Optimal Control of Greenhouse Cultivation (Βέλτιστος έλεγχος θερμοκηπιακών καλλιεργειών - έκδοση στα αγγλικά)
Optimal Control of Greenhouse Cultivation
Συγγραφέας: Gerrit van Straten, Gerard van Willigenburg, Eldert van Henten, Rachel van Ooteghem
ISBN: 9781420059618
Σελίδες: 326
Σχήμα: 17 Χ 25
Εξώφυλλο: Σκληρό
Έτος έκδοσης: 2010
Features
• Discusses economic optimization of greenhouse control through mathematical modeling
• Examines 30 years of scientific research to present a unified framework for efficient decision-making
• Presents modern methods of control and optimization including classical rule-based and multivariable feedback controllers
• Utilizes real and experimental examples and novel case discussions such as solar greenhouses
• Concludes with a discussion of open issues to stimulate new areas of research and development
Summary
Greenhouse control system manufacturers produce equipment and software with hundreds of settings and, while they hold training courses on how to adjust these settings, there is as yet no integrated instruction on when or why. Despite rapid growth in the greenhouse industry, growers are still faced with a multitude of variables and no unifying framework from which to choose the best option.
Consolidating 30 years of research in greenhouse climate control, Optimal Control of Greenhouse Cultivation utilizes mathmatical models to incorporate the wealth of scientific knowledge into a feasible optimal control methodology for greenhouse crop cultivation. Discussing several different paradigms on greenhouse climate control, it integrates the current research into physical modeling of the greenhouse climate in response to heating, ventilation, and other control variables with the biological modeling of variables such as plant evapo-transpiration and growth.
Key topics include state-space greenhouse and crop modeling needed for the design of integrated optimal controllers that exploit rather than mitigate outside weather conditions, especially sunlight, given widely different time scales. The book reviews classical rule-based and multivariable feedback controllers in comparison with the optimal hierarchical control paradigm. It considers real and hypothetical examples including lettuce, tomato, and solar greenhouses and examines experimental results of greenhouse climate control using optimal control software. The book concludes with a discussion of open issues as well as future perspectives and challenges.
Providing a tool to automatically determine the most economical controls and settings for their operation, this much-needed book relieves growers of unnecessary control tasks, and allows them to achieve the best possible trade-off between short term savings and optimal harvest yield.
Contents
Introduction and Problem Statement
Greenhouse-Crop Cultivation—Benefits and Challenges
Automatic Control
Elementary Description of the Greenhouse-Crop System
Measurements and Instrumentation
Decomposition, Fluxes, and Information Flows
General State–Space Representation
Hierarchical Computerized Control
Current Status of Computerized Control
How Is This Book Organized?.
Reference
Introduction to Optimal Control of Greenhouse Climate
Introduction and Motivation
A Simple Illustrative Example
General Formulation of Optimal Control Problems
Benefits and Difficulties Associated with Optimal Control
Open-Loop Optimal Control
Introduction
Optimal Control Theory
Optimal Control Algorithms
References
Closed-Loop Optimal Control
Introduction
State Estimation
Linear Quadratic Feedback Control
References
Greenhouse Cultivation Control Paradigms
Introduction
Optimal Control Revisited
Earlier Surveys of Greenhouse Climate Control Solutions
Classification of Proposed Greenhouse Climate Control Solutions
Discussion and Conclusion
References
A Seminal Case: Lettuce
Introduction
Models
The Optimal Control Problem
Optimal Control Case Studies
Concluding Remarks
References
An Experimental Application: Tomato.
Introduction
Tomato Model
Greenhouse Climate Model
State–Space Form of the Complete Greenhouse-Crop Model
Calibration and Model Results
Open-Loop Optimization
Two–Time-Scale Receding Horizon Controller (RHOC)
Evaluation of Optimal Control
Assessment of Economic Result as Compared with Conventional Control
Discussion and Conclusions
References
An Advanced Application: The Solar Greenhouse.
Introduction
Description of the Solar Greenhouse Concept
System Description
The Solar Greenhouse Model
Model of Crop Biophysics
Sensitivity Analysis, Calibration, and Validation
Optimal Control
References
Appendices
Developments, Open Issues, and Perspectives
Introduction
Developments in the Greenhouse Industry and Consequences for Control
Prerequisites for Future Control Systems
Challenges for Science and Technology
Showstoppers for Optimal Control
Conclusions and Perspectives
References