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Research Advances in Underground Bamboo Shoot Detection Methods

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Publicado en:Agronomy vol. 15, no. 5 (2025), p. 1116
Autor principal: Li, Wen
Otros Autores: Shao Qiong, Guo, Fan, Bian Fangyuan, Yang, Huimin
Publicado:
MDPI AG
Materias:
China
Harvesting
Microwave radiation
Artificial intelligence
Data processing
Soil moisture
Artificial neural networks
Bamboo
Edge computing
Excavation
Ecosystem integrity
Nutritive value
Electrical resistivity
Image processing
Radar imaging
Forests
Biomimetics
Aeroponics
Moisture content
Accuracy
Image analysis
Neural networks
Labor
Sensors
Soil conditions
Real time
Subsurface mapping
Forest farming
Radar
Multisensor fusion
Obstacle avoidance
Forestry
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Resumen:Underground winter bamboo shoots, prized for their high nutritional value and economic significance, face harvesting challenges owing to inefficient manual methods and the lack of specialized detection technologies. This review systematically evaluates current detection approaches, including manual harvesting, microwave detection, resistivity methods, and biomimetic techniques. While manual methods remain dominant, they suffer from labor shortages, low efficiency, and high damage rates. Microwave-based technologies demonstrate high accuracy and good depths but are hindered by high costs and soil moisture interference. Resistivity methods show feasibility in controlled environments but struggle with field complexity and low resolution. Biomimetic approaches, though innovative, face limitations in odor sensitivity and real-time data processing. Key challenges include heterogeneous soil conditions, performance loss, and a lack of standardized protocols. To address these, an integrated intelligent framework is proposed: (1) three-dimensional modeling via multi-sensor fusion for subsurface mapping; (2) artificial intelligence (AI)-driven harvesting robots with adaptive excavation arms and obstacle avoidance; (3) standardized cultivation systems to optimize soil conditions; (4) convolution neural network–transformer hybrid models for visual-aided radar image analysis; and (5) aeroponic AI systems for controlled growth monitoring. These advancements aim to enhance detection accuracy, reduce labor dependency, and increase yields. Future research should prioritize edge-computing solutions, cost-effective sensor networks, and cross-disciplinary collaborations to bridge technical and practical gaps. The integration of intelligent technologies is poised to transform traditional bamboo forestry into automated, sustainable “smart forest farms”, addressing global supply demands while preserving ecological integrity.
ISSN:2073-4395
DOI:10.3390/agronomy15051116
Fuente:Agriculture Science Database