Assessment of Water Control Model for Tomato and Paprika in the Greenhouse Using the Penman-Monteith Model |
Somnuek, Siriluk
(Renewable Energy Crop Institute, Department of Agriculture)
Hong, Youngsin (Division of Smart Farm Development, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) Kim, Minyoung (Division of Disaster Prevention Engineering, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) Lee, Sanggyu (Division of Smart Farm Development, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) Baek, Jeonghyun (Division of Smart Farm Development, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) Kwak, Kangsu (Division of Smart Farm Development, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) Lee, Hyondong (Division of Smart Farm Development, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) Lee, Jaesu (Division of Smart Farm Development, Department of Agricultural Engineer, National Institute of Agricultural Sciences, Rural Development Administration) |
1 | Choi, Y., M. Y. Kim, S. O'Shaughnessy, J. G. Jeon, Y. J. Kim, and W. J. Song. 2018. Comparison of artificial neural network and empirical models to determine daily reference evapotranspiration. Journal of the Korean society of agricultural engineer 60: 43-54. DOI: https://doi.org/10.5389/KSAE.201860.6.043 DOI |
2 | Fernandez, M. D., S. S. Bonachela, F. Orgaz, R. Thompson, J. C. Lopez, M. R. Granados, M. Gallardo, and E. Fereres. 2010. Measurement and estimation of plastic greenhouse reference evapotranspiration in a Mediterranean climate. Irrigation science 28:497-509. DOI |
3 | Harmanto, V., M. Salokhe, M. S. Babel, and H. J. Tantau. 2005. Water requirement of drip irrigated tomatoes grown in greenhouse in tropical environment. Agricultural water management 71:225-242. DOI |
4 | Jayasekara, S. N., W. H. Na, A. B. Owababi, J. W. Lee, A. Rasheed, H. K. Kim, and H. W. Lee. 2018. Comparison of environmental conditions and insulation effect between air inflated and conventional double layer greenhouse. Protected horticulture and plant factory 27:46-53. DOI |
5 | Lozano, C. S., R. Rezende, P. S. L. Freitas, T. L. Hachmann, F. A. S. Santos, and A. F. B. A. Andrean. 2017. Estimation of evapotranspiration and crop coefficient of melon cultivated in protected environment. Revista brasileira de engenharia agricola e ambiental 21:758-762. DOI |
6 | Lizarraga, A., H. Boesveld, F. Huibers, and C. Robles. 2003. Evaluating irrigation scheduling of hydroponic tomato in Navarra, Spain. Irrigation and drainage 52:177-188. DOI |
7 | Moazed, H., A. A. Ghaemi, and Rafiee, M. R. 2014. Evaluation of several reference evapotranspiration methods: a comparative study of greenhouse and outdoor condition. Iranian Journal of Science and Technology. Transactions of civil engineering 38:421-437. |
8 | Pamungkas, A. P., K. Hatou, and T. Morimoto. 2013. Modeling the evapotranspiration inside the greenhouse systems by using matlab simulink. In IFAC Proceedings Volumes 46: 33-37. Retrieved from https://doi.org/10.3182/20130327-3-JP-3017.00010 |
9 | Papadakis, G., A. Frangoudakis, and S. Kyritsis. 1994. Experimental investigation and modelling of heat and mass transfer between a tomato crop and greenhouse environment. Journal of Agriculture engineering research 57:217-227. DOI |
10 | Perez-Castro, A., J. A. Sanchez-Molina, M. Castilla, and J. Sanchez-Moreno. 2017. cFertigUAL: A fertigation management app for greenhouse vegetable crops. Agricultural water management 183:186-193. DOI |
11 | Rahil, M. H. and A. Qanadillo. 2015. Effects of different irrigation regimes on yield and water use efficiency of cucumber crop. Agricultural water management 148:10-15. DOI |
12 | Sharma, H., M. K. Shukla, P. W.Bosland, and R. Steiner. 2017. Soil moisture sensor calibration, actual evapotranspiration, and crop coefficients for drip irrigated greenhouse chile peppers. Agricultural water management 179:81-91. https://doi.org/10.1016/j.agwat.2016.07.001 DOI |
13 | Tan, C. S. 1990. Irrigation scheduling for fruit crop: low- volume drip or micro-sprinkler systems. Ministry of Agriculture, Food and Rural Affairs of Canada. Accessed 15 July, 2019. Retrieved from http://www.omafra.gov.on.ca/ english/crops/facts/90-069.htm#b. |
