Greenhouse cultivation has evolved from simple covered rows of open-fields crops to highly sophisticated controlled environment agriculture (CEA) facilities that projected the image of plant factories for urban agriculture. The advances and improvements in CEA have promoted the scientific solutions for the efficient production of plants in populated cities and multi-story buildings. Successful deployment of CEA for urban agriculture requires many components and subsystems, as well as the understanding of the external influencing factors that should be systematically considered and integrated. This review is an attempt to highlight some of the most recent advances in greenhouse technology and CEA in order to raise the awareness for technology transfer and adaptation, which is necessary for a successful transition to urban agriculture. This study reviewed several aspects of a high-tech CEA system including improvements in the frame and covering materials, environment perception and data sharing, and advanced microclimate control and energy optimization models. This research highlighted urban agriculture and its derivatives, including vertical farming, rooftop greenhouses and plant factories which are the extensions of CEA and have emerged as a response to the growing population, environmental degradation, and urbanization that are threatening food security. Finally, several opportunities and challenges have been identified in implementing the integrated CEA and vertical farming for urban agriculture.
Keywords: smart agriculture, greenhouse modelling, urban agriculture, vertical farming, automation, internet of things (IoT), wireless sensor network, plant factories
DOI: 10.25165/j.ijabe.20181101.3210

Citation: Shamshiri R R, Kalantari F, Ting K C, Thorp K R, Hameed I A, Weltzien C, et al. Advances in greenhouse automation and controlled environment agriculture: A transition to plant factories and urban agriculture. Int J Agric & Biol Eng, 2018; 11(1): 1–22.

smart agriculture, greenhouse modelling, urban agriculture, vertical farming, automation, internet of things (IoT), wireless sensor network, plant factories

Ting K C, Lin T, Davidson P C. Integrated urban controlled environment agriculture systems. In: Kozai T, Fujiwara K, Runkle E S. Singapore: Springer Singapore, 2016; p. 19–36.

Muijzenberg E W B. A history of greenhouses. Wageningen: Institute of Agricultural Engineering, 1980; 435 pp.

Woods M, Warren A S. Glass houses: A history of greenhouses, orangeries and conservatories. Rizzoli, 1988.

Enoch H Z, Enoch Y. The history and geography of the greenhouse. Ecosystems of the world, 1999: 1–16.

De Vleeschouwer O. Greenhouses and conservatories. Flammarion, 2001.

Cuce E, Harjunowibowo D, Cuce P M. Renewable and sustainable energy saving strategies for greenhouse systems: A comprehensive review. Renewable and Sustainable Energy Reviews, 2016; 64: 34–59.

Takakura T. Development of VETH chart using computer. Technical report on design standards of greenhouse environmental control systems. University of Tokyo, 1976.

Udink ten Cate A J, Bot G P A, van Dixhoorn J J. Computer control of greenhouse climates. International Society for Horticultural Science (ISHS), Leuven, Belgium, 1978.

Aitken-Christie J, Kozai T, Smith M A L. Automation and environmental control in plant tissue culture. Springer Science & Business Media, 2013.

Hanan J J. Greenhouses: Advanced technology for protected horticulture. CRC press, 1997.

Critten D L, Bailey B J. A review of greenhouse engineering developments during the 1990s. Agricultural and Forest Meteorology, 2002; 112(1): 1–22.

Shamshiri R R, Mahadi M R, Thorp K R, Ismail W I W, Ahmad D, Man H C. Adaptive management framework for evaluating and adjusting microclimate parameters in tropical greenhouse crop production systems. In: Jurić S. Rijeka: InTech, 2017.

Nelkin J, Caplow T. Sustainable controlled environment agriculture for urban areas. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2008.

Despommier D. The vertical farm: controlled environment agriculture carried out in tall buildings would create greater food safety and security for large urban populations. Journal für Verbraucherschutz und Lebensmittelsicherheit, 2011; 6(2): 233–236.

Kacira M, Sase S, Okushima L. Optimization of vent configuration by evaluating greenhouse and plant canopy ventilation rates under wind-induced ventilation. Transactions of the ASAE, 2004; 47(6): 2059.

Baudoin W, Nono-Womdim R, Lutaladio N, Hodder A, Castilla N, Leonardi C, et al. Good agricultural practices for greenhouse vegetable crops: Principles for mediterranean climate areas. FAO, 2013.

Garnaud J C. A survey of the development of plasticulture: Questions to be answered. Plasticulture, 1987; 74: 5–14.

Waaijenberg D, Sonneveld P J. Greenhouse design for the future with a cladding material combining high insulation capacity with high light transmittance. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2004.

Nisen A, Coutsse S. Photometric properties of double wall plastics used as covering for greenhouses. International Society for Horticultural Science (ISHS), Leuven, Belgium, 1981.

Graefe J, Sandmann M. Shortwave radiation transfer through a plant canopy covered by single and double layers of plastic. Agricultural and Forest Meteorology, 2015; 201: 196–208.

Bunschoten B, Pierik C. Kassenbouw neemt weer iets toe. CBS Webmagazine (Centraal Bureau voor de Statistiek), 2003: 3.

Pollet I V, Pieters J G. PAR transmittances of dry and condensate covered glass and plastic greenhouse cladding. Agricultural and Forest Meteorology, 2002;110(4): 285–298.

Tuller S E, Peterson M J. The solar radiation environment of greenhouse-grown douglas-fir seedlings. Agricultural and Forest Meteorology, 1988; 44(1): 49–65.

Santamouris M, Mihalakakou G, Balaras C A, Argiriou A, Asimakopoulos D, Vallindras M. Use of buried pipes for energy conservation in cooling of agricultural greenhouses. Solar Energy, 1995; 55(2): 111–124.

Grimstad S O. Supplementary lighting of early tomatoes after planting out in glass and acrylic greenhouses. Scientia Horticulturae, 1987; 33(3-4): 189–196.

Alhamdan A M, Al-Helal I M. Mechanical deterioration of polyethylene greenhouses covering under arid conditions. Journal of Materials Processing Technology, 2009; 209(1): 63–69.

Al-Helal I M, Alhamdan A M. Effect of arid environment on radiative properties of greenhouse polyethylene cover. Solar Energy, 2009; 83(6): 790–798.

