Literature


This section states the references to all the information given on this website. Most content was extracted from specialist books, but information was also gathered from articles for very specific topics on agriculture and hydroponic. Hence, if you feel this website is not providing enough content on a specific subtopic, feel free to look into the literature suggestions on specialist books underneath this paragraph first, before diving into the list of references. And in case you are looking for already built and tested systems, check out the section here or search for "DIY Hydroponic" on Instructables.


Literature Suggestions

Sustainability:

  • The Age of Sustainable Development by Jeffrey D. Sachs form 2015

Hydroponic and DIY Guides:

  • DIY Hydroponic Gardens by Tyler Baras from 2018
  • Do It Yourself Hydroponics by Richard Bray from 2018
  • Gardening: Hydroponics for Self Sufficiency – Vegetables, Herbs and Berries by Melissa Honeydew from 2016

Botanics and Plant ABC

  • Gemüseproduktion by Helmut Krug, Hans-Peter Liebig and Hartmut Stützel from 2002 (in German)
  • Allgemeine und molekulare Botanik by Elar W. Weiler and Lutz Nover from 2008 (in German)

Pest and Disease Management:

  • Integrated Pest and Disease Management in Greenhouse Crops by R. Albajes, M. Lodovica Guillino, J. C. Van Lenteren and Y. Elad from 2002

Plant Nutrition:

  • Plant Nutrition by Cees Sonneveld and Wim Voogt from 2009

IoT:

 


References

LiteraturverzeichnisLiteraturverzeichnis

[1] Albajes, R., M. Lodovica Guillino, J. C. Van Lenteren, and Y. Elad. 2002. Integrated Pest and Disease Management in Greenhouse Crops. New York/Dordrecht/Boston/London: Kluwer Academic Publishers.

[2] AlShrouf, A. 2017. "Hydroponics, Aeroponic and Aquaponic as Compared with Conventional Farming." American Scientific Research Journal for Engineering, Technology, and Sciences 27 (1): 247-255.

[3] Arduino. 2005. arduino.cc. Arduino. Accessed April 28th, 2020. https://www.arduino.cc.

[4] Arnold, T., K. Hammel, B. Hsueh, S. Robart, and L. Thomson. 2013. Fresh City: Impacts of local food - Social, environmental, economic dimensions. Food system assessment report, Ontario: Grey Bruce Centre for Agroecology.

[5] Baras, T. 2018. DIY Hydroponic Gardens. Minneapolis, MN, USA: Cool Springs Press.

[6] Barbosa, G. L., F. D. Alemida Gadelha, N. Kublik, A. Proctor, L. Reichelm, E. Weissinger, G. M. Wohlleb, and R. U. Halden. 2015. "Comparison of Land, Water, and Energy Requirements of Lettuce Grown Using Hydroponic vs. Conventional Agricultural Methods." International Journal of Environmental Research and Public Health (12): 6879-6891.

[7] Benke, K., and B. Tomkins. 2017. "Future food-production systems: vertical farming and controlled-environment agriculture." Sustainability: Science, Practice and Policy (13:1): 13-26.

[8] Blynk Inc. n.d. blynk.io/. Blynk Inc. Accessed May 1st, 2020. https://blynk.io/.

[9] Bray, R. 2018. Do it yourself Hydroponic – 12 easy and affordable wys to build your own hydroponic system.Hamburg, Germany: Monkey Publishing.

[10] Brechner, M. et. Al. 2014. Hydroponic Lettuce Handbook. Ithaca, NY: Cornell University. http://www.cornellcea.com/attachments/.

[11] Buzby, K. M., and L. Lin. 2014. "Scaling aquaponic systems: Balancing plant uptake with fish output." Aquacultural Engineering (63): 39-44.

[12] Custos, J.-M., C. Moyne, and T. Sterckeman. 2020. "How root nutrient uptake affects rhizosphere pH: A modelling study." Geoderma (369): 12.

[13] Despommier, D. 2013. "Farming up the city: the rise of urban vertical farms." Trens in Biotechnology (1067): 1-2.

[14] Despommier, D. 2009. "The Rise of Vertical Farms." Scientific American 31 (5): 32-39.

[15] DFRobot. 2008. dfrobot.com. DFRobot. Accessed April 28th, 2020. https://www.dfrobot.com.

[16] Donkers, H. 2015. Local Food for Global Future - Classicifcation, governance and knowledge for sustainable food security. Saarbrücken, Deutschland/Germany: Scholar's Press.

