基于深度学习的车辆行驶风险与转向意图预测模型

doi:10.16265/j.cnki.issn1003-3033.2026.04.1070

摘要/Abstract

摘要：

针对传统模型存在多维时序特征挖掘能力有限以及类别不平衡问题,提出一种基于类别平衡损失(CB)机制-非对称损失(ASL)机制-TimesNet的多任务行驶风险预测模型。利用滑动时间窗口提取多维时序特征,提升风险等级标注的客观性与细致性,并基于这些特征构建前向、后向、侧向碰撞风险及转向意图4类标签;在模型构建方面,融入TimesNet网络,有效捕捉多维时序特征的周期性变化与动态演化特性,增强复杂驾驶场景下时序信息的建模能力;结合CB与ASL机制设计损失函数,提升模型在类别不平衡条件下的预测性能。结果表明:提出的CB-ASL-TimesNet模型在行驶风险与转向意图预测任务中的平均准确率达到0.908 6,与传统机器学习模型CatBoost相比提升16%,较主流时间序列模型门控循环单元(GRU)提升5.8%,验证了所提模型在提升预测性能方面的显著有效性。

关键词: 深度学习, 行驶风险与转向意图, 类别不平衡, TimesNet, 损失函数

Abstract:

To address the limitations of traditional models in mining multi-dimensional temporal features and handling class imbalance, A multi-task driving risk prediction model based on Class Balance loss (CB)- Asymmetric Loss (ASL)-TimesNet and is proposed. A sliding time window was employed to extract multi-dimensional temporal features, improving the objectivity and granularity of risk level labeling. Based on these features, four types of labels were constructed: forward collision risk, rear collision risk, lateral collision risk, and steering intention. In terms of model design, the TimesNet architecture was incorporated to effectively capture periodic variations and dynamic evolution in multi-dimensional temporal features, thereby enhancing the modeling capability of temporal information in complex driving scenarios. Meanwhile, a hybrid loss function integrating CB and ASL was devised to improve prediction performance under class-imbalanced conditions. Experimental results demonstrate that the proposed CB-ASL-TimesNet model achieves an average accuracy of 0.908 6 in driving risk and steering intention prediction tasks. Compared with the traditional machine learning model CatBoost, the proposed approach yields a 16% improvement, and it outperforms the mainstream time-series model Gate Recurrent Unit(GRU) by 5.8%, verifying the significant effectiveness of the proposed model in enhancing prediction performance.

Key words: deep learning, driving risk and steering intention, category imbalance, TimesNet, loss function

中图分类号:

X951交通运输安全

程方明, 胡佳萌, 苟蕊. 基于深度学习的车辆行驶风险与转向意图预测模型[J]. 中国安全科学学报, 2026, 36(4): 94-102.

Cheng Fangming, Hu Jiameng, Gou Rui. A driving risk and steering intention prediction model based on deep learning[J]. China Safety Science Journal, 2026, 36(4): 94-102.

图/表 9

表1

数据结构

因素	原始特征参数及单位	描述	数据类型
物理相关因素	X轴加速度/(m/s²)	车辆垂向加速度	连续型
	Y轴加速度/(m/s²)	车辆横向加速度	连续型
	Z轴加速度/(m/s²)	车辆纵向加速度	连续型
	横滚角/(°)	—	连续型
	俯仰角/(°)	—	连续型
	偏航角/(°)	—	连续型
	速度/(km/h)	—	连续型
	高度(海拔)/m	—	连续型
	航向角/(°)	—	连续型
	航向变化量/(°)	—	连续型
	加速评分	0~100,越高表示越平稳	区间型
	刹车评分	0~100,越高表示刹车越平滑	区间型
	转弯评分	0~100,越高表示转弯越平稳	区间型
	漂移评分	0~100,越高表示越少漂移行为	区间型
	车辆与车道中心的偏移/m	—	连续型
道路相关因素	汽车相对于车道曲率的角度/(°)	—	连续型
	道路宽度/m	—	连续型
	车道检测算法状态	-1=校准中, 0=初始化, 1=未检测到, 2=检测到/运行中	离散型
	当前道路限速/(km/h)	—	连续型
	获取的最高限速的可靠性	0=未知, 1=可靠, 2=使用先前获取的最高限速, 3=根据道路类型估计	离散型
	道路类型	高速公路、主干道、二级公路等	离散型
	当前道路的车道数	—	连续型
	估计的当前车道	1=右车道, 2=最左侧车道, 3=从右往左数第二个左侧车道等	离散型
	GPS纬度	GPS坐标	连续型
	GPS经度	GPS坐标	连续型
	OSM回答查询的延迟时间/s	—	连续型
	垂直精度/m	—	连续型
	水平精度/m	—	连续型
	位置状态	状态码	离散型
	车道状态	状态码	离散型
	超速评分	0~100,越高表示超速行为越少	区间型
	与前车距离/m	—	连续型
交互相关因素	与前车碰撞时间/s	—	连续型
	检测到的车辆数	—	连续型
	跟车评分	0~100,反映与前车时距控制情况	区间型
	变道类型	+表示右向变道,-表示左向变道	离散型
	变道评分	0~100,越高表示越少急剧横向变道	区间型