Dehbi A, Bouaza A, Hamou A, Youssef B, Saiter J M. Artificial ageing of tri-layer polyethylene film used as greenhouse cover under the effect of the temperature and the UV-A simultaneously. Materials & Design, 2010; 31(2): 864–869.

Bibi-Triki N, Bendimerad S, Chermiti A, Mahdjoub T, Draoui B, Abène A. Modeling, characterization and analysis of the dynamic behavior of heat transfers through polyethylene and glass walls of greenhouses. Physics Procedia, 2011; 21:67–74.

Zhu S, Deltour J, Wang S. Modeling the thermal characteristics of greenhouse pond systems. Aquacultural Engineering, 1998; 18: 201–217.

Oreski G, Wallner G M, Lang R W. Ageing characterization of commercial ethylene copolymer greenhouse films by analytical and mechanical methods. Biosystems Engineering, 2009; 103(4): 489–496.

Janjai S, Intawee P, Kaewkiew J, Sritus C, Khamvongsa V. A large-scale solar greenhouse dryer using polycarbonate cover: Modeling and testing in a tropical environment of Lao People’s Democratic Republic. Renewable Energy, 2011; 36(3): 1053–1062.

Castilla N, Hernandez J. Greenhouse technological packages for high-quality crop production. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2007.

Cabrera F J, Baille A, López J C, González-Real M M, Pérez-Parra J. Effects of cover diffusive properties on the components of greenhouse solar radiation. Biosystems Engineering, 2009; 103(3): 344–356.

Pollet I V, Pieters J G, Deltour J, Verschoore R. Diffusion of radiation transmitted through dry and condensate covered transmitting materials. Solar Energy Materials and Solar Cells, 2005; 86(2): 177–196.

Arcidiacono C, D'Emilio A, Mazzarella R, Leonardi C. Covering materials to improve greenhouse microclimate during summer in hot climates. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2006.

Hemming S, Mohammadkhani V, Dueck T. Diffuse greenhouse covering materials - material technology, measurements and evaluation of optical properties. Acta Horticulturae, 2008; 797: 469–475.

Jarquín-Enríquez L, Mercado-Silva E M, Maldonado J L, Lopez-Baltazar J. Lycopene content and color index of tomatoes are affected by the greenhouse cover. Scientia Horticulturae, 2013; 155: 43–48.

Shamshiri R, Ismail W I W, Ahmad D. Experimental evaluation of air temperature, relative humidity and vapor pressure deficit in tropical lowland plant production environments. Advances in Environmental Biology, 2014; 8(22): 5–13.

Al-Mahdouri A, Baneshi M, Gonome H, Okajima J, Maruyama S. Evaluation of optical properties and thermal performances of different greenhouse covering materials. Solar Energy, 2013; 96: 21–32.

Kempkes F, Stanghellini C, Hemming S, Dai J. Cover materials excluding near infrared radiation: effect on greenhouse climate and plant processes. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2008.

Álvarez A J, Oliva R M, Valera D L. Software for the geometric characterisation of insect-proof screens. Computers and Electronics in Agriculture, 2012; 82: 134–144.

Mrema G C, Gumbe L O, Chepete H J, Agullo J O. Rural structures in the tropics: design and development. Food and Agriculture Organization of the United Nations, 2012.

Glenn E P, Cardran P, Thompson T L. Seasonal effects of shading on growth of greenhouse lettuce and spinach. Scientia Horticulturae, 1984; 24(3): 231–239.

Hassanien R H E, Li M. Influences of greenhouse-integrated semi-transparent photovoltaics on microclimate and lettuce growth. Int J Agric & Biol Eng, 2017; 10(6): 11–22.

Shamshiri R. Measuring optimality degrees of microclimate parameters in protected cultivation of tomato under tropical climate condition. Measurement, 2017; 106: 236–244.

Lorenzo P, Sánchez-Guerrero M C, Medrano E, García M L, Caparrós I, Giménez M. External greenhouse mobile shading: effect on microclimate, water use efficiency and yield of a tomato crop grown under different salinity levels of the nutrient solution. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2003.

Teitel M, Zhao Y. Temperature gradients in fan-ventilated greenhouses. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2014.

Seginer I, Teitel M. Effect of ceiling height on the natural ventilation of an 'infinite' screenhouse: Model predictions. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2014.

Cockshull K E, Graves C J, Cave C R J. The influence of shading on yield of glasshouse tomatoes. Journal of Horticultural Science, 1992; 67(1): 11–24.

Qiu R, Song J, Du T, Kang S, Tong L, Chen R, et al. Response of evapotranspiration and yield to planting density of solar greenhouse grown tomato in northwest China. Agricultural Water Management, 2013; 130: 44–51.

Agele S O, Iremiren G O, Ojeniyi S O. Effects of plant density and mulching on the performance of late-season tomato (Lycopersicon esculentum) in southern Nigeria. The Journal of Agricultural Science, 1999; 133(4): 397–402.

Amundson S K. Cultural techniques to improve yield and cost efficiency of greenhouse grown tomatoes. Master theses, The university of Tennessee, 2012: 82.

Kirimi J K, Itulya F M, Mwaja V N. Effects of nitrogen and spacing on fruit yield of tomato. African Journal of Horticultural Science, 2011: 5.

Ilić Z S, Milenković L, Stanojević L, Cvetković D, Fallik E. Effects of the modification of light intensity by color shade nets on yield and quality of tomato fruits. Scientia Horticulturae, 2012; 139: 90–95.

El-Aidy F, El-Afry M. Influence of shade on growth and yield of tomatoes cultivated during the summer season in Egypt. Plasticulture, 1983; 47(3): 2–6.

El-Gizawy A M, Abdallah M M F, Gomaa H M, Mohamed S S. Effect of different shading levels on tomato plants. 2. yield and fruit quality. International Society for Horticultural Science (ISHS), Leuven, Belgium, 1993.

Hochmuth G J, Hochmuth R C. Nutrient solution formulation for hydroponic (perlite, rockwool, NFT) tomatoes in Florida. HS796 Univ Fla Coop Ext Serv, Gainesville, 2001.

Cherie E. The complete guide to growing tomatoes: A complete step-by-step guide including heirloom tomatoes (back-to-basics gardening). Atlantic Publishing Group Inc. Ocala, Florida, 2010.

