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The aim of this study is to address the following issues: 1) revealing the typical behaviors and properties of pedestrian movement when going upstairs and downstairs; 2) constructing a pedestrian evacuation model to formulate the walking process of pedestrians in stair area; 3) verifying that the cell transmission model widely used in the two-dimensional walking space can also be applied to the three-dimensional staircase area. Firstly, an observation experiment is carried out to gain the pedestrian movement data in the process of going upstairs and downstairs. By collating the data, the relation between density and flow in the unidirectional process of going upstairs or going downstairs, and in the bi-directional process of going upstairs and downstairs, are drawn respectively. Then, by analyzing the fundamental diagrams, several characteristics of pedestrian movement in stair area are revealed. Based on these characteristics, an extended cell transmission model is proposed. In this model, a potential correction coefficient is introduced to change the route choice of pedestrians by using the influence of different directional pedestrians on the potential; a flow modification coefficient is introduced to describe the effect of physical parameters on the maximum flow at the boundary between two neighboring cells; and an offset coefficient is introduced to correct movement rules and strengthen the influence of preferential direction on pedestrian route choice. Further, simulations relied on the proposed model are conducted. By comparing the simulation results with the experimental data, the model is calibrated. Then the calibrated model is employed to formulate the pedestrian movement in stair area, and the sensitivity of the potential correction parameter is also discussed. The simulation results indicate that the proposed model can successfully reproduce the movement of pedestrians on stair. Moreover, the route-choice behaviors of pedestrians can be directed by varying the values of the potential correction coefficient, which can present important information about optimizing the evacuation process of pedestrians on stair, thereby reducing the risk of an accident, such as congesting and treading.
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Keywords:
- cellular transmission model /
- pedestrian flow on stairs /
- flow-density relationship /
- sensitivity analysis
[1] Galea E R, Sharp G, Lawrence P J 2008 J. Fire Prot. Eng. 18 291Google Scholar
[2] Yeo S K, He Y P 2009 Fire Saf. J. 44 183Google Scholar
[3] Yang L Z, Rao P, Zhu K J, Liu S B, Zhan X 2012 Saf. Sci. 50 1173Google Scholar
[4] Hoskins B L, Milke J A 2012 Fire Saf. J. 48 49Google Scholar
[5] 岳昊, 张旭, 陈刚, 邵春福 2012 61 130509Google Scholar
Yue H, Zhang X, Chen G, Shao C F 2012 Acta Phys. Sin. 61 130509Google Scholar
[6] Shields T J, Boyce K E 2009 Fire Saf. J. 44 881Google Scholar
[7] 岳昊, 邵春福, 关宏志, 段龙梅 2010 59 4499Google Scholar
Yue H, Shao C F, Guan H Z, Duan L M 2010 Acta Phys. Sin. 59 4499Google Scholar
[8] 陈亮, 郭仁拥, 塔娜 2013 62 050506
Chen L, Guo R Y, Ta N 2013 Acta Phys. Sin. 62 050506
[9] 永贵, 黄海军, 许岩 2013 62 010506
Yong G, Huang H J, Xu Y 2013 Acta Phys. Sin. 62 010506 (in Chinese)
[10] Sano T, Ronchi E, Minegishi Y, Nilsson D 2017 Fire Saf. J. 89 77Google Scholar
[11] 任刚, 陆丽丽, 王炜 2012 61 144501Google Scholar
Ren G, Lu L L, Wang W 2012 Acta Phys. Sin. 61 144501Google Scholar
[12] Hughes R L 2002 Trans. Res. B 32 507
[13] 董立耘, 陈立, 段晓茵 2015 64 220505Google Scholar
Dong L Y, Chen L, Duan X Y 2015 Acta Phys. Sin. 64 220505Google Scholar
[14] Huang H J, Guo R Y 2008 Phys. Rev. E 78 021131Google Scholar
[15] Helbing D, Molnar P 1995 Phys. Rev. E 51 4282Google Scholar
[16] Helbing D, Farkas I, Vicsek T 2000 Nature 407 487Google Scholar
