农产品品质管控云边端一体化中间件的研究进展与展望

doi:10.12133/j.smartag.SA202510002

摘要/Abstract

摘要：

【目的/意义】 现代农业加速向精准化、智能化管控转型，对生产过程的实时响应能力和海量多源数据处理能力提出了更高要求，推动传统中心化云计算架构向云边端协同一体化演进。为支撑农产品品质的精准感知与智能调控，有必要系统梳理云边端协同在农业领域的关键技术与应用基础，为一体化中间件设计提供理论与技术支撑。 【进展】 阐述了云边端协同技术在大田种植、设施园艺和畜牧养殖等典型农业场景中的应用模式与协同机制，归纳了农业物联网在实际落地过程中普遍存在的异构设备协议不兼容、数据标准体系缺失、边缘资源调度失衡以及隐私与安全风险等问题。在此基础上，综合分析了边缘智能调度、语义互操作与可信协同等国内外研究进展，重点梳理了面向农产品品质管控的云边端一体化适配中间件的框架结构与关键功能模块，包括品质数据标准化映射、异构协议转换引擎、基于农产品特性的智能计算调度以及模型热更新机制等，并进一步讨论了“设备–作物–模型”三位一体协同机制在屏蔽底层硬件差异、提升系统弹性适配能力方面的作用。 【结论/展望】 云边端一体化协同及其自适应中间件是支撑农产品品质智能管控的关键基础设施，可为农产品品质精准感知、自动控制与智能决策系统的开发与工程化实施提供可复用的架构思路与技术参考。未来需在跨场景数据与协议标准体系构建、边缘智能与大模型融合应用、隐私保护与可信计算机制完善，以及大规模工程化示范等方面开展深入研究，以进一步提升农产品品质管控系统的智能化、可靠性与可推广性。

关键词: 物联网, 云边端一体化, 中间件, 农产品品质, 智能管控

Abstract:

[Significance] Against the backdrop of consumption upgrading and growing health awareness, consumer concerns about agricultural products are shifting from mere safety to freshness, taste, and brand reputation, making quality a core target of modern agricultural upgrading and accelerating the transition of production modes toward precise and intelligent control. However, the traditional centralized cloud‑computing architecture dominated by a central cloud platform is increasingly constrained in weak‑network environments, low‑latency control, and local autonomy, and thus can hardly support the closed‑loop requirements of "timely detection–rapid response–continuous optimization" in quality control. Consequently, cloud–edge–device integrated collaborative architectures are regarded as an important development direction, and it is necessary to systematically sort out their key technologies and application foundations in the agricultural domain so as to provide unified theoretical and technical support for the design of integrated middleware oriented to agricultural product quality control. [Progress] Starting from the current application status of cloud–edge–device integration in agriculture, the paper focuses on three typical scenarios—field planting, facility horticulture, and livestock farming—and summarizes the functional division of perception, computation, and control among cloud, edge, and device, as well as the differences in business requirements under various geographical conditions and production modes. On this basis, it identifies multiple technical challenges in practical deployments, including heterogeneous adaptation difficulties caused by the coexistence of numerous industrial and IoT protocols, poor interoperability due to inconsistent data definitions and encodings, resource imbalance arising from the mismatch between edge computing capacity and task loads, and coarse‑grained, inefficient cloud–edge collaborative scheduling. To address these challenges, the paper synthesizes relevant research on artificial intelligence, edge computing, federated learning, and blockchain, and proposes improvement ideas for cloud–edge–device collaboration from the perspectives of resource‑allocation optimization, edge‑intelligent inference, privacy protection, and trusted sharing. Furthermore, targeting the concrete requirements of intelligent quality control for agricultural products, it constructs a cloud–edge–device integrated technical framework: at the data layer, it integrates standardized mapping of quality data and a multi‑source data dictionary system; at the access layer, it realizes heterogeneous device‑protocol conversion and unified access; at the computing layer, it achieves dynamic matching between computing resources and services through intelligent task scheduling and load balancing, multi‑level caching, model hot‑updating, and federated deployment. At the collaboration level, it proposes a "device–crop–model" trinity abstraction that brings physical devices, agronomic objects, and algorithmic models under unified middleware management, thereby masking underlying hardware differences while supporting elastic adaptation and capability reuse across diverse scenarios. [Conclusions and Prospects] The cloud–edge–device integrated collaboration and its adaptive middleware constitute the key infrastructure and connective hub of intelligent quality‑control systems for agricultural products, providing reusable architectural concepts and technical references for the development and engineering implementation of systems for precise quality perception, automatic control, and intelligent decision‑making. Looking ahead, further in‑depth research is needed on cross‑scenario data and protocol standard systems oriented to quality indicators and control actions, on the integrated application of edge intelligence and large models, on the enhancement of privacy‑protection and trusted‑computing mechanisms, and on large‑scale engineering demonstrations and validation, so as to continuously improve the intelligence level, operational reliability, and scalability of agricultural product quality‑control systems and to promote the transition of related technologies from pilot applications to large‑scale deployment.