Jones J B. Instructions for growing tomatoes in the garden and green-house. GroSystems, Anderson, SC, USA, 2013.

Morison J I L, Morecroft M. Plant growth and climate change. John Wiley & Sons, 2006: 209 p.

Zhang Z, Gates R S, Zou Z R, Hu X H. Evaluation of ventilation performance and energy efficiency of greenhouse fans. Int J Agric & Biol Eng, 2015; 8(1): 103–110.

Arbel A, Barak M, Shklyar A. Combination of forced ventilation and fogging systems for cooling greenhouses. Biosystems Engineering, 2003; 84(1): 45–55.

Sabeh N C, Giacomelli G A, Kubota C. Water use for pad and fan evaporative cooling of a greenhouse in a semi-arid climate. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2006.

Gázquez J C, López J C, Pérez-Parra J J, Baeza E J, Saéz M, Parra A. Greenhouse cooling strategies for mediterranean climate areas. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2008.

Gazquez J C, Lopez J C, Baeza E, Saez M, Sanchez-Guerrero M C, Medrano E, et al. Yield response of a sweet pepper crop to different methods of greenhouse cooling. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2006.

Duan Z, Zhan C, Zhang X, Mustafa M, Zhao X, Alimohammadisagvand B, et al. Indirect evaporative cooling: Past, present and future potentials. Renewable and Sustainable Energy Reviews, 2012; 16(9): 6823–6850.

Schnelle M A, Dole J M. Greenhouse structures and coverings. Division of Agricultural Sciences and Natural Resources, Oklahoma State University, 2015:1–4.

Li S, Willits D H. Comparing low-pressure and high-pressure fogging systems in naturally ventilated greenhouses. Biosystems Engineering, 2008; 101(1): 69–77.

Abdel-Ghany A M, Kozai T. Cooling efficiency of fogging systems for greenhouses. Biosystems Engineering, 2006; 94(1): 97–109.

Standard A. Heating, ventilating and cooling greenhouses. American Society of Agricultural and Biological Engineers, 2008; 2015: 1.

Kittas C, Katsoulas N, Baille A. SE-Structures and environment: Influence of greenhouse ventilation regime on the microclimate and energy partitioning of a rose canopy during summer conditions. Journal of Agricultural Engineering Research, 2001; 79(3): 349–360.

Jain D, Tiwari G N. Modeling and optimal design of evaporative cooling system in controlled environment greenhouse. Energy Conversion and Management, 2002; 43(16): 2235–2250.

Petek M, Dikmen S, Oǧan M M. Performance analysis of a two stage pad cooling system in broiler houses. Turkish Journal of Veterinary and Animal Sciences, 2012; 36(1): 21–26.

Willits D H. Cooling fan-ventilated greenhouses: A modelling study. Biosystems Engineering, 2003; 84(3): 315–329.

Max J F J, Horst W J, Mutwiwa U N, Tantau H-J. Effects of greenhouse cooling method on growth, fruit yield and quality of tomato (Solanum lycopersicum L.) in a tropical climate. Scientia Horticulturae, 2009; 122(2): 179–186.

Molina-Aiz F D, Valera D L, Peña A A, Gil J A, López A. A study of natural ventilation in an Almería-type greenhouse with insect screens by means of tri-sonic anemometry. Biosystems Engineering, 2009;104(2):224–242.

Rigakis N, Katsoulas N, Teitel M, Bartzanas T, Kittas C. A simple model for ventilation rate determination in screenhouses. Energy and Buildings, 2015; 87: 293–301.

Ganguly A, Ghosh S. A review of ventilation and cooling technologies in agricultural greenhouse application. Iranica Journal of Energy & Environment, 2011; 2(1): 32–46.

Du K, Sun Z, Han H, Liu S. Development of a web-based wireless telemonitoring system for agro-environment. Computer and Computing Technologies in Agriculture, Volume II, Boston, MA: Springer US, 2008.

Beccali G, Cellura M, Culotta S, Lo Brano V, Marvuglia A. A web-based autonomous weather monitoring system of the town of palermo and its utilization for temperature nowcasting. Computational Science and Its Applications – ICCSA 2008, Berlin, Heidelberg: Springer Berlin Heidelberg, 2008.

Okayasu T, Yamabe N, Marui A, Miyazaki T, Mitsuoka M, Inoue E. Development of field monitoring and work recording system in agriculture. Proc. 5th Int. Symp. Mach. Mech. Agr. Biosys. Engng. (ISMAB), CD-ROM, 2010.

Nugroho A P, Okayasu T, Inoue E, Hirai Y, Mitsuoka M. Development of actuation framework for agricultural informatization supporting system. IFAC Proceedings Volumes, 2013; 46(4): 181–6.

Dumitraşcu A, Ştefănoiu D, Culiţă J. Remote monitoring and control system for environment applications. Advances in Intelligent Control Systems and Computer Science, 2013: 223–34.

Gaddam A. Designing a wireless sensors network for monitoring and predicting droughts. ICST 2014 : 8th International Conference on Sensing Technology, Liverpool, UK, 2014.

Fukatsu T, Kiura T, Hirafuji M. A web-based sensor network system with distributed data processing approach via web application. Computer Standards & Interfaces, 2011; 33(6): 565–573.

Mizoguchi M, Ito T, Chusnul A, Mitsuishi S, Akazawa M. Quasi real-time field network system for monitoring remote agricultural fields. SICE Annual Conference, 2011.

Arif C, Setiawan B I, Mizoguchi M, Saptomo S K, Sutoyo S, Liyantono L, et al. Performance of quasi-real-time paddy field monitoring systems in Indonesia. Proceedings of the Asia-Pacific Advanced Network, 2014; 37: 10–19.

Kaloxylos A, Eigenmann R, Teye F, Politopoulou Z, Wolfert S, Shrank C, et al. Farm management systems and the future internet era. Computers and Electronics in Agriculture, 2012; 89: 130–144.

Kaloxylos A, Groumas A, Sarris V, Katsikas L, Magdalinos P, Antoniou E, et al. A cloud-based farm management system: Architecture and implementation. Computers and Electronics in Agriculture, 2014; 100: 168–179.

Prima A, Okayasu T, Hoshi T, Inoue E, Hirai Y, Mitsuoka M, et al. Development of a remote environmental monitoring and control framework for tropical horticulture and verification of its validity under unstable network connection in rural area. Computers and Electronics in Agriculture, 2016;124: 325–339.

