Calibrating chemical multisensory devices for real world applications: An in-depth comparison of quantitative machine learning approaches

Vito, Saverio De; Esposito, E.; Salvato, M.; Popoola, Olalekan; Formisano, Fabrizio; Jones, R. L.; Francia, G. Di

doi:10.1016/j.snb.2017.07.155

Cited by 100 publications

(82 citation statements)

References 34 publications

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“…In the majority of cases, these tested LCS consisted of electrochemical sensors. Only for NO 2 did we observe that supervised learning techniques (ANN, RF, SVM) performed slightly better than MLRs when looking at the R 2 of comparison tests in the field, except for SVR, which is in slight contradiction with other studies [101]. However, the number of records is much higher for MLR than for supervised learning techniques.…”

Section: Calibration Of Sensorscontrasting

confidence: 84%

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Review of the Performance of Low-Cost Sensors for Air Quality Monitoring

et al. 2019

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A growing number of companies have started commercializing low-cost sensors (LCS) that are said to be able to monitor air pollution in outdoor air. The benefit of the use of LCS is the increased spatial coverage when monitoring air quality in cities and remote locations. Today, there are hundreds of LCS commercially available on the market with costs ranging from several hundred to several thousand euro. At the same time, the scientific literature currently reports independent evaluation of the performance of LCS against reference measurements for about 110 LCS. These studies report that LCS are unstable and often affected by atmospheric conditions—cross-sensitivities from interfering compounds that may change LCS performance depending on site location. In this work, quantitative data regarding the performance of LCS against reference measurement are presented. This information was gathered from published reports and relevant testing laboratories. Other information was drawn from peer-reviewed journals that tested different types of LCS in research studies. Relevant metrics about the comparison of LCS systems against reference systems highlighted the most cost-effective LCS that could be used to monitor air quality pollutants with a good level of agreement represented by a coefficient of determination R2 > 0.75 and slope close to 1.0. This review highlights the possibility to have versatile LCS able to operate with multiple pollutants and preferably with transparent LCS data treatment.

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Section: Calibration Of Sensorscontrasting

confidence: 84%

“…The use of supervised learning techniques (ANN, RF, or SVR) either did not improve performance for CO or gave similar results as MLR for NO. This is in slight contradiction with other studies on the performance of supervised techniques [100,101]. In the majority of cases, these tested LCS consisted of electrochemical sensors.…”

Section: Calibration Of Sensorscontrasting

confidence: 77%

Review of the Performance of Low-Cost Sensors for Air Quality Monitoring

et al. 2019

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“…In addition, the study concluded that the performances of the low-cost sensors were significantly impacted by temperature and relative humidity (RH). Recurrent NN architectures were also tested for calibrating some gas sensors (De Vito et al, 2018;Esposito et al, 2016). The results showed that the dynamic approaches performed better than traditional static calibration approaches.…”

Section: Introductionmentioning

confidence: 99%

Evaluation and calibration of a low-cost particle sensor in ambient conditions using machine-learning methods

Ying

et al. 2020

Atmos. Meas. Tech.

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Abstract. Particle sensing technology has shown great potential for monitoring particulate matter (PM) with very few temporal and spatial restrictions because of its low cost, compact size, and easy operation. However, the performance of low-cost sensors for PM monitoring in ambient conditions has not been thoroughly evaluated. Monitoring results by low-cost sensors are often questionable. In this study, a low-cost fine particle monitor (Plantower PMS 5003) was colocated with a reference instrument, the Synchronized Hybrid Ambient Real-time Particulate (SHARP) monitor, at the Calgary Varsity air monitoring station from December 2018 to April 2019. The study evaluated the performance of this low-cost PM sensor in ambient conditions and calibrated its readings using simple linear regression (SLR), multiple linear regression (MLR), and two more powerful machine-learning algorithms using random search techniques for the best model architectures. The two machine-learning algorithms are XGBoost and a feedforward neural network (NN). Field evaluation showed that the Pearson correlation (r) between the low-cost sensor and the SHARP instrument was 0.78. The Fligner and Killeen (F–K) test indicated a statistically significant difference between the variances of the PM2.5 values by the low-cost sensor and the SHARP instrument. Large overestimations by the low-cost sensor before calibration were observed in the field and were believed to be caused by the variation of ambient relative humidity. The root mean square error (RMSE) was 9.93 when comparing the low-cost sensor with the SHARP instrument. The calibration by the feedforward NN had the smallest RMSE of 3.91 in the test dataset compared to the calibrations by SLR (4.91), MLR (4.65), and XGBoost (4.19). After calibrations, the F–K test using the test dataset showed that the variances of the PM2.5 values by the NN, XGBoost, and the reference method were not statistically significantly different. From this study, we conclude that a feedforward NN is a promising method to address the poor performance of low-cost sensors for PM2.5 monitoring. In addition, the random search method for hyperparameters was demonstrated to be an efficient approach for selecting the best model structure.

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“…Whenever the sensor response has a linear behavior with respect to the reference data, multiple linear regression (MLR) [11], [12], [14], [19] is used for calibrating the sensors. Nevertheless, when the response is non-linear, models such as K-nearest neighbors (KNN) [19], [20], Gaussian processes [20] and more recently supportvector regression (SVR) [14], [15], [21], random forest (RF) [13], [14], [20] and artificial neural networks (ANN) [11], [15], [20] have been used to calibrate low-cost sensors. Most of these works are focused on studying and analyzing the quality of different commercial low-cost sensors and the performance of electro-chemical sensors.…”

Section: Related Workmentioning

confidence: 99%

“…For this reason, much research has focused on the interaction of environmental conditions such as temperature and relative humidity [3], [4], [7], [8], [9] or on the interactions of other pollutants [10], [11] with respect to one pollutant sensor. In addition, there is recently a greater interest in comparing and studying [11], [12], [13], [14], [15] how signal processing techniques behave for calibrating different air pollution lowcost sensors in IoT platforms. Many of these investigations focus on comparing what is the error obtained using several linear and non-linear machine learning algorithms.…”

Section: Introductionmentioning

confidence: 99%

A Comparative Study of Calibration Methods for Low-Cost Ozone Sensors in IoT Platforms

Ferrer-Cid

Barceló-Ordinas

García-Vidal

et al. 2019

IEEE Internet Things J.

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This paper shows the result of the calibration process of an IoT platform for the measurement of tropospheric ozone (O3). This platform, formed by sixty nodes, deployed in Italy, Spain and Austria, consisted of one hundred and forty metal-oxide O3 sensors, twenty-five electro-chemical O3 sensors, twenty-five electro-chemical NO2 sensors and sixty temperature and relative humidity sensors. As ozone is a seasonal pollutant, which appears in summer in Europe, the biggest challenge is to calibrate the sensors in a short period of time. In the paper, we compare four calibration methods in the presence of a large data set for model training and we also study the impact of a limited training data set on the long-range predictions. We show that the difficulty in calibrating these sensor technologies in a real deployment is mainly due to the bias produced by the different environmental conditions found in the prediction with respect to those found in the data training phase.

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Calibrating chemical multisensory devices for real world applications: An in-depth comparison of quantitative machine learning approaches

Cited by 100 publications

References 34 publications

Review of the Performance of Low-Cost Sensors for Air Quality Monitoring

Review of the Performance of Low-Cost Sensors for Air Quality Monitoring

Evaluation and calibration of a low-cost particle sensor in ambient conditions using machine-learning methods

A Comparative Study of Calibration Methods for Low-Cost Ozone Sensors in IoT Platforms

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