Precision agriculture (PA) through the use and utilization of innovative technologies is a concept in agricultural management that enables long-term efficiency gains, control of unforeseen changes, and a reduction of negative impacts on the environment. However, there are even more reasons and benefits to using precision agriculture technologies (PATs) on farms, but the actual use on small farms is often questionable. The main objective of this research was to evaluate and analyze the current state of PA and its potential on a set of small farms. In addition, a comparison was made between small farms located in less favored areas (LFAs) and more favored areas (MFAs) to find if specific characteristics of the surrounding environment affect the (non-) implementation of these technologies by farm owners, with respect to the given regional possibilities. The result shows that 57.5% of respondents on these farms have never implemented PATs before and 20% are beginners in their respective fields. It was found that there were no statistically significant differences in the integration between fewer LFAs and MFAs technologies and their use in this study. The majority of respondents believe that the main changes need to occur on the level of politics. The results show that the level of cost or initial investment is the main reason and the main obstacle in the implementation of PATs on the surveyed farms.
Keywords: precision agriculture, small farm, technological innovations, implementation, situation overview, survey, ICT
DOI: 10.25165/j.ijabe.20221503.6111

Citation: Rakun J, Rihter E, Kelc D, Denis S, Vindiš P, Berk P, et al. Possibilities and concerns of implementing precision agriculture technologies on small farms in Slovenia. Int J Agric & Biol Eng, 2022; 15(3): 16–21.

precision agriculture, small farm, technological innovations, implementation, situation overview, survey, ICT

Wang M H. Possible adoption of precision agriculture for developing countries at the threshold of the new millennium. Computers and Electronics in Agriculture, 2001; 30(1–3): 45–50.

Weick C W. Agribusiness technology in 2010: Directions and challenges. Technology in Society, 2001; 23(1): 59–72.

Robertson M J, Lewellyn R S, Mandel R, Lawes R, Bramley V, Swift L, et al. Adoption of variable rate fertiliser application in the Australian grains industry: status, issues and prospects. Precision Agriculture, 2012; 13(2): 181–199.

Raza U, Salam A. Zenneck waves in decision agriculture: An empirical verification and application in EM-based underground wireless power transfer. Smart Cities, 2020; 3(2): 308–340.

Kviz Z, Kroulik M, Chyba J. Soil damage reduction and more environmental friendly agriculture by using advanced machinery traffic. Agronomy Research, 2014; 12(1): 121–128.

International Society for Precision Agriculture. ISPA Forms Official Definition of 'Precision Agriculture', 2019. Available: https://www.precisionag.com/market-watch/ispa-forms-official-definition-of-precision-agriculture/. Accessed on [2020-07-02].

Earl R, Wheeler P N, Blackmore B S, Godwin R J. Precision farming - the management of variability. The Journal of the Institution of Agricultural Engineers, 1996; 51: 418–423.

Hrubovcak J, Vasavada U, Aldy J E. Green technologies for more sustainable agriculture. Agriculture Information Bulletin, No. 752, Economic Research Service, US Department of Agriculture, Washington, DC, 1999.

Fountas S, Blackmore S, Ess D, Hawkins S, Blumhoff G, Lowenberg- Deboer J, et al. Farmer experience with precision agriculture in Denmark and the US eastern corn belt. Precision Agriculture, 2005; 6: 121–141.

Reichardt M, Jürgens C. Adoption and perspective of precision farming (PF) in Germany: Results of several surveys among the different agricultural target groups. Precision Agriculture, 2009; 10(1): 73–94.

Barnes A P, Soto I, Eory V, Beck B, Balafoutis A, Sánchez B, et al. Exploring the adoption of precision agricultural technologies: A cross regional study of EU farmers. Land Use Policy, 2019; 80: 163–174.

Koutsos T, Menexes G. Economic, agronomic, and environmental benefits from the adoption of precision agriculture technologies. International Journal of Agricultural and Environmental Information Systems (IJAEIS), 2019; 10(1): 40–56.

Adrian A M, Norwood S H, Mask P L. Producers perceptions and attitudes toward precision agriculture technologies. Computers and Electronics in Agriculture, 2005; 48(3): 256–271.

Smale M, Heisey P W. Simultaneous estimation of seed-fertilizer adoption decisions: An application to hybrid maize in Malawi. Technological Forecasting and Social Change, 1993; 43: 353–368.

