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Year 2021, Volume: 4 Issue: 1, 39 - 45, 31.05.2021
https://doi.org/10.34088/kojose.768344

Abstract

References

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  • [2] Tong-Ke F., 2017. Smart Agriculture Based on Cloud Computing and IOT. Journal of Convergence Information Technology, 8(2), pp.210-216.
  • [3] Husti, I., Daroczi, M., Kovacks, I., 2017. Towards sustainable agriculture and biosystems engineering book Edited by: Anikó Nyéki, Attila J. Kovács, Gábor Milics.
  • [4] EBSO, 2015. Sanayi 4.0. Retrieved from http://www.ebso.org.tr/ebsomedia/documents/sanayi-40_88510761.pdf
  • [5] Kirkaya, A., 2020. Akıllı tarım teknolojileri uygulamaları. Retrieved from https://www.researchgate.net/publication/339029285_AKILLI_TARIM_TEKNOLOJILERI_UYGULAMALARI
  • [6] Corallo, A., Latino, M.E., Menegoli, M., 2018. From Industry 4.0 to Agriculture 4.0: A Framework to Manage Product Data in Agri-Food Supply Chain for Voluntary Traceability. World Academy of Science, Engineering and Technology, International Journal of Nutrition and Food Engineering, 12, pp.146-150.
  • [7] Ozdogan, B., Gacar, A., Aktaş, H., 2017. Digital Agriculture Practices in The Context of Agriculture 4.0. Journal of Economics, Finance and Accounting. 4. 184-191. 10.17261/Pressacademia.2017.448.
  • [8] Duman, B., Ozsoy, K., 2019. Endüstri 4.0 perspektifinde akıllı tarım. Retrieved from https://www.researchgate.net/publication/334234038_ENDUSTRI_40_PERSPEKTIFINDE_AKILLI_TARIM_SMART_AGRICULTURE_IN_INDUSTRY_40_PERSPECTIVE
  • [9] Sørensene, C. G., Fountas, S., Nash, E., Pesonen, L., Bochtis, D., Pedersen, S. M., Basso, B., Blackmore, S. B., 2010. Conceptual Model of a Future Farm Management Information System, Computers and Electronics in Agriculture, 72(1), pp.37-47.
  • [10] Yane, D., 2010. Research and Analysis about System of Digital Agriculture Based on a Network Platform, In International Conference on Computer and Computing Technologies in Agriculture, Springer Berlin Heidelberg. pp.274-282.
  • [11] Zambon, I., Cecchini, M., Egidi, G., Saporito, M., Colantoni, A., 2019. Revolution 4.0: Industry vs. Agriculture in a Future Development for SMEs. Processes. 7. 36. 10.3390/pr7010036.
  • [12] Kalkışım, A., Akkaş, M., Yucedag, I., 2019. Nesnelerin İnterneti ve Nesnelerinin İnternetinin Tarım Alanında Kullanımı. Retrieved from https://www.researchgate.net/publication/336020647_NESNELERIN_INTERNETI_VE_NESNELERIN_INTERNETININ_TARIM_ALANINDA_KULLANIMI
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  • [14] Rajakumar, G., Sankari, M.S., Shunmugapriya, D., Maheswari, S.P.U., 2018 Iot Based Smart Agricultural Monitoring System”, Asian Journal of Applied Science and Technology (AJAST), 2(2), pp.474-480.
  • [15] Kumar, V., Ramasamy, R., 2017. Implementation of Iot In Smart Irrigation System Using Arduino Processor”, International Journal of Civil Engineering and Technology (IJCIET).
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  • [18] Doknić, V., 2014. Internet of Things Greenhouse Monitoring and Automation System, Summer term.
  • [19] Akay, M., 2018. Endüstri 4.0 ile Akıllı Tarıma Geçiş. Retrieved from https://www.researchgate.net/publication/326550785_ENDUSTRI_40_ILE_AKILLI_TARIMA_GECIS
  • [20] Kaloxylos, A., Eigenmann, R., Teye, F., Politopoulou, Z., Wolfert, S., Shrank, C., Dilinger, M., Lampropoulou, I., Antoniou E., Pesonen, L., Nicole, H., 2012. Farm Management Systems and The Future Internet Era, Computers and Electronics in Agriculture, 89, pp.130-144.
  • [21] Oliver Wyman Report., 2018. Agriculture 4.0: The Future of Farming technology.
  • [22] Kirkaya, A., 2020. Akıllı tarım teknolojileri uygulamaları. Retrieved from https://www.researchgate.net/publication/339029285_AKILLI_TARIM_TEKNOLOJILERI_UYGULAMALARI
  • [23] Yanli, Z., 2009. An Introduction to the Development and Regulation of Agricultural Insurance in China. Geneva Pap. Risk Insur. Issues Pract., 34, pp.78–84.
  • [24] Pinstrup-Andersen, P., Shimokawa, S., 2006. Rural Infrastructure and Agricultural Development; World Bank: Washington, DC, USA. Avaliable online: http://siteresources.worldbank.org/INTDECABCTOK2006/Resources/Per_Pinstrup_Andersen_Rural_Infrastructure.pdf
  • [25] Amadi, B.C., 1998. The impact of rural road construction on agricultural development: An empirical study of Anambra state in nigeria. Agricultural System, 27, pp.1–9.
  • [26] Kaplan, R., 2010. “AHP Yöntemiyle Tedarikçi Seçimi: Perakende Sektöründe Bir Uygulama”, Master’s Thesis (Yüksek Lisans Tezi), İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, İstanbul.
  • [27] Esen, H. Ö., 2008. “Applied Operational Research” (“Uygulamalı Yöneylem Araştırması”), (S. Tolun, Ed.), Çağlayan Kitabevi.

