吉林大学学报(工学版) ›› 2024, Vol. 54 ›› Issue (6): 1582-1592.doi: 10.13229/j.cnki.jdxbgxb.20220888

• 交通运输工程·土木工程 • 上一篇    

基于动态扩散图卷积的交通流量预测算法

井佩光1(),田雨豆1,汪少初2,李云3(),苏育挺1   

  1. 1.天津大学 电气自动化与信息工程学院,天津 300072
    2.天津市测绘院有限公司,天津 300072
    3.广西财经学院 大数据与人工智能学院,南宁 530001
  • 收稿日期:2022-07-13 出版日期:2024-06-01 发布日期:2024-07-23
  • 通讯作者: 李云 E-mail:pgjing@tju.edu.cn;liyun@guat.edu.cn
  • 作者简介:井佩光(1988-),男,副教授,博士.研究方向:短视频语义分析及理解,跨媒体智能计算,机器学习,时间序列处理.E-mail:pgjing@tju.edu.cn
  • 基金资助:
    国家自然科学基金项目(62361002);辽宁省自然科学基金项目(2023-MS-139)

Traffic flow prediction algorithm based on dynamic diffusion graph convolution

Pei-guang JING1(),Yu-dou TIAN1,Shao-chu WANG2,Yun LI3(),Yu-ting SU1   

  1. 1.School of Electrical and Information Engineering,Tianjin University,Tianjin 300072,China
    2.Tianjin Institute of Surveying and Mapping Co. Ltd. ,Tianjin 300072,China
    3.College of Big Data and Artificial Intelligence,Guangxi University of Finance and Economics,Nanning 530001,China
  • Received:2022-07-13 Online:2024-06-01 Published:2024-07-23
  • Contact: Yun LI E-mail:pgjing@tju.edu.cn;liyun@guat.edu.cn

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摘要:

为了得到准确的交通流量预测结果,提出一种基于动态扩散图卷积的交通流量预测模型。首先,利用扩散图卷积模型对不同节点间的空间特征进行学习;其次,通过引入动态邻接矩阵,以确保各节点在不同时刻间的特征都得到充分学习;再次,采用门控循环单元,对交通流量数据进行时间特征提取;最后,通过模型层级间的残差连接,传递更多原始信息以增强模型的稳定性。在4个公开数据集上的实验结果证明本文算法在交通流量预测任务中的有效性。

关键词: 人工智能, 交通流量预测, 门控循环单元, 扩散图卷积

Abstract:

In order to obtain accurate traffic flow prediction results, a traffic flow prediction algorithm based on dynamic diffusion graph convolution was proposed. Firstly, the model used the diffusion graph convolution model to learn the spatial characteristics between different nodes. Secondly, the dynamic adjacency matrix was introduced to ensure that the characteristics of each node at each time can be learned. Once more, the model used the gated recurrent unit to extract the time characteristics of traffic flow data. Finally, residual connection between model levels was used to transfer more original information and enhance the stability of the model. The experimental results on four open data sets can prove the effectiveness of the algorithm in traffic flow prediction tasks.

Key words: artificial intelligence, traffic flow prediction, gated recurrent unit, diffusion graph convolution

中图分类号: 

  • TN18

图1

动态扩散图卷积的交通流量预测算法"

图2

基于DGCN的GRU"

图3

层间级残差连接"

表 1

DDGCN中不同模块对实验结果的影响"

模块MAERMSEMAPE
DGCN21.0835.0613.79
DGCN+DAM20.9334.5813.56
DGCN+DAM+GRU19.9132.7712.92
DDGCN19.2831.5012.72

图4

不同道路口在50 min 四个模型的预测值与真值对比图"

表2

DDGCN与其他模型在不同数据集下15 min的实验结果"

模型PeMSD3PeMSD4PeMSD7MPeMSD8
MAERMSEMAPEMAERMSEMAPEMAERMSEMAPEMAERMSEMAPE
HA20.6842.4621.3722.1934.3312.752.033.879.0918.4533.3210.16
VAR23.9938.3322.7722.5334.7412.272.383.698.9921.8732.1013.39
DCRNN14.4924.8716.5918.8830.4214.889.8613.8428.6414.6922.349.28
ASTGCN20.633.6021.0422.2134.716.034.557.7311.7120.0130.2412.8
Graph-Wave13.5823.1912.1118.6629.5813.551.763.244.0514.3522.199.23
AGCRN13.2122.6812.9218.2129.3712.021.803.364.2014.1722.399.25
STODE16.5027.8416.6920.8432.8213.772.033.965.0614.6725.9710.62
STG-NCDE14.3524.9414.2117.4630.0514.441.733.894.6815.0223.849.73
SCINet14.0222.3413.1218.9730.5811.861.793.354.9414.8923.329.46
DDGCN13.0322.5313.0018.1429.1411.641.723.634.2714.0222.649.21

