小生境环境监控系统设计
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摘要
依靠人力想要将农田小生境内生物的生存条件控制在最佳是复杂且难以实现的。"智慧农业"的提出使得农业生产的智能化、自动化成为可能,依据农业物联网架构,设计实现了基于ZigBee技术与NB-IOT技术的农田小生境环境监控系统,分析了系统中涉及的主要模块及功能,系统应用测试表明,完成了农田小生境的温湿度、光照等环境信息的采集、远程传输及处理等工作,并能通过远程控制设备改变小生境内的环境,以达到生物的适宜生存条件。
It is complex and difficult to control the living conditions of the organisms in farmland by human resources.The proposal of "smart agriculture" makes the intelligentization and automation of agricultural production possible. Based on the agricultural Internet of Things architecture, this paper designs and realizes the environmental monitoring system of farmland niche based on ZigBee technology and NB-IOT technology.It also analyzes the main modules and functions involved in the system.System application tests show that the collection, remote transmission and processing of environmental information such as temperature and humidity, illumination and so on are completed, and the environment in the field can be changed by remote control equipment in order to achieve the suitable living conditions of living things.
It is complex and difficult to control the living conditions of the organisms in farmland by human resources.The proposal of "smart agriculture" makes the intelligentization and automation of agricultural production possible. Based on the agricultural Internet of Things architecture, this paper designs and realizes the environmental monitoring system of farmland niche based on ZigBee technology and NB-IOT technology.It also analyzes the main modules and functions involved in the system.System application tests show that the collection, remote transmission and processing of environmental information such as temperature and humidity, illumination and so on are completed, and the environment in the field can be changed by remote control equipment in order to achieve the suitable living conditions of living things.
引文
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[12]赵远超,赵建平,田全利,et al.基于NB-IoT技术的智能温室大棚温湿度检测系统[J].电子技术,2018(7).
[13]王能辉,胡国强.基于NB-IoT的农田远程监测系统的设计[J].陕西农业科学,2017,63(12):82-85.
[2]豆东东,陈广锋.基于机器视觉的蔬菜生长状况分析[J]中国农机化学报,2016,37(10):162-165.
[3]候洪丽,张霄霞,王福明.ZigBee无线传输技术综述[J].山西电子技术,2011(4):84-86.
[4]杨峰,初强.NB-IoT技术特点与前景[J].中国新通信,201719(14).
[5]余少波,蔡绍昌.MiWind物联网技术与LoRa技术的对比[J].中国有线电视,2017(4):466-471.
[6]张水保,徐守志,李丰杰.智能温室远程监控系统设计[J]三峡大学学报(自然科学版),2012,34(2):76-79.
[7]岳青,张海辉,卢博友.基于WSN的温室环境监测节点设计[J].安徽农业科学,2010,38(30):17219-17221.
[8]陈莉,陶正苏.环境监测无线传感器网络节点的设计[J]仪表技术与传感器,2008(10):7-8.
[9]赵嘉伟,吕俐衡,沈洪吉,et al.zigbee技术在农业温室大棚中的应用研究[J].科技风,2017(15):217-218.
[10]王寅涛,邵峥嵘.基于物联网的温室远程测控系统设计[J]北京农业职业学院学报,2014,28(5):31-35.
[11]廖建尚.基于CC2530和ZigBee的智能农业温湿度采集系统设计[J].物联网技术,2015,5(8):25-29.
[12]赵远超,赵建平,田全利,et al.基于NB-IoT技术的智能温室大棚温湿度检测系统[J].电子技术,2018(7).
[13]王能辉,胡国强.基于NB-IoT的农田远程监测系统的设计[J].陕西农业科学,2017,63(12):82-85.
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