Trunk highway passenger flow forecasting method based on comprehensive transportation network
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摘要: 提出了一种融合多种运输方式的干线公路客流预测方法;通过引入基于“人次”的标准客运单元和“点-线”的枢纽节点转化方法,将公路、铁路、航空以及水运等不同运输方式子网络进行融合,构建了可体现不同运输方式之间换乘关系的综合交通网络模型;考虑出行经济费用、出行时间、最大出行恢复时间、舒适度等因素,构建了综合交通网络下不同运输方式的阻抗模型;利用额定载客数和单位时间发车次数等参数,实现了综合交通网络下不同运输方式路段最大容量的标定;基于标准客运单元和综合交通网络模型提出了考虑综合交通阻抗的客流分布预测模型,实现了考虑其他运输方式影响的干线公路客流预测,并以黑龙江省哈大绥齐地区为例进行方法验证。研究结果表明:与2019年的实际观测值相比,在无伴行线路时基于综合交通网络的干线公路客流预测方法预测结果平均误差为5.47%,略低于传统四阶段法的6.14%,但在有伴行线路时该方法平均误差为4.58%,远小于传统四阶段法的11.89%;相比传统四阶段法,该方法能够更好地反映综合交通网络结构变化后转移客流对干线公路客流量的影响;相比新增水运线路,新增高速铁路或普通铁路伴行线路对干线公路客流影响更大,更能促使公路客流向铁路进行转移。Abstract: A trunk highway passenger flow forecasting method integrating multiple transport modes was proposed. By introducing the standard passenger transport unit based on the man-time and the hub nodes conversion method from point to line, the sub-networks of different transport modes, such as highways, railways, airlines and waterways, were integrated, and the comprehensive transportation network model which can reflect the transfer relationship among different transport modes was built. By considering the travel economic cost, travel time, maximum travel recovery time, comfort level and other factors, the impedance functions of different transport modes in the comprehensive transportation network were constructed. The maximum capacities of different transport modes in the comprehensive transportation network were calibrated by using the rated passenger number and the number of departures per unit time. Based on the standard passenger transport unit and comprehensive transportation network model, the passenger flow distribution forecasting model considering the impedance of comprehensive transportation was proposed. On this basis, the passenger flow forecasting model considering the influence of different transport modes was realized. Taking Harbin, Daqing, Suihua and Qiqihar area in Heilongjiang Province as an example, the method was verified. Analysis results show that compared with the actual observation value in 2019, the average error of forecasting results of the passenger flow forecasting method based on the comprehensive transportation network is 5.47%, slightly lower than the 6.14% of the traditional four-stage method when there are no accompanying lines around the characteristic roads. However, the average error of forecasting results of the proposed method is 4.58% when the accompanying lines are around the characteristic roads, far less than the error value 11.89% of the traditional four-stage method. Compared with the traditional four-stage method, the proposed method can better reflect the influence of the transfer passenger on the traffic volume of the trunk highway after the structural change of comprehensive transportation network. Compared with adding waterways, adding high-speed or conventional railways accompanying lines have more obvious impact on the passenger flow of trunk highways, and can promote the transfer of passenger flow from highways to railways. 4 tabs, 12 figs, 32 refs.
