Journal of Jilin University(Engineering and Technology Edition) ›› 2024, Vol. 54 ›› Issue (12): 3505-3512.doi: 10.13229/j.cnki.jdxbgxb.20230184

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Real-time detection method of angry driving behavior based on bracelet data

Shi-feng NIU1,2(),Shi-jie YU2,Yan-jun LIU2,Chong MA2   

  1. 1.Key Laboratory of Automotive Transportation Safety Assurance Technology for Transportation Industry,Chang'an University,Xi'an 710064,China
    2.School of Automobile,Chang'an University,Xi'an 710064,China
  • Received:2023-03-01 Online:2024-12-01 Published:2025-01-24

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Abstract:

A method for detecting drivers' angry driving behavior has been designed using widely used popular smart bracelet, which provides a new way and method for effective monitoring of angry driving behavior. 50 drivers were recruited to conduct a simulated driving experiment, and a simulated driving scene that caused anger was designed. Then, heart rate index HR and eight heart rate variability (HRV) indexes such as RR.mean, SDNN, RMSSD, PNN50, SDSD, HF, LF and LF/HF obtained from bracelet collection data were used to study the correlation between the acquisition indexes and the angry driving behavior, and screen the significant influence indexes Finally, using three methods, namely support vector machine (SVM), K-nearest neighbor (KNN) and linear discriminant analysis (LDA), established and verified the detection model of angry driving behavior. The results show that the model based on KNN algorithm has the best performance on anger recognition. The accuracy of anger intensity recognition can reach 75%, and the accuracy of anger state recognition is 86 %. The results show that the wearable device (smart bracelet) can reasonably detect the driver 's anger state and anger intensity.

Key words: vehicle application engineering, anger driving behavior, machine learning, smart bracelet, heart rate variability

CLC Number: 

  • U492.8

Fig.1

Smart bracelet and ECG collection App"

Fig.2

Schematic diagram of driving simulation system composition"

Fig.3

Three-screen automobile driving simulator"

Fig.4

Number of people whose scores are equal to 1 and greater than or equal to 4"

Table 1

Experimental scene of anger induction"

正常情绪实验场景愤怒诱导实验场景
道路顺畅且无其他车辆干扰的城市道路,天气条件正常,能见度清晰,双向四车道,限速为60 km/h,相对愤怒诱导场景进行设置A:周边车辆抢道加塞
B:交通拥挤
C:等红灯
D:前车启动慢

Table 2

Angry driving behavior alternative detection indicator"

特征类型符号含义
心率HR/(次·min-1-

HRV

时域特征

RR.mean/msRR间期均值
SDNN/msRR间期标准差
RMSSD/msRR间期差值均方根
NN50/次RR间期大于50 ms的个数
PNN50/%NN50除以NN间期总数的比例

HRV

频域特征

LF/ms2低频功率(0.04~0.15 Hz)
HF/ms2高频功率(0.15~0.4 Hz)
LF/HFLF和HF的比值

非线性

指标

SD1表示垂直于标识线点的标准偏差
SD2表示的同一条直线的标准偏差
SD2/SD1横纵标准偏差比值

Fig.5

Poincaré figure"

Table 3

Difference detection results of angry driving behavior detection indicators under different anger levels"

指标卡方自由度渐近显著性
HR155.1142.000
RR.mean98.1752.000
SDNN10.6442.005
RMSSD22.9422.000
PNN5014.4602.001
SD27.70220.026
SD11.98620.159
SD2/SD17.90020.005
LF0.21520.834
HF78.04620.000
LF/HF4.85320.063

Table 4

Evaluation indicators and formulas"

指标公式
TPRTPR=TPTP+FN×100%
FPRFPR=FPTN+FP×100%
PPAPPA=TPTP+FP×100%
F1F1=2×PPA×TPRTPR+PPA
ACCACC=TP+TNTP+FP+FN+FP×100%
AUCAUC=iUranki-M×1+M2M×N

Table 5

Effect of angry driving behavior detection model distinguishing anger level"

模型指标TPRPPAF1FPR
SVM正常0.9090.8330.8700.190
轻微0.6670.7500.7060.171
强烈0.6000.480.5330.121
KNN正常0.9010.8260.8620.184
轻微0.8120.7200.7630.242
强烈0.8250.8250.8250.033
LDA正常0.8350.8150.8240.181
轻微0.8720.6670.7560.331
强烈0.5000.9520.6560.005

Table 6

Detection effect table of anger driving behavior detection model distinguishing anger level"

评价指标SVMKNNLDA
TPR0.7250.8460.736
FPR0.1610.1530.172
PPA0.6880.7900.811
F1 score0.7030.8170.745
AUC0.9400.9400.940
ACC0.7340.7590.737

Fig.6

Recognition effect of each classifier on two driving anger states"

Table 7

Detection effect table of angry driving behavior detection model without distinguishing anger level"

评价指标SVMKNNLDA
TPR0.8760.8930.785
FPR0.1020.1660.121
PPA0.8690.8060.833
F1 score0.8720.8470.809
ACC0.8880.8600.838
AUC0.9600.9400.930
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