Plant stress prediction model on nutrient film technique hydroponic in a natural greenhouse

This study aimed to identify plant stress on the NFT hydroponic module in the greenhouse using the mathematical model of the 4 th -order polynomial regression equation. The artificial Neural Network (ANN) approach was also conducted to analyze factors affecting plant growth and yield. Tatsoi plants...

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Bibliographic Details
Published in:IOP conference series. Earth and environmental science 2023-06, Vol.1182 (1), p.12002
Main Authors: Setiawati, DA, Sutiarso, L, Ngadisih, Murtiningrum
Format: Article
Language:English
Subjects:
ann
Artificial neural networks
Brassica
Canopies
greenhouse
Greenhouses
Hydroponics
Leaves
Light intensity
Luminous intensity
mathematical model
Mathematical models
Microclimate
Modules
Neural networks
nft hydroponic
Plant growth
Plant morphology
Plant stress
Plants
plant’s stress
Polynomials
Prediction models
Relative humidity
Water stress
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Summary:This study aimed to identify plant stress on the NFT hydroponic module in the greenhouse using the mathematical model of the 4 th -order polynomial regression equation. The artificial Neural Network (ANN) approach was also conducted to analyze factors affecting plant growth and yield. Tatsoi plants ( Brassica rapa subsp. Narinosa ) were grown in the NFT hydroponic module with three treatments of irrigation time, i.e. , 6 hours (A6), 12 hours (A12), and 24 hours (A24). Measured parameters include microclimate (temperature, relative humidity, and light intensity) and plant morphology (leaf canopy area, root length, leaf number, and plant weight). The value of the resulting model’s coefficient of determination (R 2 ) for A6, A12, and A24 were 0.9986, 0.994, and 0.9988, respectively. The results of the validation test also show that the prediction data built from the model is very close to the actual data of tatsoi plant’s leaf canopy area. Based on the ANN approach, the MAPE value (0.240) and error (0.00116) A6 treatment were the smallest, whereas the largest R 2 value (0.979) was also obtained in this treatment. Furthermore, analysis of the plant weight showed that changes in the leaf canopy area due to water stress ultimately affect plant yield.
ISSN:1755-1307
1755-1315
DOI:10.1088/1755-1315/1182/1/012002