Evaluation of Industry 4.0 Applications for Agriculture using AHP Methodology

Year 2021, Volume: 4 Issue: 1, 39 - 45, 31.05.2021
https://doi.org/10.34088/kojose.768344

Abstract

In today’s world because of increasing competition, shifting customer demands and expectations firms have to shorten their time-to-market, increase their flexibility and efficiency. Industry 4.0 applications as meet these requirements gain popularity. Awareness of the necessity of Industry 4.0 applications for excellent customer experience and great innovation capacity and studies searching advantageous applications for related sectors are increasing day by day. In this context, the agriculture sector, like other sectors, adapts to the changing conditions within the scope of Industry 4.0, and the concept of Agriculture 4.0, which includes digital agricultural technologies, appears. This study provides a detailed framework for the transition from Industry 4.0 to Agriculture 4.0 and digital agricultural tools. In addition, it is aimed to contribute to the literature by choosing the best alternative by evaluating these digital agricultural tools with the Analytical Hierarchy Process method according to cost, income, applicability and practicality criteria.

References

  • [1] Kovács, I., Husti, I., 2018. The role of digitalization in the agricultural 4.0 – how to connect the industry 4.0 to agriculture?. Hungarian Agricultural Engineering, pp.38-42.
  • [2] Tong-Ke F., 2017. Smart Agriculture Based on Cloud Computing and IOT. Journal of Convergence Information Technology, 8(2), pp.210-216.
  • [3] Husti, I., Daroczi, M., Kovacks, I., 2017. Towards sustainable agriculture and biosystems engineering book Edited by: Anikó Nyéki, Attila J. Kovács, Gábor Milics.
  • [4] EBSO, 2015. Sanayi 4.0. Retrieved from http://www.ebso.org.tr/ebsomedia/documents/sanayi-40_88510761.pdf
  • [5] Kirkaya, A., 2020. Akıllı tarım teknolojileri uygulamaları. Retrieved from https://www.researchgate.net/publication/339029285_AKILLI_TARIM_TEKNOLOJILERI_UYGULAMALARI
  • [6] Corallo, A., Latino, M.E., Menegoli, M., 2018. From Industry 4.0 to Agriculture 4.0: A Framework to Manage Product Data in Agri-Food Supply Chain for Voluntary Traceability. World Academy of Science, Engineering and Technology, International Journal of Nutrition and Food Engineering, 12, pp.146-150.
  • [7] Ozdogan, B., Gacar, A., Aktaş, H., 2017. Digital Agriculture Practices in The Context of Agriculture 4.0. Journal of Economics, Finance and Accounting. 4. 184-191. 10.17261/Pressacademia.2017.448.
  • [8] Duman, B., Ozsoy, K., 2019. Endüstri 4.0 perspektifinde akıllı tarım. Retrieved from https://www.researchgate.net/publication/334234038_ENDUSTRI_40_PERSPEKTIFINDE_AKILLI_TARIM_SMART_AGRICULTURE_IN_INDUSTRY_40_PERSPECTIVE
  • [9] Sørensene, C. G., Fountas, S., Nash, E., Pesonen, L., Bochtis, D., Pedersen, S. M., Basso, B., Blackmore, S. B., 2010. Conceptual Model of a Future Farm Management Information System, Computers and Electronics in Agriculture, 72(1), pp.37-47.
  • [10] Yane, D., 2010. Research and Analysis about System of Digital Agriculture Based on a Network Platform, In International Conference on Computer and Computing Technologies in Agriculture, Springer Berlin Heidelberg. pp.274-282.
  • [11] Zambon, I., Cecchini, M., Egidi, G., Saporito, M., Colantoni, A., 2019. Revolution 4.0: Industry vs. Agriculture in a Future Development for SMEs. Processes. 7. 36. 10.3390/pr7010036.