Serôdio C, Boaventura Cunha J, Morais R, Couto C, Monteiro J. A networked platform for agricultural management systems. Computers and Electronics in Agriculture, 2001; 31(1): 75–90.

Morais R, Fernandes M A, Matos S G, Serôdio C, Ferreira P J S G, Reis M J C S. A ZigBee multi-powered wireless acquisition device for remote sensing applications in precision viticulture. Computers and Electronics in Agriculture, 2008; 62(2): 94–106.

López Riquelme J A, Soto F, Suardíaz J, Sánchez P, Iborra A, Vera J A. Wireless Sensor Networks for precision horticulture in Southern Spain. Computers and Electronics in Agriculture, 2009; 68(1): 25–35.

Li T, Zhang M, Ji Y H, Sha S, Jiang Y Q, Minzan L. Management of CO2 in a tomato greenhouse using WSN and BPNN techniques. Int J Agric & Biol Eng, 2015; 8(4): 43–51.

Tzounis A, Bartzanas T, Kittas C, Katsoulas N, Ferentinos K P. Spatially distributed greenhouse climate control based on wireless sensor network measurements. International Symposium on Applications of Modelling as an Innovative Technology in the Horticultural Supply Chain, 2015; 111–120.

Ji Y H, Jiang Y Q, Li T, Zhang M, Sha S, Li M Z. An improved method for prediction of tomato photosynthetic rate based on WSN in greenhouse. Int J Agric & Biol Eng, 2016; 9(1): 146–152.

Pahuja R, Verma H K, Uddin M. A wireless sensor network for greenhouse climate control. IEEE Pervasive Computing, 2013; 12(2): 49–58.

Hebel M A, Tate R F, Watson D G. Results of wireless sensor network transceiver testing for agricultural applications. 2007 ASAE Annual Meeting; St. Joseph, MI: ASABE, 2007.

Chen Y, Shi Y L, Wang Z Y, Huang L. Connectivity of wireless sensor networks for plant growth in greenhouse. Int J Agric & Biol Eng, 2016; 9(1): 89–98.

Zhou Y, Yang X, Guo X, Zhou M, Wang L. A design of greenhouse monitoring & control system based on zigbee wireless sensor network. Wireless Communications, Networking and Mobile Computing, International Conference on IEEE, 2007: 2563–2567.

Azaza M, Tanougast C, Fabrizio E, Mami A. Smart greenhouse fuzzy logic based control system enhanced with wireless data monitoring. ISA transactions, 2016; 61: 297–307.

Gubbi J, Buyya R, Marusic S, Palaniswami M. Internet of things (IoT): A vision, architectural elements, and future directions. Future Generation Computer Systems, 2013; 29(7): 1645–1660.

Atzori L, Iera A, Morabito G. The internet of things: A survey. Computer Networks, 2010; 54(15): 2787–2805.

Jin J, Gubbi J, Marusic S, Palaniswami M. An information framework for creating a smart city through internet of things. IEEE Internet of Things Journal, 2014; 1(2): 112–121.

Liao S-H, Chu P-H, Hsiao P-Y. Data mining techniques and applications – A decade review from 2000 to 2011. Expert Systems with Applications, 2012; 39(12): 11303–11311.

Chung B-K, Xia C, Song Y-H, Lee J-M, Li Y, Kim H, et al. Sampling of Bemisia tabaci adults using a pre-programmed autonomous pest control robot. Journal of Asia-Pacific Entomology, 2014; 17(4): 737–743.

He D, Zeadally S. An analysis of RFID authentication schemes for internet of things in healthcare environment using elliptic curve cryptography. IEEE Internet of Things Journal, 2015; 2(1): 72–83.

Miorandi D, Sicari S, de Pellegrini F, Chlamtac I. Internet of things: Vision, applications and research challenges. Ad Hoc Networks, 2012; 10(7): 1497–1516.

Najera P, Lopez J, Roman R. Real-time location and inpatient care systems based on passive RFID. Journal of Network and Computer Applications, 2011; 34(3): 980–989.

Liao M-S, Chen S-F, Chou C-Y, Chen H-Y, Yeh S-H, Chang Y-C, et al. On precisely relating the growth of Phalaenopsis leaves to greenhouse environmental factors by using an IoT-based monitoring system. Computers and Electronics in Agriculture, 2017; 136: 125–139.

Peng G, Lahlali R, Hwang S-F, Pageau D, Hynes R K, McDonald M R, et al. Crop rotation, cultivar resistance, and fungicides/biofungicides for managing clubroot (Plasmodiophora brassicae) on canola. Canadian Journal of Plant Pathology, 2014; 36(sup1): 99–112.

Lin M-J, Hsu B-D. Photosynthetic plasticity of Phalaenopsis in response to different light environments. Journal of Plant Physiology, 2004; 161(11): 1259–1268.

Caponetto R, Fortuna L, Nunnari G, Occhipinti L. A fuzzy approach to greenhouse climate control. Proceedings of the American Control Conference, 1998; 3: 1866–1870.

Pan L F, Wang W L, Wu Q D. Application of adaptive fuzzy logic system to model for greenhouse climate. Intelligent Control and Automation, 2000 Proceedings of the 3rd World Congress, 2000; 3(1): 1687–1691.

Lin C J. A GA-based neural fuzzy system for temperature control. Fuzzy Sets and Systems, 2004; 143(2): 311–333.

Castañeda-Miranda R, Ventura-Ramos E, del Rocío Peniche-Vera R, Herrera-Ruiz G. Fuzzy greenhouse climate control system based on a field programmable gate array. Biosystems Engineering, 2006; 94(2): 165–177.

Xu F, Sheng J Q, Chen J L. Rough sets based fuzzy logic control for greenhouse temperature. 2006 2nd IEEE/ASME International Conference on Mechatronics and Embedded Systems and Applications, 2006.

Boulard T, Roy J-C, Pouillard J-B, Fatnassi H, Grisey A. Modelling of micrometeorology, canopy transpiration and photosynthesis in a closed greenhouse using computational fluid dynamics. Biosystems Engineering, 2017; 158(Supplement C): 110–133.

