4 research outputs found
Sens-BERT: Enabling Transferability and Re-calibration of Calibration Models for Low-cost Sensors under Reference Measurements Scarcity
Low-cost sensors measurements are noisy, which limits large-scale
adaptability in airquality monitoirng. Calibration is generally used to get
good estimates of air quality measurements out from LCS. In order to do this,
LCS sensors are typically co-located with reference stations for some duration.
A calibration model is then developed to transfer the LCS sensor measurements
to the reference station measurements. Existing works implement the calibration
of LCS as an optimization problem in which a model is trained with the data
obtained from real-time deployments; later, the trained model is employed to
estimate the air quality measurements of that location. However, this approach
is sensor-specific and location-specific and needs frequent re-calibration. The
re-calibration also needs massive data like initial calibration, which is a
cumbersome process in practical scenarios.
To overcome these limitations, in this work, we propose Sens-BERT, a
BERT-inspired learning approach to calibrate LCS, and it achieves the
calibration in two phases: self-supervised pre-training and supervised
fine-tuning. In the pre-training phase, we train Sens-BERT with only LCS data
(without reference station observations) to learn the data distributional
features and produce corresponding embeddings. We then use the Sens-BERT
embeddings to learn a calibration model in the fine-tuning phase. Our proposed
approach has many advantages over the previous works. Since the Sens-BERT
learns the behaviour of the LCS, it can be transferable to any sensor of the
same sensing principle without explicitly training on that sensor. It requires
only LCS measurements in pre-training to learn the characters of LCS, thus
enabling calibration even with a tiny amount of paired data in fine-tuning. We
have exhaustively tested our approach with the Community Air Sensor Network
(CAIRSENSE) data set, an open repository for LCS.Comment: 1
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Improving Air Pollutant Metal Oxide Sensor Quantification Practices through: An Exploration of Sensor Signal Normalization, Multi-Sensor and Universal Calibration Model Generation, and Physical Factors Such as Co-Location Duration and Sensor Age
As low-cost sensors have become ubiquitous in air quality measurements, there is a need for more efficient calibration and quantification practices. Here, we deploy stationary low-cost monitors in Colorado and Southern California near oil and gas facilities, focusing our analysis on methane and ozone concentration measurement using metal oxide sensors. In comparing different sensor signal normalization techniques, we propose a z-scoring standardization approach to normalize all sensor signals, making our calibration results more easily transferable among sensor packages. We also attempt several different physical co-location schemes, and explore several calibration models in which only one sensor system needs to be co-located with a reference instrument, and can be used to calibrate the rest of the fleet of sensor systems. This approach greatly reduces the time and effort involved in field normalization without compromising goodness of fit of the calibration model to a significant extent. We also explore other factors affecting the performance of the sensor system quantification method, including the use of different reference instruments, duration of co-location, time averaging, transferability between different physical environments, and the age of metal oxide sensors. Our focus on methane and stationary monitors, in addition to the z-scoring standardization approach, has broad applications in low-cost sensor calibration and utility.</div