Abstract
In existing closed-loop soilless cultures, nutrient solutions are controlled by the electrical conductivity (EC) of the solution. However, the EC of nutrient solutions is affected by both growth environments and crop growth, so it is hard to predict the EC of nutrient solution. The objective of this study was to predict the EC of root-zone nutrient solutions in closed-loop soilless cultures using recurrent neural network (RNN). In a test greenhouse with sweet peppers (Capsicum annuum L.), data were measured every 10 s from October 15 to December 31, 2014. Mean values for every hour were analyzed. Validation accuracy (R2) of a single-layer long short-term memory (LSTM) was 0.92 and root-mean-square error (RMSE) was 0.07, which were the best results among the different RNNs. The trained LSTM predicted the substrate EC accurately at all ranges. Test accuracy (R2) was 0.72 and RMSE was 0.08, which were lower than values for the validation. Deep learning algorithms were more accurate when more data were added for training. The addition of other environmental factors or plant growth data would improve model robustness. A trained LSTM can control the nutrient solutions in closed-loop soilless cultures based on predicted future EC. Therefore, the algorithm can make a planned management of nutrient solutions possible, reducing resource waste.
Highlights
Due to benefits including improved crop yield and quality, soilless cultures in greenhouses have been growing rapidly in popularity
Three sweet pepper (Capsicum annuum L.) plants were grown in a rockwool slab and seven slabs were used per row
Regardless of the number of layers, long short-term memory (LSTM) showed the higher accuracy than gated recurrent unit (GRU)
Summary
Due to benefits including improved crop yield and quality, soilless cultures in greenhouses have been growing rapidly in popularity. Most open-loop soilless cultures release drainage nutrient solutions without treatment, causing environmental pollution such as eutrophication and accumulation of heavy metals (Fargašová, 1994; Siddiqi et al, 1998; Le Bot et al, 2001; Nicoletto et al, 2017). To resolve this problem, closed-loop soilless cultures are being studied as sustainable crop cultivation systems. Root-zone EC should be controlled within target range because it significantly influences the growth and quality of crops (Sonneveld and Voogt, 2009). Predicting EC is important for nutrient management of closed soilless cultures
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