A Self-Predictable Crop Yield Platform (SCYP) Based On Crop Diseases Using Deep Learning

This paper proposes a self-predictable crop yield platform (SCYP) based on crop diseases using deep learning that collects weather information (temperature, humidity, sunshine, precipitation, etc.) and farm status information (harvest date, disease information, crop status, ground temperature, etc.)...

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Veröffentlicht in:	Sustainability 2019-07, Vol.11 (13), p.3637
Hauptverfasser:	Lee, SangSik, Jeong, YiNa, Son, SuRak, Lee, ByungKwan
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Sprache:	eng
Schlagworte:	Agricultural production Artificial intelligence Climate change Crop diseases Crop yield Crops Datasets Deep learning Evaporation Harvesting Humidity Learning theory Medical imaging Meteorological data Model accuracy Neural networks Precipitation Sensors Smartphones Sunlight Temperature
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description	This paper proposes a self-predictable crop yield platform (SCYP) based on crop diseases using deep learning that collects weather information (temperature, humidity, sunshine, precipitation, etc.) and farm status information (harvest date, disease information, crop status, ground temperature, etc.), diagnoses crop diseases by using convolutional neural network (CNN), and predicts crop yield based on factors such as climate change, crop diseases, and others by using artificial neural network (ANN). The SCYP consists of an image preprocessing module (IPM) to determine crop diseases through the Google Vision API and image resizing, a crop disease diagnosis module (CDDM) based on CNN to diagnose the types and extent of crop diseases through photographs, and a crop yield prediction module (CYPM) based on ANN by using information of crop diseases, remaining time until harvest (based on the date), current temperature, humidity and precipitation (amount of snowfall) in the area, sunshine amount, ground temperature, atmospheric pressure, moisture evaporation in the ground, etc. Four experiments were conducted to verify the efficiency of the SCYP. In the CDMM, the accuracy and operation time of each model were measured using three neural network models: CNN, region-CNN(R-CNN), and you only look once (YOLO). In the CYPM, rectified linear unit (ReLU), Sigmoid, and Step activation functions were compared to measure ANN accuracy. The accuracy of CNN was about 3.5% higher than that of R-CNN and about 5.4% higher than that of YOLO. The operation time of CNN was about 37 s less than that of R-CNN and about 72 s less than that of YOLO. The CDDM had slightly less operation time, but in this paper, we prefer accuracy over operation time to diagnose crop diseases efficiently and accurately. When the activation function of the ANN used in the CYPM was ReLU, the accuracy of the ANN was 2% higher than that of Sigmoid and 7% higher than that of Step. The CYPM prediction was about 34% more accurate when using multiple diseases than when not using them. Therefore, the SCYP can predict farm yields more accurately than traditional methods.
doi_str_mv	10.3390/su11133637
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subjects	Agricultural production Artificial intelligence Climate change Crop diseases Crop yield Crops Datasets Deep learning Evaporation Harvesting Humidity Learning theory Medical imaging Meteorological data Model accuracy Neural networks Precipitation Sensors Smartphones Sunlight Temperature
title	A Self-Predictable Crop Yield Platform (SCYP) Based On Crop Diseases Using Deep Learning
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