Shamshiri R R, Mahadi M R, Thorp K R, Ismail W I W, Ahmad D, Man H C. Adaptive management framework for evaluating and adjusting microclimate parameters in tropical greenhouse crop production systems. In: Jurić S. Plant Engineering. Rijeka: InTech, 2017; p.9.

Impron I, Hemming S, Bot G P A. Simple greenhouse climate model as a design tool for greenhouses in tropical lowland. Biosystems Engineering, 2007; 98(1): 79–89.

Lu N, Nukaya T, Kamimura T, Zhang D, Kurimoto I, Takagaki M et al. Control of vapor pressure deficit (VPD) in greenhouse enhanced tomato growth and productivity during the winter season. Scientia Horticulturae, 2015; 197: 17–23.

Lafont F, Balmat J F, Pessel N, Fliess M. A model-free control strategy for an experimental greenhouse with an application to fault accommodation. Computers and Electronics in Agriculture, 2015; 110: 139–149.

Gruber J K, Guzmán J L, Rodríguez F, Bordons C, Berenguel M, Sánchez J A. Nonlinear MPC based on a Volterra series model for greenhouse temperature control using natural ventilation. Control Engineering Practice, 2011; 19(4): 354–366.

Speetjens S L, Stigter J D, van Straten G. Towards an adaptive model for greenhouse control. Computers and Electronics in Agriculture, 2009; 67(1-2): 1–8.

Bennis N, Duplaix J, Enéa G, Haloua M, Youlal H. Greenhouse climate modelling and robust control. Computers and Electronics in Agriculture, 2008; 61(2): 96–107.

Fleisher D H, Baruh H. An optimal control strategy for crop growth in advanced life support systems. Life Support & Biosphere Science, 2001; 8(1): 43–53.

Van Ooteghem R J C. Optimal control design for a solar greenhouse. IFAC Proceedings Volumes, 2010; 43(26): 304–309.

Van Henten E J, Bontsema J. Time-scale decomposition of an optimal control problem in greenhouse climate management. Control Engineering Practice, 2009; 17(1): 88–96.

Ioslovich I, Gutman P O, Linker R. Hamilton-Jacobi-Bellman formalism for optimal climate control of greenhouse crop. Automatica, 2009; 45(5): 1227–1231.

Van Beveren P J M, Bontsema J, van Straten G, van Henten E J. Optimal control of greenhouse climate using minimal energy and grower defined bounds. Applied Energy, 2015; 159: 509–519.

Van Beveren P J M, Bontsema J, van Straten G, van Henten E J. Minimal heating and cooling in a modern rose greenhouse. Applied Energy, 2015; 137: 97–109.

Sanchez-Molina J A, Li M, Rodriguez F, Guzman J L, Wang H, Yang X T. Development and test verification of air temperature model for Chinese solar and Spainish Almeria-type greenhouses. Int J Agric & Biol Eng, 2017; 10(4): 66–76.

Blasco X, Martínez M, Herrero J M, Ramos C, Sanchis J. Model-based predictive control of greenhouse climate for reducing energy and water consumption. Computers and Electronics in Agriculture, 2007; 55(1): 49–70.

Ji R, Qi L, Huo Z. Design of fuzzy control algorithm for precious irrigation system in greenhouse. Computer and Computing Technologies in Agriculture V, Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

Márquez-Vera M A, Ramos-Fernández J C, Cerecero-Natale L F, Lafont F, Balmat J-F, Esparza-Villanueva J I. Temperature control in a MISO greenhouse by inverting its fuzzy model. Computers and Electronics in Agriculture, 2016; 124: 168–174.

El-Madbouly E I, Hameed I A, Abdo M I. Reconfigurable adaptive fuzzy fault-hiding control for greenhouse climate control system. International Journal of Automation and Control, 2017; 11(2): 164–187.

Nachidi M, Rodríguez F, Tadeo F, Guzman J L. TakagiSugeno control of nocturnal temperature in greenhouses using air heating. ISA Transactions, 2011; 50(2): 315–320.

Liu X-W, Dai T-F. Design for fuzzy decoupling control system of temperature and humidity. Advanced Research on Computer Science and Information Engineering, Berlin, Heidelberg: Springer Berlin Heidelberg, 2011.

Vadiee A, Martin V. Energy management in horticultural applications through the closed greenhouse concept, state of the art. Renewable and Sustainable Energy Reviews, 2012; 16(7): 5087–5100.

Ghasemi Mobtaker H, Ajabshirchi Y, Ranjbar S F, Matloobi M. Solar energy conservation in greenhouse: Thermal analysis and experimental validation. Renewable Energy, 2016; 96(Part A): 509–519.

Taki M, Rohani A, Rahmati-joneidabad M. Solar thermal simulation and applications in greenhouse. Information Processing in Agriculture, 2017.

Ha T, Lee I-B, Kwon K-S, Hong S-W. Computation and field experiment validation of greenhouse energy load using building energy simulation model, 2015; 8(6): 116–127.

Flores-velazquez J, Montero J I, Baeza E J, Lopez J C. Mechanical and natural ventilation systems in a greenhouse designed using computational fluid dynamics. Int J Agric & Biol Eng, 2014; 7(1): 1–16.

Chen J, Xu F, Tan D, Shen Z, Zhang L, Ai Q. A control method for agricultural greenhouses heating based on computational fluid dynamics and energy prediction model. Applied Energy, 2015;141: 106–118.

Xu J, Li Y, Wang R Z, Liu W, Zhou P. Experimental performance of evaporative cooling pad systems in greenhouses in humid subtropical climates. Applied Energy, 2015; 138: 291–301.

Espinoza K, Valera D L, Torres J A, López A, Molina-Aiz F D. An Auto-tuning pi control system for an open-circuit low-speed wind tunnel designed for greenhouse technology. Sensors, 2015: 19723–19749.

Ioslovich I, Gutman P-O, Linker R. Hamilton–Jacobi–Bellman formalism for optimal climate control of greenhouse crop. Automatica, 2009; 45(5): 1227–1231.

Van Beveren P, Bontsema J, van Straten G, van Henten E J. Minimal heating and cooling in a modern rose greenhouse. IFAC Proceedings Volumes, 2013; 46(18): 282–287.

Van Beveren P, Bontsema J, van Straten G, van Henten E. Minimal heating and cooling in a modern rose greenhouse. Applied energy, 2015; 137: 97–109.

