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基于文本挖掘的铁路沿线自然灾害网络潜在风险路径预测

顾爽 程国柱 闫冬阳

顾爽, 程国柱, 闫冬阳. 基于文本挖掘的铁路沿线自然灾害网络潜在风险路径预测[J]. 交通运输工程学报, 2026, 26(5): 260-274. doi: 10.19818/j.cnki.1671-1637.2026.121
引用本文: 顾爽, 程国柱, 闫冬阳. 基于文本挖掘的铁路沿线自然灾害网络潜在风险路径预测[J]. 交通运输工程学报, 2026, 26(5): 260-274. doi: 10.19818/j.cnki.1671-1637.2026.121
GU Shuang, CHENG Guo-zhu, YAN Dong-yang. Prediction of potential risk paths in natural disaster network along railway lines based on text mining[J]. Journal of Traffic and Transportation Engineering, 2026, 26(5): 260-274. doi: 10.19818/j.cnki.1671-1637.2026.121
Citation: GU Shuang, CHENG Guo-zhu, YAN Dong-yang. Prediction of potential risk paths in natural disaster network along railway lines based on text mining[J]. Journal of Traffic and Transportation Engineering, 2026, 26(5): 260-274. doi: 10.19818/j.cnki.1671-1637.2026.121

基于文本挖掘的铁路沿线自然灾害网络潜在风险路径预测

doi: 10.19818/j.cnki.1671-1637.2026.121
基金项目: 

中央高校基本科研业务费专项资金项目 2572023CT21

黑龙江省哲学社会科学研究规划年度项目 24GLC014

详细信息
    作者简介:

    顾爽(1994-),女,黑龙江依兰人,讲师,理学博士,博士后,E-mail: s.gu@nefu.edu.cn

    通讯作者:

    程国柱(1977-),男,河北大成人,教授,博士生导师,工学博士,博士后,E-mail: guozhucheng@126.com

  • 中图分类号: U298

Prediction of potential risk paths in natural disaster network along railway lines based on text mining

Funds: 

Fundamental Research Funds for the Central Universities 2572023CT21

Annual Philosophy and Social Science Foundation of Heilongjiang Province 24GLC014

More Information
Article Text (Baidu Translation)
  • 摘要:

    为揭示铁路沿线自然灾害链式传播机理,量化其对铁路运输安全的威胁并解析风险演化规律,构建了基于文本挖掘与复杂网络的铁路沿线自然灾害风险路径预测模型。以铁路沿线历史灾害文本数据集为基础,改进了文本挖掘技术,优化词袋模型并结合关键字提取方法,精准抽取了灾害数据中的铁路站点、致灾因子、后果及严重程度等核心要素;基于复杂网络理论,以关键词为节点(3类实体),以同事件共现语义关联为边(6类关系),建立了铁路灾害风险异构网络;设计多元路径搜索算法遍历网络拓扑,融合关联共现矩阵量化节点间风险传导强度,实现了多类型传播路径的过程化挖掘。分析结果表明:模型接收者操作特征曲线接近左上角,曲线下面积为0.938,准确率达94.873%,F1分数为0.899;量化输出节点对间风险传导值,成功定位高概率灾害链为芒康站→强降雪→香格里拉站→人员受灾→电力设备损毁(风险值0.866)、江达站→贡觉站→强对流天气→人员伤亡(风险值0.841)。所得模型通过文本驱动构建灾害语义网络,可实现铁路风险路径的定量化预测与关键传导链识别,精准定位二次灾害高发链路,为复杂环境铁路的风险主动防控提供支持。

     

  • 图  1  异构的灾害网络模拟

    Figure  1.  Simulation of a heterogeneous disaster network

    图  2  高原铁路沿线自然灾害异构网络

    Figure  2.  Heterogeneous network of natural disasters along the plateau railway

    图  3  不同方法在同质路径中的ROC曲线比较

    Figure  3.  ROC curve comparison for different methods in homogeneous paths

    图  4  不同方法在异质路径中的ROC曲线

    Figure  4.  ROC curve comparison for different methods in heterogeneous paths

    图  5  不同方法在所有混合路径中的ROC曲线比较

    Figure  5.  ROC curve comparison for different methods in all mixed paths

    图  6  PRP模型与其他对比方法t检验的箱线图与数据点叠加图

    Figure  6.  Box plot and data point overlay for t-test of PRP model and other comparative methods

    图  7  PRP模型对高原铁路沿线自然灾害风险路径预测结果的可视化

    Figure  7.  Visualization of PRP model for predicting natural disaster risk paths along the plateau railway

