Indoor occupancy estimation from carbon dioxide concentration
This work addresses real-time occupancy estimation for building management and energy efficiency, but it is incremental as it builds on existing Extreme Learning Machine methods with specific adaptations.
The paper tackles the problem of estimating indoor occupancy from carbon dioxide concentration by developing a dynamic model using a Feature Scaled Extreme Learning Machine algorithm and pre-smoothing techniques, achieving up to 94% accuracy with a tolerance of four occupants in an office setting.
This paper presents an indoor occupancy estimator with which we can estimate the number of real-time indoor occupants based on the carbon dioxide (CO2) measurement. The estimator is actually a dynamic model of the occupancy level. To identify the dynamic model, we propose the Feature Scaled Extreme Learning Machine (FS-ELM) algorithm, which is a variation of the standard Extreme Learning Machine (ELM) but is shown to perform better for the occupancy estimation problem. The measured CO2 concentration suffers from serious spikes. We find that pre-smoothing the CO2 data can greatly improve the estimation accuracy. In real applications, however, we cannot obtain the real-time globally smoothed CO2 data. We provide a way to use the locally smoothed CO2 data instead, which is real-time available. We introduce a new criterion, i.e. $x$-tolerance accuracy, to assess the occupancy estimator. The proposed occupancy estimator was tested in an office room with 24 cubicles and 11 open seats. The accuracy is up to 94 percent with a tolerance of four occupants.