Informatics Studies

The paper explores the emerging field of agricultural informatics and its transformative impact on sustainable farming practices. Examines key technologies driving this revolution, including the Internet of Things (IoT), Artificial Intelligence (AI), remote sensing, Big Data analytics, and Blockchain. It evaluates their applications in precision agriculture, intelligent pest management, climate-smart farming, and supply chain optimization and highlights the potential of Informatics to significantly enhance productivity, resource efficiency, and environmental sustainability in agriculture. Addressing critical challenges such as data privacy, the digital divide between large and small-scale farmers, and standardization; authors explore  future trends, including integrating robotics, vertical farming, and nanotechnology in agriculture. By synthesizing current research and industry developments, this review provides a holistic understanding of the potential and challenges of agricultural informatics in reshaping global food systems.

Dream Tech solutions (2024). IoT Applications in Agriculture. https://blog.dreamztech.com/wp-content/uploads/2018/09/iot-agriculture-1.jpg. Accessed on 17.09.2024

Analytics Vidya (2024). Generative A I tools and Techniques. https://editor.analyticsvidhya.com/uploads/98360AI_image_55.png. Accessed on 17.09.2024

AgGateway.(2021).ADAPTFramework.:https://www.aggateway.org/GetConnected/ADAPTAspx.

Allemang, D., and Teegarden, B. (2016). A global data ecosystem for agriculture and food. F1000Research, 5.

Balafoutis, A., Beck, B., Fountas, S., Vangeyte, J., Wal, T. V. D., Soto, I. and Eory, V. (2017). Precision agriculture technologies positively contribute to GHG emissions mitigation, farm productivity and economics. Sustainability, 9(8), 1339.

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

Berckmans, D. (2017). General introduction to precision livestock farming. Animal Frontiers, 7(1), 6-11.

Bhat, S. A., Huang, Z.,Huang N.F., (2021). Big Data and AI Revolution in Precision Agriculture: Survey and Challenges.Digital Object Identifier10.1109/ACCESS.2021.3102227.

Burgess, P. J., Graves, A. R., García de Jalón, S., Palma, J. H., Dupraz, C., and van Noordwijk, M. (2019). I am modelling agroforestry systems. In Agroforestry for Sustainable Agriculture (pp. 209-238). Burleigh Dodds Science Publishing.

Caro, M. P., Ali, M. S., Vecchio, M., and Giaffreda, R. (2018). Blockchain-based traceability in Agri-Food supply chain management: A practical implementation. 2018 IoT Vertical and Topical Summit on Agriculture - Tuscany (IOT Tuscany), 1-4.

Davison, S., Olt, S., and Andersen, T. (2019). AgGateway's ADAPT Framework: A standard for interoperability. Precision Agriculture, 20(1), 28-41.

Defourny, P., Bontemps, S., Bellemans, N., Cara, C., Dedieu, G., Guzzonato, E. and Koetz, B. (2019). Near real-time agriculture monitoring at national scale at parcel resolution: Performance assessment of the Sen2-Agri automated system in various cropping systems worldwide. Remote Sensing of Environment, 221, 551-568.

Eastwood, C., Klerkx, L., and Nettle, R. (2017). Dynamics and distribution of public and private research and extension roles for technological innovation and diffusion: Case studies of the implementation and adaptation of precision farming technologies. Journal of Rural Studies, pp. 49, 1–12.

Eastwood, C., Klerkx, L., Ayre, M., and Dela Rue, B. (2019). Managing socio-ethical challenges in the development of intelligent farming: From a fragmented to a comprehensive approach for responsible research and innovation. Journal of Agricultural and Environmental Ethics, 32(5), 741–768.

Egli, L., Meyer, C., Scherber, C., Kreft, H., and Tscharntke, T. (2018). Winners and losers of national and global efforts to reconcile agricultural intensification and biodiversity conservation. Global Change Biology, 24(5), 2212-2228.