  • [12] Kalkışım, A., Akkaş, M., Yucedag, I., 2019. Nesnelerin İnterneti ve Nesnelerinin İnternetinin Tarım Alanında Kullanımı. Retrieved from https://www.researchgate.net/publication/336020647_NESNELERIN_INTERNETI_VE_NESNELERIN_INTERNETININ_TARIM_ALANINDA_KULLANIMI
  • [13] Kılavuz, E, Erdem, İ., 2019. Dünyada Tarım 4.0 Uygulamaları ve Türk Tarımının Dönüşümü. Social Sciences, 14(4), pp.133-157.
  • [14] Rajakumar, G., Sankari, M.S., Shunmugapriya, D., Maheswari, S.P.U., 2018 Iot Based Smart Agricultural Monitoring System”, Asian Journal of Applied Science and Technology (AJAST), 2(2), pp.474-480.
  • [15] Kumar, V., Ramasamy, R., 2017. Implementation of Iot In Smart Irrigation System Using Arduino Processor”, International Journal of Civil Engineering and Technology (IJCIET).
  • [16] Meola, A., 2016. Why IoT, big data & smart farming are the future of agriculture, https://www.businessinsider.com/internet-of-things-smart-agriculture-2016-10.
  • [17] Suma, N., Samson, S.R., Saranya, S., Shanmugapriya, G., Subhashri, R., 2017. IOT Based Smart Agriculture Monitoring System” International Journal on Recent and Innovation Trends in Computing and Communication, 5(2), pp.177-181.
  • [18] Doknić, V., 2014. Internet of Things Greenhouse Monitoring and Automation System, Summer term.
  • [19] Akay, M., 2018. Endüstri 4.0 ile Akıllı Tarıma Geçiş. Retrieved from https://www.researchgate.net/publication/326550785_ENDUSTRI_40_ILE_AKILLI_TARIMA_GECIS
  • [20] Kaloxylos, A., Eigenmann, R., Teye, F., Politopoulou, Z., Wolfert, S., Shrank, C., Dilinger, M., Lampropoulou, I., Antoniou E., Pesonen, L., Nicole, H., 2012. Farm Management Systems and The Future Internet Era, Computers and Electronics in Agriculture, 89, pp.130-144.
  • [21] Oliver Wyman Report., 2018. Agriculture 4.0: The Future of Farming technology.
  • [22] Kirkaya, A., 2020. Akıllı tarım teknolojileri uygulamaları. Retrieved from https://www.researchgate.net/publication/339029285_AKILLI_TARIM_TEKNOLOJILERI_UYGULAMALARI
  • [23] Yanli, Z., 2009. An Introduction to the Development and Regulation of Agricultural Insurance in China. Geneva Pap. Risk Insur. Issues Pract., 34, pp.78–84.
  • [24] Pinstrup-Andersen, P., Shimokawa, S., 2006. Rural Infrastructure and Agricultural Development; World Bank: Washington, DC, USA. Avaliable online: http://siteresources.worldbank.org/INTDECABCTOK2006/Resources/Per_Pinstrup_Andersen_Rural_Infrastructure.pdf
  • [25] Amadi, B.C., 1998. The impact of rural road construction on agricultural development: An empirical study of Anambra state in nigeria. Agricultural System, 27, pp.1–9.
  • [26] Kaplan, R., 2010. “AHP Yöntemiyle Tedarikçi Seçimi: Perakende Sektöründe Bir Uygulama”, Master’s Thesis (Yüksek Lisans Tezi), İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, İstanbul.
  • [27] Esen, H. Ö., 2008. “Applied Operational Research” (“Uygulamalı Yöneylem Araştırması”), (S. Tolun, Ed.), Çağlayan Kitabevi.
There are 27 citations in total.

Details

Primary Language English
Subjects Industrial Engineering
Journal Section Articles
Authors

Melda Güliz Ateş 0000-0002-2243-9642

Yıldız Şahin 0000-0002-6283-5340

Publication Date May 31, 2021
Acceptance Date February 6, 2021
Published in Issue Year 2021 Volume: 4 Issue: 1

Cite

APA Ateş, M. G., & Şahin, Y. (2021). Evaluation of Industry 4.0 Applications for Agriculture using AHP Methodology. Kocaeli Journal of Science and Engineering, 4(1), 39-45. https://doi.org/10.34088/kojose.768344