Accurate Estimation of Gaseous Strength using Transient Data

TL;DR

This paper introduces a computationally efficient Method of Moments approach for accurately estimating gas source strength in buildings using transient data, improving upon traditional methods.

Contribution

The paper proposes a novel Method of Moments-based estimation technique that is both accurate and computationally efficient for real-time gas source strength estimation.

Findings

Method of Moments outperforms RLS in accuracy

Algorithm is suitable for recursive implementation

Experimental results validate effectiveness

Abstract

Information about the strength of gas sources in buildings has a number of applications in the area of building automation and control, including temperature and ventilation control, fire detection and security systems. Here, we consider the problem of estimating the strength of a gas source in an enclosure when some of the parameters of the gas transport process are unknown. Traditionally, these problems are either solved by the Maximum-Likelihood (ML) method which is accurate but computationally intense, or by Recursive Least Squares (RLS, also Kalman) filtering which is simpler but less accurate. In this paper, we suggest a different statistical estimation procedure based on the concept of Method of Moments. We outline techniques that make this procedure computationally efficient and amenable for recursive implementation. We provide a comparative analysis of our proposed method based on experimental results as well as Monte-Carlo simulations. When used with the building control systems, these algorithms can estimate the gaseous strength in a room both quickly and accurately, and can potentially provide improved indoor air quality in an efficient manner.