Ericsson. (2020). Connected Agriculture: The role of 5G in the future of food production. Ericsson Mobility Report.

EU Code of Conduct. (2018). EU Code of Conduct on Agricultural Data Sharing by Contractual Agreement.

European Commission. (2018). EU Budget: the Common Agricultural Policy beyond 2020. Press release. Brussels.

FAO. (2017). The future of food and agriculture – Trends and challenges. Rome.

Farooq, M. S., Riaz, S., Abid, A., Umer, T., and Zikria, Y. B. (2020). Role of IoT technology in agriculture: A systematic literature review. Electronics, 9(2), 319.

Ferentinos, K. P. (2018). Deep learning models for plant disease detection and diagnosis. Computers and Electronics in Agriculture, 145, 311-318.

Food and Agriculture Organization (FAO). (2021). Climate-Smart Agriculture. http://www.fao.org/climate-smart-agriculture/en/

Fraceto, L. F., Grillo, R., de Medeiros, G. A., Scognamiglio, V., Rea, G., and Bartolucci, C. (2016). Nanotechnology in agriculture: Which innovation potential does it have? Frontiers in Environmental Science, 4, 20.

Goldman Sachs. (2016). Precision Farming: Cheating Malthus with Digital Agriculture. Equity Research.

Goldstein, A., Fink, L., Meitin, A., Bohadana, S., Lutenberg, O., and Ravid, G. (2018). Applying machine learning on sensor data for irrigation recommendations: revealing the agronomist's tacit knowledge. Precision Agriculture, 19(3), 421-444.

Grand View Research. (2021). Vertical Farming Market Size, Share and Trends Analysis Report by Structure, By Offering, By Growing Mechanism, By Fruits, Vegetables and Herbs, By Region, And Segment Forecasts, 2021 - 2028.

Hickey, L. T., Hafeez, A. N., Robinson, H., Jackson, S. A., Leal-Bertioli, S. C., Tester, M. and Wulff, B. B. (2019). Breeding crops to feed 10 billion. Nature Biotechnology, 37(7), 744–754.

Hunt, E. R., Daughtry, C. S. T., Mirsky, S. B., and Hively, W. D. (2018). Remote Sensing with Unmanned Aircraft Systems for Precision Agriculture Applications. IEEE Geoscience and Remote Sensing Magazine, 6(1), 48–56.

Janssen, S. J., Porter, C. H., Moore, A. D., Athanasiadis, I. N., Foster, I., Jones, J. W., and Antle, J. M. (2017). Towards a new generation of agricultural system data, models and knowledge products: Information and communication technology. Agricultural Systems, pp. 155, 200–212.

Kamath, R. (2018). Food traceability on blockchain: Walmart's pork and mango pilots with IBM. The Journal of the British Blockchain Association, 1(1), 3712.

Kamilaris, A., Fonts, A., and Prenafeta-Boldύ, F. X. (2019). The rise of blockchain technology in agriculture and food supply chains. Trends in Food Science and Technology, pp. 91, 640–652.

Kamilaris, A., Fonts, A., and Prenafeta-Boldύ, F. X. (2019). The rise of blockchain technology in agriculture and food supply chains. Trends in Food Science and Technology, pp. 91, 640–652.

Khanna, A., and Kaur, S. (2019). Evolution of the Internet of Things (IoT) and its significant impact on Precision Agriculture. Computers and Electronics in Agriculture, 157, 218-231.

Kholif, A. E., Gouda, G. A., Olafadehan, O. A., and Abdelfattah, Z. M. (2018). The use of biological additives to enhance crop yield and nutritional quality. In Sustainable Agriculture Reviews 27 (pp. 57-77). Springer, Cham.

King, A. (2017). Technology: The future of agriculture. Nature, 544(7651), S21-S23.

Liakos, K. G., Busato, P., Moshou, D., Pearson, S., and Bochtis, D. (2018). Machine learning in agriculture: A review. Sensors, 18(8), 2674.

