Application and evaluation of Stanghellini model in the determination of crop evapotranspiration in a naturally ventilated greenhouse

Stanghellini model is one of the few models primarily developed to predict the evapotranspiration of crops (ETc) in naturally ventilated greenhouses. However, there is insufficient data on the model regarding its use, particularly in China where solar greenhouses without heating systems are fast spr...

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Bibliographic Details
Published in:International journal of agricultural and biological engineering 2018-11, Vol.11 (6), p.95-103
Main Authors: Joe Acquah, Samuel, Yan, Haofang, Zhang, Chuan, Wang, Guoqing, Zhao, Baoshan, Wu, Haimei, Zhang, Hengnian
Format: Article
Language:English
Subjects:
Agricultural production
Air temperature
Crops
Data processing
Evapotranspiration
Flow measurement
Greenhouses
Heating systems
Irrigation
Leaf area
Leaf area index
Net radiation
Regression analysis
Regression models
Relative humidity
Seasons
Sensitivity analysis
Solar radiation
Tomatoes
Ventilation
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Summary:Stanghellini model is one of the few models primarily developed to predict the evapotranspiration of crops (ETc) in naturally ventilated greenhouses. However, there is insufficient data on the model regarding its use, particularly in China where solar greenhouses without heating systems are fast spreading for vegetable growth and production. The application of Stanghellini model and the evaluation of its performance using meteorological and tomato plant data generated inside an unheated and naturally ventilated multi-span Venlo-type greenhouse is exploited in this study. Model capability was evaluated by utilizing data from sap flow measurements, meteorological and crop data. Measured meteorological data included solar radiation (Rs), air temperature (Ta), relative humidity (RH) and net radiation (Rn). Average leaf area index (LAI) measured during the experimental period was 1.00, 3.30, 4.05 and 2.93; while determined crop coefficients (Kc) changed from 0.40, 0.62, 1.12 to 0.83 for the initial stage, development stage, mid-season stage and late-season stage, respectively. Results from the study indicated that the average hourly ETc of tomato plants using sap flow measurements were 0.165 mm/h, 0.148 mm/h, 0.192 mm/h and 0.154 mm/h for the initial stage, development stage, mid-season stage and late-season stage, respectively. Meanwhile, the ETc values obtained from calculation using Stanghellini model were 0.158 mm/h, 0.152 mm/h, 0.202 mm/h and 0.162 mm/h for the initial stage, development stage, mid-season stage and late-season stage, respectively. These ETc values calculated by the Stanghellini model were close to the measured values within the same period. The coefficients of correlation (R2) based on hourly ETc for the calibration data was 0.94 and that of the validation dataset was 0.90. Scatter plots of the estimated and measured hourly ETc revealed that the R2 and the slope of the regression line for May, June and July were 0.94, 0.90, 0.96 and 1.15, 0.97, 1.10 respectively. These data were well represented around the 1:1 regression line. A model sensitivity analysis carried out illustrates how the changes in Rs and Ta affects greenhouse ETc. Stanghellini model was therefore proven to be suitable for ETc estimation with acceptable accuracy in unheated and naturally ventilated greenhouses in the Northeast region of China.
ISSN:1934-6344
1934-6352
DOI:10.25165/j.ijabe.20181106.3972