Response of AquaCrop Model to Different Irrigation Schedules for Irrigated Cabbage

Pawar, G. S.; Kale, Mayura; Lokhande, J. N.

doi:10.1007/s40003-016-0238-2

Cited by 29 publications

(22 citation statements)

References 11 publications

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“…The performance of the model was found to be good as described by the of 0.91. The results also concur with those of Pawar, Kale [23] who carried out a research in India where the model was able to simulate biomass with a NSE of 0.96. A study by Lievens [24] carried out in North Eastern Thailand revealed that Aquacrop model was able to relate well the simulated to the actual biomass of sweet corn with a root mean square error (RMSE) of 0.56.…”

Section: Simulation Of Tomato Water Productivity Using Aquacrop Modelsupporting

confidence: 89%

Modeling Tomato Water Productivity Using Aquacrop Model in Njoro Sub County, Nakuru, Kenya

Sang

Wambua

Raude

2020

JERR

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Aims: To model tomato water productivity under deficit sub – surface drip irrigation and grass mulch densities using Aquacrop model. Study Design: The study was factorial experimental with twelve treatments. Place and Duration of Study: Tatton Agriculture Park, Egerton University, Nakuru, Kenya between January to May 2019. Methodology: Tomato (Lycopersicon esculentum mill) crop (Tylka F1) was used to determine the effect of deficit irrigation and mulching on its productivity. Aquacrop model was calibrated to simulate the tomato yield, biomass and water productivity. Aquacrop model was used to estimate the tomato water requirements, water productivity, yield and biomass under deficit irrigation and mulching. The study was carried out on 36 experimental plots measuring 2 by 2 m with the total area under study being 144 m2. Results: The results showed a good correlation between the actual and simulated water productivity as determined by the Nash and Sutcliffe efficiency (NSE) of 0.00, Root Mean Square Error (RMSE) (%) of 0.04 and Coefficient of determination (R2) of 0.72. Conclusion: The study calibrated Aquacrop model for simulating tomato crop water productivity in Njoro Sub County and showed that the model is a good estimator of tomato water productivity.

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Section: Simulation Of Tomato Water Productivity Using Aquacrop Modelsupporting

confidence: 89%

Modeling Tomato Water Productivity Using Aquacrop Model in Njoro Sub County, Nakuru, Kenya

Sang

Wambua

Raude

2020

JERR

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“…The contrast between Bello and Walker (2017) with our results might be that; (1) they did not account for the fact that amaranth was harvested repeatedly during the growing period, (2) the effective rooting depth was not measured but estimated from literature, and (3) they used an empirical equation to convert leaf area index (LAI) to CC, which might have underestimated CC. Studies by Greaves and Wang (2017), Pawar et al (2017), and Razzaghi et al (2017) showed that AquaCrop was capable of simulating CC for maize, cabbage and potato, but not under water-stressed conditions. The strength of AquaCrop is its ability to separate ETa into soil evaporation (Es) and transpiration (Tr) Raes et al, 2009;Steduto et al, 2009), which enables the assessment of productive (Tr) and non-productive (Es) water use.…”

Section: Discussionmentioning

confidence: 99%

“…It is a challenge to compare WP from different locations because of varying climatic conditions, methods used in calculating WP, irrigation water management, soil fertility management, and vapour pressure deficit (Zwart and Bastiaanssen, 2004); other studies report the total amount of water applied, whereas others report ETa. For example, Pawar et al (2017) reported WPETa of cabbage ranging from 50 to 69 kg ha -1 mm -1 , however, the denominator was total irrigation water applied. Wenhold et al (2012) benchmarked WPETa of leafy vegetables using a dataset (AGB per ETa) that was derived from different literature sources and reported values ranging from 2 to 90 kg ha -1 mm -1 for selected leafy vegetables.…”

Section: Discussionmentioning

confidence: 99%

“…AquaCrop has been utilised in many studies (e.g. Abedinpour et al, 2012;Araya et al, 2016;Battisti et al, 2017;Bello and Walker, 2016;Greaves and Wang, 2017;Katerji et al, 2013;Mirsafi et al, 2016;Montoya et al, 2016;Mustafa et al, 2017;Paredes et al, 2014;Paredes et al, 2015;Pawar et al, 2017;Razzaghi et al, 2017;Tavakoli et al, 2015;Yuan et al, 2013) The rain-shelter has a rain sensor that triggers an electric motor during a rainfall event and the shelter automatically covers the experimental field. Therefore, the experiment experiences normal field conditions, except when it is raining (Mabhaudhi et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

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Assessment of nutritional water productivity and improvement strategies for traditional vegetables in South Africa

Nyathi

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“…Sampling can be conducted from 120 cm soil depth [3]. Usually soil profile study was allowed to demonstrate the soil characteristics at experimental field and determined the analysis of physicochemical belongings [5]. In this model, the condition of soil water in the lower, middle and upper positions has been measured as the input of the AquaCrop model in order to predict the water use efficiency of the sugarcane [6].…”

Section:  Soil Profile Datamentioning

confidence: 99%

Examination of Sugarcane Yield by Simulating Aqua Crop to Overcome the Irrigation Deficiency

2019

IJRTE

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Crop simulation models are significant apparatus used for measuring crop yield response to various conditions, also designed for conceiving systems to get better agricultural administration. Sugarcane is a major C4 crop grown in canal irrigated areas of the country. It has been observed that climatic distortions particularly precipitation and greatest temperature affect crop productivity and sugar recovery. AquaCrop is a typical model used here to develop the yield of sugarcane under different situations. The development of canopy cover is mainly affected by evapotranspiration and lacking of soil water balance. So the prime objective of this research is to study the stability of soil water in the root sector by delivering more cane yields with less water. By using AquaCrop, the crop water productivity can be maintained, canopy cover gets developed and finally the crops can be saved from destruction. It is an incorporated application programming to mimic the associations between plant, water and soil. So, field administration and water system administration should be considered for producing more water productivity. Four basic segments are required in this model namely climate, crop, field and irrigation management and soil profiles to expand the water efficiency.

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Response of AquaCrop Model to Different Irrigation Schedules for Irrigated Cabbage

Cited by 29 publications

References 11 publications

Modeling Tomato Water Productivity Using Aquacrop Model in Njoro Sub County, Nakuru, Kenya

Modeling Tomato Water Productivity Using Aquacrop Model in Njoro Sub County, Nakuru, Kenya

Assessment of nutritional water productivity and improvement strategies for traditional vegetables in South Africa

Examination of Sugarcane Yield by Simulating Aqua Crop to Overcome the Irrigation Deficiency

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