[17] 杨凌霄, 赵小梅, 高自友, 郑建风 2011 60 100501Google Scholar
Yang L X, Zhao X M, Gao Z Y, Zheng J F 2011 Acta Phys. Sin. 60 100501Google Scholar
[18] Qu Y C, Gao Z Y, Xiao Y, Li X G 2014 Saf. Sci. 70 189Google Scholar
[19] Burstedde C, Klauck K, Schadschneider A, Zittart J 2001 Physica A 295 507Google Scholar
[20] Guo R Y, Guo X 2012 Chin. Phys. B 21 018901Google Scholar
[21] Guo R Y, Huang H J, Wong S C 2011 Trans. Res. B 45 490Google Scholar
[22] 霍非舟 2015 博士学位论文 (合肥:中国科学技术大学)
Huo F Z 2015 Ph. D. Dissertation (Hefei: University of Science and Technology of China) (in Chinese)
[23] Fujiyama T, Tyler N 2010 Transport. Plan. Techn. 33 177202Google Scholar
[24] Xu X, Song W G 2009 Build. Environ. 44 1039Google Scholar
[25] Ma J, Song W G, Tian W, Lo S M, Liao G X 2012 Saf. Sci. 50 1665Google Scholar
[26] 张培红, 鲁韬, 陈宝智, 卢兆明 2005 人类工效学 11 8Google Scholar
Zhang P H, Lu T, Chen B Z, Lu Z M 2005 Chin. J. Ergon. 11 8Google Scholar
[27] Kretz T, Grunebohm A, Kessel A, Klupfel H, Meyer Konig H, Schreckenberg M 2008 Saf. Sci. 46 72Google Scholar
[28] Peacock R D, Hoskins B L, Kuligowski E D 2012 Saf. Sci. 50 1655Google Scholar
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图 3 (a) 上楼过程中楼梯区域平均流量-密度散点图及关系曲线; (b) 下楼过程中楼梯区域平均流量-密度散点图及关系曲线; (c) 上下楼过程中楼梯区域平均流量-密度散点图及关系曲线
Figure 3. (a) The relation of the density against the average flow when going upstairs; (b) the relation of the density against the average flow when going downstairs; (c) the relation of the density against the average flow when going upstairs and downstairs.
图 10 (a) 稳定状态之前楼梯区域双向运动的流量-密度关系图; (b) 稳定状态之后楼梯区域双向运动的流量-密度关系图
Figure 10. (a) Fundamental density-flow diagram of the bi-directional pedestrian flow on the stairs before the stabilization process; (b) fundamental density-flow diagram of the bi-directional pedestrian flow on the stairs after the stabilization process.
图 11 楼梯区域双向运动的流量-密度关系散点图 (a) δ = 1.0, θ = 0.8; (b) δ = 0.6, θ = 0.8; (c) δ = 0.3, θ = 0.8; (d) δ = 1.4, θ = 0.8
Figure 11. Fundamental density-flow diagram of the bi-directional pedestrian flow on the stairs when (a) δ = 1.0 and θ = 0.8; (b) δ = 0.6 and θ = 0.8; (c) δ = 0.3 and θ = 0.8; (d) δ = 1.4 and θ = 0.8.
图 12 楼梯区域双向运动中上行行人(左)、下行行人(中)及双向行人(右)模拟结果伪彩图(颜色深浅表示每个元胞内行人数量与元胞容量之比) (a) δ = 1.0, θ = 0.8; (b) δ = 0.6, θ = 0.8; (c) δ = 0.3, θ = 0.8; (d) δ = 1.4, θ = 0.8
Figure 12. Pseudo-color plots delineating the ratio of the number of pedestrians in each cell to the capacity of the cell during the walking process of bi-directional pedestrian flows on the stairs (upward flow in the left, downward flow in the middle, and bi-directional flows in the right) when δ = 1.0 and θ = 0.8 in (a), δ = 0.6 and θ = 0.8 in (b), δ = 0.3 and θ = 0.8 in (c), δ = 1.4 and θ = 0.8 in (d).
表 1 实验楼梯的基本参数
Table 1. The basic parameters of the staircases.
有效宽度/m 有效长度/m 台阶数/级 台阶高度/m 台阶宽度/m 楼梯坡度 tanθ 有效面积/m2 3.16 8.95 38 0.15 0.37 0.40 28.28 表 2 楼梯区域上的部分观测数据
Table 2. Some observation data on staircase area.
数据
编号行人数量
N/人流入量
IF/人·$\Delta t$−1流出量
OF/人·$\Delta t$−1T T+10 s U D U D 1 11 13 0 8 0 6 2 25 26 0 12 0 11 3 29 24 0 12 0 17 4 32 31 0 21 0 22 5 33 28 0 19 0 14 6 18 20 12 0 10 0 7 39 36 14 0 17 0 8 29 33 21 0 17 0 9 54 54 12 0 12 0 10 14 12 8 0 10 0 11 18 19 3 3 2 3 12 26 28 6 9 5 8 13 50 46 9 13 10 16 14 48 44 8 8 8 12 15 38 35 8 11 10 12 注: U, 上行; D, 下行. 表 3 稳定过程中的部分流量数据
Table 3. Some flow data in the stabilization process.
时间步 60 61 62 63 64 65 66 67 68 上楼流量/人·s−1 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 下楼流量/人·s−1 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 时间步 80 81 82 83 84 85 86 87 88 上楼流量/人·s−1 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 下楼流量/人·s−1 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 6.0 表 4 稳定过程结束后的部分流量数据
Table 4. Some flow data after the stabilization process.