[17] Dos Santos, U. J., G. Pessin, and C. A., Da Rodas Righi, R. Da Costa. 2019. "AgriPrediction: A proactive internet of things model to anticipate problems and improve production in agricultural crops." Computers and Electronics in Agriculture (161): 202-213.

[18] Duston, J. 2017. "Assessing the Potential Environmental Impacts of Controlled Environment Agriculture in Detroit and the Future of This Industry Based on Local Food Trends." Maste's Thesis at Harvard University: Harvard Extension School.

[19] Enzi, Vera. 2019. Advantages of urban greening (not published) Graz, Austria, (May 10th).

[20] FAO. 2015. fao.org. Food and Agriculture Organization of the United Nations. Accessed April 7th, 2020. http://www.fao.org/urban-agriculture/en/.

[21] Forchino, A. A., D. Brigolin, R. Pastres, and H. Lourguioui. 2017. "Aquaponics and sustainability: The comparison of two different aquaponic techniques using the Life Cycle Assessment (LCA)." Aquacultural Engineering (77): 80-88.

[22] Future Lectures', audience. 2018. "Future Lectures." Lebensmittel bewegen: Wie kann sich Graz regional versorgen? Autria - Graz, October 30.

[23] Gericke, W. F. 1940. The Complete Guide to Soilless Gardening. New York: Prentice-Hall INC.

[24] Goldstein, B., M. Hauschild, J. Fernandez, and M. Birkved. 2016. "Testing the environmental performance of urban agriculture as a food supply in northern climates." Journal of Cleaner Production (135): 984-994.

[25] GrünstattGrau. 2019. gruenstattgrau.at. Accessed May 17th, 2019. https://gruenstattgrau.at/urban-greening/leistungen-von-begruenung/.

[26] Hoadland, D. R., and D. I. Arnon. 1950. "The water-culture method for growing plants without soil." California Agricultural Experiment Station (347): 31.

[27] Honeydew, M. 2016. Gardening: Hydroponics for Self Sufficiency – Vegetables, Herbs and Berries. Wroclaw, Poland: Amazon.

[28] Incrocci, L., and A. Pardossi. 2003. "A simple model for salt accumulation in closed-loop hydroponics." Acta Horticulturae (614): 149-154.

[29] Jimdo. 2007. www.jimdo.com/. Jimdo. Accessed January 13th, 2020. https://www.jimdo.com/.

[30] Khudoyberdiev, A., S. Ahmad, I. Ullah, and D.H. Kim. 2020. "An Optimization Scheme Based on Fuzzy Logic Control for Efficient Energy Consumption in Hydroponics Environment." Energies (13): 289-316.

[31] Krug, H., H.-P. Liebig, and H. Stützel. 2002. Vegetable Production (in German). III. Stuttgart, Germany: Eugen Ulmer Verlag.

[32] Lee, M., J. Lee, B. Park, and Y. Miyazaki. 2015. "Interaction with indoor plants may reduce psychological and physiological stress by suppressing autonomic nervous system activity in young adults: a randomized crossover study." Journal of Physiological Anthropology (34): 21-27.

[33]_MathWorks. 1984. en.mathworks.com/products/matlab.html. MathWorks. Accessed May 1st, 2020. https://en.mathworks.com/products/matlab.html.

[34] MathWorks. 1984. thingspeak.com. MathWorks. Accessed January 13th, 2020. https://thingspeak.com.

[35] McDowell, R. W., T. J. van der Weerden, and J. Campbell. 2011. "Nutrient losses associated with irrigation, intensification and management of land use: A study of large scale irrigation in North Otago, New Zealand." Agricultural Water Management (Agricultural Water Management) (98): 877-885.

[36] Meadows, D. et.al. 1972. The Limits To Growth. Potomac Associates - Universe Books.

[37] Minjuan, W., D. Chen, and G. Wanlin. 2019. "Evaluation of the growth, photosynthetic characteristics, antioxidant T capacity, biomass yield and quality of tomato using aeroponics, hydroponics and porous tube-vermiculite systems in bio-regenerative life support systems." Life Sciences in Space Research(22): 68-75.

[38] Moon, A., J. Kim, J. Zhang, and S. W. Son. 2018. "Evaluating fidelity of lossy compression on spatiotemporal data from an IoT T enabled smart farm." Computers and Electronics in Agriculture (154): 304-313.

