TY - GEN
T1 - An Approach for Evacuation Vulnerability Assessment with Consideration of Predicted Evacuation Time
AU - Han, Zishuang
AU - Kawano, Kohei
AU - Djamaluddin, Ibrahim
AU - Sugahara, Takumi
AU - Honda, Hiroyuki
AU - Taniguchi, Hisatoshi
AU - Mitani, Yasuhiro
N1 - Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.
PY - 2024
Y1 - 2024
N2 - Heavy rainfall is a frequent and widespread severe weather hazard that may cause flood damage and human casualties. Since heavy rainfall is a progressive disaster, its scale and hazardous areas can be foreseen beforehand. Therefore, evacuating people from hazardous buildings to shelters in advance is an efficient effort to reduce casualties, but a scientific basis is still required. This paper proposes an approach for assessing each building’s evacuation vulnerability based on predicted evacuation time, aiming to support evacuation decision-making under heavy rainfall. As such, this paper applies Dijkstra’s algorithm to find the evacuation route from each building to accessible shelters. Moreover, a prediction model based on the random forest algorithm is developed to estimate their time-varying evacuation time. Road spatial and temporal characteristics that may affect evacuation time are used when developing the model. Finally, the proposed approach is implemented in Joso City, Japan, to verify its feasibility. As a result, the proposed approach accurately predicts and visualizes the evacuation time between each building and its optimal evacuation shelter. It also visually identifies the hard-to-evacuate buildings. The results indicate that the proposed approach can effectively reflect evacuation vulnerability and support heavy rainfall evacuation decision-making, which proves its validity and practicality.
AB - Heavy rainfall is a frequent and widespread severe weather hazard that may cause flood damage and human casualties. Since heavy rainfall is a progressive disaster, its scale and hazardous areas can be foreseen beforehand. Therefore, evacuating people from hazardous buildings to shelters in advance is an efficient effort to reduce casualties, but a scientific basis is still required. This paper proposes an approach for assessing each building’s evacuation vulnerability based on predicted evacuation time, aiming to support evacuation decision-making under heavy rainfall. As such, this paper applies Dijkstra’s algorithm to find the evacuation route from each building to accessible shelters. Moreover, a prediction model based on the random forest algorithm is developed to estimate their time-varying evacuation time. Road spatial and temporal characteristics that may affect evacuation time are used when developing the model. Finally, the proposed approach is implemented in Joso City, Japan, to verify its feasibility. As a result, the proposed approach accurately predicts and visualizes the evacuation time between each building and its optimal evacuation shelter. It also visually identifies the hard-to-evacuate buildings. The results indicate that the proposed approach can effectively reflect evacuation vulnerability and support heavy rainfall evacuation decision-making, which proves its validity and practicality.
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U2 - 10.1007/978-981-99-9219-5_2
DO - 10.1007/978-981-99-9219-5_2
M3 - Conference contribution
AN - SCOPUS:85188724521
SN - 9789819992188
T3 - Lecture Notes in Civil Engineering
SP - 11
EP - 22
BT - Geo-Sustainnovation for Resilient Society - Select Proceedings of CREST 2023
A2 - Hazarika, Hemanta
A2 - Haigh, Stuart Kenneth
A2 - Chaudhary, Babloo
A2 - Murai, Masanori
A2 - Manandhar, Suman
PB - Springer Science and Business Media Deutschland GmbH
T2 - 2nd International Conference on Construction Resources for Environmentally Sustainable Technologies, CREST 2023
Y2 - 20 November 2023 through 22 November 2023
ER -