Incrocci L, Stanghellini C, Kempkes F. Carbon dioxide fertilization in Mediterranean greenhouses: When and how is it economical? International Symposium on Strategies Towards Sustainability of Protected Cultivation in Mild Winter Climate 807, 2008.

Linker R, Seginer I, Gutman P. Optimal CO2 control in a greenhouse modeled with neural networks. Computers and Electronics in Agriculture, 1998; 19(3): 289–310.

Van Beveren P, Bontsema J, van Straten G, van Henten E. Optimal control of greenhouse climate using minimal energy and grower defined bounds. Applied Energy, 2015; 159: 509–519.

Nadal A, Llorach-Massana P, Cuerva E, López-Capel E, Montero J I, Josa A, et al. Building-integrated rooftop greenhouses: An energy and environmental assessment in the mediterranean context. Applied Energy, 2017; 187: 338–351.

Vadiee A, Martin V. Thermal energy storage strategies for effective closed greenhouse design. Applied Energy, 2013; 109: 337–343.

Vadiee A, Martin V. Energy analysis and thermoeconomic assessment of the closed greenhouse-The largest commercial solar building. Applied Energy, 2013; 102: 1256–1266.

Heuvelink E, Bakker M, Marcelis L, Raaphorst M. Climate and yield in a closed greenhouse. Acta Horticulturae, 2008; 801: 1083–1092.

Farzaneh-Gord M, Arabkoohsar A, Deymi Dashtebayaz M, Khoshnevis A A. New method for applying solar energy in greenhouses to reduce fuel consumption. Int J Agric & Biol Eng, 2013; 6(4): 64–75.

Van Den Bulck N, Coomans M, Wittemans L, Hanssens J, Steppe K. Monitoring and energetic performance analysis of an innovative ventilation concept in a Belgian greenhouse. Energy and Buildings, 2013; 57: 51–57.

Kittas C, Bartzanas T. Greenhouse microclimate and dehumidification effectiveness under different ventilator configurations. Building and Environment, 2007; 42(10): 3774–3784.

Mashonjowa E, Ronsse F, Milford J R, Pieters J G. Modelling the thermal performance of a naturally ventilated greenhouse in Zimbabwe using a dynamic greenhouse climate model. Solar Energy, 2013; 91: 381–393.

Wu F-Q, Zhang L-B, Xu F, Ai Q-L, Chen J-L. Numerical modeling and analysis of the environment in a mechanically ventilated greenhouse. Proceedings of SPIE, 2009; 7491(1): 749106–749108.

DAYIOĞLU M A. Performance analysis of a greenhouse fan-pad cooling system: gradients of horizontal temperature and relative humidity. Tarım Bilimleri Dergisi, 2015; 21(1): 132–143.

Fuchs M, Dayan E, Presnov E. Evaporative cooling of a ventilated greenhouse rose crop. Agricultural and Forest Meteorology, 2006; 138(1): 203–215.

Montero J I. Evaporative cooling in greenhouses: Effect on microclimate, water use efficiency and plant respons. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2006.

Jain D. Development and testing of two-stage evaporative cooler. Building and Environment, 2007; 42(7): 2549–2554.

Jamaludin D, Ahmad D, Kamaruddin R, Jaafar H Z E. Microclimate inside a tropical greenhouse equipped with evaporative cooling pads. Pertanika Journal of Science and Technology, 2014; 22(1): 255–272.

Villarreal-Guerrero F, Kacira M, Fitz-Rodríguez E, Kubota C, Giacomelli G A, Linker R, et al. Comparison of three evapotranspiration models for a greenhouse cooling strategy with natural ventilation and variable high pressure fogging. Scientia Horticulturae, 2012; 134: 210–221.

Shamshiri R, Ismail W I W. A review of greenhouse climate control and automation systems in tropical regions. J Agric Sci Appl, 2013; 2(3): 176–183.

Li T, Ji Y H, Zhang M, Sha S, Li M Z. Universality of an improved photosynthesis prediction model based on PSO-SVM at all growth stages of tomato. Int J Agric & Biol Eng, 2017; 10(2): 63–73.

Baptista F J F. Modelling the climate in unheated tomato greenhouses and predicting Botrytis cinerea infection. Universidade de Evora (Portugal), 2007.

Dimokas G, Tchamitchian M, Kittas C. Calibration and validation of a biological model to simulate the development and production of tomatoes in Mediterranean greenhouses during winter period. Biosystems Engineering, 2009; 103(2): 217–227.

Takakura T. Technical models of the greenhouse environment. International Society for Horticultural Science (ISHS), Leuven, Belgium, 1989.

Tap R F. Economics-based optimal control of greenhouse tomato crop production. Wageningen University, 2000.

Van Henten E J. Sensitivity analysis of an optimal control problem in greenhouse climate management. Biosystems Engineering, 2003; 85(3): 355–364.

Luo W, de Zwart H F, Dail J, Wang X, Stanghellini C, Bu C. Simulation of greenhouse management in the subtropics, Part I: Model validation and scenario study for the winter season. Biosystems Engineering, 2005; 90(3): 307–318.

Sethi V P, Dubey R K, Dhath A S. Design and evaluation of modified screen net house for off-season vegetable raising in composite climate. Energy Conversion and Management, 2009; 50(12): 3112–3128.

Fitz-Rodríguez E, Kubota C, Giacomelli G A, Tignor M E, Wilson S B, McMahon M. Dynamic modeling and simulation of greenhouse environments under several scenarios: A web-based application. Computers and Electronics in Agriculture, 2010; 70(1): 105–116.

Panwar N L, Kaushik S C, Kothari S. Solar greenhouse an option for renewable and sustainable farming. Renewable and Sustainable Energy Reviews, 2011; 15(8): 3934–3945.

Nebbali R, Roy J C, Boulard T. Dynamic simulation of the distributed radiative and convective climate within a cropped greenhouse. Renewable Energy, 2012; 43: 111–129.

Yu H, Chen Y, Hassan S G, Li D. Prediction of the temperature in a Chinese solar greenhouse based on LSSVM optimized by improved PSO. Computers and Electronics in Agriculture, 2016; 122: 94–102.

De Zwart H F. Analyzing energy-saving options in greenhouse cultivation using a simulation model. De Zwart, 1996.