Lipper, L., Thornton, P., Campbell, B. M., Baedeker, T., Braimoh, A., Bwalya, M., and Torquebiau, E. F. (2014). Climate-smart agriculture for food security. Nature Climate Change, 4(12), 1068–1072.

Lowenberg-DeBoer, J., Huang, I. Y., Grigoriadis, V., and Blackmore, S. (2020). Economics of robots and automation in field crop production. Precision Agriculture, 21(2), 278–299.

Mahlein, A. K., Kuska, M. T., Behmann, J., Polder, G., and Walter, A. (2018). Hyperspectral sensors and imaging technologies in phytopathology: state of the art. Annual Review of Phytopathology, 56, 535-558.

Markets and Markets. (2020). Big Data in Agriculture Market by Application (Precision et al.), By Component (Solution, Services), By Deployment Mode (Cloud, On-Premise), By Organization Size, and Region - Global Forecast to 2025. https://www.marketsandmarkets.com/Market-Reports/big-data-agriculture- market 186644511.html

Mohanty, S. P., Hughes, D. P., and Salathé, M. (2016). Using deep learning for image-based plant disease detection. Frontiers in Plant Science, p. 7, 1419.

Neethirajan, S. (2017). Recent advances in wearable sensors for animal health management. Sensing and Bio-Sensing Research, pp. 12, 15–29.

Paustian, K., Lehmann, J., Ogle, S., Reay, D., Robertson, G. P., and Smith, P. (2016). Climate-smart soils. Nature, 532(7597), 49–57.

Rose, D. C., Wheeler, R., Winter, M., Lobley, M., and Chivers, C. A. (2021). Agriculture 4.0: Making it work for people, production, and the planet. Land Use Policy, p. 100, 104933.

Rosenzweig, C., Ruane, A. C., Antle, J., Elliott, J., Ashfaq, M., Chatta, A. A. and Wiebe, K. (2018). Coordinating AgMIP data and models across global and regional scales for 1.5° C and 2.0° C assessments. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 376(2119), 20160455.

Schimmelpfennig, D. (2016). Farm profits and adoption of precision agriculture. ERR-217, U.S. Department of Agriculture, Economic Research Service.

Voulodimos, A. S., Patrikakis, C. Z., Sideridis, A. B., Ntafis, V. A., and Xylouri, E. M. (2010). A complete farm management system based on animal identification using RFID technology. Computers and Electronics in Agriculture, 70(2), 380-388.

Weiss, M., Jacob, F., and Duveiller, G. (2020). Remote sensing for agricultural applications: A meta-review. Remote Sensing of Environment, 236, 111402.

Wiseman, L., Sanderson, J., Zhang, A., and Jakku, E. (2019). Farmers and their data: An examination of farmers' reluctance to share their data through the lens of the laws impacting smart farming. NJAS-Wageningen Journal of Life Sciences, 90, 100301.

Wiseman, L., Sanderson, J., Zhang, A., and Jakku, E. (2019). Farmers and their data: An examination of farmers' reluctance to share their data through the lens of the laws impacting smart farming. NJAS-Wageningen Journal of Life Sciences, 90, 100301.

Wolfert, S., Ge, L., Verdouw, C., and Bogaardt, M. J. (2017). Big data in smart farming–a review. Agricultural Systems, 153, 69-80.

Wolfert, S., Ge, L., Verdouw, C., and Bogaardt, M. J. (2017). Big data in smart farming – A review. Agricultural Systems, 153, 69-80.

Woodard, J. D. (2016). Big data and Ag-Analytics: An open source, open data platform for agricultural, environmental finance, insurance, and risk. Agricultural Finance Review, 76(1), 15–26.

World Bank. (2019). Future of Food: Harnessing Digital Technologies to Improve Food System Outcomes. World Bank, Washington, DC.