P-Flash – A machine learning-based model for flashover prediction using recovered temperature data

Research was conducted to examine the use of Support Vector Regression (SVR) to build a model to forecast the potential occurrence of flashover in a single-floor, multi-room compartment fire. Synthetic temperature data for heat detectors in different rooms were generated, 1000 simulation cases are c...

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Veröffentlicht in:	Fire safety journal 2021-06, Vol.122, p.103341, Article 103341
Hauptverfasser:	Wang, Jun, Tam, Wai Cheong, Jia, Youwei, Peacock, Richard, Reneke, Paul, Fu, Eugene Yujun, Cleary, Thomas
Format:	Artikel
Sprache:	eng
Schlagworte:	Data points Detectors Fire fighting Fire modeling Firefighters Flashover Flashover prediction Heat Heat detector Learning algorithms Machine learning Mathematical models Operating temperature Prediction models Segmentation Sensors Situational awareness Smart firefighting Support vector machines
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creator	Wang, Jun Tam, Wai Cheong Jia, Youwei Peacock, Richard Reneke, Paul Fu, Eugene Yujun Cleary, Thomas
description	Research was conducted to examine the use of Support Vector Regression (SVR) to build a model to forecast the potential occurrence of flashover in a single-floor, multi-room compartment fire. Synthetic temperature data for heat detectors in different rooms were generated, 1000 simulation cases are considered, and a total of 8 million data points are utilized for model development. An operating temperature limitation is placed on heat detectors where they fail at a fixed exposure temperature of 150 ̊C and no longer provide data to more closely follow actual performance. The forecast model P-Flash (Prediction model for Flashover occurrence) is developed to use an array of heat detector temperature data, including in adjacent spaces, to recover temperature data from the room of fire origin and predict potential for flashover. Two special treatments, sequence segmentation and learning from fitting, are proposed to overcome the temperature limitation of heat detectors in real-life fire scenarios and to enhance prediction capabilities to determine if the flashover condition is met even with situations where there is no temperature data from all detectors. Experimental evaluation shows that P-Flash offers reliable prediction. The model performance is approximately 83% and 81%, respectively, for current and future flashover occurrence, considering heat detector failure at 150 ̊C. Results demonstrate that P-Flash, a new data-driven model, has potential to provide fire fighters real-time, trustworthy, and actionable information to enhance situational awareness, operational effectiveness, and safety for firefighting.
doi_str_mv	10.1016/j.firesaf.2021.103341
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Experimental evaluation shows that P-Flash offers reliable prediction. The model performance is approximately 83% and 81%, respectively, for current and future flashover occurrence, considering heat detector failure at 150 ̊C. 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Experimental evaluation shows that P-Flash offers reliable prediction. The model performance is approximately 83% and 81%, respectively, for current and future flashover occurrence, considering heat detector failure at 150 ̊C. 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subjects	Data points Detectors Fire fighting Fire modeling Firefighters Flashover Flashover prediction Heat Heat detector Learning algorithms Machine learning Mathematical models Operating temperature Prediction models Segmentation Sensors Situational awareness Smart firefighting Support vector machines
title	P-Flash – A machine learning-based model for flashover prediction using recovered temperature data
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