Graamans L, Baeza E, van den Dobbelsteen A, Tsafaras I, Stanghellini C. Plant factories versus greenhouses: Comparison of resource use efficiency. Agricultural Systems, 2018; 160: 31–43.

Gary C, Jones J W, Tchamitchian M. Crop modelling in horticulture: State of the art. Scientia Horticulturae, 1998; 74(1-2): 3–20.

Heuvelink E. Evaluation of a dynamic simulation model for tomato crop growth and development. Annals of Botany, 1999; 83(4): 413–422.

Gary C, Baille A, Navarrete M, Espanet R. TOMPOUSSE, un modèle simplifié de prévision du rendement et du calibre de la tomate. Actes du Séminaire de l'AIP intersectorielle" Serres", INRA, Avignon, 1997: 100–109.

Abreu P, Meneses J F, Gary C. Tompousse, a model of yield prediction for tomato crops: calibration study for unheated plastic greenhouses. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2000.

Jones J W, Dayan E, Allen L H, van Keulen H, Challa H. A dynamic tomato growth and yield model (TOMGRO). Transactions of the ASAE, 1991; 34(2): 663–672.

Jones J W, Kenig A, Vallejos C E. Reduced state–variable tomato growth model. Transactions of the ASAE, 1999; 42(1): 255–265.

Kenig A. TOMGRO v3. 0 A dynamic model of tomato growth and yield. Ch. II-5 In: Optimal environmental control for indeterminate greenhouse crops. Seginer I, Jones J W, Gutman P, Vallejos C E. BARD Research Report No. IS-1995-91RC. Haifa, 1997.

Cooman A, Medina A, Schrevens E, Tenorio J. Simulation of greenhouse management for the cultivation of tomato in the high altitude tropics. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2005.

Gallardo M, Thompson R B, Rodríguez J S, Rodríguez F, Fernández M D, Sánchez J A, et al. Simulation of transpiration, drainage, N uptake, nitrate leaching, and N uptake concentration in tomato grown in open substrate. Agricultural Water Management, 2009; 96(12): 1773–1784.

Shamshiri R, Ahmad D, Ishak Wan Ismail W, Che Man H, Zakaria A, Yamin M, et al. Comparative evaluation of naturally ventilated screenhouse and evaporative cooled greenhouse based on optimal vapor pressure deficit. 2016 ASABE Annual International Meeting, St. Joseph, MI: ASABE, 2016; 1.

Ehret D L, Hill B D, Helmer T, Edwards D R. Neural network modeling of greenhouse tomato yield, growth and water use from automated crop monitoring data. Computers and Electronics in Agriculture, 2011; 79(1): 82–89.

Clarke N D, Shipp J L, Papadopoulos A P, Jarvis W R, Khosla S, Jewett T J, et al. Development of the harrow greenhouse manager: A decision-support system for greenhouse cucumber and tomato. Computers and Electronics in Agriculture, 1999; 24(3): 195–204.

Gupta M K, Samuel D V K, Sirohi N P S. Decision support system for greenhouse seedling production. Computers and Electronics in Agriculture, 2010; 73(2): 133–145.

Pawlowski A, Sánchez-Molina J A, Guzmán J L, Rodríguez F, Dormido S. Evaluation of event-based irrigation system control scheme for tomato crops in greenhouses. Agricultural Water Management, 2017; 183: 16–25.

Sánchez-Molina J A, Pérez N, Rodríguez F, Guzmán J L, López J C. Support system for decision making in the management of the greenhouse environmental based on growth model for sweet pepper. Agricultural Systems, 2015; 139: 144–152.

Fisher P R, Heins R D, Ehler N, Lieth J H. A decision-support system for real-time management of Easter lily (Lilium longiflorum Thunb.) scheduling and height-I. System description. Agricultural Systems, 1997; 54(1): 23–37.

200. Sun Z F, Zhang Z B, Tong C F. Development of a real time on-line aided decision-making support system for greenhouse tomato production. Transaction of CSAE, 2001; 17(7): 75–78. (in Chinese)

Tchamitchian M, Martin-Clouaire R, Lagier J, Jeannequin B, Mercier S. SERRISTE: A daily set point determination software for glasshouse tomato production. Computers and Electronics in Agriculture, 2006; 50(1): 25–47.

Körner OSGV. Decision support for dynamic greenhouse climate control strategies. Computers and Electronics in Agriculture, 2008; 60: 18–30.

Cañadas J, Sánchez-Molina J A, Rodríguez F, del Águila I M. Improving automatic climate control with decision support techniques to minimize disease effects in greenhouse tomatoes. Information Processing in Agriculture, 2017; 4(1): 50–63.

Aiello G, Giovino I, Vallone M, Catania P, Argento A. A decision support system based on multisensor data fusion for sustainable greenhouse management. Journal of Cleaner Production, 2018; 172: 4057–4065.

205. Short T H, Draper C M, Donnell M A. Web-based decision support system for hydroponic vegetable production. International Conference on Sustainable Greenhouse Systems-Greensys, 2004: 867–870.

El-Attal A H. Decision model for hydroponic tomato production (hytodmod) using utility theory. The Ohio State University, 1995.

Shamshiri R, Che Man H, Zakaria A J, Beveren P V, Wan Ismail W I, Ahmad D. Membership function model for defining optimality of vapor pressure deficit in closed-field cultivation of tomato. International Society for Horticultural Science (ISHS), Leuven, Belgium, 2017.

Shamshiri R, van Beveren P, Che Man H, Zakaria A J. Dynamic Assessment of air temperature for tomato (Lycopersicon esculentum Mill) cultivation in a naturally ventilated net-screen greenhouse under tropical lowlands climate. Journal of Agricultural Science and Technology, 2017; 19(1): 59–72.

Ellis J. Agricultural transparency: Reconnecting urban centres with food production, 2012.

Abel C. The vertical garden city: towards a new urban topology. CTBUH Journal, 2010; 2: 20–30.

Despommier D. The vertical farm: Feeding the world in the 21st century. Macmillan, 2010.

Caplow T. Building integrated agriculture: Philosophy and practice. Urban Futures, 2009; 2030: 48–51.

