CAJ | 학술논문

为了解决现有光环境调控系统存在光照度不可调、能耗高、部署困难等问题，该文设计基于无线传感器网络的光环境调控系统。该光环境调控系统以 CC2530处理器为核心设计中央控制节点、监测节点、调光节点，采用ZigBee协议实现自组网络、监测数据和控制信号传输。监测节点通过周期监测光合有效辐射值，利用自然光中太阳高度角与红蓝光比例关系，计算当前红蓝光光量子通量密度；利用智能中央控制节点计算其与作物所需目标量的差值，并将其转换为脉宽调制控制信号，通过调光节点控制LED输出亮度，实现LED调光灯输出光量的动态、精确、无线调控。试验检验表明，该系统红蓝光光量子通量密度监测误差小于6%，调控输出光照度相对误差小于3%，可满足多个温室实时、按需、定量光环境调控的需求，具有部署灵活、易扩展、低能耗的特点。
위료해결현유광배경조공계통존재광조도불가조、능모고、부서곤난등문제，해문설계기우무선전감기망락적광배경조공계통。해광배경조공계통이 CC2530처리기위핵심설계중앙공제절점、감측절점、조광절점，채용ZigBee협의실현자조망락、감측수거화공제신호전수。감측절점통과주기감측광합유효복사치，이용자연광중태양고도각여홍람광비례관계，계산당전홍람광광양자통량밀도；이용지능중앙공제절점계산기여작물소수목표량적차치，병장기전환위맥관조제공제신호，통과조광절점공제LED수출량도，실현LED조광등수출광량적동태、정학、무선조공。시험검험표명，해계통홍람광광양자통량밀도감측오차소우6%，조공수출광조도상대오차소우3%，가만족다개온실실시、안수、정량광배경조공적수구，구유부서령활、역확전、저능모적특점。
In China, the monitoring methods and regulation systems of precision agriculture have some deficiencies, especially in light environment regulation. Recently, light environment regulation has become a significant research focus in the precision agriculture development of our country. Important factors in light environment regulation consist of expandability, energy consumption, deployment and maintenance, and dynamic regulation of light illumination, which directly affects crop production, quality, and efficiency. First, studies on the biological mechanisms of photosynthesis have provided a theoretical basis for accurate and quantitative regulating of the light of crops. Secondly, with the rapid development of semiconductor and opto-electronics technology, specific-band, single-wavelength and narrow-band light emitting diodes have been produced. And wireless sensor network technology has been applied to more and more fields, such as environmental monitoring and controlling. Based on the above analysis, using a wireless sensor network, an intelligent light environment regulation system was designed, which was described from the overall architecture, hardware, software features, and experimental verification. The system adopted a tree topology and took CC2530 as the core processor, which could realize a self-organized network and information transmission by ZigBee. It was comprised of three kinds of nodes:the central control node, environmental monitoring node, and light regulation node. The environmental monitoring node adapted a 6450 vantage pro-solar radiation sensor and a DS18B20 temperature sensor to gather internal environment information in a greenhouse. Using the proportional relationship of a solar elevation angle and a red-blue light, the current photo flux density (PFD) of the red-blue light was calculated, which was combined with the temperature information in the greenhouse and was transmitted to the central control node periodically. At the same time, the monitoring node realized routing forward as the ZigBee routing node. The light regulation node, as a ZigBee leaf node, received regulating control parameters of the red-blue light. Through controlling the light emitting diodes output intensity by pulse width modulation (PWM), the light regulation node implemented real-time, wireless, and quantitative supplemental light control. The central control node, as the ZigBee root node, had functions of network coordination and intelligent controlling. According to the monitoring information and threshold value of temperature and photo flux density of the red-blue light, the supplement light value of crops were calculated, and then was converted to a PWM control signal which was transmitted to the light regulation nodes. Based on the characteristics of the actual system and light requirements of crop growth, the actual deployment scheme of the regulation system was optimized, which could effectively improve the utilization rate of light intensity. From October 2012, the system has been deployed in the modern agriculture exhibition area of Wuquan in Yangling. Compared to the results tested by spectrometer, the relative error of PFD values of red-blue light monitored was within 6%. Field test results showed less than 3% relative tolerance in outputting light value. Experiments proved the system could realize real-time, on-demand, quantitative regulated under the condition of temperature constraint and dynamically adjusted energy output under the condition of meeting the demand of crops. So it has the advantages of highly reliable, easy to expand, low-power.