Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster

Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster

For traffic management under sudden disasters in high-density areas, the first and foremost step is to prevent traffic congestion in the disaster-affected area by traffic flow management and control, so as to provide enough and flexible traffic capacity for emergency evacuation and emergency rescue....

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Bibliographic Details
Main Authors: Ciyun Lin, Yongli Yu, Dayong Wu, Bowen Gong
Format: Article
Language:English
Published: MDPI AG 2020-05-01
Series:Applied Sciences
Subjects:
catastrophe border identification
traffic congestion
dynamic traffic management
risk management
cusp catastrophe theory
VISSIM
Online Access:https://www.mdpi.com/2076-3417/10/9/3197
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spelling doaj-1e014c9654714641aa9792b0b7fe2c982020-11-25T02:11:13ZengMDPI AGApplied Sciences2076-34172020-05-01103197319710.3390/app10093197Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire DisasterCiyun Lin0Yongli Yu1Dayong Wu2Bowen Gong3Department of Traffic Information and Control Engineering, Jilin University, Changchun 130022, ChinaDepartment of Traffic Information and Control Engineering, Jilin University, Changchun 130022, ChinaTexas A&M Transportation Institute, Texas A&M University, College Station, TX 77843, USADepartment of Traffic Information and Control Engineering, Jilin University, Changchun 130022, ChinaFor traffic management under sudden disasters in high-density areas, the first and foremost step is to prevent traffic congestion in the disaster-affected area by traffic flow management and control, so as to provide enough and flexible traffic capacity for emergency evacuation and emergency rescue. Catastrophe border identification is the foundation and the key to traffic congestion prediction under sudden disaster. This paper uses a mathematical model to study the regional traffic flow in the high-density area under sudden fire disaster based on the Cusp Catastrophe Theory (CCT). The catastrophe border is identified by fitting the CCT-based regional traffic flow model to explore the stable traffic flow changing to the instable state, as to provide a theoretical basis for traffic flow management and control in disaster-affected areas, and to prevent the traffic flow being caught into disorder and congestion. Based on VISSIM simulator data by building simulation scenarios with and without sudden fire disaster in a Sudoku traffic network, the catastrophe border is identified as 439 pcu/lane/h, 529 pcu/lane/h, 377 pcu/lane/h at 5 s, 10 s, 15 s data collection interval in a Sudoku traffic network respectively. The corresponding relative precision, which compares to the method of Capacity Assessment Approach (CAA), is 89.1%, 92.7% and 76.5% respectively. It means that 10 s data collection interval would be the suitable data collection interval in catastrophe border identification and regional traffic flow control in high-density area under sudden fire disaster.https://www.mdpi.com/2076-3417/10/9/3197catastrophe border identificationtraffic congestiondynamic traffic managementrisk managementcusp catastrophe theoryVISSIM
collection DOAJ
language English
format Article
sources DOAJ
author Ciyun Lin
Yongli Yu
Dayong Wu
Bowen Gong
spellingShingle Ciyun Lin
Yongli Yu
Dayong Wu
Bowen Gong
Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster
Applied Sciences
catastrophe border identification
traffic congestion
dynamic traffic management
risk management
cusp catastrophe theory
VISSIM
author_facet Ciyun Lin
Yongli Yu
Dayong Wu
Bowen Gong
author_sort Ciyun Lin
title Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster
title_short Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster
title_full Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster
title_fullStr Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster
title_full_unstemmed Traffic Flow Catastrophe Border Identification for Urban High-Density Area Based on Cusp Catastrophe Theory: A Case Study under Sudden Fire Disaster
title_sort traffic flow catastrophe border identification for urban high-density area based on cusp catastrophe theory: a case study under sudden fire disaster
publisher MDPI AG
series Applied Sciences
issn 2076-3417
publishDate 2020-05-01
description For traffic management under sudden disasters in high-density areas, the first and foremost step is to prevent traffic congestion in the disaster-affected area by traffic flow management and control, so as to provide enough and flexible traffic capacity for emergency evacuation and emergency rescue. Catastrophe border identification is the foundation and the key to traffic congestion prediction under sudden disaster. This paper uses a mathematical model to study the regional traffic flow in the high-density area under sudden fire disaster based on the Cusp Catastrophe Theory (CCT). The catastrophe border is identified by fitting the CCT-based regional traffic flow model to explore the stable traffic flow changing to the instable state, as to provide a theoretical basis for traffic flow management and control in disaster-affected areas, and to prevent the traffic flow being caught into disorder and congestion. Based on VISSIM simulator data by building simulation scenarios with and without sudden fire disaster in a Sudoku traffic network, the catastrophe border is identified as 439 pcu/lane/h, 529 pcu/lane/h, 377 pcu/lane/h at 5 s, 10 s, 15 s data collection interval in a Sudoku traffic network respectively. The corresponding relative precision, which compares to the method of Capacity Assessment Approach (CAA), is 89.1%, 92.7% and 76.5% respectively. It means that 10 s data collection interval would be the suitable data collection interval in catastrophe border identification and regional traffic flow control in high-density area under sudden fire disaster.
topic catastrophe border identification
traffic congestion
dynamic traffic management
risk management
cusp catastrophe theory
VISSIM
url https://www.mdpi.com/2076-3417/10/9/3197
work_keys_str_mv AT ciyunlin trafficflowcatastropheborderidentificationforurbanhighdensityareabasedoncuspcatastrophetheoryacasestudyundersuddenfiredisaster
AT yongliyu trafficflowcatastropheborderidentificationforurbanhighdensityareabasedoncuspcatastrophetheoryacasestudyundersuddenfiredisaster
AT dayongwu trafficflowcatastropheborderidentificationforurbanhighdensityareabasedoncuspcatastrophetheoryacasestudyundersuddenfiredisaster
AT bowengong trafficflowcatastropheborderidentificationforurbanhighdensityareabasedoncuspcatastrophetheoryacasestudyundersuddenfiredisaster
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