林业物联网发展现状与展望

doi:10.11707/j.1001-7488.LYKX20250284

摘要/Abstract

摘要：

近年来，为促进林业现代化建设、推动林草高质量智慧化发展，我国积极发展林业物联网技术。本文首先介绍了国内外林业物联网的发展历程，并从感知、通信、平台管理3个方面详细阐述了射频识别、传感器、ZigBee、LoRa、NB-IoT、数据存储与质量控制、安全与访问控制等林业物联网领域的关键技术。在此基础上，本文深入分析了林业物联网在林草湿资源监管、林业生态环境监测、森林灾害监测预警、野生动物监测、自然保护地智慧监管、林业产业等多个林业场景中的应用。林业物联网是林业天空地一体化监测的重要组成部分，在地面调查和高频精细化观测数据的实时获取中发挥着重要作用，同时也是森林火灾和森林病虫害早期监测预警的重要手段，在近年来飞速发展的林产品溯源、生态旅游、森林康养等领域也发挥着重要作用。通过对林业物联网应用现状的分析可以发现，虽然林业物联网技术已在各领域得到了广泛应用，但我国林业物联网的发展仍存在标准体系不健全、专用传感器自主研发能力不足、偏远林区电力和通信基础薄弱等瓶颈。我国自主研发的林业传感器在精度、稳定性、可靠性等方面与国外同类产品仍存在一定差距；电力供给和通信条件的困境仍阻碍着林业物联网监测数据的长期连续自动获取与更新。在数据处理分析方法上，人工智能等新技术、新方法在部分林业领域仍未得到有效应用；同时，林业数据共享机制、生态敏感数据安全保护等方面也有待进一步发展完善。针对上述问题，本文对我国林业物联网的发展进行了展望。未来应通过多方通力合作推动林业物联网标准体系建设；面向林业应用场景和环境研发具有自主产权的林业传感器、探索多能互补的野外供电系统、多网络智能融合的通信技术；促进林业物联网数据分析基础理论和智能算法发展；系统建立林业物联网数据安全管理体系；并推动无人机、人工智能、边缘计算、区块链等技术在林业物联网中的应用。本文通过梳理国内外林业物联网的应用现状和我国在该领域面临的挑战，以期为我国林业物联网发展和智慧林草建设提供参考。

关键词: 林业物联网, 林业生态监测, 森林灾害监测, 林业传感器, 无线通信

Abstract:

In recent years, China has been actively developing forestry Internet of Things (IoT) technology in order to promote modernization of forestry and facilitate the high-quality and smart development of forestry and grassland. Firstly, this paper outlines the development process of forestry IoT both domestically and internationally. Next, this paper introduces key technologies in the field from three aspects: perception, communication, and platform management. It elaborates on important technologies in the field of forestry IoT, such as radio frequency identification (RFID), sensors, ZigBee, LoRa, NB-IoT, data storage and quality control, and security and access control. On this basis, this paper analyzes in-depth the application of forestry IoT in many scenarios, such as forests, grasslands and wetlands resources supervision, forestry ecological environment monitoring, forest disaster monitoring and early warning, wildlife monitoring, intelligent supervision of nature reserves, and forestry industry. Forestry IoT is an important component of integrated sky-ground monitoring in forestry, playing a significant role in real-time collection of ground surveys and high-frequency, fine-scale observational data. It also serves as a crucial means for early monitoring and warning of forest fires and pests. Moreover, it plays an important role in rapidly developing fields such as traceability of forest products, ecotourism, and forest wellness in recent years. Analysis of the current application of forestry IoT reveals that although forestry IoT technology has been widely applied in various fields, there are still bottlenecks in the development of forestry IoT in China, such as an incomplete standard system, insufficient independent research and development capabilities for specialized sensors, and weak power and communication infrastructure in remote forest areas. Domestically developed forestry sensors still lag behind foreign counterparts in terms of accuracy, stability, and reliability. The challenges in power supply and communication continue to hinder the long-term, continuous, and automated acquisition and updating of forestry IoT monitoring data. In terms of data processing and analysis methods, new technologies and approaches such as artificial intelligence have not yet been effectively applied in certain forestry areas. Furthermore, forestry data sharing mechanisms and the protection of sensitive ecological data security still require further development and refinement. Finally, in response to the aforementioned challenges, this paper presents a forward-looking perspective on the development of forestry IoT in China. This includes promoting the establishment of a forestry IoT standard system through multi-stakeholder collaboration, developing forestry sensors with proprietary tailored to specific application scenarios and environments, and exploring multi-energy complementary field power supply system alongside intelligently integrated multi-network communication technologies. It also emphasizes advancing fundamental theories and intelligent algorithms for forestry IoT data analysis, systematically establishing the data security management framework for forestry IoT, and promoting the application of technologies such as drones, artificial intelligence, edge computing, and blockchain within the forestry IoT ecosystem. By reviewing the current application status of forestry IoT globally and the challenges faced in China, this paper aims to provide valuable insights for the advancement of forestry IoT and the development of smart forestry and grassland in China.

