An extended social force model on unidirectional flow considering psychological and behavioral impacts of hazard source

doi:10.1088/1674-1056/ad1173

Abstract An accurate assessment of the evacuation efficiency in case of disasters is of vital importance to the safety design of buildings and street blocks. Hazard sources not only physically but psychologically affect the pedestrians, which may further alter their behavioral patterns. This effect is especially significant in narrow spaces, such as corridors and alleys. This study aims to integrate a non-spreading hazard source into the social force model following the results from a previous experiment and simulation, and to simulate unidirectional pedestrian flows over various crowd densities and clarity-intensity properties of the hazard source. The integration include a virtual repulsion force from the hazard source and a decay on the social force term. The simulations reveal (i) that the hazard source creates virtual bottlenecks that suppress the flow, (ii) that the inter-pedestrian push forms a stabilisation phase on the flow-density curve within medium-to-high densities, and (iii) that the pedestrians are prone to a less orderly and stable pattern of movement in low clarity-intensity scenarios, possibly with lateral collisions passing the hazard source.

Keywords: evacuation social force model hazard source unidirectional pedestrian flow

Received: 08 September 2023
Revised: 03 November 2023
Accepted manuscript online: 01 December 2023

PACS:	89.20.-a	(Interdisciplinary applications of physics)
	89.40.-a	(Transportation)

Fund: Project supported by National Key Research and Development Program of China (Grant Nos. 2022YFC3320800 and 2021YFC1523500) and the National Natural Science Foundation of China (Grant Nos. 71971126, 71673163, 72304165, 72204136, and 72104123).

Corresponding Authors: Tao Chen
E-mail: chentao.a@tsinghua.edu.cn

Cite this article:

Kaifeng Deng(邓凯丰), Meng Li(李梦), Xiangmin Hu(胡祥敏), and Tao Chen(陈涛) An extended social force model on unidirectional flow considering psychological and behavioral impacts of hazard source 2024 Chin. Phys. B 33 028901

