Temporal and spatial simulation of production-scale irrigated cotton systems

Site-specific management of cotton (Gossypium hirsutum) cropping systems at the production-scale requires information regarding environmental interactions across the landscape. Landscape-scale cotton models could track these interactions and be integrated into future decision support tools designed...

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Bibliographic Details
Published in:Precision agriculture 2015-12, Vol.16 (6), p.630-653
Main Authors: Booker, J. D, Lascano, R. J, Molling, C. C, Zartman, R. E, Acosta-Martínez, V
Format: Article
Language:English
Subjects:
Agricultural production
Agriculture
Aquifers
Atmospheric Sciences
Biomedical and Life Sciences
Chemistry and Earth Sciences
Computer Science
Cotton
crop production
Crop science
Cropping systems
Crops
decision support systems
Gossypium hirsutum
Growing season
Growth models
Irrigation
Irrigation systems
landscapes
Life Sciences
Management decisions
Moisture content
Nitrogen
Physics
Plant growth
Rain
Remote Sensing/Photogrammetry
Seasons
Sensors
Simulation
Soil Science & Conservation
Soil sciences
Soil water
soil water content
Statistics for Engineering
Studies
temporal variation
Water content
Weather
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Summary:Site-specific management of cotton (Gossypium hirsutum) cropping systems at the production-scale requires information regarding environmental interactions across the landscape. Landscape-scale cotton models could track these interactions and be integrated into future decision support tools designed to manage variable inputs; however, modeling of cotton systems across the landscape has not been evaluated. Cotton production in the Southern Texas High Plains is dependent on irrigation from the Ogallala Aquifer, and thus tracking soil water content across fields could help producers plan their use of diminishing aquifer resources. Our hypothesis was that the PALMScot model, a grid-based landscape-scale cotton model, would capture spatial and temporal variability and environmental interactions affecting soil water and plant growth within a 70-ha field throughout two contrasting growing seasons, without adjustment of input parameters for the model. Thus, our objective was to compare values of soil water content and crop height calculated by the PALMScot model with corresponding field measured values at multiple locations across a fine textured, pivot irrigated production cotton field during two growing seasons. The PALMScot model calculated values of soil water and crop height across the field with a root mean squared deviation (RMSD) for soil water content in the 1.0-m profile ≤0.032 m³/m³ and most Nash–Sutcliffe efficiency (NSE) values ≥0.48. Values of RMSD for crop height were ≤0.10 m at all locations in 2010 and 2011. We conclude that PALMScot correctly and efficiently calculated soil water content and crop height across the field, throughout each season, and the model has potential as a site-specific management tool for cotton cropping systems.
ISSN:1385-2256
1573-1618
DOI:10.1007/s11119-015-9397-6