轨道交通与常规公交交互胁迫关系验证分析

焦柳丹; 罗凤莲; 吴雅; 张羽

doi:10.3963/j.jssn.1674-4861.2021.06.015

轨道交通与常规公交交互胁迫关系验证分析

doi: 10.3963/j.jssn.1674-4861.2021.06.015

焦柳丹^1, ,,
罗凤莲¹,
吴雅²,
张羽¹

1.
重庆交通大学经济与管理学院重庆 400074
2.
西南大学资源环境学院重庆 400715

基金项目:

国家自然科学基金青年项目 71901043

国家自然科学基金青年项目 72004187

详细信息

通讯作者:
焦柳丹（1989—），博士，副教授.研究方向：城市轨道交通.E-mail：jld06171@126.com

中图分类号: U491.17
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出版历程
- 收稿日期: 2021-04-22
- 网络出版日期: 2022-01-12

A Validation Study of Interactive Stress Relationship Between Urban Rail and Regular Bus Transportation Systems

1.
School of Economics and Management, Chongqing Jiaotong University, Chongqing 400074, China
2.
College of Resources and Environment, Southwest University, Chongqing 400715, China

摘要

摘要: 为了揭示城市轨道交通与常规公交之间的交互胁迫的演化特点, 通过借鉴城市化水平与生态环境之间的交互胁迫理论, 构建轨道交通与常规公交交互胁迫模型, 以我国2009年之前开通运营城市轨道交通的10个城市为样本, 基于轨道交通与常规公交之间的客运总量、线路长度及运营车辆3个维度的历史演化规律分析基础上, 验证轨道交通与常规公交之间交互胁迫关系, 进而对不同城市轨道交通与常规公交演化特点进行分类分析。研究结果表明: ①城市轨道交通与常规公交之间存在交互胁迫关系, 演变轨迹符合双指数曲线。②不同城市的轨道交通与常规公交在3个维度的演变轨迹上存在不均衡性, 客运总量的拐点出现早于运营线路长度和运营车辆数。③根据拐点的出现情况, 将10个城市分为5类, 其中, 重庆的轨道交通与常规公交在客运总量、线路长度及运营车辆3个维度的拐点出现均较晚, 表明重庆的公交发展模式较为协调, 常规公交在轨道交通的胁迫下仍然保持了一定的竞争力。
- 轨道交通 /
- 常规公交 /
- 演化轨迹 /
- 交互胁迫模型 /
- 双指数拟合
Abstract: An interactive stress model of urban rail and conventional bus transportation is established based on the interactive stress theory traditionally applied to study the relationship between urbanization level and ecological environment. It is used to reveal the interactive relationship between urban rail and conventional bus transportation systems. Ten cities in China that have operated urban rail transit before Year 2009 are selected for a case study. The interactive stess relationship between urban rail and conventional bus transportation systems among the ten cities is verified through the following three indicators: passenger flow, the length of operating lines, and the number of operating vehicles. Then, the evolution pathways of urban rail transit and conventional public transport in different cities are classified. Study results of this paper show that: ① There is an interactive stress relationship between urban rail and public bus transportation systems, and the evolution trajectory can be best described using the double exponential curve. ② There is an imbalance between rail transit and conventional bus transport in different cities over their evolution pathways measured through the above three indicators. The inflexion point of the total passenger volume occurs earlier than the length of operating lines and the number of operating vehicles. ③ According to inflexion points, ten cities are divided into five categories. The inflexion points of Chongqing in the three dimensions are late, indicating that the development mode of public transport in Chongqing is relatively coordinated. Conventional public transport still maintains certain competitiveness under the stress of rail transit.
- urban rail transit /
- regular bus transportation /
- evolutionary trajectory /
- interactive stress model /
- double exponential fitting

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图 1 城市常规公交与轨道交通交互关系双指数曲线

Figure 1. Double exponential curve for interactive stress effect between urban bus and rail transport system

