Abstract
Sensors in the built environment ensure safety and comfort by tracking contaminants in the occupied space. In the event of contaminant release, it is important to use the limited sensor data to rapidly and accurately identify the release location of the contaminant. Identification of the release location will enable subsequent remediation as well as evacuation decision-making. In previous work, we used an operator theoretic approach—based on the Perron–Frobenius (PF) operator—to estimate the contaminant concentration distribution in the domain given a finite amount of streaming sensor data. In the current work, the approach is extended to identify the most probable contaminant release location. The release location identification is framed as a Bayesian inference problem. The Bayesian inference approach requires considering multiple release location scenarios, which is done efficiently using the discrete PF operator. The discrete PF operator provides a fast, effective and accurate model for contaminant transport modeling. The utility of our PF-based Bayesian inference methodology is illustrated using single-point release scenarios in both two and three-dimensional cases. The method provides a fast, accurate, and efficient framework for real-time identification of contaminant source location.
Highlights
The accidental or intentional release of pollutants in the built environment presents a serious risk factor to occupant health and safety
The method used for the construction of the PF operator (Markov matrix) described in Section 2.2 is validated for an IEA-Annex building geometry [48] with a manikin
We present a method for identifying contaminant source location using the PF operatorbased transport model coupled with a sequential Bayesian inference formulation
Summary
The accidental or intentional release of pollutants in the built environment presents a serious risk factor to occupant health and safety. In addition to common pollutants—like CO2, volatile organic chemical compounds (VOCs), atmospheric particulate matter (pollens), and microbial contaminants—which affect indoor air quality (IAQ) [1], maliciously released pollutants in enclosed public spaces can cause human fatalities Such events include release of chemical and biological weapons (CBW) or the transmission of infectious diseases (TID) with examples being the sarin gas attack in the Tokyo subway system in 1995 [2,3], spread of influenza in aircraft [4], spread of SARS and COVID virus [5,6,7] and outbreaks of measles and tuberculosis infection in offices and schools [8,9]. While the approach does not require a lot of prior information, it does suffer from numerical instabilities
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