    图  8  风险传导路径可视化

    Figure  8.  Visual of risk transmission path

    表  1  典型链路预测方法

    Table  1.   Typical link prediction methods

    方法 分数计算公式
    启发式方法 局部算法 共同邻居(Common Neighbors, CN) $S_{i j}=|\varGamma(i) \cap \varGamma(j)|$
    优先依附(Preferential Attachment, PA) Sij=kikj
    Jaccard系数(JC) $S_{i j}=\frac{|\varGamma(i) \bigcap \varGamma(j)|}{|\varGamma(i) \bigcup \varGamma(j)|}$
    全局算法 平均通勤时间(Average Commute Time, ACT) $S_{i j}=\frac{1}{l_{i i}^{+}+l_{j j-}^{+}+2 l_{i j}^{+}}$
    矩阵森林(Matrix Forest, MF) Sij=lij
    图嵌入方法 随机游走(Random Walk, RW) Sij=qij+qji
    节点嵌入算法(Node2Vec)
    图神经网络方法 图采样聚合网络(Graph Sample and Aggregate, GraphSAGE)
    图卷积神经网络(Graph Convolutional Network, GCN)
    下载: 导出CSV

    表  2  高原铁路沿线部分自然灾害原始数据示例

    Table  2.   Example of original data on some natural disasters along the plateau railway

    事件ID 事件类型 公告日期 影响地区 灾情概述(节选)
    HL2014000035 洪涝 2014-07-22 四川省绵阳、德阳、乐山 7月19日以来,部分地区出现大雨、暴雨过程,引发洪涝灾害,截至7月22日统计,造成绵阳、德阳、乐山3市6个县(市、区)13万人受灾,100余间房屋倒塌,700余间损坏;直接经济损失6 800余万元
    DF2014000031 大风 2014-07-27 西藏自治区拉萨市林周县、昌都地区察雅县、阿里地区措勤县 7月25日,拉萨市林周县、昌都地区察雅县、阿里地区措勤县遭受风雹灾害,2人因雷击死亡
    DZA201400004 地震 2014-08-05 四川省凉山彝族自治州宁南县、金阳县 8月3日16:30分,云南省昭通市鲁甸县发生6.5级地震,震源深度12 km。截至8月5日初步统计,地震造成四川省凉山彝族自治州宁南县、金阳县1.16万人受灾,近500余间房屋严重损坏,2 000余间一般损坏
    NSL201400004 泥石流 2014-08-09 西藏自治区昌都县卡若镇 8月7日,昌都地区昌都县卡若镇发生泥石流灾害,造成1人死亡
    下载: 导出CSV

    表  3  每种链接类型的样本数量

    Table  3.   Number of samples for each link type

    路径类型 P-P C-C S-S P-C P-S C-S 整体
    样本数量 621 44 118 394 840 159 2 176
    下载: 导出CSV

    表  4  不同方法在不同路径类型中的AUC与准确率

    Table  4.   AUC and accuracy of different methods in different path types

    方法 指标 P-P C-C S-S P-C P-S C-S 混合路径
    CN AUC 0.858 0.886 0.927 0.901 0.937 0.904 0.928
    准确率/% 94.502 90.323 89.474 91.223 88.688 90.226 93.879
    F1分数 0.873 0.875 0.874 0.841 0.870 0.879 0.892
    PA AUC 0.829 0.867 0.859 0.845 0.936 0.904 0.906
    准确率/% 97.608 87.097 91.729 89.096 89.465 86.466 93.692
    F1分数 0.837 0.843 0.849 0.820 0.833 0.871 0.880
    JC AUC 0.870 0.780 0.903 0.894 0.850 0.906 0.839
    准确率/% 97.032 90.323 90.977 91.755 91.144 87.218 94.397
    F1分数 0.860 0.864 0.875 0.863 0.825 0.854 0.884
    ACT AUC 0.835 0.869 0.866 0.839 0.891 0.899 0.859
    准确率/% 97.493 90.323 87.218 92.420 89.399 87.218 93.317
    F1分数 0.852 0.845 0.865 0.880 0.888 0.865 0.890
    MF AUC 0.823 0.853 0.833 0.859 0.835 0.835 0.792
    准确率/% 97.562 83.871 80.451 88.697 88.623 88.948 93.692
    F1分数 0.869 0.834 0.870 0.849 0.853 0.878 0.881
    RW AUC 0.866 0.881 0.865 0.851 0.930 0.854 0.891
    准确率/% 94.430 87.097 85.714 88.963 90.109 86.466 93.042
    F1分数 0.891 0.853 0.893 0.892 0.850 0.889 0.886
    Node2Vec AUC 0.894 0.893 0.923 0.887 0.900 0.904 0.859
    准确率/% 97.125 90.323 87.970 88.564 90.045 88.722 93.821
    F1分数 0.885 0.891 0.880 0.874 0.900 0.880 0.896
    GraphSAGE AUC 0.830 0.848 0.881 0.826 0.887 0.842 0.843
    准确率/% 96.940 87.419 82.707 87.766 88.559 90.451 93.184
    F1分数 0.892 0.866 0.866 0.882 0.882 0.874 0.894
    GCN AUC 0.898 0.875 0.929 0.888 0.905 0.915 0.875
    准确率/% 97.976 93.545 90.226 91.755 90.304 87.970 94.196
    F1分数 0.861 0.863 0.889 0.884 0.901 0.891 0.891
    PRP AUC 0.909 0.918 0.942 0.928 0.968 0.943 0.938
    准确率/% 97.884 93.548 89.474 90.957 89.528 90.977 94.873
    F1分数 0.896 0.889 0.885 0.897 0.899 0.897 0.899
    下载: 导出CSV