Thomaier S, Specht K, Henckel D, Dierich A, Siebert R, Freisinger U B, et al. Farming in and on urban buildings: Present practice and specific novelties of Zero-Acreage Farming (ZFarming). Renewable Agriculture and Food Systems, 2015; 30(1): 43–54.

Mok H-F, Williamson V G, Grove J R, Burry K, Barker S F, Hamilton A J. Strawberry fields forever? Urban agriculture in developed countries: A review. Agronomy for Sustainable Development, 2014; 34(1): 21–43.

Taylor J R, Lovell S T. Mapping public and private spaces of urban agriculture in Chicago through the analysis of high-resolution aerial images in Google Earth. Landscape and Urban Planning, 2012; 108(1): 57–70.

Benis K, Ferrão P. Potential mitigation of the environmental impacts of food systems through urban and peri-urban agriculture (UPA) – A life cycle assessment approach. Journal of Cleaner Production, 2017; 140: 784–795.

Pölling B, Mergenthaler M, Lorleberg W. Professional urban agriculture and its characteristic business models in Metropolis Ruhr, Germany. Land Use Policy, 2016; 58: 366–379.

Cahya D L. Analysis of urban agriculture sustainability in metropolitan Jakarta (Case study: Urban agriculture in Duri Kosambi). Procedia - Social and Behavioral Sciences, 2016; 227: 95–100.

Ahlström L, Zahra M. Integrating a greenhouse in an urban area. Unpublished master’s thesis, Chalmers University of Technology, Göteborg, Sweden, 2011.

Kaplan PBT-DM. Encyclopedia of food and agricultural ethics. 2014.

Besthorn F H. Vertical farming: Social work and sustainable urban agriculture in an age of global food crises. Australian Social Work, 2013; 66(2): 187–203.

Holloway M. The glass house in the desert. Scientific American, 2002; 286(1): 90–92.

Lehmann S, Yeang K. Meeting with the green urban planner: a conversation between Ken Yeang and Steffen Lehmann on eco-masterplanning for green cities. Journal of Green Building, 2010; 5(1): 36–40.

Kim H-G, Park D-H, Chowdhury O R, Shin C-S, Cho Y-Y, Park J-W. Location-based intelligent robot management service model using RGPSi with AoA for vertical farm. Advances in Computer Science and its Applications, Berlin, Heidelberg: Springer Berlin Heidelberg, 2014.

Banerjee C, Adenaeuer L. Up, up and away! The economics of vertical farming. Journal of Agricultural Studies, 2014; 2(1): 40–60.

Joachim S. Skyfarming: An alternative to horizontal croplands. Resource Magazine, 2011.

Germer J, Sauerborn J, Asch F, de Boer J, Schreiber J, Weber G, et al. Skyfarming an ecological innovation to enhance global food security. Journal für Verbraucherschutz und Lebensmittelsicherheit, 2011; 6(2): 237.

Sivamani S, Bae N, Cho Y. A smart service model based on ubiquitous sensor networks using vertical farm ontology. International Journal of Distributed Sensor Networks, 2013.

Al-Chalabi M. Vertical farming: Skyscraper sustainability? Sustainable Cities and Society, 2015; 18: 74–77.

Miller A. Scaling up or selling out?: A critical appraisal of current developments in vertical farming. Carleton University, 2011.

Kalantari F, Mohd Tahir O, Mahmoudi Lahijani A, Kalantari S. A review of vertical farming technology: A guide for implementation of building integrated agriculture in cities. Trans Tech Publ, 2017.

Liu X. Design of a modified shipping container as modular unit for the minimally structured & modular vertical farm (MSM-VF): The University of Arizona, 2014.

Montero J I, Baeza E, Heuvelink E, Rieradevall J, Muñoz P, Ercilla M. Productivity of a building-integrated roof top greenhouse in a Mediterranean climate. Agricultural Systems, 2017; 158: 14–22.

Pons O, Nadal A, Sanyé-mengual E, Llorach-massana P, Rosa M. Roofs of the future: Rooftop greenhouses to improve buildings metabolism. Procedia Engineering, 2015; 123: 441–448.

Sanyé-Mengual E, Cerón-Palma I, Oliver-Solà J, Montero J I, Rieradevall J. Integrating horticulture into cities: A guide for assessing the implementation potential of rooftop greenhouses (RTGs) in industrial and logistics parks. Journal of Urban Technology, 2015; 22(1): 87–111.

Ercilla-Montserrat M, Izquierdo R, Belmonte J, Ignacio J, Muñoz P, Linares C D, et al. Science of the total environment building-integrated agriculture: A first assessment of aerobiological air quality in rooftop greenhouses (i-RTGs). Science of the Total Environment, 2017; 598: 109–120.

Kozai T. Resource use efficiency of closed plant production system with artificial light: Concept, estimation and application to plant factory. Proceedings of the Japan Academy, Series B, 2013; 89(10): 447–461.

Glaser J A. Green chemistry with nanocatalysts. Clean Technologies and Environmental Policy, 2012; 14(4): 513–520.

Miyagi A, Uchimiya H, Kawai-Yamada M. Synergistic effects of light quality, carbon dioxide and nutrients on metabolite compositions of head lettuce under artificial growth conditions mimicking a plant factory. Food Chemistry, 2017; 218: 561–568.

Shimokawa A, Tonooka Y, Matsumoto M, Ara H, Suzuki H, Yamauchi N, et al. Effect of alternating red and blue light irradiation generated by light emitting diodes on the growth of leaf lettuce. bioRxiv, 2014.

García-Fraile P, Menéndez E, Rivas R. Role of bacterial biofertilizers in agriculture and forestry. AIMS Bioengineering, 2015; 2(3): 183–205.

Kalantari F, Tahir O M, Joni R A, Fatemi E. Opportunities and challenges in sustainability of vertical farming: A review. Journal of Landscape Ecology, 2017: 5–30.

Eigenbrod C, Gruda N. Urban vegetable for food security in cities: A review. Agronomy for Sustainable Development, 2015; 35(2): 483–498.

Zoll F, Specht K, Siebert R. Innovation in urban agriculture: Evaluation data of a participatory approach (ROIR). Data in Brief, 2016; 7: 1473–1476.

Despommier D. Farming up the city: The rise of urban vertical farms. Trends in Biotechnology, 2013; 31(7): 388–389.

Voss P M. Vertical farming: An agricultural revolution on the rise. Halmstad, 2013.