14 | Woo, Y. H., H. J. Kim, Y. I. Nam, I. H. Cho, and Y. S. Kwon. 2000. Predicting and measuring transpiration based on phyto monitoring of tomato in greenhouse. Protected horticulture and plant factory 41:459-463. |
15 | Yang, X., T. H. Short, R. D. Fox, and W. L. Bauerle. 1989. The Microclimate and transpiration of a greenhouse cucumber crop. American society of agricultural engineers 32:2143-2150. DOI |
16 | Baek, J. H., J. W. Heo, H. H. Kim, Y. Hong, and J. S. Lee. 2018. Research platform design for the Korea smart greenhouse based on cloud computing. Protected horticulture and plant factory 27:27-33. DOI |
17 | Aiswarya, L., K. Arunadevi, R. Lalitha, and S. Vallalkannan. 2019. Estimation of actual crop evapotranspiration of green chili in semi-arid region under different atmospheric condition. International journal of current microbiology and applied sciences 8:1104-1110. https://doi.org/10.20546/ijcmas.2019.805.127 DOI |
18 | Albuquerque, F.S., E.F.F. Silva, J.A.C. Albuquerque Filho, and G.S. Lima. 2012. Water requirement and crop coefficient of fertigated sweet pepper. Brazilian journal of Irrigation and drainage 17:481-493. |
19 | Bakker, J. C., G. P. A. Bot, H. Challa, and N. J. van de Braak. 1995. Greenhouse Climate Control. Wageningen Pers, Wageningen, The Netherlands. 15-160. |
20 | Allen, R. G., L. S. Pereira, D. Raes, and M. Smith. 1998. Crop evaporation-guidelines for computing crop water requirements. FAO Irrigation and drainage paper 56. FAO. |
21 | Baptista, F. J., B. J. Bailey, and J. Meneses. 2005. Measuring and modelling transpiration versus evapotranspiration of a tomato crop grown on soil in a Mediterranean greenhouse. Acta horticulture 691:313-320. DOI |
22 | Chopda, A., A. P. Sahu, D. M. Das, B. Panigrahi, and S. C. Senapati. 2018. Variation in actual evapotranspiration of green chili inside and outside the rooftop greenhouse under deficit irrigation. International journal of current microbiology and applied sciences 7:4152-4159. DOI |
23 | Costa, P. M., I. Pocas, and M. Cunha 2019. Modelling evapotranspiration of soilless cut roses "Red Naomi" based on climatic and crop predictors. Horticultural science 46:107-114. https://doi.org/10.17221/147/2017-HORTSCI DOI |
24 | Fazlil llahi, W. F. 2009. Evapotranspiration models in greenhouse. Master's Thesis, Wageningen University. |
25 | Karaca C., B. Tekelioglu, D. Buyuktas, and R. Bastug. 2017. Assessment of the equations computing reference crop evapotranspiration. Academia journal of engineering and applied sciences ICAE-IWC (Special Issue):144-161. |
26 | Katsoulas, N. and C. Stanghellini. 2019. Modelling crop transpiration in greenhouses: Different models for different applications. Agronomy 9:1-17. https://doi.org/10.3390/agronomy9070392 DOI |
27 | Kitta, E., A. Baille, N. Katsoulas, and N. Rigakis. 2014. Predicting reference evapotranspiration for screenhousegrown crops. Agricultural water management 143:122-130. https://doi.org/10.1016/j.agwat.2014.07.006 DOI |
28 | Snyder, R. G. 1992. Greenhouse tomato handbook. Publication No. 1828. Mississippi State University. Cooperative extension service, USA. p. 30. |
29 | Nikolaou, G., D. Neocleous, N. Katsoulas, and C. Kittas. 2019. Review: irrigation of greenhouse crops. Horticulture 5:1-20. |
30 | Perera, K. C., A. W. Western, B. Nawarathna, and B. George. 2015. Comparison of hourly and daily reference crop evapotranspiration equations across seasons and climate zones in Australia. Agricultural water management 148: 84-96. https://doi.org/10.1016/j.agwat.2014.09.016 DOI |
31 | van Iersel, M. W., M. Chappell, and J. D. Lea-cox. 2013. Sensors for improved efficiency of irrigation in greenhouse and nursery production. American society for horticultural science 23:735-746. |
32 | Villarreal-Guerrero, F., M. Kacira, E. Fitz-Rodriguez, C. Kubota, G. A. Giacomelli, R. Linker, and A. Arbel. 2012. Comparison of three evapotranspiration models for a greenhouse cooling strategy with natural ventilation and variable high-pressure fogging. Scientia Horticulture 134: 210-221. DOI |