Isgin T, Bilgic A, Forster L, Batte M T. Using count data models to determine the factors affecting farmers’ quantity decisions of precision farming technology adoption. Computers and Electronics in Agriculture, 2008; 62(2): 231–242.

Paudel K, Pandit M, Mishra A, Segarra E. Why don’t farmers adopt precision farming technologies in cotton production? 2011 AAEA & NAREA Joint Annual Meeting, 2011; pp.24-26. doi: 10.22004/ag.econ.104828.

Paustian M, Theuvsen L. Adoption of precision agriculture technologies by german crop farmers. Precision Agriculture, 2017; 18(5): 701–716.

McBride W D, Daberkow S G. Information and the adoption of precision farming technologies. Journal of Agribusiness, 2003; 21(1): 21–38.

Daberkow S G, McBride W D. Farm and operator characteristics affecting the awareness and adoption of precision agriculture technologies in the US. Precision Agriculture, 2003; 4(2): 163–177.

Borusiewicz A, Kapela K, Drozyner P, Marczuk T. Application of precision agriculture technology in Podlaskie Voivodeship. Agricultural Engineering, 2016; 20(1): 5–11.

Van der Wal T, Vullings L A E, Zaneveld-Reijnders J, Bink R J. Doorontwikkeling van de Precisielandbouw in Nederland. Wageningen Environmental Research Rapport, 2017; 94p.

European Parliament. Precision agriculture and the future of farming in Europe. European Parliamentary Research Service (EPRS). Scientific Foresight Unit (STOA), 2016. Available: https://www.europarl.europa.eu/RegData/etudes/STUD/2016/581892/EPRS_STU(2016)581892_EN.pdf. Accessed on [2020-04-01].

European Commission. The Common Agricultural Policy at a Glance. The Common Agricultural Policy Supports Farmers and Ensures Europe's Food Security, 2018.

Massot A. The common agricultural policy (CAP) and the Treaty, 2019. Available: https://www.europarl.europa.eu/factsheets/en/sheet/103/ the-common-agricultural-policy-cap-and-the-treaty. Accessed on [2020-04-09].

Say S M, Keskin M, Sefri M, Sekerli Y E. Adoption of precision agriculture technologies in developed and developing countries. The Online Journal of Science and Technology, 2017; 8(1): 41–49.

Rogers E M, Singhal A, Quinlan M M, Stacks D W (Ed.), Salwen M B (Ed.), Eichhorn K C (Ed.). Diffusion of innovations. An Integrated Approach to Communication Theory and Research (3rd ed.). Abington: Routledge, 1983. Available: https://doi.org/10.4324/9780203710753-35. Accessed on [2020-05-02].

Burgess P J, Morris J. Agricultural technology and land use futures: The UK case. Land Use Policy, 2009; 26(1): 222–229.

Edwards-Jones G. Modelling farmer decision-making: Concepts, progress and challenges. Animal Science, 2006; 82: 783–790.

Bahr C, Forristal D, Fountas S, Gil E, Greiner G, Hoefarter R, et al. EIP-AGRI Focus Group Precision Farming. Final Report, 2015. Available: https://www.researchgate.net/publication/289345187_EIP-AGRI_ Focus_ Group_Precision_Farming_FINAL_REPORT/references, 1993. Accessed on [2020-05-20].

Travnikar T, Bedrač M, Bele S, Brečko J, Cunder T, Kožar M, et al. Slovensko kmetijstvo v številkah. Kmetijski inštitut Slovenije, 2019. Available: https://www.kis.si/f/docs/Slovensko_kmetijstvo_v_stevilkah_OEK/KIS_Slovensko_kmetijstvo_v_stevilkah_2019_SLO_splet_.pdf. Accessed on [2020-05-16].

SURS Statistični urad Republike Slovenije. Število in sestava prebivalstva, Slovenija, 2016. Available: https://www.stat.si/StatWeb/ Field/Index/17/104. Accessed on [2020-05-27].

SURS Statistični urad Republike Slovenije. Struktura kmetijskih gospodarstev, Slovenija, 2016. Available: https://www.stat.si/StatWeb/ News/Index/6742. Accessed on [2020-05-28].

Glossary of Statistical Terms. Less-favoured area (LFA), 2011. Available: https://stats.oecd.org/glossary/detail.asp?ID=1520. Accessed [2020-04-17].