A Method for Predicting Traffic Accidents Based on an Ensemble Empirical Mode Decomposition and an Optimized LSTM Model
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摘要: 道路交通事故精准预测是有效提升交通安全的重要手段,由于事故数据经常呈现非线性、波动性、无周期性等特征,现有的算法存在预测效果不佳的问题。为此本文提出基于集合经验模态分解降噪算法(ensemble empirical mode decomposition,EEMD)和优化长短时记忆神经网络(long short-term memory,LSTM)的交通事故数量预测模型。在单一模型的基础上,引入降噪算法EEMD对噪声大的交通事故时间序列进行降噪处理,利用EEMD对事故时间序列进行分解得到多个子序列和1个残差项;基于粒子群优化算法(particle swarm optimization,PSO)优化LSTM网络结构参数,并在LSTM的最优网络结构下提取数据中的时间特征信息进行预测,对各子序列及残差的预测结果求和得到最终预测结果。研究结果表明:相对于EMD-PSO-LSTM,PSO-LSTM,EEMD-LSTM,LSTM这4个模型,EEMD-PSO-LSTM的预测效果最好,其对应的预测误差ermse分别降低了8.7%、48.3%、53.1%、57.6%,误差emape分别降低了12.4%、36.9%、50.6%、61.2%。进一步研究表明,运用EEMD对数据进行降噪预处理能提高预测精度,与PSO-LSTM模型相比,EEMD-PSO-LSTM模型的误差ermse降低了60.2%,emape降低了12.4%,判定系数r2提高了0.616 5;引入PSO模型优化神经网络结构同样也能有效提升预测效果,与EEMD-LSTM模型相比,EEMD-PSO-LSTM模型的误差ermse减小了53.1%,emape降低了50.6%,判定系数r2提高了0.807 8。该研究结果能够提高交通事故预测精度,帮助相关部门有效提高道路交通安全水平。Abstract: Accurate prediction of road traffic accidents is essential to improve traffic safety effectively. Due to the frequent non-linear, fluctuating, and nonperiodic characteristics of accident data, existing algorithms have the problem of poor prediction performance. Therefore, a method for traffic prediction that uses a long short-term memory network (LSTM) combined with ensemble empirical mode decomposition (EEMD) and particle swarm optimization (PSO) is proposed. Based on a single model, the EEMD is first used to break down the noise of accident data and obtain multiple subsequences and a residual. Based on LSTM optimized by PSO, the temporal feature information extracted from the data is predicted under the optimal network structure of LSTM. Then, the prediction results of each subsequence and residual are summed to obtain the final prediction result. The results show that, compared with the EMD-PSO-LSTM, PSO-LSTM, EEMD-LSTM, and LSTM, the ermse of EEMD-PSO-LSTM is reduced by 8.7%, 48.3%, 53.1%, and 57.6%, respectively. Meanwhile, the emape is reduced by 12.4%, 36.9%, 50.6%, and 61.2%, respectively. Compared with the PSO-LSTM, the ermse of the EEMD-PSO-LSTM is reduced by 60.2%, the emape is reduced by 12.4%, and the r2 is increased by 0.616 5. The PSO Introduced to optimize neural networks can help improve prediction performance. Compared with the EEMD-LSTM, the ermse of the EEMD-PSO-LSTM is reduced by 53.1%, the emape is diminished by 50.6%, and the r2 is climbed to 0.807 8. The results can improve the prediction accuracy of traffic accidents and help relevant departments effectively improve road traffic safety.
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图 2 不同迭代次数下EEMD分解误差对比分析
Figure 2. Comparative analysis of EEMD decomposition error under different iterations
图 3 不同白噪声比下EEMD分解误差对比分析
Figure 3. Comparative analysis of EEMD decomposition error under different white noise ratio
图 4 不同白噪声组数下EEMD分解误差对比分析
Figure 4. Comparative analysis of EEMD decomposition error under different number of white noise
图 9 各子序列对应预测结果及子序列的相对误差
Figure 9. Prediction results of each subsequence and relative error
图 11 基于不同算法性能分析对比图
Figure 11. Comparison of performance analysis based on different algorithms
表 1 原始事故序列描述统计分析
Table 1. Descriptivestatistical analysis of original accident sequences
统计指标 数值 数量 365 范围 86.0 最小值 0 最大值 86 均值 27.302 方差 408.09 偏度 0.81 峰度 -0.161 
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表 2 各分量及趋势项分析结果
Table 2. Results of components and trend items
分量 平均周期/d 与原序列相关系数 方差贡献率/% F1 3.47 0.379** 32.336 F2 6.87 0.288** 16.411 F3 19.16 0.280** 13.661 F4 36.40 0.270** 12.201 F5 52 0.374** 10.872 F6 182 0.776** 8.531 F7 364 0.790** 5.223 F8 364 0.548** 0.420 R 0.409** 0.344 注:**表示在0.01水平上显著相关。
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表 3 PSO-LSTM参数初始化
Table 3. Initial parameters of the PSO-LSTM model
网络参数 初始值 进化次数 10 种群规模 10 学习因子c1 1.5 学习因子c2 1.5 初始隐层单元数 20 初始学习率 0.001 时间步 10 迭代次数 500
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表 4 经PSO算法优化的LSTM模型参数
Table 4. LSTM model parameters optimized by PSO algorithm
分量 学习率 隐含层 F1 0.011 230 F2 0.009 191 F3 0.011 52 F4 0.007 150 F5 0.013 29 F6 0.007 166 F7 0.005 163 F8 0.010 210 R 0.013 251
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表 5 模型预测误差对比
Table 5. Model prediction error comparison
模型 ermse emape r2 EEMD-PSO-LSTM 5.5102 0.423 4 0.739 7 EMD-PSO-LSTM 6.033 4 0.483 4 0.7162 PSO-LSTM 10.659 3 0.671 4 0.1232 EEMD-LSTM 11.742 9 0.856 6 -0.068 1 LSTM 12.983 1 1.0909 -0.307 7 BP 13.188 4 2.071 1 -0.203 5 AMRIA 17.415 7 2.1546 -0.232 8
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