Journal of Jilin University(Engineering and Technology Edition) ›› 2025, Vol. 55 ›› Issue (2): 577-590.doi: 10.13229/j.cnki.Jdxbgxb.20230411

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Chain-effect utility of factors influencing residents' commuting mode choice in polluted weather

Yu-ran LI1(),Fei WANG2,Cai-hua ZHU1,Fei HAN1,Yan LI1()   

  1. 1.College of Transportation Engineering,Chang'an University,Xi'an 710064,China
    2.CCCC First Highway Consultants Co. ,Ltd. ,Xi'an 710075,China
  • Received:2023-04-26 Online:2025-02-01 Published:2025-04-16
  • Contact: Yan LI E-mail:l_yuran@163.com;lyan@chd.edu.cn

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Abstract:

To explore the complete commuting mode choice behavior when residents are aware of PM2.5 inhalation and risk under different polluted weather, a revised ordering-based max-relevance and min-redundancy greedy (OMRMRG) Bayesian Network model was established to analyze the chain-effect utility of various variables. A questionnaire was designed to obtain residents' travel intentions in polluted weather after informing them of the risk level of their current commuting patterns and the pollutant inhalation of different travel modes. An OMRMRG structural learning algorithm with the introduction of mutual information theory was proposed to explore the chain-effect utility based on the causal relationship between variables. The results of analyzing the survey data of Xi'an residents show that: the variable chain with the greatest influence under light pollution is age-the presence of private car-daily commuting mode-polluted weather commuting mode, and 39% of residents reselect a commuting mode with a lower risk level than the daily commuting mode. The chain-effect utility of the influencing factors under heavy pollution is shown as age-income-the presence of private car-polluted weather commuting mode, and the correlations between the adjacent variables are positive, positive, positive and negative, respectively. The study reveals the chain-effect utility of different pollution conditions affecting residents' commuting patterns, which is beneficial to develop more constructive induced strategies to help residents travel healthily.

Key words: transportation planning and management, complete commuting process, chain-effect utility, Bayesian network, OMRMRG model, PM2.5 inhalation volume

CLC Number: 

  • U268.6

Table 1

Pollutant inhalation per minute of various travel modes"

方式年龄/岁轻度污染中度污染重度污染方式年龄/岁轻度污染中度污染重度污染
步行<222.691.743.582.314.673.01步行31~452.301.603.061.603.992.78
22~302.471.673.282.224.282.8946~602.211.572.941.573.832.73
骑行<224.452.835.923.767.724.90骑行31~453.662.544.872.546.344.41
22~304.002.655.323.536.934.5946~603.502.494.652.496.064.32
公交<222.521.553.352.074.372.69公交31~451.961.352.611.353.412.33
22~302.211.442.941.923.832.4946~601.831.312.441.313.172.26
地铁<222.581.763.432.344.473.05地铁31~452.101.592.791.593.642.76
22~302.301.673.062.223.992.8946~602.001.532.671.533.472.66
汽车<221.570.802.091.072.731.39汽车31~450.820.521.090.521.430.91
22~301.140.661.520.881.981.1446~600.660.460.880.461.140.80

Table 2

PM2.5 inhalation risk classification table"

空气质量

指数类别

AQI

指数值

PM2.5浓度限值/(μg·m-3

PM2.5吸入量限值/

(μg·min-1

等级

表示

颜色

对健康影响情况
0~500~350~0.55绿色 基本无空气污染
51~10036~750.56~1.17黄色 空气质量可接受,但可能对极少数异常敏感人群健康有较小影响
轻度污染101~15076~1151.18~1.80橙色 易感人群症状有轻度加剧,健康人群出现刺激症状
中度污染151~200116~1501.81~2.34红色 进一步加剧易感人群症状,可能对健康人群心脏、呼吸系统有影响
重度污染201~300151~2502.35~3.91紫色 心脏病和肺病患者症状加剧,运动耐受力降低,健康人群普遍出现症状
严重污染>300>250>3.91褐红色 健康人群运动耐受力降低,有明显强烈症状,提前出现某些疾病

Fig.1

Personal attribute"

Table 3

Questionnaire design"

属性变量符号定义

通勤者个

人属性

性别Gen0:女性 1:男性
年龄/岁Age1:<22 2:22~30 3:31~45 4:46~60
受教育程度Edu1:小学及以下 2:初中 3:高中(中专)4:本科(大专)5:研究生
家庭月收入/元Inc

1:<2 000 2:2 000~5 000 3:5 000~10 000 4:10 000~20 000

5:>20 000

吸烟状况Smo0:无 1:有
是否有心脏病或呼吸系统疾病史Sick0:无 1:有
私家车拥有情况Car0:无车 1:有车
非机动车拥有情况Bike0:无车 1:有车
通勤模式通勤距离Dis1:0~3 km 2:3~5 km 3:5~10 km 4:>10 km
完整通勤过程Mode需填写完整通勤链(如步行5 min-骑行10 min-地铁30 min-步行6 min),不足5 min的通勤方式忽略不计
早上通勤时间MT6:00~7:00(XMT1); 7:00~8:00(XMT2); 8:00~9:00(XMT3); 其他时间(XMT4) (若超过1 h,以整个通勤过程中的时间占比最长的时间段为准)
晚上通勤时间ET17:00~18:00(XET1); 18:00~19:00(XET2); 19:00~20:00(XET3); 其他(XET4) (若超过1 h,以整个通勤过程中的时间占比最长的时间段为准)
污染感知空气质量预报关注程度Wea1:基本不;2:偶尔;3:经常
PM2.5的危害了解程度Risk1:不了解;2:了解一些;3:了解
污染防护措施了解程度Pro1:不了解;2:了解一些;3:了解
是否采取污染防护措施Poll1:从不;2:偶尔;3:经常;4:总是
告知被调查者在3个场景下采用日常通勤模式时的风险等级和潜在危险,同时告知采用不同出行方式的PM2.5吸入量值和风险等级,具体空气质量指数类别和PM2.5吸入量对应风险等级划分参照表2
得知污染信息下的通勤模式场景一/二/三Scene1/2/33个场景下的完整通勤过程

Fig.2

Distribution of PM2.5 inhalation risk levels"

Fig.3

Mutual information values between commuting mode and variables"

Fig.4

Structures of Bayesian network under various scenes"

Table 4

Performance comparison of different Bayesian network learning algorithms"

算法场景一场景二场景三
平均运行时间/s平均识别率/%

平均BIC

评分

平均运行时间/s平均识别率/%

平均BIC

评分

平均运行时间/s平均识别率/%

平均BIC

评分

K2算法13.5383.45-2 643.1212.9383.56-2 758.9514.7382.74-2 690.44
爬山法14.1282.64-2 837.3814.5881.75-2 842.4314.9684.15-2 943.63
OMRMRG5.6490.56-1 834.296.3988.46-1 958.535.3490.70-2 068.97
改进OMRMRG3.8893.53-1 539.882.9492.94-1 746.863.2494.29-1 748.53

Fig.5

Characteristics of commuting mode choice behaviors under various scenes"

Fig.6

Distribution of PM2.5 inhalation increment under various polluted weathers"

Fig.7

Posterior probability distribution of commuting mode choice under polluted weather"

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