Deep learning for precision agriculture: A bibliometric analysis

被引:71
作者
Coulibaly, Solemane [1 ,2 ]
Kamsu-Foguem, Bernard [1 ,2 ]
Kamissoko, Dantouma [1 ]
Traore, Daouda [1 ]
机构
[1] Univ Segou, sis Sebougou BP 24, Segou, Mali
[2] Lab Genie Prod ENI Tarbes, 47,ave Azereix,BP 1629 65016, F-65000 Tarbes, France
来源
INTELLIGENT SYSTEMS WITH APPLICATIONS | 2022年 / 16卷
关键词
Bibliometrics; Deep learning; Precision agriculture; Environment; AUTOMATIC CLASSIFICATION; CITATION ANALYSIS; WEED DETECTION; CROP; NETWORKS; LOCALIZATION; INFORMATION; FREQUENCY; TOOL;
D O I
10.1016/j.iswa.2022.200102
中图分类号
TP18 [人工智能理论];
学科分类号
081104 ; 0812 ; 0835 ; 1405 ;
摘要
Recent advances in communication technologies with the emergence of connected objects have changed the agricultural area. In this new digital age, the development of artificial intelligence, particularly deep learning, has allowed for acceleration and improvement in the processing of collected data. To highlight the evolution and advances observed in deep learning in agriculture, we conducted a bibliometric study on more than 400 recent research studies. The analyses carried out on recent research works suggest that deep learning is widely involved in the digitization of agriculture areas with high accuracy exceeding the standard image processing techniques. Most of the works focus on crop classification problems, weed, and pest identification. Their methods are mainly based on convolutional neural network architecture. From the cases study, we have identified three key challenges that are essential in the deep learning methods applied in agriculture: (i) the need to consider the perception of the domain actors, their appropriation or interaction with the existing tools; (ii) the requirement to perform statistical tests to analyze the performance of the classifiers resulting from the learning process; and (iii) the need to perform statistical cross-validations with the training data. In the end, we summarized the agricultural data processing process consisting of several parts, for a better consideration of the expectations resulting from the challenges addressed. We consider that this study can serve as a guideline of research for the scientist and practician in the application of deep learning methodology in agriculture.
引用
收藏
页数:18
相关论文
共 122 条
[1]  
Affouard A., 2019, Pl@ntNet
[2]   Cotton pests classification in field-based images using deep residual networks [J].
Alves, Adao Nunes ;
Souza, Witenberg S. R. ;
Borges, Dibio Leandro .
COMPUTERS AND ELECTRONICS IN AGRICULTURE, 2020, 174
[3]   bibliometrix: An R-tool for comprehensive science mapping analysis [J].
Aria, Massimo ;
Cuccurullo, Corrado .
JOURNAL OF INFORMETRICS, 2017, 11 (04) :959-975
[4]   Solving Current Limitations of Deep Learning Based Approaches for Plant Disease Detection [J].
Arsenovic, Marko ;
Karanovic, Mirjana ;
Sladojevic, Srdjan ;
Anderla, Andras ;
Stefanovic, Darko .
SYMMETRY-BASEL, 2019, 11 (07)
[5]  
Arun Pandian J, 2019, Mendeley Data
[6]  
AUAgroup, 2021, Early-crop-weed
[7]   On Pixel-Wise Explanations for Non-Linear Classifier Decisions by Layer-Wise Relevance Propagation [J].
Bach, Sebastian ;
Binder, Alexander ;
Montavon, Gregoire ;
Klauschen, Frederick ;
Mueller, Klaus-Robert ;
Samek, Wojciech .
PLOS ONE, 2015, 10 (07)
[8]   SegNet: A Deep Convolutional Encoder-Decoder Architecture for Image Segmentation [J].
Badrinarayanan, Vijay ;
Kendall, Alex ;
Cipolla, Roberto .
IEEE TRANSACTIONS ON PATTERN ANALYSIS AND MACHINE INTELLIGENCE, 2017, 39 (12) :2481-2495
[9]   Deep Learning with Unsupervised Data Labeling for Weed Detection in Line Crops in UAV Images [J].
Bah, M. Dian ;
Hafiane, Adel ;
Canals, Raphael .
REMOTE SENSING, 2018, 10 (11)
[10]  
Benavoli A, 2017, J MACH LEARN RES, V18