农业工程学报
農業工程學報
농업공정학보
2013年
9期
170-177
,共8页
李颖慧%李民赞*%邓小蕾%孙红%郑立华
李穎慧%李民讚*%鄧小蕾%孫紅%鄭立華
리영혜%리민찬*%산소뢰%손홍%정립화
无线传感器网络%监测%温室%营养液%电导率
無線傳感器網絡%鑑測%溫室%營養液%電導率
무선전감기망락%감측%온실%영양액%전도솔
wireless sensor network%monitoring%greenhouse%nutrient solutions%electrical conductivity
温室营养液无土栽培,具有节约种植成本、生产效率高等优点.监测营养液的电导率、pH值等特性参数,是实现营养液无土栽培信息化与自动化的基础.为了实现温室无土栽培营养液的实时监测,开发了基于无线传感器网络(wireless sensor network, WSN)的营养液电导率实时监测系统.系统以JN5139为中央控制器同时控制营养液电导率信息采集单元和无线通讯单元,实现了营养液电导率信息的实时采集与处理、LCD显示和键盘输入等人机交互操作以及基于WSN的营养液电导率实时测量自组织网络,同时系统集成了GPRS模块,实现了营养液电导率与温度信息的远程传输与监控等功能.系统采用星型网络拓扑结构,并进行定时休眠、传感器掉电控制来节省能源消耗.针对系统的实用性和可靠性进行了系统标定、温度补偿以及温室试验,分析比较了电导率测量线性与非线性模型.试验结果表明分段线性模型建模效果较好,分段拟合R2均在0.97以上.系统的测量范围为0.5~2.9 mS/cm,测量结果能够精确到0.01 mS/cm,总体测量相对误差为2.10%,较好地满足了温室营养液电导率实时监测的要求,为无土栽培的科学管理提供技术手段.
溫室營養液無土栽培,具有節約種植成本、生產效率高等優點.鑑測營養液的電導率、pH值等特性參數,是實現營養液無土栽培信息化與自動化的基礎.為瞭實現溫室無土栽培營養液的實時鑑測,開髮瞭基于無線傳感器網絡(wireless sensor network, WSN)的營養液電導率實時鑑測繫統.繫統以JN5139為中央控製器同時控製營養液電導率信息採集單元和無線通訊單元,實現瞭營養液電導率信息的實時採集與處理、LCD顯示和鍵盤輸入等人機交互操作以及基于WSN的營養液電導率實時測量自組織網絡,同時繫統集成瞭GPRS模塊,實現瞭營養液電導率與溫度信息的遠程傳輸與鑑控等功能.繫統採用星型網絡拓撲結構,併進行定時休眠、傳感器掉電控製來節省能源消耗.針對繫統的實用性和可靠性進行瞭繫統標定、溫度補償以及溫室試驗,分析比較瞭電導率測量線性與非線性模型.試驗結果錶明分段線性模型建模效果較好,分段擬閤R2均在0.97以上.繫統的測量範圍為0.5~2.9 mS/cm,測量結果能夠精確到0.01 mS/cm,總體測量相對誤差為2.10%,較好地滿足瞭溫室營養液電導率實時鑑測的要求,為無土栽培的科學管理提供技術手段.
온실영양액무토재배,구유절약충식성본、생산효솔고등우점.감측영양액적전도솔、pH치등특성삼수,시실현영양액무토재배신식화여자동화적기출.위료실현온실무토재배영양액적실시감측,개발료기우무선전감기망락(wireless sensor network, WSN)적영양액전도솔실시감측계통.계통이JN5139위중앙공제기동시공제영양액전도솔신식채집단원화무선통신단원,실현료영양액전도솔신식적실시채집여처리、LCD현시화건반수입등인궤교호조작이급기우WSN적영양액전도솔실시측량자조직망락,동시계통집성료GPRS모괴,실현료영양액전도솔여온도신식적원정전수여감공등공능.계통채용성형망락탁복결구,병진행정시휴면、전감기도전공제래절성능원소모.침대계통적실용성화가고성진행료계통표정、온도보상이급온실시험,분석비교료전도솔측량선성여비선성모형.시험결과표명분단선성모형건모효과교호,분단의합R2균재0.97이상.계통적측량범위위0.5~2.9 mS/cm,측량결과능구정학도0.01 mS/cm,총체측량상대오차위2.10%,교호지만족료온실영양액전도솔실시감측적요구,위무토재배적과학관리제공기술수단.
The application of hydroponics and a substrate-based culture in a greenhouse has been paid much attention to by more and more people for its environmental protection and high efficiency in the production. In order to promote automation of the soilless culture in a greenhouse, it is necessary to monitor the electrical conductivity (EC) of the nutrient solution used in greenhouse. Therefore, a monitoring system for EC of the nutrient solution in a greenhouse based on WSN was developed. The system consisted of a measurement section, a transmission control section, and a terminal server. The measurement section, including a conductivity electrode (DJS-1C) and a digital temperature sensor (DS18B20), could measure the EC and temperature of nutrient solution and then send the data to the transmission control section. The transmission control section could collect and process the data from different sensor nodes, and then display the result on the LCD screen to satisfy the needs of human-device interaction. It could also transmit the data of EC and temperature to the terminal server. The core controller of the whole system was a JN5139 module, which was responsible for collecting data in the measurement section, connecting with a GPRS module in the transmission control section through serial ports, and controlling GPRS by using AT commands. In this way, the system realized the remote transmission and management of soilless culture information. The data transmission was performed based on the IEEE802.15.4 standard and TCP/IP protocol. To save the consumption of power, the system was developed in a star network topology, combining with regular sleep and switches of the power of information collecting modules. Calibration tests were done in the laboratory to verify the accuracy of the system. Several estimation models were built and verified such as Piecewise linear model, Power function model, Logarithmic model, and Polynomial model. The results showed that the Piecewise linear model was the best choice, and the R2 for fitting was greater than 0.97. In addition, experiments in greenhouse were conducted from June, 2012 to July, 2012 to monitor the EC of the nutrient solution of tomatoes. The precision reached to 0.01 mS/cm with a relative error of 2.10%and the range of the measurement was from 0.5 mS/cm up to 2.9 mS/cm. It was proved that the system could satisfy the requirements of real-time EC measurement in greenhouse.