McCarthy, Alison (2010) Improved irrigation of cotton via real-time, adaptive control of large mobile irrigation machines. [Thesis (PhD/Research)]
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Improving the efficiency of water use in agriculture is increasingly essential to maintain the profi�tability and sustainability of farms. This involves applying only the minimum necessary irrigation water to maintain or improve the yield of individual plants. Improving cotton yield involves management of flower/fruit production in relation to vegetative growth. The cotton industry represents a signi�cant proportion of agricultural production and water use in Australia.
Irrigation control strategies can be used to improve site-specifi�c irrigation. These control strategies generally require weather, plant and/or soil data to determine irrigation volumes and/or timing that improve crop water use efficiency while maintaining or
improving crop yield. In this dissertation the difficulties in applying standard control theory to irrigation control are reviewed, in particular that the system, the growing
crop, varies with time and does not have fully-defi�ned dynamics. Hence, as the plant response and environmental conditions fluctuate throughout the season, control strategies which accommodate temporal and spatial variability in the �field and which locally
modify the control actions (irrigation amounts) need to be `adaptive'. Such irrigation control systems may then be implemented on large mobile irrigation machines, both
`lateral move' and `centre pivot' confi�gurations, to provide automatic machine operation.
This dissertation presents the specifi�cation and creation of a simulation framework `VARIwise' to aid the development, evaluation and management of spatially and
temporally varied site-specifi�c irrigation control strategies. The cotton model OZCOT has been integrated into VARIwise to provide feedback data in the control strategy simulations. VARIwise can accommodate sub-�field scale variations in all input parameters using a 1 m2 cell size, and permits application of diff�ering control strategies within the fi�eld, as well as diff�ering irrigation amounts down to this scale.
An automatic model calibration procedure was developed for VARIwise to enable realtime input of �field data into the framework. The model calibration procedure was
accurately implemented with measured �field data and the calibrated model was then used to evaluate the eff�ect of using diff�erent types of data in an irrigation control system. With the fi�eld data collected, the model was most eff�ectively calibrated using the full set of plant, soil and weather data, while either weather-and-plant or soil-and-plant input provided adequate inputs to the control system if only two inputs were available.
A literature review of control systems identifi�ed three adaptive control strategies that are applicable to irrigation, namely: (i) Iterative Learning Control (ILC) which involves applying irrigation volumes to cells in the �field calculated by comparing the desired and
measured value of the input variable for control (e.g. soil moisture defi�cit); (ii) iterative hill climbing control which involves applying test irrigation volumes to test cells in the fi�eld to determine the application that produced the best crop response and applying
that volume to the remainder of the �field; and (iii) Model Predictive Control (MPC) which involves using a calibrated crop model to evaluate various irrigation applications
and timings to determine which irrigation decision to implement.
The three control strategies were implemented and simulated in VARIwise to evaluate their respective robustness to limitations in data availability and system constraints.
These strategies eff�ectively adapted to temporal changes in weather conditions and spatially variable soil properties. For the set of fi�eld conditions simulated in VARIwise,
the ILC, iterative hill climbing and MPC controllers produced their highest yield and water use efficiency with soil data, weather-and-plant data, and the full data input,
respectively. MPC was most sensitive to spatially sparse input data but performed well with spatially variable rainfall and limited machine capacity. ILC was least sensitive to spatially sparse input data and variable rainfall, whilst iterative hill climbing control was
most sensitive to spatially sparse input data and variable rainfall. Hence, in situations of high data input MPC should be implemented, whilst in situations of low data input ILC should be implemented. Iterative hill climbing control was most sensitive to limited irrigation machine capacity.
It is further concluded that cotton yield and irrigation water use efficiency may be signifi�cantly improved using adaptive control systems; and that adaptive control systems
can adjust the irrigation application and improve the irrigation performance despite various data availability limitations and irrigation hardware constraints.
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|Item Type:||Thesis (PhD/Research)|
|Item Status:||Live Archive|
|Additional Information:||Doctor of Philosophy (PhD) thesis.|
|Depositing User:||ePrints Administrator|
|Faculty / Department / School:||Historic - Faculty of Engineering and Surveying - Department of Electrical, Electronic and Computer Engineering|
|Date Deposited:||17 Oct 2011 05:45|
|Last Modified:||13 Jul 2016 01:53|
|Uncontrolled Keywords:||large mobile irrigation machines; irrigation machines; VARIwise|
|Fields of Research :||07 Agricultural and Veterinary Sciences > 0799 Other Agricultural and Veterinary Sciences > 079901 Agricultural Hydrology (Drainage, Flooding, Irrigation, Quality, etc.)|
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