Publikation:

Automated Phytosensing : Ozone Exposure Classification Based on Plant Electrical Signals

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2025

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Mohr, Felix

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https://doi.org/10.1109/cietes63869.2025.10995087
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2025 IEEE Symposia on Computational Intelligence for Energy, Transport and Environmental Sustainability (CIETES) : 17-20 March 2025 ; conference location: Trondheim, Norway. Piscataway, NJ: IEEE, 2025, S. 1-7. ISBN 979-8-3315-0826-5. Verfügbar unter: doi: 10.1109/cietes63869.2025.10995087

Zusammenfassung

In our project WatchPlant, we propose to use a decentralized network of living plants as air-quality sensors by measuring their electrophysiology to infer the environmental state, also called phytosensing. We conducted in-lab experiments exposing ivy (Hedera helix) plants to ozone, an important pollutant to monitor, and measured their electrophysiological response. However, there is no well established automated way of detecting ozone exposure in plants. We propose a generic automatic toolchain to select a high-performance subset of features and highly accurate models for plant electrophysiology. Our approach derives plant- and stimulus-generic features from the electrophysiological signal using the tsfresh library. Based on these features, we automatically select and optimize machine learning models using AutoML. We use forward feature selection to increase model performance. We show that our approach successfully classifies plant ozone exposure with accuracies of up to 94.6% on unseen data. We also show that our approach can be used for other plant species and stimuli. Our toolchain automates the development of monitoring algorithms for plants as pollutant monitors. Our results help implement significant advancements for phytosensing devices contributing to the development of cost-effective, high-density urban air monitoring systems in the future.

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004 Informatik

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Gases, Accuracy, Conferences, Green products, Electrophysiology, Feature extraction, Libraries, Pollution measurement, Sensors, Monitoring

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2025 IEEE Symposia on Computational Intelligence for Energy, Transport and Environmental Sustainability (CIETES), 17. März 2025 - 20. März 2025, Trondheim, Norway
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ISO 690AUST, Till, Eduard BUSS, Felix MOHR, Heiko HAMANN, 2025. Automated Phytosensing : Ozone Exposure Classification Based on Plant Electrical Signals. 2025 IEEE Symposia on Computational Intelligence for Energy, Transport and Environmental Sustainability (CIETES). Trondheim, Norway, 17. März 2025 - 20. März 2025. In: 2025 IEEE Symposia on Computational Intelligence for Energy, Transport and Environmental Sustainability (CIETES) : 17-20 March 2025 ; conference location: Trondheim, Norway. Piscataway, NJ: IEEE, 2025, S. 1-7. ISBN 979-8-3315-0826-5. Verfügbar unter: doi: 10.1109/cietes63869.2025.10995087
BibTex
@inproceedings{Aust2025-03-17Autom-75522,
  title={Automated Phytosensing : Ozone Exposure Classification Based on Plant Electrical Signals},
  year={2025},
  doi={10.1109/cietes63869.2025.10995087},
  isbn={979-8-3315-0826-5},
  address={Piscataway, NJ},
  publisher={IEEE},
  booktitle={2025 IEEE Symposia on Computational Intelligence for Energy, Transport and Environmental Sustainability (CIETES) : 17-20 March 2025 ; conference location: Trondheim, Norway},
  pages={1--7},
  author={Aust, Till and Buss, Eduard and Mohr, Felix and Hamann, Heiko}
}
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