K-means cluster output.

K-means cluster output.

<div><p>Firefighting operations in high-rise building fires require firefighters to navigate complex environments while undertaking physically demanding, heavy-load tasks, which often lead to severe fatigue, impairing their operational efficiency and decision-making. This study aims to d...

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Bibliographic Details
Main Author: Mingwei Xu (9548454) (author)
Other Authors: Shangxue Yang (21370261) (author), Ke Wang (82395) (author), Chengliu Yu (21370264) (author), Guanlin Liu (1437838) (author), Chao Dai (316953) (author), Ruiqi Wang (354713) (author)
Published: 2025
Subjects:
Medicine
Molecular Biology
Developmental Biology
Biological Sciences not elsewhere classified
Information Systems not elsewhere classified
undertaking physically demanding
r &# 178
navigate complex environments
firefighter &# 8217
fire rescue missions
established using k
entropy weight analysis
bp neural network
6 &# 8211
24 %, demonstrating
10 features derived
subjective fatigue ratings
comprehensive fatigue index
reaction time data
enhancing operational effectiveness
tier fatigue classification
subjective fatigue levels
robust fatigue classification
level fatigue classification
heart rate variability
f ), enabling
dynamic fatigue prediction
high prediction accuracy
fatigue levels
heart rate
severe fatigue
fatigue states
reaction times
operational efficiency
prediction model
significant potential
scientific basis
rpe scale
often lead
metrics serving
means clustering
load tasks
key metrics
including electrocardiogram
findings highlight
approach provides
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Summary:<div><p>Firefighting operations in high-rise building fires require firefighters to navigate complex environments while undertaking physically demanding, heavy-load tasks, which often lead to severe fatigue, impairing their operational efficiency and decision-making. This study aims to develop a robust fatigue classification and prediction model to assess and forecast firefighters’ fatigue levels. Key metrics, including electrocardiogram (ECG) signals, subjective fatigue ratings, and reaction time data, were utilized. Experiments involving six healthy adult male participants simulated firefighting scenarios, during which subjective fatigue levels (6–20 Borg’s RPE scale) and reaction times were recorded. A five-level fatigue classification was established using K-means clustering, and entropy weight analysis was applied to define a comprehensive fatigue index (F), enabling a three-tier fatigue classification: light, moderate, and severe fatigue. A BP neural network was employed for dynamic fatigue prediction, with 10 features derived from heart rate and heart rate variability (HRV) metrics serving as inputs and the comprehensive fatigue index (F) as the output. The BP neural network model achieved a high prediction accuracy with an R² value of 93.24%, demonstrating its capability to accurately predict firefighters’ fatigue states. This approach provides a scientific basis for optimizing firefighter training protocols and enhancing operational effectiveness during fire rescue missions. The findings highlight the significant potential of this method for advancing firefighter fatigue monitoring and management.</p></div>

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