[1] Proulx G 2002 SFPE handbook of fire protection engineering 3
[2] Cooper L Y 1983 Fire Safety Journal 5 135
[3] Purser D 2003 Fire Safety Science 7 91
[4] Burstedde C, Klauck K, Schadschneider A and Zittartz J 2001 Physica A 295 507
[5] Helbing D and Molnar P 1995 Phys. Rev. E 51 4282
[6] Wang J, Sarvi M, Ma J, Haghani M, Alhawsawi A, Chen J and Lin P 2022 Building Simulation (Tsinghua University Press) pp. 1-14
[7] Zhu Y, Chen T, Ding N and Fan W C 2020 Chin. Phys. B 29 010401
[8] Wang G, Chen T, Hu X, Zheng H and Jiang W 2022 Physica A 603 127638
[9] Zhu Y, Chen T, Ding N, Chraibi M and Fan W C 2021 Physica A 573 125926
[10] Hu X, Chen T, Deng K and Wang G 2022 Chaos: An Interdisciplinary Journal of Nonlinear Science 32 063140
[11] Kim H, Han J and Han S 2019 Journal of Ambient Intelligence and Humanized Computing 10 4869
[12] Wal C, Formolo D, Robinson M A, Minkov M and Bosse T 2017 Transactions on computational collective intelligence XXVII (Springer International Publishing) pp. 139-177
[13] Yue H, Zhang J, Chen W, Wu X, Zhang X and Shao C 2021 Physica A 571 125844
[14] Yue H, Zhang B Y, Shao C F and Xing Y 2014 Chin. Phys. B 23 050512
[15] Wu X S, Yue H, Liu Q M, Zhang X and Shao C F 2021 Chin. Phys. B 30 018902
[16] Jia X, Yue H, Tian X and Yin H 2017 Simulation 93 1013
[17] Yuen J and Lee E 2012 Safety Science 50 1704
[18] Zhang D, Zhu H, Du L and Hostikka S 2018 Phys. Lett. A 382 3172
[19] Lv W, Song W G, Ma J and Fang Z M 2013 IEEE Transactions on Intelligent Transportation Systems 14 1753
[20] Gao Y, Zhuang Y, Dong F, Peng F, Zhang P, Yang L and Ni Y 2020 Physica A 544 122670
[21] Fu L, Liu Y, Shi Y and Zhao Y 2021 J. Stat. Mech. 2021 073402
[22] Duan J, Zhai W and Cheng C 2020 International Journal of Environmental Research and Public Health 17 8640
[23] Alaska Y A, Aldawas A D, Aljerian N A, Memish Z A and Suner S 2017 Travel Medicine and Infectious Disease 15 67
[24] Sharma A, McCloskey B, Hui D S, Rambia A, Zumla A, Traore T, Shafi S, El-Kafrawy S A, Azhar E I, Zumla A, et al. 2023 Travel Medicine and Infectious Disease 52
[25] Vorst H C 2010 Procedia Engineering 3 15
[26] Mehmood S, Ahmed S and Kristensen A S 2019 Proceedings of the 11th International Conference on Computer Modeling and Simulation pp. 70-74
[27] Wang J H, Yan W Y, Zhi Y R and Jiang J C 2016 Procedia Engineering 135 128
[28] Jiang Q, Zhou Y, Zhang L, Li K and Li H 2022 Europhys. Lett. 137 41001
[29] Xu S, Wang J, Li J, Wang Y and Wang Z 2021 Journal of Loss Prevention in the Process Industries 72 104556
[30] Deng K, Li M, Wang G, Hu X, Zhang Y, Zheng H, Tian K and Chen T 2022 International Journal of Environmental Research and Public Health 19 6905
[31] Hu X, Chen T, Deng K and Wang G 2023 Physica A 619 128731
[32] Yuan Q 2013 Study on People's Evacuation Behavior in High-Rise Building Fire Master's thesis (Tsinghua University)
[33] Sherman M, Peyrot M, Magda L and Gershon R 2011 Fire Safety Journal 46 414
[34] Fahy R F, Proulx G, et al. 2001 2nd International Symposium on Human Behaviour in Fire (Boston, MA, USA) pp. 175-183
[35] Proulx G 1995 Fire Safety Journal 24 229
[36] Seike M, Kawabata N and Hasegawa M 2016 Tunnelling and Underground Space Technology 53 61
[37] Chen J, Wang J, Wang B, Liu R and Wang Q 2018 Fire Safety Journal 96 189
[38] Deng K, Xing S, Wang G, Hu X and Chen T 2023 Journal of Environmental Psychology 93 102228
[39] Deng K, Xing S, Wang G, Hu X and Chen T 2023 Journal of Environmental Psychology 88 102034
[40] Deng K, Hu X, Li M and Chen T 2023 Physica A 627 129127
[41] Lu X, Luh P B, Tucker A, Gifford T, Astur R S and Olderman N 2016 IEEE Robotics and Automation Letters 2 255
[42] Ronchi E, Gwynne S M, Purser D A and Colonna P 2013 Fire Technology 49 411
[43] Cao S C, Song W G, Liu X D and Mu N 2014 Procedia Engineering 71 403
[44] Li X, Geng Z, Kuang H, Bai X and Fan Y 2019 Physica A 533 122047
[45] Liu Q 2018 Physica A 502 315
[46] Zhang P, Yang L, Lo S, Wang D, Li M, Jiang J and Jiang N 2022 Safety Science 154 105865
[47] Şahin C, Rokne J and Alhajj R 2019 Physica A 528 121432
[48] Garcimartín A, Parisi D R, Pastor J M, Martín-Gómez C and Zuriguel I 2016 J. Stat. Mech. 2016 043402
[49] Garcimartín A, Pastor J M, Martín-Gómez C, Parisi D and Zuriguel I 2017 Sci. Rep. 7 10792