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表 1 2009年及2019年城市公共交通发展状况

Table 1. Development of urban public transportation of 2009 and 2019

城市	公共汽(电)车						轨道交通
	客运总量/(万人·次)		线路长度/km		运营车辆/辆		客运总量/(万人·次)		线路长度/km		运营车辆/辆
	2009年	2019年	2009年	2019年	2009年	2019年	2009年	2019年	2009年	2019年	2009年	2019年
北京	516 517	313 366	18 270	27 632	21 716	23 010	142 268	396 238	228	699	2 014	6 449
长春	63 897	75 194	899	6 405	4 212	5 087	2 954	23 204	39	118	140	895
重庆	150 056	257 088	3 896	29 745	8 077	14 276	4 181	104 187	19	328	136	2 130
大连	96 151	92 212	941	5 492	4 811	5 683	6 885	21 967	87	181	143	628
广州	242 200	224 090	16 604	24 368	10 715	15 388	67 520	330 994	147	523	722	2 854
南京	104 178	91 518	3 119	12 018	6 081	8 700	11 353	115 730	22	394	120	1 736
上海	270 600	208 500	23 033	24 780	16 272	17 899	131 837	388 445	355	705	1 833	5 911
深圳	213 603	158 973	2 270	21 606	11 928	17 110	13 823	203 216	25	316	162	2 598
天津	116 425	111 058	11 832	25 526	7 897	12 746	5 271	54 578	71	231	228	1 220
武汉	165 610	142 954	5 463	9 724	7 241	9 631	1 317	122 373	10	335	48	2 416

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表 2 城市常规公交与轨道交通客流量交互胁迫双指数函数方程

Table 2. Double exponential function for interactive stress effect on passenger flows of urban bus and rail transport system

城市	交互胁迫函数关系式	m	n	b	a	p	R²
北京	z=0.993 3-0.171 6(10^{(y-0.824 6)/0.613 5}-0.749 8)²	0.993 3	0.171 6	0.824 6	0.613 5	0.749 8	0.927 2
长春	z=0.026 4-5.830 2 (10^{(y-0.794 2)/0.278 9}-0.630 9)²	0.026 4	5.830 2	0.794 2	0.278 9	0.630 9	0.210 9
重庆	z=0.457 6-0.975 8(10^{(y-0.584 3)/0.289 0}-1.427 1)²	0.457 6	0.975 8	0.584 3	0.289 0	1.427 1	0.944 4
大连	z=0.174 0-0.909 0(10^{(y-0.663 7)/0.433 2}-0.213 6)²	0.174 0	0.909 0	0.663 7	0.433 2	0.213 6	0.621 7
广州	z=0.423 5-0.016 7(10^{(y-0.679 3)/0.337 9}-1.970 4)²	0.423 5	0.016 7	0.679 3	0.337 9	1.970 4	0.767 3
南京	z=0.104 5-0.032 4(10^{(y-0.476 3)/0.375 9}-0.477 2)²	0.104 5	0.032 4	0.476 3	0.375 9	0.477 2	0.846 1
上海	z=0.479 3-0.021 4 (10^{(y-0.751 3)/0.492 2}-0.523 9)²	0.479 3	0.021 4	0.751 3	0.492 2	0.523 9	0.950 0
深圳	z=0.357 7-0.232 3(10^{(y-0.741 9)/0.540 7}-0.231 6)²	0.357 7	0.232 3	0.741 9	0.540 7	0.231 6	0.853 1
天津	z=0.175 6-1.565 0(10^{(y-0.633 4)/0.187 0}-1.458 0)²	0.175 6	1.565 0	0.633 4	0.187 0	1.458 0	0.803 7
武汉	z=0.175 6-3.070 9(10^{(y-0.856 7)/0.156 7}-1.040 8)²	0.175 6	3.070 9	0.856 7	0.156 7	1.040 8	0.577 9

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表 3 城市常规公交与轨道交通运营线路长度交互胁迫双指数函数方程

Table 3. Double exponential function for interactive stress effect on the length of operating lines of urban bus and rail transport system

