果园环境远程监测系统构建与设计
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摘要
为了实时获取果园环境信息,及时科学指导生产,设计了1种果园环境信息远程监测系统。该系统主要基于LoRa技术和GpRS无线传输技术,通过布置在园区的传感器进行数据采集,LoRa模块负责传感器数据汇集,GpRS模块将数据进行远程传输。在用户中心开发了基于B/S结构的远程监测系统,实现了数据信息的实时及历史查询,数据报表及变化曲线的导出等功能。系统采用低功耗设计,集采集、监视、环境信息获取于一体,适用于果园环境的大范围、远距离监测。
To obtain the real time information of the orchard environment for the scientific guidance of production, a remote monitoring system for orchard environment information was designed. The system is mainly based on LoRa technology and GPRS wireless transmission technology. Data collection was done through the sensors arranged in the orchard, with LoRa module responsible for the collection of sensor data, and GPRS module for the transition of data remotely. A remote monitoring system based on B/S structure was developed in the user center, which realized real-time and historical query of data information, data report and export of change curves. The system integrates the function of collecting, monitoring, and obtaining environmental information with low power consumption. It is suitable for large-scale and long-distance monitoring in orchard environment.
To obtain the real time information of the orchard environment for the scientific guidance of production, a remote monitoring system for orchard environment information was designed. The system is mainly based on LoRa technology and GPRS wireless transmission technology. Data collection was done through the sensors arranged in the orchard, with LoRa module responsible for the collection of sensor data, and GPRS module for the transition of data remotely. A remote monitoring system based on B/S structure was developed in the user center, which realized real-time and historical query of data information, data report and export of change curves. The system integrates the function of collecting, monitoring, and obtaining environmental information with low power consumption. It is suitable for large-scale and long-distance monitoring in orchard environment.
引文
[1]张强,魏钦平,刘惠平,等.苹果园土壤养分与果实品质关系的多元分析及优化方案[J].中国农业科学,2011,44(8):1654-1661.
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[4]中华人民共和国农业部环境保护科研监测所.NY/T395-2012,农田土壤环境质量监测技术规范[S].北京:中国农业出版社,2012.
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[8]李增焕,汪文超,崔远来.基于B/S模式的灌区工情管理信息系统开发与应用[J].中国农村水利水电,2017(6):18-22.
[9]查修齐,吴荣泉,高元钧.C/S到B/S模式转换的技术研究[J].计算机工程,2014,40(1):263-267.
[10]陈娟,李元,李万国.基于B/S模式的嵌入式系统测试方法与实现[J].电子技术应用,2016,42(2):50-52,56.
[2]孙曼,张乃谦,金立标,等.基于LoRa标准的MAC层协议研究[J].电视技术,2016,40(10):77-81.
[3]牛广文.基于GPRS通信的远程土壤墒情自动监测系统设计[J].自动化与仪器仪表,2015(2):36-37,40.
[4]中华人民共和国农业部环境保护科研监测所.NY/T395-2012,农田土壤环境质量监测技术规范[S].北京:中国农业出版社,2012.
[5]张洋,刘军,严汉宇,等.精通STM32F4[M].北京:北京航空航天大学出版社,2015:1-2.
[6]Semteech.SX1276/77/78数据手册[EB].www.semtech.com
[7]SIM800A_硬件设计手册[EB].http://simcomm2m.com/module/detail.aspx?id=129[2017-04-26].
[8]李增焕,汪文超,崔远来.基于B/S模式的灌区工情管理信息系统开发与应用[J].中国农村水利水电,2017(6):18-22.
[9]查修齐,吴荣泉,高元钧.C/S到B/S模式转换的技术研究[J].计算机工程,2014,40(1):263-267.
[10]陈娟,李元,李万国.基于B/S模式的嵌入式系统测试方法与实现[J].电子技术应用,2016,42(2):50-52,56.
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