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浙江大学学报(工学版)
浙江大学学报(工学版)  2026, Vol. 60 Issue (6): 1185-1195    DOI: 10.3785/j.issn.1008-973X.2026.06.005
土木工程、交通工程     
异质性解耦与特征分层建模驱动的交通流预测
侯越(),谢金龙,张琳栋,尹杰,王甜甜
兰州交通大学 电子与信息工程学院,甘肃 兰州 730070
Traffic flow prediction driven by heterogeneity decoupling and feature layered modeling
Yue HOU(),Jinlong XIE,Lindong ZHANG,Jie YIN,Tiantian WANG
School of Electronic and Information Engineering, Lanzhou Jiaotong University, Lanzhou 730070, China
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摘要:

为了解决现有交通流预测模型难以捕捉不同时间片下的动态变化,且无法充分考虑不同区域流量分布的差异化特征的问题,提出新型的交通流预测模型CFHD-Former. 该模型引入自适应高频异质化模块和渐进调优机制,增强对不同时间片交通状态的适应性. 在捕捉时间异质化特征的基础上,利用核心流动点识别模块,根据节点流量特征来划分核心与非核心流动路网,通过空间编码器实现对2类路网的异质化建模. 在反向传播过程中引入频域自相关MAE损失函数,考虑预测序列不同时间步间的依赖关系,达到降低多步预测误差的目的. 实验结果表明,相较于最优的基线模型,在PEMS04、PEMS08及METRLA 3个数据集上,所提CFHD-Former模型的MAE分别降低了1.70%、4.58%、4.44%. 结果验证了CFHD-Former模型在复杂路网时空异质性建模方面的有效性,为城市交通流预测提供了新的解决方案.
关键词: 交通流预测时空异质性核心流动点识别异质化建模差异化特征    
Abstract:

A new traffic flow prediction model named CFHD-Former was proposed in order to address the limitations of existing traffic flow prediction models that struggle to capture dynamic variations across different time slices and cannot adequately consider the heterogeneous characteristics of traffic volume distributions across regions. An adaptive high-frequency heterogeneity module and a progressive optimization mechanism were introduced to enhance its adaptability to traffic states under different time slices. A core flow node identification module was employed building on the captured temporal heterogeneity feature in order to partition the road network into core and non-core flow networks based on nodal traffic flow characteristics. Heterogeneous modeling of the two types of road network was implemented via a spatial encoder. A frequency-domain autocorrelation MAE loss function was incorporated during backpropagation in order to consider the dependencies among different time steps within the prediction sequence, thereby reducing multi-step prediction errors. The experimental results demonstrated that the MAE of the proposed CFHD-Former model was reduced by 1.70%, 4.58% and 4.44% on the PEMS04, PEMS08 and METR-LA datasets, respectively compared with the best-performing baseline model. Results verified the effectiveness of CFHD-Former in modeling the spatio-temporal heterogeneity of complex road networks and provided a new solution for urban traffic flow prediction.
Key words: traffic flow prediction    spatio-temporal heterogeneity    core flow point identification    heterogeneous modeling    heterogeneous characteristic
收稿日期: 2025-03-06 出版日期: 2026-05-06
CLC:  U 491  
基金资助: 国家自然科学基金资助项目(62063014,62363020).
作者简介: 侯越(1979—),女,教授,博导,从事大数据智能交通的研究. orcid.org/0000-0002-8289-329X. E-mail:houyue@mail.lzjtu.cn
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引用本文:

侯越,谢金龙,张琳栋,尹杰,王甜甜. 异质性解耦与特征分层建模驱动的交通流预测[J]. 浙江大学学报(工学版), 2026, 60(6): 1185-1195.

Yue HOU,Jinlong XIE,Lindong ZHANG,Jie YIN,Tiantian WANG. Traffic flow prediction driven by heterogeneity decoupling and feature layered modeling. Journal of ZheJiang University (Engineering Science), 2026, 60(6): 1185-1195.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.06.005        https://www.zjujournals.com/eng/CN/Y2026/V60/I6/1185

图 1  住宅区与市中心位置分布
图 2  市中心与住宅区的流量时变特征对比
图 3  输入-预测序列的自相关性分析
图 4  CFHD-Former模型的架构图
图 5  时间Transformer的结构
图 6  节点流入流出能力计算的示意图
图 7  空间Transformer的结构
图 8  递归与直接预测范式的对比
图 9  频域变换的示意图
数据集地区节点长度日期
PeMS04旧金山湾区307169922018.01—02
PeMS08圣贝纳迪诺区170178562016.07—09
METRLA洛杉矶县207342722012.03—06
表 1  Caltrans PeMS数据集的基本信息
模型PEMS04PEMS08METRLA
MAERMSEMAPE/%MAERMSEMAPE/%MAERMSEMAPE/%
ARIMA28.5540.3619.5531.2333.4719.256.0811.3714.62
ST-Norm18.9630.9812.6915.4124.779.763.146.458.60
SCINet19.3031.2812.0515.7624.6510.013.466.629.25
STGCN19.5731.2813.4416.0825.3910.603.166.388.69
DCRNN19.6331.2613.5916.2225.1710.813.246.478.92
GWNet18.8330.0112.9414.9823.9910.213.176.619.21
DGCRN19.0130.5112.1914.8023.759.463.186.388.76
GMAN19.1431.6013.1915.3124.9210.133.256.528.76
ASTGNN18.6030.9112.3615.0024.759.503.306.648.78
PDFormer18.5130.2412.3814.3423.689.883.156.548.71
CFHD-Former18.3229.9812.0113.7423.289.033.036.268.35
表 2  基于PEMS04、PEMS08、METRLA数据集的不同基准线模型的预测准确度对比
图 10  不同消融模型的预测性能分析
tp/minMAE
CFHD-Former-HFCFHD-Former-PTCFHD-Former-CPCFHD-Former-FLCFHD-Former
1512.8512.2512.4112.0511.94
3015.8515.1714.2114.0813.67
6018.9816.9315.8616.1715.25
tp/minRMSE
CFHD-Former-HFCFHD-Former-PTCFHD-Former-CPCFHD-Former-FLCFHD-Former
1520.3619.3920.3319.7119.55
3026.2425.9824.3424.1623.41
6031.2528.9627.1327.9426.09
tp/minMAPE/%
CFHD-Former-HFCFHD-Former-PTCFHD-Former-CPCFHD-Former-FLCFHD-Former
158.367.918.207.967.89
3010.209.939.309.218.95
6012.4611.1810.4710.7510.07
表 3  消融模型在不同时间步下的预测性能
图 11  关键超参数的敏感性分析
图 12  核心流动点的地理空间分布
图 13  核心与非核心流动点的流量时变模式对比
图 14  基于不同日期数据的t-SNE降维可视化
图 15  CFHD-Former与DGCRN拟合真实值的对比
图 16  CFHD-Former与基线模型在不同扰动比例噪声下的预测误差对比
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