    表  5  PRP模型与其他对比方法的t检验结果

    Table  5.   The t-test results of PRP model compared with other methods

    对比方法 均值差 t统计量 P 95%置信区间 结论
    PRP-CN 0.013 7 25.973 7 <0.001 [0.012 7, 0.014 8] 显著不同
    PRP-PA 0.008 0 14.844 4 <0.001 [0.007 0, 0.009 1] 显著不同
    PRP-JC 0.078 6 52.807 8 <0.001 [0.075 7, 0.081 5] 显著不同
    PRP-ACT 0.038 0 55.874 2 <0.001 [0.036 7, 0.039 4] 显著不同
    PRP-MF 0.063 0 129.819 1 <0.001 [0.062 0, 0.063 9] 显著不同
    PRP-RW 0.233 1 67.683 0 <0.001 [0.226 3, 0.239 8] 显著不同
    PRP-Node2Vec -0.004 4 -14.200 8 <0.001 [-0.005 0, -0.003 8] 显著不同
    PRP-GraphSAGE 0.250 3 95.019 1 <0.001 [0.245 1, 0.255 5] 显著不同
    PRP-GCN 0.115 7 62.523 8 <0.001 [0.112 1, 0.119 3] 显著不同
    下载: 导出CSV

    表  6  不同路径类型的预测结果

    Table  6.   Prediction results of different path types

    路径类型 预测结果 分数
    P-P 贡觉-芒康 0.917
    江达-贡觉 0.911
    昌都-甘孜 0.910
    C-C 降雪-泥石流 0.951
    山洪-滑坡 0.940
    风雹-山体崩塌 0.931
    S-S 人员受灾-电力设备损毁 0.945
    房屋倒损-电力设备损毁 0.906
    房屋倒损-供水设备损毁 0.902
    P-C 甘孜-风雹 0.918
    雅安-地震 0.916
    眉山-洪涝 0.911
    P-S 自贡-经济损失 0.955
    香格里拉-人员受灾 0.953
    洛隆-房屋倒损 0.951
    C-S 强对流天气-人员伤亡 0.929
    大风-道路损毁 0.913
    滑坡-桥梁损毁 0.908
    下载: 导出CSV

    表  7  风险传导过程量化分析

    Table  7.   Quantitative analysis of risk transmission process

    路径 传导步骤 当前节点(风险值) 预测分数 传导至下一节点风险值 结论
    1 起点 P1(SP1=0.6) 风险放大:灾害后果严重
    第1跳 P1(SP1=0.6) SP1C1=0.901 0.6×0.901=0.541
    第2跳 C1(SC1=0.541) SC1P2=0.890 0.541×0.890=0.481
    第3跳 P2(SP2=0.481) SP2S1=0.953 0.481×0.953=0.458
    第4跳 S1(SS1=0.458) SS1S2=0.945 0.458×0.945=0.433
    后果与放大 S2(SS2=0.433) wS2=2.0 0.433×2.0=0.866
    2 起点 P3(SP3=0.7) 风险放大:灾害后果严重
    第1跳 P3(SP3=0.7) SP3P4=0.911 0.7×0.911=0.638
    第2跳 P4(SP4=0.638) SP4C2=0.946 0.638×0.946=0.603
    第3跳 C2(SC2=0.603) SC2S3=0.929 0.603×0.929=0.560
    后果与放大 S3(SS3=0.560) wS3=1.5 0.560×1.5=0.841
    下载: 导出CSV
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出版历程
  • 收稿日期:  2025-05-22
  • 录用日期:  2025-11-27
  • 修回日期:  2025-10-28
  • 刊出日期:  2026-05-28

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