Key words: internet of things, cloud-edge-device integration, middleware, agricultural product quality, intelligent control

中图分类号:

TP399
S126

王婷, 王娜, 崔运鹏, 刘娟. 农产品品质管控云边端一体化中间件的研究进展与展望[J]. 智慧农业(中英文), doi: 10.12133/j.smartag.SA202510002.

WANG Ting, WANG Na, CUI Yunpeng, LIU Juan. Research Progress and Prospects of Cloud-Edge-Device Integrated Middleware for Agricultural Product Quality Control[J]. Smart Agriculture, doi: 10.12133/j.smartag.SA202510002.

图/表 11

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表4

农业领域常用协议类型

类型	名称	特点	适用场景
有线通信协议	RS-485	支持长距离传输、抗干扰能力强，可实现一对多通信	常用于农业自动化设备，如：温室环境监测、土壤传感器与PLC或数据采集器连接
	Modbus	基于串行通信的开放式协议，结构简单、可靠性高，但传输速率较慢（通常9 600 bps）	常用于老旧设备或低速数据采集，如农机定位终端与云平台的数据传输，或通过网关转换协议（如DeviceNET转Modbus TCP）实现设备互联
	CAN	面向消息传输，抗干扰能力强	适合分布式系统。例如，农业机械的实时控制和大规模生产场景
无线通信协议	Zigbee	基于IEEE 802.15.4标准，低功耗、自组网，支持星型/网状拓扑	适合大规模传感器网络，常用于智能大棚环境监测（如温湿度、光照、CO₂等参数采集）或牲畜健康追踪
	蓝牙	低功耗、短距离	适用于移动设备与传感器的快速连接。例如，便携式农业检测设备或手机端数据查看
	LoRa	超远传输距离（农村达10 km）、低功耗，穿透力强	适合大范围农田监测。例如，土壤湿度监测、水肥一体化系统远程控制等
	NB-IoT	基于蜂窝网络，覆盖广、支持海量设备接入，但依赖运营商网络	智能水表、气象站等需长期稳定传输的场景
	Wi-Fi	高速率、高带宽，但功耗较高	农业监控摄像头或需要实时视频传输的场景
物联网应用层协议	MQTT	轻量级发布/订阅模式，支持低带宽环境，适合云端数据交互	Arduino传感器通过MQTT上传温湿度数据至云平台，或智能灌溉系统的远程控制
	HTTP/HTTPS	互联网通用协议，兼容性强，但实时性较差	农业数据平台的数据展示与历史查询
	CoAP	专为资源受限设备设计，基于用户数据报协议（User Datagram Protocol， UDP），支持低功耗传输	农业传感器与边缘计算设备的轻量级数据交互

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表5

参考文献 33

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架构类型	主要内容	参考文献
云-边-端	构建基于云-边-端协作的智能物联网架构	［2］
云-边-端	集成云-边-端架构与区块链技术提升服务质量和可信计算能力	［3］
云-边-端	在云-边-端架构中提出基于数据属性的数据共享框架	［4］
云-边-端	为云-边-端计算架构中的隐私数据共享开发并行安全流程制框架	［5］
云-边-端	为云-边-端网络设计提出启发式链路路径规划方法	［6］
云-边-端和云-（边）-端	为云-边-端计算任务调度优化提出基于博弈论的创新算法	［7］

参数项	示例值	说明
model_name	Tomato_Sweetness_Enhance_v3	模型的描述性名称
model_version	3.1.2	模型的具体版本号
algorithm_type	深度神经网络（Deep Neural Network，DNN）	模型所使用的核心算法类型，如模糊逻辑、神经网络等
effective_stage	开花期	模型最适用的物候期

参数项	示例值	说明
target_temperature_day	｛'min'： 25， 'max'： 28｝	白天目标温度范围/摄氏度
target_temperature_night	｛'min'： 17， 'max'： 19｝	夜间目标温度范围/摄氏度
target_humidity	｛'min'： 60， 'max'： 70｝	目标空气相对湿度范围/%
light_supplement_plan	｛'start'： '06：00'， 'duration_hours'： 4｝	补光计划，定义补光灯的启动时间和持续时长
CO2_concentration_ppm	1 000	目标二氧化碳浓度（mg/m³），用于控制CO₂发生器
irrigation_trigger_soil_moisture	45	触发灌溉的土壤湿度阈值/%

生长周期	关注重点	模式	传感策略	采样频率	边缘模型	算力分配
苗期	根系生长，环境温湿度	低功耗值守	仅保留温湿度、土壤水分等标量数据的采集	低频（60 min/次）	无	边缘网关挂起高能耗的图形处理器（Graphics Processing Unit，GPU），仅维持基础连接
开花坐果期	授粉率、病虫害监测	高算力边缘推理	启动高清摄像头与多光谱传感器	高频（10 min/次）	花朵识别模型、叶部病虫害检测模型	对采集图像进行实时推理，赋予该类警报数据最高传输优先级
成熟采收期	转色度、产量预估	品质感知优先	采集果实色泽RGB值与糖度积累关联数据	中频（30 min/次）	果实成熟度分级模型	边缘计算实时统计红果比例，辅助预测最佳采收时间