时间步 106 107 108 109 110 111 112 113 114 上楼流量/人·s−1 6.0 5.9 5.7 5.2 4.6 3.9 3.1 2.4 1.8 下楼流量/人·s−1 5.9 5.5 4.7 3.7 2.7 1.8 1.1 0.7 0.4 表 5 稳定过程结束后的部分行人数据
Table 5. Some pedestrian data after the stabilization process.
时间步 106 107 108 109 110 111 112 113 114 上楼人数/人 96.6 90.6 84.6 78.6 72.6 66.6 60.6 54.6 48.6 下楼人数/人 76.7 70.1 64.8 58.8 52.8 46.8 40.8 34.9 29.0 -
[1] Galea E R, Sharp G, Lawrence P J 2008 J. Fire Prot. Eng. 18 291Google Scholar
[2] Yeo S K, He Y P 2009 Fire Saf. J. 44 183Google Scholar
[3] Yang L Z, Rao P, Zhu K J, Liu S B, Zhan X 2012 Saf. Sci. 50 1173Google Scholar
[4] Hoskins B L, Milke J A 2012 Fire Saf. J. 48 49Google Scholar
[5] 岳昊, 张旭, 陈刚, 邵春福 2012 61 130509Google Scholar
Yue H, Zhang X, Chen G, Shao C F 2012 Acta Phys. Sin. 61 130509Google Scholar
[6] Shields T J, Boyce K E 2009 Fire Saf. J. 44 881Google Scholar
[7] 岳昊, 邵春福, 关宏志, 段龙梅 2010 59 4499Google Scholar
Yue H, Shao C F, Guan H Z, Duan L M 2010 Acta Phys. Sin. 59 4499Google Scholar
[8] 陈亮, 郭仁拥, 塔娜 2013 62 050506
Chen L, Guo R Y, Ta N 2013 Acta Phys. Sin. 62 050506
[9] 永贵, 黄海军, 许岩 2013 62 010506
Yong G, Huang H J, Xu Y 2013 Acta Phys. Sin. 62 010506 (in Chinese)
[10] Sano T, Ronchi E, Minegishi Y, Nilsson D 2017 Fire Saf. J. 89 77Google Scholar
[11] 任刚, 陆丽丽, 王炜 2012 61 144501Google Scholar
Ren G, Lu L L, Wang W 2012 Acta Phys. Sin. 61 144501Google Scholar
[12] Hughes R L 2002 Trans. Res. B 32 507
[13] 董立耘, 陈立, 段晓茵 2015 64 220505Google Scholar
Dong L Y, Chen L, Duan X Y 2015 Acta Phys. Sin. 64 220505Google Scholar
[14] Huang H J, Guo R Y 2008 Phys. Rev. E 78 021131Google Scholar
[15] Helbing D, Molnar P 1995 Phys. Rev. E 51 4282Google Scholar
[16] Helbing D, Farkas I, Vicsek T 2000 Nature 407 487Google Scholar
[17] 杨凌霄, 赵小梅, 高自友, 郑建风 2011 60 100501Google Scholar
Yang L X, Zhao X M, Gao Z Y, Zheng J F 2011 Acta Phys. Sin. 60 100501Google Scholar
[18] Qu Y C, Gao Z Y, Xiao Y, Li X G 2014 Saf. Sci. 70 189Google Scholar
[19] Burstedde C, Klauck K, Schadschneider A, Zittart J 2001 Physica A 295 507Google Scholar
[20] Guo R Y, Guo X 2012 Chin. Phys. B 21 018901Google Scholar
[21] Guo R Y, Huang H J, Wong S C 2011 Trans. Res. B 45 490Google Scholar
[22] 霍非舟 2015 博士学位论文 (合肥:中国科学技术大学)
Huo F Z 2015 Ph. D. Dissertation (Hefei: University of Science and Technology of China) (in Chinese)
[23] Fujiyama T, Tyler N 2010 Transport. Plan. Techn. 33 177202Google Scholar
[24] Xu X, Song W G 2009 Build. Environ. 44 1039Google Scholar
[25] Ma J, Song W G, Tian W, Lo S M, Liao G X 2012 Saf. Sci. 50 1665Google Scholar
[26] 张培红, 鲁韬, 陈宝智, 卢兆明 2005 人类工效学 11 8Google Scholar
Zhang P H, Lu T, Chen B Z, Lu Z M 2005 Chin. J. Ergon. 11 8Google Scholar
[27] Kretz T, Grunebohm A, Kessel A, Klupfel H, Meyer Konig H, Schreckenberg M 2008 Saf. Sci. 46 72Google Scholar
[28] Peacock R D, Hoskins B L, Kuligowski E D 2012 Saf. Sci. 50 1655Google Scholar
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