Please use this identifier to cite or link to this item:
doi:10.22028/D291-35037
Title: | High-Performance VOC Quantification for IAQ Monitoring Using Advanced Sensor Systems and Deep Learning |
Author(s): | Robin, Yannick Amann, Johannes Baur, Tobias Goodarzi, Payman Schultealbert, Caroline Schneider, Tizian Schütze, Andreas |
Language: | English |
Title: | Atmosphere |
Volume: | 12 |
Issue: | 11 |
Publisher/Platform: | MDPI |
Year of Publication: | 2021 |
Free key words: | volatile organic compounds (VOCs) indoor air quality (IAQ) deep neural networks neural network architecture search temperature-cycled operation (TCO) |
DDC notations: | 500 Science |
Publikation type: | Journal Article |
Abstract: | With air quality being one target in the sustainable development goals set by the United Nations, accurate monitoring also of indoor air quality is more important than ever. Chemiresistive gas sensors are an inexpensive and promising solution for the monitoring of volatile organic com pounds, which are of high concern indoors. To fully exploit the potential of these sensors, advanced operating modes, calibration, and data evaluation methods are required. This contribution outlines a systematic approach based on dynamic operation (temperature-cycled operation), randomized calibration (Latin hypercube sampling), and the use of advances in deep neural networks originally developed for natural language processing and computer vision, applying this approach to volatile organic compound measurements for indoor air quality monitoring. This paper discusses the pros and cons of deep neural networks for volatile organic compound monitoring in a laboratory en vironment by comparing the quantification accuracy of state-of-the-art data evaluation methods with a 10-layer deep convolutional neural network (TCOCNN). The overall performance of both methods was compared for complex gas mixtures with several volatile organic compounds, as well as interfering gases and changing ambient humidity in a comprehensive lab evaluation. Furthermore, both were tested under realistic conditions in the field with additional release tests of volatile organic compounds. The results obtained during field testing were compared with analytical measurements, namely the gold standard gas chromatography mass spectrometry analysis based on Tenax sampling, as well as two mobile systems, a gas chromatograph with photo-ionization detection for volatile organic compound monitoring and a gas chromatograph with a reducing compound photometer for the monitoring of hydrogen. The results showed that the TCOCNN outperforms state-of-the-art data evaluation methods, for example for critical pollutants such as formaldehyde, achieving an uncertainty of around 11 ppb even in complex mixtures, and offers a more robust volatile organic compound quantification in a laboratory environment, as well as in real ambient air for most targets. |
DOI of the first publication: | 10.3390/atmos12111487 |
Link to this record: | urn:nbn:de:bsz:291--ds-350376 hdl:20.500.11880/32030 http://dx.doi.org/10.22028/D291-35037 |
ISSN: | 2073-4433 |
Date of registration: | 8-Dec-2021 |
Faculty: | NT - Naturwissenschaftlich- Technische Fakultät |
Department: | NT - Systems Engineering |
Professorship: | NT - Prof. Dr. Andreas Schütze |
Collections: | SciDok - Der Wissenschaftsserver der Universität des Saarlandes |
Files for this record:
File | Description | Size | Format | |
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atmosphere-12-01487.pdf | 2,83 MB | Adobe PDF | View/Open |
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