城市	交互胁迫函数关系式	m	n	b	a	p	R²
北京	z=1.349 0-0.511 5(10^{(y-1.114 7)/1.234 4}-1.513 3)²	1.349 0	0.511 5	1.114 7	1.234 4	1.513 3	0.947 1
长春	z=1.116 0-1.055 7(10^{(y-0.647 6)/2.596 7}-1.104 1)²	1.116 0	1.055 7	0.647 6	2.596 7	1.104 1	0.592 7
重庆	z=1.506 0-1.209 7(10(^{y-0.591 7)/1.513 3}-1.211 9)²	1.506 0	1.209 7	0.591 7	1.513 3	1.211 9	0.827 2
大连	z=0.689 2-0.891 0(10^{(y-0.768 0)/1.323 4}-1.003 1)²	0.689 2	0.891 0	0.768 0	1.323 4	1.003 1	0.753 7
广州	z=6.349 1-2.382 5(10^{(y-0.823 2)/14.205 2}-1.585 1)²	6.349 1	2.382 5	0.823 2	14.205 2	1.585 1	0.600 1
南京	z=0.387 3-0.781 2(10^{(y-0.789 0)/0.557 0}-0.910 2)²	0.387 3	0.781 2	0.789 0	0.557 0	0.910 2	0.822 1
上海	z=0.934 3-0.213 1 (10^{(y-1.317 0)/1.841 5}-0.984 7)²	0.934 3	0.213 1	1.317 0	1.841 5	0.984 7	0.942 2
深圳	z=0.745 9-1.641 3(10^{(y-0.738 9)/0.396 4}-1.051 1)²	0.745 9	1.641 3	0.738 9	0.396 4	1.051 1	0.751 7
天津	z=1.592 0-1.469 5(10^{(y-0.579 9)/1.187 1}-1.192 8)²	1.592 0	1.469 5	0.579 9	1.187 1	1.192 8	0.906 3
武汉	z=0.351 7-0.498 4(10^{(y-0.935 2)/0.679 1}-0.782 7)²	0.351 7	0.498 4	0.935 2	0.679 1	0.782 7	0.824 5

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表 4 城市常规公交与轨道交通运营车辆交互胁迫双指数函数方程

Table 4. Double exponential function for interactive stress effect on the number of operating vehicles of urban bus and rail transport system

城市	交互胁迫函数关系式	m	n	b	a	p	R²
北京	z=0.887 8-4.965 2(10^{(y-0.981 9)/0.818 4}-1.137 8)²	0.887 8	4.965 2	0.981 9	0.818 4	1.137 8	0.669 3
长春	z=4.106 2-1.907 1(10^{(y-0.657 8)/11.448 1}-1.468 7)²	4.016 2	1.907 1	0.657 8	11.448 1	1.468 7	0.502 2
重庆	z=0.484 8-1.466 6(10^{(y-0.638 4)/0.400 3}-1.067 4)²	0.484 8	1.466 6	0.638 4	0.400 3	1.067 4	0.884 3
大连	z=0.084 6-0.768 1(10^{(y-0.762 3)/0.389 9}-0.718 6)²	0.084 6	0.768 1	0.762 3	0.389 9	0.718 6	0.773 5
广州	z=0.534 0-0.877 7(10^{(y-0.787 2)/0.579 5}-0.877 0)²	0.534 0	0.877 7	0.787 2	0.579 5	0.877 0	0.980 6
南京	z=0.225 5-1.254 5(10^{(y-0.654 3)/0.410 7}-0.906 3)²	0.225 5	1.254 5	0.654 3	0.410 7	0.906 3	0.922 4
上海	z=0.746 2-1.515 2(10^{(y-2.408 9)/0.341 9}-0.364 2)²	0.746 2	1.515 2	2.408 9	0.341 9	0.364 2	0.563 9
深圳	z=0.603 4-0.935 5(10^{(y-0.737 0)/0.512 4}-0.864 5)²	0.603 4	0.935 5	0.737 0	0.512 4	0.864 5	0.914 1
天津	z=0.432 1-2.724 1(10^{(y-0.602 0)/0.376 7}-1.032 1)²	0.432 1	2.724 1	0.602 0	0.376 7	1.032 1	0.835 6
武汉	z=0.258 4-0.694 1(10^{(y-0.785 1)/0.457 6}-0.774 7)²	0.258 4	0.694 1	0.785 1	0.457 6	0.774 7	0.976 9

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表 5 拐点分类情况

Table 5. Classification of inflection points

分类情况	城市	拐点较早	拐点较晚	未有拐点
Ⅰ	北京	客运总量	运营车辆	线路长度
	南京	客运总量	运营车辆	线路长度
	天津	客运总量	运营车辆	线路长度
Ⅱ	大连	客运总量		线路长度、运营车辆
	广州	客运总量		线路长度、运营车辆
	上海	客运总量		线路长度、运营车辆
Ⅲ	武汉		客运总量	线路长度、运营车辆
Ⅲ	长春		客运总量	线路长度、运营车辆
Ⅳ	深圳	客运总量	线路长度	运营车辆
Ⅴ	重庆		客运总量、线路长度、运营车辆

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