Show simple item record

AuthorSuebsombut, Paweena
AuthorSekhari, Aicha
AuthorSureephong, Pradorn
AuthorBelhi, Abdelhak
AuthorBouras, Abdelaziz
Available date2023-04-09T08:34:50Z
Publication Date2021
Publication NameApplied Sciences (Switzerland)
ResourceScopus
URIhttp://dx.doi.org/10.3390/app112411820
URIhttp://hdl.handle.net/10576/41758
AbstractWater, an essential resource for crop production, is becoming increasingly scarce, while cropland continues to expand due to the world's population growth. Proper irrigation scheduling has been shown to help farmers improve crop yield and quality, resulting in more sustainable water consumption. Soil Moisture (SM), which indicates the amount of water in the soil, is one of the most important crop irrigation parameters. In terms of water usage optimization and crop yield, estimating future soil moisture (forecasting) is an essentially valuable task for crop irrigation. As a result, farmers can base crop irrigation decisions on this parameter. Sensors can be used to estimate this value in real time, which may assist farmers in deciding whether or not to irrigate. The soil moisture value provided by the sensors, on the other hand, is instantaneous and cannot be used to directly compute irrigation parameters such as the best timing or the required water quantity to irrigate. The soil moisture value can, in fact, vary greatly depending on factors such as humidity, weather, and time. Using machine learning methods, these parameters can be used to predict soil moisture levels in the near future. This paper proposes a new Long-Short Term Memory (LSTM)-based model to forecast soil moisture values in the future based on parameters collected from various sensors as a potential solution. To train and validate this model, a real-world dataset containing a set of parameters related to weather forecasting, soil moisture, and other related parameters was collected using smart sensors installed in a greenhouse in Chiang Mai province, Thailand. Preliminary results show that our LSTM-based model performs well in predicting soil moisture with a 0.72% RMSE error and a 0.52% cross-validation error (LSTM), and our Bi-LSTM model with a 0.76% RMSE error and a 0.57% cross-validation error. In the future, we aim to test and validate this model on other similar datasets. 2021 by the authors. Licensee MDPI, Basel, Switzerland.
SponsorThe authors would like to express their gratitude to DISP laboratory and SUNSpACe project 598748-EPP-1-2018-1-FR-EPPKA2-CBHE-JP (2018-3228/001-001), and acknowledge the support of Université Lumière Lyon 2 (France), Chiang Mai University—College of Arts Media and Technology (Thailand), and Qatar University. This publication was also made possible by NPRP Grant No. NPRP11S-1227-170135 from the Qatar National Research Fund (a member of Qatar Foundation), Qatar.
Languageen
PublisherMDPI
SubjectBidirectional LSTM
Deep learning
LSTM
Machine learning
Smart irrigation
Soil moisture
TitleField data forecasting using lstm and bi-lstm approaches
TypeArticle
Issue Number24
Volume Number11
dc.accessType Open Access


Files in this item

Thumbnail

This item appears in the following Collection(s)

Show simple item record