表3

DDGCN与其他模型在不同数据集下30 min的实验结果"

模型PeMSD3PeMSD4PeMSD7MPeMSD8
MAERMSEMAPEMAERMSEMAPEMAERMSEMAPEMAERMSEMAPE
HA22.7744.8824.0623.3137.4715.023.365.5910.8619.8535.4512.61
VAR23.9938.3322.7723.7136.3715.893.675.2510.7623.2333.4615.66
DCRNN15.4126.2515.1619.7030.9914.089.4514.1928.8215.1923.7415.96
ASTGCN20.2833.2420.3124.1036.9217.834.497.5911.4421.5631.9414.83
Graph-Wave13.9824.2514.7518.9730.4113.372.194.185.2514.4923.779.73
AGCRN14.3725.1913.7119.4331.1012.942.274.445.5415.3224.2710.01
STODE16.5027.8416.6920.8432.8213.772.434.265.5815.1425.9710.62
STG-NCDE15.6426.6114.9219.4332.0212.782.334.495.6015.8525.1210.02
SCINet15.4824.6214.2419.0230.0211.852.614.675.7416.0325.139.53
DDGCN14.1224.1313.6719.0530.1011.722.084.045.2514.6123.529.64

表4

DDGCN与其他模型在不同数据集下60 min的实验结果"

模型PeMSD3PeMSD4PeMSD7MPeMSD8
MAERMSEMAPEMAERMSEMAPEMAERMSEMAPEMAERMSEMAPE
HA24.9146.0025.8124.5039.8316.584.297.6911.5621.1936.6413.79
VAR23.9938.3322.7725.1838.3617.484.777.3211.2124.2235.1316.57
DCRNN16.2227.7317.1620.0632.5213.863.356.898.1116.3425.4710.55
ASTGCN17.8629.7017.5923.0935.7816.183.616.449.1819.1728.8613.19
Graph-Wave22.8336.7622.2419.6731.3813.282.695.176.8215.9223.829.69
AGCRN16.3227.7315.0819.7932.2913.132.805.617.1315.9525.2910.17
STODE16.5027.8416.6920.8432.8213.772.975.667.3616.8125.9710.62
STG-NCDE15.5727.3515.0619.3431.1012.872.735.416.8615.8525.1210.02
SCINet15.7927.6714.5819.3031.8212.062.705.316.8115.7624.829.91
DDGCN15.5027.2114.5619.2831.5012.722.685.406.8015.7424.9810.08

图5

不同道路口在50 min四个模型的预测值和真值对比图"

表5

不同预测时间参数下的时间敏感性分析结果"

