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Frontiers of Agricultural Science and Engineering

ISSN 2095-7505

ISSN 2095-977X(Online)

CN 10-1204/S

Postal Subscription Code 80-906

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Front. Agr. Sci. Eng.    2023, Vol. 10 Issue (4) : 648-653    https://doi.org/10.15302/J-FASE-2023505
PERSPECTIVE
INTERACTIVE KNOWLEDGE LEARNING BY ARTIFICIAL INTELLIGENCE FOR SMALLHOLDERS
Weili ZHANG1(), Renlian ZHANG1, Hongjie JI1, Anja SEVERIN2, Zhaojun LI1
1. Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing 100081, China
2. Electrical Engineering and Information Technology Faculty, Technical University of Munich, Munich 80333, Germany
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Abstract

Enhancement of farming management relies heavily on enhancing farmer knowledge. In the past, both the direct learning approach and the personnel extension system for improving fertilization practices of smallholders has proven insufficiently effective. Therefore, this article proposes an interactive knowledge learning approach using artificial intelligence as a promising alternative. The system consists of two parts. The first is a dialog interface that accepts information from farmers about their current farming practices. The second part is an intelligent decision system, which categorizes the information provided by farmers in two categories. The first consists of on-farm constraints, such as fertilizer resources, split application times and seasons. The second comprises knowledge-based practices by farmers, such as nutrient in- and output balance, ratios of different nutrients and the ratios of each split nutrient amount to the total nutrient input. The interactive knowledge learning approach aims to identify and rectify incorrect practices in the knowledge-based category while considering the farmer’s available finance, labor, and fertilizer resources. Investigations show that the interactive knowledge learning approach can make a strong contribution to prevention of the overuse of nitrogen and phosphorus fertilizers, and mitigating agricultural non-point source pollution.
Keywords artificial intelligence      extension system      non-point source pollution control      smallholders      fertilization     
Corresponding Author(s): Weili ZHANG   
Just Accepted Date: 22 May 2023   Online First Date: 12 June 2023    Issue Date: 13 December 2023
 Cite this article:   
Weili ZHANG,Renlian ZHANG,Hongjie JI, et al. INTERACTIVE KNOWLEDGE LEARNING BY ARTIFICIAL INTELLIGENCE FOR SMALLHOLDERS[J]. Front. Agr. Sci. Eng. , 2023, 10(4): 648-653.
 URL:  
https://academic.hep.com.cn/fase/EN/10.15302/J-FASE-2023505
https://academic.hep.com.cn/fase/EN/Y2023/V10/I4/648
Fig.1  Comparison of three patterns for fertilization determination.
AssembleFunction
IFarmers fertilization practice input data analyzer
CNPKDetermining NPK requirements of crops
CmidDetermining middle and micro nutrient requirements of crops
FEvaluating on season and potential nutrient supplies of fertilizer resources
SNCEvaluating soil available nitrogen supply
SPKEvaluating soil available P & K-supplies
SpHEvaluating lime requirement
SmidEvaluating soil middle and micro nutrient status for the crop
SLastEvaluating nutrients left through the last crop
EEvaluating effect of meteorological condition on fertilization
GEvaluating effect of site specific conditions on fertilization
VRegional parameter manager
RIdentification system (address wrong practice from knowledge depending category)
JRectified nutrient recommendation
MNutrient split application during crop growing season
KDetermining interactive fertilization prescription
Tab.1  Functions of the main AI system assembles
Fig.2  The intelligent decision system integrated with 17 model assembles and the essential knowledge banks.
Fig.3  Interactive knowledge learning approach can supply onsite recommendation to each smallholder farmer
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