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表 1 综合交通网络组成要素
Table 1. Elements of comprehensive transportation network
要素 要素组成 点 交叉节点 公路交叉口、航道交叉口、铁路交叉点等 换乘节点 火车站、公路客运站、飞机场等交通枢纽 边 公路路线、铁路路线、水运航道、飞机航线、表示综合交通枢纽换乘关系的虚拟线段等 表 2 客运出行基础费用验证
Table 2. Verification of passenger travel basic costs
运输方式 起讫点 里程/km 实际费用/元 计算费用/元 费用误差/% 公路 哈尔滨—齐齐哈尔 329 80.50 82.25 2.13 哈尔滨-绥化 458 112.00 114.50 2.18 哈尔滨—大庆 173 43.50 43.25 0.58 普通铁路 哈尔滨—绥化 135 19.50 19.78 1.44 绥化—齐齐哈尔 430 62.50 59.58 4.67 哈尔滨—齐齐哈尔 292 43.50 41.38 4.87 高速铁路 哈尔滨—齐齐哈尔 325 98.00 100.75 2.81 哈尔滨—北京 1 231 550.50 543.61 1.25 哈尔滨—郑州 1 843 799.00 813.87 1.86 表 3 干线公路特征路段客流预测结果
Table 3. Forecast results of passenger flow at characteristic sections of trunk highway
路段名称 公路等级 其他运输方式伴行情况 2017年客流量/(人次·d-1) 2019年客流量/(人次·d-1) 预测结果 本文方法预测客流量/(人次·d-1) 预测误差/% 传统四阶段法预测客流量/(人次·d-1) 预测误差/% 国道黑大公路(G202)哈尔滨至兰西段 一级公路 现存铁路伴行线 20 661 21 203 21 873 3.16 23 519 10.92 绥满高速(G10)哈尔滨段至肇东段 高速公路 现存铁路伴行线 28 322 36 398 33 806 -7.12 33 898 -6.87 鹤哈高速(G1111)哈尔滨至绥化段 高速公路 现存铁路伴行线 24 657 25 517 26 413 3.51 28 649 12.27 双嫩高速(G4512)齐齐哈尔段 高速公路 现存铁路伴行线 13 817 13 406 14 108 5.24 15 816 17.98 绥满高速(G10)阿城至尚志段 高速公路 现存铁路伴行线 14 786 15 378 15 976 3.89 17 130 11.39 国道绥满公路(G301)肇东至向阳段 一级公路 无其他运输方式伴行 22 361 23 821 25 112 5.42 24 836 4.26 国道三莫公路(G333)依安界至讷河段 二级公路 无其他运输方式伴行 9 118 9 671 10 285 6.35 10 303 6.54 哈尔滨绕城高速(G1001)朝阳互通—瓦盆窑互通 高速公路 无其他运输方式伴行 26 793 30 033 28 937 -3.65 28 176 -6.18 京哈高速(G1)省界至双城段 高速公路 无其他运输方式伴行 23 679 24 247 25 809 6.44 26 083 7.57 表 4 新增伴行线路后干线公路特征路段客流预测结果
Table 4. Forecast results of passenger flow in characteristic sections of trunk highway after adding new accompanying lines
路段名称 等级 其他运输方式伴行情况 2017年客流量/(人次·d-1) 预测结果 本文方法未来年客流量/(人次·d-1) 增长率/% 传统四阶段法未来年客流量/(人次·d-1) 增长率/% 机场路(S102) 一级公路 无其他运输方式伴行 18 926 22 179 17.19 21 693 14.62 国道绥满公路(G301)肇东至向阳段 一级公路 无其他运输方式伴行 22 361 26 174 17.05 25 696 14.91 国道黑大公路(G202)哈尔滨至兰西段 一级公路 现状存在铁路伴行线 20 661 22 968 11.17 24 165 16.96 绥满高速(G10)哈尔滨段至肇东段 高速公路 现状存在铁路伴行线 28 322 34 977 23.50 35 496 25.33 鹤哈高速(G1111)哈尔滨至绥化段 高速公路 现状存在铁路伴行线 24 657 28 117 14.03 30 210 22.52 国道黑大公路(G202)明水至拜泉段 一级公路 新增普通铁路伴行线 15 723 14 973 -4.77 18 291 16.33 绥满高速(G10)林甸至齐齐哈尔段 高速公路 新增高速铁路伴行线 18 122 15 962 -11.92 21 429 18.25 哈肇公路(G102)木兰至通河段 二级公路 新增水运伴行线 8 049 8 798 9.31 9 582 19.05 哈同高速(G1011)方正段 高速公路 新增水运伴行线 22 571 24 556 8.79 25 757 14.12 国道明沈公路(G203)望奎至绥望界 二级公路 新增普通铁路伴行线 9 518 9 893 3.94 11295 18.67 -
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