Constrained temperature and relative humidity predictive control: Agricultural greenhouse case of study

IF 7.7 Q1 AGRICULTURE, MULTIDISCIPLINARY
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Abstract

The importance of Model Predictive Control (MPC) has significant applications in the agricultural industry, more specifically for greenhouse’s control tasks. However, the complexity of the greenhouse and its limited prior knowledge prevent an exact mathematical description of the system. Subspace methods provide a promising solution to this issue through their capacity to identify the system’s comportment using the fit between model output and observed data. In this paper, we introduce an application of Constrained Model Predictive Control (CMPC) for a greenhouse temperature and relative humidity. For this purpose, two Multi Input Single Output (MISO) systems, using Numerical Subspace State Space System Identification (N4SID) algorithm, are firstly suggested to identify the temperature and the relative humidity comportment to heating and ventilation actions. In this sense, linear state space models were adopted in order to evaluate the robustness of the control strategy. Once the system is identified, the MPC technique is applied for the temperature and the humidity regulation. Simulation results show that the regulation of the temperature and the relative humidity under constraints was guaranteed, both parameters respect the ranges 15 °C ≤ Tint ≤ 30 °C and 50 % ≤ Hint ≤ 70 % respectively. On the other hand, the control signals uf and uh applied to the fan and the heater, respect the hard constraints notion, the control signals for the fan and the heater did not exceed 0 ≤ uf ≤ 4.3 Volts and 0 ≤ uh ≤ 5 Volts, respectively, which proves the effectiveness of the MPC and the tracking tasks. Moreover, we show that with the proposed technique, using a new optimization toolbox, the computational complexity has been significantly reduced. The greenhouse in question is devoted to Schefflera Arboricola cultivation.

约束温度和相对湿度预测控制:农业大棚案例研究
模型预测控制(MPC)在农业领域有着重要的应用,尤其是在温室控制任务中。然而,温室的复杂性和有限的先验知识阻碍了对系统的精确数学描述。子空间方法能够利用模型输出与观测数据之间的拟合关系来识别系统的组合,从而为这一问题提供了一个很有前景的解决方案。本文介绍了受约束模型预测控制(CMPC)在温室温度和相对湿度方面的应用。为此,首先建议使用数值子空间状态空间系统识别(N4SID)算法来识别两个多输入单输出(MISO)系统,以确定温度和相对湿度对加热和通风操作的适应性。从这个意义上说,采用线性状态空间模型是为了评估控制策略的鲁棒性。一旦系统被识别,MPC 技术就会应用于温度和湿度的调节。仿真结果表明,温度和相对湿度的调节在约束条件下得到了保证,两个参数的范围分别为 15 °C ≤ Tint ≤ 30 °C 和 50 % ≤ Hint ≤ 70 %。另一方面,应用于风扇和加热器的控制信号 uf 和 uh 遵守了硬约束概念,风扇和加热器的控制信号分别不超过 0 ≤ uf ≤ 4.3 伏和 0 ≤ uh ≤ 5 伏,这证明了 MPC 和跟踪任务的有效性。此外,我们还展示了使用新优化工具箱的拟议技术,其计算复杂度已显著降低。该温室专门用于种植 Schefflera Arboricola。
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来源期刊
Information Processing in Agriculture
Information Processing in Agriculture Agricultural and Biological Sciences-Animal Science and Zoology
CiteScore
21.10
自引率
0.00%
发文量
80
期刊介绍: Information Processing in Agriculture (IPA) was established in 2013 and it encourages the development towards a science and technology of information processing in agriculture, through the following aims: • Promote the use of knowledge and methods from the information processing technologies in the agriculture; • Illustrate the experiences and publications of the institutes, universities and government, and also the profitable technologies on agriculture; • Provide opportunities and platform for exchanging knowledge, strategies and experiences among the researchers in information processing worldwide; • Promote and encourage interactions among agriculture Scientists, Meteorologists, Biologists (Pathologists/Entomologists) with IT Professionals and other stakeholders to develop and implement methods, techniques, tools, and issues related to information processing technology in agriculture; • Create and promote expert groups for development of agro-meteorological databases, crop and livestock modelling and applications for development of crop performance based decision support system. Topics of interest include, but are not limited to: • Smart Sensor and Wireless Sensor Network • Remote Sensing • Simulation, Optimization, Modeling and Automatic Control • Decision Support Systems, Intelligent Systems and Artificial Intelligence • Computer Vision and Image Processing • Inspection and Traceability for Food Quality • Precision Agriculture and Intelligent Instrument • The Internet of Things and Cloud Computing • Big Data and Data Mining
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