Abstract

Fire detection is a critical component of a building safety monitoring system and remains an important research area with weighty practical relevance. Significant advances have occurred in recent years in building automation, and the operation of buildings has become more complex and requires ever more effective monitoring systems. In this work, we develop a novel fire detection method using deep Long-Short Term Memory (LSTM) neural networks and variational autoencoder (VAE) to meet these increasingly stringent requirements and outperform existing fire detection methods. To evaluate the effectiveness of our method, we develop high-fidelity simulations, and we use datasets from real-world fire and non-fire experiments provided by NIST. We compare and discuss the performance of our proposed fire detection with alternative methods, including the standard LSTM, cumulative sum control chart (CUSUM), exponentially weighted moving average (EWMA), and two currently used fixed-temperature heat detectors. The results using the simulation-based and the real-world experiments are complementary, and they indicate that the LSTM-VAE robustly outperforms the other detection methods with, for example, statistically significant shorter alarm time lags, no missed detection, and no false alarms. The results also identify shortcomings of other detection methods and indicate a clear ranking among them (LSTM-VAE $\mathrm {\succ }EWMA\succ LSTM\mathrm {\succ }CUSUM$ ).

Highlights

  • We first provide the context within which our work on fire detection is situated

  • We present the final performance analysis of the different methods that have a threshold setting for their detection, namely the Long-Short Term Memory (LSTM)-variational autoencoder (VAE), the standard LSTM (Appendix E), the exponentially weighted moving average (EWMA) (Appendix E), and the CUSUM (Appendix E)

  • We evaluated and compared the performance of our proposed fire detection with alternative methods, namely the standard LSTM, CUSUM, exponentially weighted moving average (EWMA), and two currently used fixed-temperature heat detectors with thresholds of 47◦C and 58◦C each

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Summary

Introduction

We first provide the context within which our work on fire detection is situated. This includes some background on fire detection and a brief discussion of machine learning for anomaly detection. We delineate our scope and objectives and provide a roadmap for the remainder of this work. A. BACKGROUND ON FIRE DETECTION Significant advances have occurred in recent years in building automation and information systems. The operation of buildings has become more complex, and several of its functions require increasingly more effective and reliable monitoring of the environment within buildings (their internal state). As a critical component of a building safety

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