In Smart Farming, geospatial machine learning has the potential to enable data-driven crop management across large areas for optimization of resource consumption. In this work, we describe an edge-to-cloud system designed for soil-plant moisture detection and classification in a realistic scenario, where ground truth data are scarce and inaccurate and yet district-level irrigation water provisioning must rely on these data. Global data sources are scouted and integrated with purposely-designed edge and fog components to support soil and crop data collection, data filtering and validation, and moisture assessment. Exploiting suitable combinations of large scale data (retrieved in public satellite data hubs) and specific but inaccurate manual data, sufficiently accurate moisture assessments are obtained by machine learning algorithms, thereby avoiding expensive manual labeling of large data collections as well as human inspection of individual plots. The resulting accuracy (in the order of 80%) is comparable with that obtained by human-laboured approaches.
An Edge-to-Cloud System enabling Geospatial Machine Learning for Soil-Plant Moisture Classification / Penzotti, G.; Mazzara, N. T.; Letterio, T.; Amoretti, M.; Caselli, S.. - (2024), pp. 132-136. (Intervento presentato al convegno 2024 32nd Euromicro International Conference on Parallel, Distributed and Network-Based Processing (PDP) tenutosi a Dublin, Ireland nel 20-22 March, 2024) [10.1109/PDP62718.2024.00025].
An Edge-to-Cloud System enabling Geospatial Machine Learning for Soil-Plant Moisture Classification
Penzotti G.
Membro del Collaboration Group
;Mazzara N. T.Membro del Collaboration Group
;Amoretti M.Membro del Collaboration Group
;Caselli S.Membro del Collaboration Group
2024-01-01
Abstract
In Smart Farming, geospatial machine learning has the potential to enable data-driven crop management across large areas for optimization of resource consumption. In this work, we describe an edge-to-cloud system designed for soil-plant moisture detection and classification in a realistic scenario, where ground truth data are scarce and inaccurate and yet district-level irrigation water provisioning must rely on these data. Global data sources are scouted and integrated with purposely-designed edge and fog components to support soil and crop data collection, data filtering and validation, and moisture assessment. Exploiting suitable combinations of large scale data (retrieved in public satellite data hubs) and specific but inaccurate manual data, sufficiently accurate moisture assessments are obtained by machine learning algorithms, thereby avoiding expensive manual labeling of large data collections as well as human inspection of individual plots. The resulting accuracy (in the order of 80%) is comparable with that obtained by human-laboured approaches.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.