Key words: forestry Internet of Things, forestry ecological monitoring, forest disaster monitoring, forestry sensors, wireless communications

中图分类号:

S719
S7-05

刘璇昕,于新文,张旭,邓广,欧阳萱,范东璞,陈艳. 林业物联网发展现状与展望[J]. 林业科学, 2026, 62(1): 188-206.

Xuanxin Liu,Xinwen Yu,Xu Zhang,Guang Deng,Xuan Ouyang,Dongpu Fan,Yan Chen. Development Status and Prospects of Forestry Internet of Things[J]. Scientia Silvae Sinicae, 2026, 62(1): 188-206.

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项目Items	ZigBee	Sigfox	LoRa	NB-IoT
问世时间Established year	2003	2009	2012	2015
组网方式Networking	ZigBee网关 ZigBee gateway	Sigfox基站 Sigfox base station	LoRa网关 LoRa gateway	蜂窝组网 Cellular networks
传输距离Transmission distance/km	0.01~0.10	最远50 Up to 50	最远20 Up to 20	最远20 Up to 20
频段Frequency band	非授权频段 Unlicensed band	非授权频段 Unlicensed band	非授权频段 Unlicensed band	授权频段 License band
传输速度Transmission speed/kbps	20~250	0.1	0.3~50	20~250

监测因子 Monitoring factors	通信技术 Communications technology	供电方式 Power supply	监测地 Monitoring location	相关文献 Related literature
温度、湿度、光照强度 Temperature, humidity, illuminance	433 MHz无线自组网 433 MHz wireless self-organizing network	3.6 V锂电池 3.6 V lithium battery	黑龙江省孟家岗林场 Mengjiagang Forest Farm, Heilongjiang Province	李丹等（2014）
11种土壤、大气、光照参数 11 soil, atmospheric, and light parameters	GPRS/北斗卫星 GPRS/BeiDou satellite	太阳能-蓄电池-市电互补供电 Complementary solar-battery-utility power supply	北京鹫峰国家森林公园 Jiufeng National Forest Park, Beijing	郑一力等（2018）
冠层图像 Canopy image	LoRa	不间断电源模块 Uninterruptible power supply module	南京中山植物园 Zhongshan Botanical Garden, Nanjing	Wang et al.（2022）
温度、湿度、气体 Temperature, humidity, gas	WIFI	太阳能 Solar	孟加拉国加济布尔森林 Gazipur forest, Bangladeshi	Mohammed et al.（2019）
温度、湿度、CO₂浓度、水位 Temperature, humidity, CO₂ concentration, water level	WIFI	锂电池 Lithium battery	泰国普吉岛东部海岸线的红树林 Mangrove forest along the eastern shoreline of Phuket, Thailand	Boonrat et al.（2024）
土壤温湿度、空气湿度、光照强度 Soil temperature and humidity, air humidity, illuminance	LoRa	—	印度尼西亚布拉维雅大学森林 The forest in university of Brawijaya, Indonesia	Nurwarsito et al.（2025）

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