Abstract
The following work presents algorithms for semi-automatic validation, feature extraction and ranking of time series measurements acquired from MOX gas sensors. Semi-automatic measurement validation is accomplished by extending established curve similarity algorithms with a slope-based signature calculation. Furthermore, a feature-based ranking metric is introduced. It allows for individual prioritization of each feature and can be used to find the best performing sensors regarding multiple research questions. Finally, the functionality of the algorithms, as well as the developed software suite, are demonstrated with an exemplary scenario, illustrating how to find the most power-efficient MOX gas sensor in a data set collected during an extensive screening consisting of 16,320 measurements, all taken with different sensors at various temperatures and analytes.
Funder
Bonn-Rhein-Sieg University of Applied Sciences
Subject
Computational Mathematics,Computational Theory and Mathematics,Numerical Analysis,Theoretical Computer Science
Reference19 articles.
1. Mandal, D., and Banerjee, S. (2022). Surface Acoustic Wave (SAW) Sensors: Physics, Materials and Applications. Sensors, 22.
2. Jaaniso, R., and Tan, O.K. (2013). Semiconductor Gas Sensors, Woodhead Publishing.
3. Yaqoob, U., and Younis, M. (2021). Chemical Gas Sensors: Recent Developments, Challenges and the Potential of Machine Learning—A Review. Sensors, 21.
4. Electronic Noses: From Advanced Materials to Sensors Aided with Data Processing;Adv. Mater. Technol.,2018
5. Metal-oxide-semiconductor based gas sensors: Screening, preparation, and integration;Phys. Chem. Chem. Phys.,2017