农业工程学报
農業工程學報
농업공정학보
2013年
7期
139-147
,共9页
张京%杨启良*%戈振扬%齐亚峰%周兵%殷欣
張京%楊啟良*%戈振颺%齊亞峰%週兵%慇訢
장경%양계량*%과진양%제아봉%주병%은흔
温室%监测%无线传感器网络%土壤含水率%温度%湿度%CC2530
溫室%鑑測%無線傳感器網絡%土壤含水率%溫度%濕度%CC2530
온실%감측%무선전감기망락%토양함수솔%온도%습도%CC2530
greenhouse%monitoring%wireless sensor networks%soil moisture%temperature%humidity%CC2530
针对传统温室环境监测系统布线繁杂、成本较高、监测灵活性差及以往无线传感器网络(wireless sensor network, WSN)能耗较高等问题,设计了一种基于WSN的温室环境参数监测系统.利用CC2530无线传感网络芯片和外围接口搭建了系统硬件,使用Z-Stack协议栈编制了系统底层软件,基于VB软件平台开发了的温室环境监测系统上位机软件,并验证分析了CC2530芯片的传输特性.结果表明,节点在距地表1.5 m时的有效传输距离为60 m,单个节点使用2节5号电池能够持续进行温室环境参数数据采集工作45 d,能较为准确的对温室环境温湿度及作物土壤体积含水率进行监测,系统具有较高的实用性与可靠性.
針對傳統溫室環境鑑測繫統佈線繁雜、成本較高、鑑測靈活性差及以往無線傳感器網絡(wireless sensor network, WSN)能耗較高等問題,設計瞭一種基于WSN的溫室環境參數鑑測繫統.利用CC2530無線傳感網絡芯片和外圍接口搭建瞭繫統硬件,使用Z-Stack協議棧編製瞭繫統底層軟件,基于VB軟件平檯開髮瞭的溫室環境鑑測繫統上位機軟件,併驗證分析瞭CC2530芯片的傳輸特性.結果錶明,節點在距地錶1.5 m時的有效傳輸距離為60 m,單箇節點使用2節5號電池能夠持續進行溫室環境參數數據採集工作45 d,能較為準確的對溫室環境溫濕度及作物土壤體積含水率進行鑑測,繫統具有較高的實用性與可靠性.
침대전통온실배경감측계통포선번잡、성본교고、감측령활성차급이왕무선전감기망락(wireless sensor network, WSN)능모교고등문제,설계료일충기우WSN적온실배경삼수감측계통.이용CC2530무선전감망락심편화외위접구탑건료계통경건,사용Z-Stack협의잔편제료계통저층연건,기우VB연건평태개발료적온실배경감측계통상위궤연건,병험증분석료CC2530심편적전수특성.결과표명,절점재거지표1.5 m시적유효전수거리위60 m,단개절점사용2절5호전지능구지속진행온실배경삼수수거채집공작45 d,능교위준학적대온실배경온습도급작물토양체적함수솔진행감측,계통구유교고적실용성여가고성.
@@@@Aiming at the problems of traditional greenhouse environment monitoring systems such as complicated wiring, high cost, inflexible monitoring, and high energy consumption of previous wireless sensor networks (WSNs), this paper designed a WSN-based greenhouse environmental parameter monitoring system, constructed its hardware with a CC2530 wireless sensor network chip and peripheral interface, compiled its underlying software by using the protocol stack of Z-Stack, and developed the PC software of greenhouse environment monitoring system based on a VB software platform. The transmission characteristics of a CC2530 chip was analyzed, and the experimental results showed that the effective transmission distance of the nodes was 60 m when they were placed 1.5 m above the ground. The connection between RSSI and the distance of nodes could be seen that the transmission power of the nodes gradually increased with the change of distance. The magnitude of RSSI attenuated faster when the distance of nodes was between 0 to 20 m. The fluctuation of RSSI because of the signal was blocked by the jatropha in the greenhouse, and the average height of jatropha was 2 m. The packet loss rate started to increase when the RSSI was less than -80 dBm, and the basic signal transmission capability of nodes was lost when the RSSI was less than-90 dBm. Besides, a single node with two 5th batteries could sustain the acquisition of greenhouse environmental parameter data for 45 d and accurately detect the temperature, humidity, and soil volumetric water content for greenhouse environment. During the experiment of energy consumption, the sensor nodes of soil moisture acquired data every half-hour, and the sensor nodes of temperature and humidity collected data every hour. The sensor nodes of soil moisture significantly consumed more energy than the sensor nodes of temperature and humidity under the same conditions of power transmission after 20 d. There was a slight increase for the voltage of nodes in the process of dormancy. Once the voltage of nodes falls below 3 V, although it has few impacts to the capacity of signal transmission, it may lead to abnormal work for the sensors. Above all, this system was proved to be practical and reliable.