模型15 min30 min60 min
MAERMSEMAPEMAERMSEMAPEMAERMSEMAPE
DDGCNPeMSD313.0322.5313.0014.1225.2313.6715.5027.2114.56
PeMSD418.1429.1411.6419.0530.1011.7219.2831.5012.72
PeMSD7M1.723.634.273.102.084.045.255.406.80
PeMSD814.0222.649.2114.6123.529.6415.7424.9810.08
DDGCN1PeMSD315.6428.3015.1316.1427.2514.8617.1330.2216.63
PeMSD418.5730.3112.0619.8331.9812.0521.9833.8314.09
PeMSD7M2.024.309.313.323.239.423.876.897.02
PeMSD815.5023.2113.1515.4224.5610.2916.1725.0211.00
DDGCN2PeMSD318.2630.1816.7319.7331.6618.4519.1232.2719.61
PeMSD419.7931.3713.2519.4033.1914.4321.6935.1315.39
PeMSD7M2.394.639.433.055.069.283.316.658.38
PeMSD816.5925.7910.5516.9427.4511.4917.7728.1711.34
1 Li Y G, Shahabi C. A brief overview of machine learning methods for short-term traffic forecasting and future directions[J]. Sigspatial Special, 2018, 10(1): 3-9.
2 Vlahogianni E I, Karlaftis M G, Golias J C. Short-term traffic forecasting: where we are and where we're going[J]. Transportation Research Part C: Emerging Technologies, 2014, 43: 3-19.
3 Smith B L, Williams B M, Oswald R K. Comparison of parametric and nonparametric models for traffic flow forecasting[J]. Transportation Research Part C, 2002, 10(4): 303-321.
4 Zivot E, Wang J H. Vector autoregressive models for multivariate time series[EB/OL]. [2022-07-02].
5 Williams B M, Hoel L A. Modeling and forecasting vehicular traffic flow as a seasonal ARIMA process: theoretical basis and empirical results[J]. Journal of Transportation Engineering, 2003, 129(6): 664-672.
6 Wu C H, Ho J M, Lee D T. Travel-time prediction with support vector regression[J]. IEEE Transactions on Intelligent Transportation Systems, 2004, 5(4): 276-281.
7 Lint H V, Hinsbergen C V. Short-term traffic and travel time prediction models[J]. Transportation Research Circular, 2012, 22(1): 22-41.
8 Yao H X, Wu F, Ke J T, et al. Deep multi-view spatial-temporal network for taxi demand prediction[C]∥International Conference on Artificial Intelligence, New Orleans, LA, USA, 2018, 32: 2588-2595.
9 Zhang C Y, Paul P. Long-term mobile traffic forecasting using deep spatio-temporal neural networks[C]∥International Symposium on Mobile Ad Hoc Networking and Computing, LA, USA, 2018, 231-240.
10 Guo S N, Lin Y F, Li S J, et al. Deep spatial-temporal 3D convolutional neural networks for traffic data forecasting[J]. IEEE Transactions on Intelligent Transportation Systems, 2019, 20(10): 3913-3926.
11 苏育挺,王骥,赵玮,等.基于动态图卷积的图像情感分布预测[J].吉林大学学报: 工学版,2023,53(9):2601-2610.
Su Yu-ting, Wang Ji, Zhao Wei, et al. Image sentiment distribution prediction based on dynamic graph convolution[J]. Journal of Jilin University (Engineering Edition), 2023, 53(9): 2601-2610.
12 Li Y G, Yu R, Shahabi C, et al. Diffusion convolutional recurrent neural network: data-driven traffic forecasting[C]∥International Conference on Learning Representations, Vancouver, Canada, 2018: 1-16.
13 Guo S N, Lin Y F, Feng N, et al. Attention based spatial-temporal graph convolutional networks for traffic flow forecasting[C]∥International Conference on Artificial Intelligence, Honolulu, Hawaii, USA, 2019, 33(1): 922-929.
14 Zhao L, Song Y J, Zhang C, et al. T-GCN: a temporal graph convolutional network for traffic prediction[J]. IEEE Transactions on Intelligent Transportation Systems, 2020, 21(9): 3848-3858.
15 Bai L, Yao L, Li C, et al. Adaptive graph convolutional recurrent network for traffic forecasting[C]∥International Conference on Neural Information Processing Systems, Virtual, 2020, 33: 17804-17815.
16 Wu Z H, Pan S R, Long G D, et al. Graph wavenet for deep spatial-temporal graph modeling[C]∥International Conference on Artificial Intelligence, Honolulu, Hawaii, USA, 2019: 1907-1913.
17 Li Z M, Lai D R. Dynamic network embedding via temporal path adjacency matrix factorization[C]∥International Conference on Information & Knowledge Management, Atlanta, GA, USA, 2022: 1219-1228.
18 Cho K, Merrienboer B V, Gulcehre C, et al. Learning phrase representations using rnn encoder-decoder for statistical machine translation[C]∥International Conference on Empirical Methods in Natural Language Processing, Columbia, Maryland, USA, 2014: 1724-1734.
19 Shuman D I, Narang S K, Frossard P, et al. The emerging field of signal processing on graphs: extending high-dimensional data analysis to networks and other irregular domains[J]. IEEE signal processing magazine, 2013, 30(3): 83-98.
20 Chen P, Sun Z Q, Bing L D, et al. Recurrent attention network on memory for aspect sentiment analysis[C]∥International Conference on Empirical Methods in Natural Language Processing, Copenhagen, Denmark, 2017: 452-461.
21 Chen J Y, Wang X K, Xu X H. Gc-lstm: graph convolution embedded lstm for dynamic link prediction[DB/OL]. [2022-07-02].
22 Si C Y, Chen W H, Wang W, et al. An attention enhanced graph convolutional lstm network for skeleton-based action recognition[C]∥International Conference on Computer Vision and Pattern Recognition, Long Beach, California, USA, 2019: 1227-1236.
23 Fang Z, Long Q Q, Song G, et al. Spatial-temporal graph ode networks for traffic flow forecasting[C]∥ International Conference on Knowledge Discovery & Data Mining, Virtual, 2021: 364-373.
24 Choi J, Choi H, Hwang J, et al. Graph neural controlled differential equations for traffic forecasting[C]∥International Conference on Artificial Intelligence, Wien, Vienna, Austria, 2022, 36(6): 6367-6374.
25 Liu M H, Zeng A, Xu Z, et al. Time series is a special sequence: forecasting with sample convolution and interaction[C]∥International Conference on Neural Information Processing Systems, Orleans, Louisiana, USA, 2022: 1-18.
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