[1]	Pedestrian flow through exit: Study focused on evacuation pattern Bo-Si Zhang(张博思), Zhi-Hong Yu(余志红), Bo-Lin Sun(孙柏林), Zi-Yu Guo(郭紫钰), and Mo Chen(陈默). Chin. Phys. B, 2024, 33(1): 018902.
[2]	Model considering panic emotion and personality traits for crowd evacuation Hua-Kai Sun(孙华锴) and Chang-Kun Chen(陈长坤). Chin. Phys. B, 2023, 32(5): 050401.
[3]	Pedestrian evacuation simulation in multi-exit case: An emotion and group dual-driven method Yong-Xing Li(李永行), Xiao-Xia Yang(杨晓霞), Meng Meng(孟梦), Xin Gu(顾欣), and Ling-Peng Kong(孔令鹏). Chin. Phys. B, 2023, 32(4): 048901.
[4]	Simulation based on a modified social force model for sensitivity to emergency signs in subway station Zheng-Yu Cai(蔡征宇), Ru Zhou(周汝), Yin-Kai Cui(崔银锴), Yan Wang(王妍), and Jun-Cheng Jiang(蒋军成). Chin. Phys. B, 2023, 32(2): 020507.
[5]	Effect of a static pedestrian as an exit obstacle on evacuation Yang-Hui Hu(胡杨慧), Yu-Bo Bi(毕钰帛), Jun Zhang(张俊), Li-Ping Lian(练丽萍), Wei-Guo Song(宋卫国), and Wei Gao(高伟). Chin. Phys. B, 2023, 32(1): 018901.
[6]	Passenger management strategy and evacuation in subway station under Covid-19 Xiao-Xia Yang(杨晓霞), Hai-Long Jiang(蒋海龙), Yuan-Lei Kang(康元磊), Yi Yang(杨毅), Yong-Xing Li(李永行), and Chang Yu(蔚畅). Chin. Phys. B, 2022, 31(7): 078901.
[7]	Simulation of crowd dynamics in pedestrian evacuation concerning panic contagion: A cellular automaton approach Guan-Ning Wang(王冠宁), Tao Chen(陈涛), Jin-Wei Chen(陈锦炜), Kaifeng Deng(邓凯丰), and Ru-Dong Wang(王汝栋). Chin. Phys. B, 2022, 31(6): 060402.
[8]	An extended cellular automata model with modified floor field for evacuation Da-Hui Qin(秦大辉), Yun-Fei Duan(段云飞), Dong Cheng(程栋), Ming-Zhu Su(苏铭著), Yong-Bo Shao(邵永波). Chin. Phys. B, 2020, 29(9): 098901.
[9]	Simulation study on cooperation behaviors and crowd dynamics in pedestrian evacuation Ya-Ping Ma(马亚萍), Hui Zhang(张辉). Chin. Phys. B, 2020, 29(3): 038901.
[10]	Simulation-based optimization of inner layout of a theater considering the effect of pedestrians Qing-Fei Gao(高庆飞), Yi-Zhou Tao(陶亦舟), Yan-Fang Wei(韦艳芳), Cheng Wu(吴成), Li-Yun Dong(董力耘). Chin. Phys. B, 2020, 29(3): 034501.
[11]	Analyzing floor-stair merging flow based on experiments and simulation Yu Zhu(朱萸), Tao Chen(陈涛), Ning Ding(丁宁), Wei-Cheng Fan(范维澄). Chin. Phys. B, 2020, 29(1): 010401.
[12]	Evacuation simulation considering action of guard in artificial attack Chang-Kun Chen(陈长坤), Yun-He Tong(童蕴贺). Chin. Phys. B, 2019, 28(1): 010503.
[13]	Effect of exit location on flow of mice under emergency condition Teng Zhang(张腾), Shen-Shi Huang(黄申石), Xue-Lin Zhang(张学林), Shou-Xiang Lu(陆守香), Chang-Hai Li(黎昌海). Chin. Phys. B, 2019, 28(1): 010505.
[14]	Evacuation flow of pedestrians considering compassion effect Yu-Zhang Chen(陈煜章), Ming Li(李明), Rui Jiang(姜锐), Mao-Bin Hu(胡茂彬). Chin. Phys. B, 2018, 27(8): 088901.
[15]	Spatial memory enhances the evacuation efficiency of virtual pedestrians under poor visibility condition Yi Ma(马毅), Eric Wai Ming Lee(李伟民), Meng Shi(施朦), Richard Kwok Kit Yuen(袁国杰). Chin. Phys. B, 2018, 27(3): 038901.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Metrics
Related Articles

An extended social force model on unidirectional flow considering psychological and behavioral impacts of hazard source

Cite this article:

Online attention