Machine learning and statistical models for predicting indoor air quality

Wei, Wenjuan; Ramalho, Olivier; Malingre, Laeticia; Sivanantham, S.; Little, John C.; Mandin, Corinne

doi:10.1111/ina.12580

Cited by 151 publications

(81 citation statements)

References 86 publications

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“…24 While significant, these applications do not explore how to identity periods of emissions or differentiate between indoor and outdoor sources. 25 We refer the reader to 21,26,27 for a broad description of the approach. Here, we provide an overview.…”

Section: Methods Of Analysismentioning

confidence: 99%

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Automating the interpretation of PM _2.5 time‐resolved measurements using a data‐driven approach

2020

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The rapid development of automated measurement equipment enables researchers to collect greater quantities of time-resolved data from indoor and outdoor environments. While significant, the interpretation of the resulting data can be a timeconsuming effort. This paper introduces an automated process of interpreting PM 2.5 time-resolved data and differentiating PM 2.5 emissions resulting from indoor and outdoor sources. We use Random Forest (RF), a machine learning approach, to study a dataset of 836 indoor emission events that occurred over a 2-week period in 18 apartments in California. In this paper, we show model development and evaluate its performance as the sample size and source vary. We discuss the characteristics of the dataset that tended to help the source identification and why. For example, we show that data from many events and from different apartments are essential for the model to be suitable for analyzing a new separate dataset. We also show that longitudinal data appear to be more helpful than the time frequency of measurements within a given apartment. We use the resulting RF model to analyze PM 2.5 data of an entirely separate dataset collected from 65 new homes in California. The RF model identifies 442 indoor emission events, with only a few misidentifications.

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Section: Methods Of Analysismentioning

confidence: 99%

“…However, only a few applications have been reported in IAQ studies for predicting indoor PM 2.5 concentration 22,23 and indoor radon 24 . While significant, these applications do not explore how to identity periods of emissions or differentiate between indoor and outdoor sources 25 …”

Section: Methodsmentioning

confidence: 99%

Automating the interpretation of PM _2.5 time‐resolved measurements using a data‐driven approach

2020

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“…Indoor air pollutant concentrations may be estimated using an indoor-outdoor (I/O) ratio, indoor air quality model, a statistical model, and artificial intelligence such as machine learning [51,52]. The I/O ratio may generally be used to estimate the concentration of indoor air pollutants [47].…”

Section: Indoor Air Exposurementioning

confidence: 99%

Environmental Health Surveillance System for a Population Using Advanced Exposure Assessment

Yang

Park

Cho

et al. 2020

Toxics

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Human exposure to air pollution is a major public health concern. Environmental policymakers have been implementing various strategies to reduce exposure, including the 10th-day-no-driving system. To assess exposure of an entire population of a community in a highly polluted area, pollutant concentrations in microenvironments and population time–activity patterns are required. To date, population exposure to air pollutants has been assessed using air monitoring data from fixed atmospheric monitoring stations, atmospheric dispersion modeling, or spatial interpolation techniques for pollutant concentrations. This is coupled with census data, administrative registers, and data on the patterns of the time-based activities at the individual scale. Recent technologies such as sensors, the Internet of Things (IoT), communications technology, and artificial intelligence enable the accurate evaluation of air pollution exposure for a population in an environmental health context. In this study, the latest trends in published papers on the assessment of population exposure to air pollution were reviewed. Subsequently, this study proposes a methodology that will enable policymakers to develop an environmental health surveillance system that evaluates the distribution of air pollution exposure for a population within a target area and establish countermeasures based on advanced exposure assessment.

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“…On the other hand, AI-based prediction systems can deliver prior information about upcoming critical changes in IAQ levels. Hence, building occupants can take preventive majors to avoid serious health impacts [5,125]. The research communities from the past years are exploring the potential of AI to design intelligent environments where building occupants get automatic, real-time updates about changing environmental conditions [24,95,135].…”

Section: Introductionmentioning

confidence: 99%

Indoor air quality prediction systems for smart environments: A systematic review

Saini

Dutta

Marques

2020

AIS

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Air quality is a critical matter of concern in terms of the impact on public health and well-being. Although the consequences of poor air quality are more severe in developing countries, they also have a critical impact in developed countries. Healthcare costs due to air pollution reach $150 billion in the USA, whereas particulate matter causes 412,000 premature deaths in Europe, every year. According to the Environmental Protection Agency (EPA), indoor air pollutant levels can be up to 100 times higher in comparison to outdoor air quality. Indoor air quality (IAQ) is in the top five environmental risks to global health and well-being. The research community explored the scope of artificial intelligence (AI) in the past years to deal with this problem. The IAQ prediction systems contribute to smart environments where advanced sensing technologies can create healthy living conditions for building occupants. This paper reviews the applications and potential of AI for the prediction of IAQ to enhance building environment and public health. The results show that most of the studies analyzed incorporate neural networks-based models and the preferred evaluation metrics are RMSE, R 2 score and error rate. Furthermore, 66.6% of the studies include CO2 sensors for IAQ assessment. Temperature and humidity parameters are also included in 90.47% and 85.71% of the proposed methods, respectively. This study also presents some limitations of the current research activities associated with the evaluation of the impact of different pollutants based on different geographical conditions and living environments. Moreover, the use of reliable and calibrated sensor networks for real-time data collection is also a significant challenge.

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Machine learning and statistical models for predicting indoor air quality

Cited by 151 publications

References 86 publications

Automating the interpretation of PM _2.5 time‐resolved measurements using a data‐driven approach

Automating the interpretation of PM _2.5 time‐resolved measurements using a data‐driven approach

Environmental Health Surveillance System for a Population Using Advanced Exposure Assessment

Indoor air quality prediction systems for smart environments: A systematic review

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Machine learning and statistical models for predicting indoor air quality

Cited by 151 publications

References 86 publications

Automating the interpretation of PM 2.5 time‐resolved measurements using a data‐driven approach

Automating the interpretation of PM 2.5 time‐resolved measurements using a data‐driven approach

Environmental Health Surveillance System for a Population Using Advanced Exposure Assessment

Indoor air quality prediction systems for smart environments: A systematic review

Contact Info

Product

Resources

About

Automating the interpretation of PM _2.5 time‐resolved measurements using a data‐driven approach

Automating the interpretation of PM _2.5 time‐resolved measurements using a data‐driven approach