[39] Nasr, J. Smit and J. 1992. "Urban agriculture for sustainable cities: using wastes and idle land and water bodies as resources." Environment and Ubranization (4): 141-152.

[40] Ono, E. 2001. Monitoring of nutrient solution for hydroponically grown sweetpotato (Ipomoea batatas). Tucson, Arizona, USA: University of Arizona.

[41] Paine, T. C. E., T. R. Marthews, V. R. Vogt, D. Purves, M. Rees, A. Hector, and L. A. Turnbull. 2012. "How to fit nonlinear plant growth models and calculate growth rates: an update for ecologists." Methods in Ecology and Evolution (3): 245-256.

[42] Pii, Y., S. Cesco, and T. Mimmo. 2015. "Shoot ionome to predict the synergism and antagonism between nutrients as affected by substrate and physiological status." Plant Physiology and Biochemistry (94): 48-56.

[43] Plenty. 2014. university.upstartfarmers. Plenty. Accessed May 26th, 2019. https://university.upstartfarmers.com/.

[44] Ragnarsdottir, K.V., H.U. Sverdrup, and D. Koca. 2011. "Challenging the planetary boundaries I: Basic principles of an integrated model for phosphorous supply dynamics and global population size." Applied Geochemistry (26): 303-306.

[45] Raspberry Pi Foundation. 2012. raspberrypi.org. Raspberry Pi Foundation. Accessed April 28th, 2020. https://www.raspberrypi.org.

[46] Resh, H. M. 2013. Hydroponic Food Production - A definitive guidebook for the advanced home gardener and the commercial hydroponic grower. 7th ed. Boca Raton, FL, USA: CRC Press.

[47] Rockström, J. et.al. 2009. A Safe Operating Space for Humanity. Macmillan Publishers Limited.

[48] Romeo, C., E. B. Vea, and Thomsenm M. 2018. Environmental impacts of urban hydroponics in Europe: a case study in Lyon. Copenhagen, Denmark: 25th CIRP Life Cycle Engineering (LCE) Conference, 30 April – 2 May 2018.

[49] Sachs, J. D. 2015. The Age Of Sustainable Development. Columbia Univers. Press.

[50] Salt, D. E. 2004. "Update on Plant Ionomics." Plant Physiology (136): 2451-2456.

[51] Sanjuan-Delmás, D., A. Josa, P. Muños, S. Gassó, J. Rieradevall, and X. Gabarrell. 2020. "Applying nutrient dynamics to adjust the nutrient-water balance in hydroponic crops. A case study with open hydroponic tomato crops from Barcelona." Scientia Horticulturae (261): 10.

[52] Sanjuan-Delmas, D., P. Llorach-Massana, A. Nadal, M. Ercilla-Montserrat , P. Muñoz, J. I. Montero, A. Josa, X. Gabarrell, and J Rieradevall. 2018. "Environmental assessment of an integrated rooftop greenhouse for food production in cities." Journal of Cleaner Production (177): 326-337.

[53] Sayara, T., B. Amarneh, T. Saleh, K. Aslan, R. Abuhanish, and A. Jawabreh. 2016. "Hydroponic and Aquaponic Systems for Sustainable Agriculture and Environment." International Journal of Plant Science and Ecology 2 (3): 23-29.

[54] Singh, Hardeep. 2015. Fertilizer and cultivar selection of different vegetable crops and evaluation of different pH buffers in hydroponics. Ludhiana, India: Agricultural University Ludhiana.

[55] Sonneveld, C., and W. Voogt. 2009. Plant nutrition of greenhouse crops. Edited by Springer Science+Business Media. Dordrecht Heidelberg London New York: Springer.

[56] Trejo-Téllez, L. I., and F. C. Gómez-Merino. 2012. "Nutrient Solutions for Hydroponic Systems." In Hydroponics - A Standard Methodology for Plant Biological Researches, 244. Montecillo, Texoco, Mexico: InTech.

[57] Truog, E. 1947. "The Liming of Soils." In USDA Yearbook of Agriculture 1943-1947, pp. 569-570. US Department of Agriculture.

[58] Wackernagel, Maltis. 1988. Ecological Footprint and Appropriated Carrying Capacity: A Tool for Planning Toward Sustainability. Zürich Swiss: The Swiss Federal Institute of Technology.

[59] Weiler, E., and L. Nover. 2008. Allgemeine und molekulare Botanik. Stuttgart, Germany: Georg Thieme Verlag KG.