表1

表2

图1

表3

表4

表5

图2

表6

图3

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标签	标签设计依据	标签设计方法	类别样本数(K=2/K=3/K=4)
前向碰撞风险	Z轴加速度、与前车距离、碰撞时间、速度、超速评分、跟车评分、加速评分	K-means聚类	K=2:6 033/22 293 K=3:4 397/1 602/22 327 K=4:587/1 157/1 423/25 168
后向碰撞风险	Z轴加速度、速度、刹车评分、加速评分		K=2:5 401/22 925 K=3:3 555/3 453/21 318 K=4:875/1 828/4 551/21 072
侧向碰撞风险	Y轴加速度、漂移评分、变道评分、转弯评分、车道偏离估计		K=2:7 457/20 869 K=3:6 097/5 732/16 497 K=4:663/6 197/1 447/20 019
转向意图预测	变道类型(左变道、右变道、直行)	行为驱动规则	1 615/1 092/25 619

模块	超参数	范围	说明
TimesNet	d_model	64,128,256	模型内部特征维度
	e_layers	1,2	TimesBlock堆叠层数,即TimesBlock模块数量
	d_ff	64,128,256	前馈网络隐藏维度
	num_kernels	3,5	卷积核数量,用于提取不同周期特征
	top_k	3,4,5	FFT提取主导频率时保留的最大频率数量
损失函数	γ^-	2,3	对易分类的负类样本的惩罚程度
	γ⁺	0	对易分类的正类样本的惩罚程度
	t	0.05	非对称概率截断阈值
	β	0.999,0.999 2,0.999 4,0.999 6	CB Loss中的类别平衡因子

指标	指标含义	评估依据	评估标准
准确率A	预测正确的样本占总样本的比例	(TP+TN)/(TP+TN+FP+FN)	值越高越好
精确率R	预测为正例的样本中真实正例的比例	TP/(TP+FP)	值越高越好
召回率P	真正例被预测为正例的比例	TP/(TP+FN)	值越高越好
F₁值	调和平均的R和P	$\frac{2\times R\times P}{(R+P)}$	越接近1越好

模型	4项任务平均指标
模型	A	R	P	F₁
CatBoost	0.782 9	0.782 9	0.790 6	0.753 6
BP	0.787 1	0.787 1	0.795 7	0.784 8
CNN	0.825 6	0.825 6	0.837 9	0.825 5
GRU	0.858 9	0.858 9	0.852 0	0.847 7
Transformer	0.851 6	0.851 6	0.865 6	0.851 9
TimeMixer	0.861 1	0.861 1	0.858 5	0.856 1
TimesNet	0.876 4	0.876 4	0.870 9	0.868 1

模型	4项任务平均指标
模型	A	R	P	F₁
TimesNet	0.876 4	0.876 4	0.870 9	0.868 1
CB-TimesNet	0.867 0	0.867 0	0.867 2	0.872 5
ASL-TimesNet	0.889 2	0.889 2	0.880 3	0.881 2
CB-ASL- TimesNet	0.908 6	0.908 6	0.895 5	0.897 1