314-325.
[3]	张红, 朱思雨, 张玺君, 魏轿云. 基于自适应图卷积优化元图学习的非平稳交通流预测研究[J]. 计算机工程, 2026, 52(5): 456-466.
[4]	崔少国, 许松, 王名洋, 周粤. 面向智能教育的深度学习知识追踪研究进展[J]. 计算机工程, 2026, 52(4): 39-61.
[5]	张震, 游兰, 彭庆喜, 金红, 曾昊秋, 夏宇春. XSGCL: 用于推荐的轻量级图对比学习框架[J]. 计算机工程, 2026, 52(4): 163-175.
[6]	韦昊东, 万良. 基于静态特征组合的图神经网络Android恶意软件检测方法[J]. 计算机工程, 2026, 52(3): 190-200.
[7]	薛阳, 秦瑶, 张舒翔. 基于双重图注意力网络生成子图的图神经协同推荐[J]. 计算机工程, 2026, 52(2): 89-100.
[8]	郭天晟, 谢瑾奎. 自适应调节图增强与表示结构的推荐模型[J]. 计算机工程, 2026, 52(2): 69-78.
[9]	陈振清, 万加富, 张锐. 融合时序依赖性与数据特征的自适应无损分段压缩方法[J]. 计算机工程, 2026, 52(2): 79-88.
[10]	贾江浩, 张梓葳, 郜丽婷, 文娟, 薛一鸣. 基于层次感知匹配的文本隐写分析方法[J]. 计算机工程, 2026, 52(2): 245-252.
[11]	冉烔宇, 汤梦姿, 解庆, 刘永坚. 基于信息融合的半监督有序分类框架[J]. 计算机工程, 2026, 52(2): 287-298.
[12]	李强, 谭兴义, 郑唯, 刘震, 杨文海. 基于对抗训练与对比表示蒸馏的图神经网络推理优化[J]. 计算机工程, 2026, 52(1): 126-135.
[13]	李志仁, 郑卫国. 基于简单路径图的链接预测[J]. 计算机工程, 2026, 52(1): 95-104.
[14]	陈亮, 赵英, 史晟辉, 尹琳. 基于超图神经网络的链路预测方法[J]. 计算机工程, 2026, 52(1): 136-143.
[15]	曹渝昆, 王天浩, 李云峰, 陈明, 李晶晶, 刘元旻. 基于关系感知图神经网络的Text-to-SQL方法[J]. 计算机工程, 2025, 51(9): 129-138.

选择文件类型/文献管理软件名称

选择包含的内容

基于图神经网络的多指标沉井下沉姿态预测

Multi-Indicator Sinking Attitude Prediction of Open Caisson Based on Graph Neural Network

RichHTML

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 10

参考文献 27

相关文章 15

编辑推荐

Metrics

本文评价

模态框（Modal）标题

选择文件类型/文献管理软件名称

选择包含的内容

基于图神经网络的多指标沉井下沉姿态预测

Multi-Indicator Sinking Attitude Prediction of Open Caisson Based on Graph Neural Network

RichHTML

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 10

参考文献 27

相关文章 15

编辑推荐

Metrics

本文评价