Urban Agriculture through IoT-based Resilient Hydroponic Farming – A Machine Learning Approach

Authors

  • Sushant Kumar Pattnaik School of Electronics Engineering, KIIT University, Bhubaneswar, India
  • Soumya Ranjan Samal Faculty of Telecommunications, Technical University of Sofia, Sofia, Bulgaria, Silicon University, Bhubaneswar, India
  • Shuvabrata Bandopadhaya Banasthali Vidyapith, Rajasthan, India
  • Debi Prasad Pradhan Silicon University, Bhubaneswar, India
  • Jitendra Kumar Das School of Electronics Engineering, KIIT University, Bhubaneswar, India
  • Antoni Ivanov Faculty of Telecommunications, Technical University of Sofia, Sofia, Bulgaria
  • Vladmir Poulkov Faculty of Telecommunications, Technical University of Sofia, Sofia, Bulgaria
  • Albena Mihovska Research and Development and Innovation Consortium, Sofia, Bulgaira

DOI:

https://doi.org/10.13052/jmm1550-4646.2163

Keywords:

Automated-Soilless Culture, Hydroponics, Internet of Things, Machine Learning, Nutrient Film Technique, Smart Agriculture

Abstract

Procuring resilience, resource efficiency, productivity, pest and malady control in agrarian production is imperative when climate change poses a threat. In recent years, hydroponics is considered as an emerging farming technique and is popular in urban areas due to its minimal water use and ability to grow plants without soil. In the Nutrient Film Technique (NFT) based hydroponics system, plants are cultivated by using water content nutrient solutions. Integration of Internet of Things (IoT) technology to NFT based hydroponic systems, many advancements such as minimizing water usage, real-time plant growth monitoring, efficient nutrient diffusion and reduction in human efforts can be achieved. In this work, an IoT based smart hydroponics system using NFT is proposed. Key components of the proposed solution include sensor networks for data acquisition, a robust Machine Learning (ML) framework for data analysis and prediction, as well as actuators for automated control of environmental conditions. The system monitors different real-time environmental parameters and the status of the plant’s growth and controls the nutritional value of water in an automated and cost-effective way. A Support Vector Machine (SVM) algorithm is used to predict the pH values with an accuracy of 89.6%, surpassing the Decision Tree (DT) and Random Forest Regression methods.

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Author Biographies

Sushant Kumar Pattnaik, School of Electronics Engineering, KIIT University, Bhubaneswar, India

Sushant Kumar Pattnaik received his M. Tech degree in Electronics and Communication from NIT, Rourkela in 2010. He received his B. E. (Electrical and Electronics Engineering) from Berhampur University in 2001. He is now working as Assistant Professor, Electronics & Communication Engineering, Silicon Institute of Technology, Bhubaneswar. He has got more than 11 years teaching and research experience in the field of VLSI Design, IoT & Embedded Systems. He was having 3 years of Industrial Experience in the field of power electronics (UPS Manufacturing Company) and 3 years of Research experience in the field of VLSI & Embedded Systems at NIT Rourkela.

Soumya Ranjan Samal, Faculty of Telecommunications, Technical University of Sofia, Sofia, Bulgaria, Silicon University, Bhubaneswar, India

Soumya Ranjan Samal received his Ph.D. degree in Communication Networks, Faculty of Telecommunications from Technical University of Sofia at Sofia, Bulgaria. He received his B.Tech. degree in Electronics & Instrumentation Engineering from Biju Patnaik University of Technology, India in 2004. Soumya then went on to pursue his M.E. in Computer Science & Engineering from the Utkal University of Bhubaneswar, India in 2009. He, as an Associate Professor in Silicon University, India has acquired a solid experience about 18 years of teaching in Communication Engineering. Soumya also worked as a Project Engineer in Indian Institute of Technology, Bombay, India in 2005. His research area of interest includes, Interference Management in 5G cellular network, Green Communication movement to develop Energy Efficient solutions through antenna parameters and IoT.

Shuvabrata Bandopadhaya, Banasthali Vidyapith, Rajasthan, India

Shuvabrata Bandopadhaya is currently working as an associate professor in the department of electronics at the School of Physical Sciences, Banasthali Vidyapith, Rajasthan. He has received his M.Tech. and Ph.D. degrees in communication systems specialisation from KIIT University, Bhubaneswar, India. He has nearly 20 years of experience in teaching and research at various reputed institutes and universities in India. His areas of research interest include wireless communication and networks, Internet of Things, and AI.

Debi Prasad Pradhan, Silicon University, Bhubaneswar, India

Debi Prasad Pradhan is currently working as a Technical Assistant at the IoT Lab and Industrial Control Lab at Silicon University, Bhubaneswar. He holds an M.Tech. degree in Electronics and Communication (2018) from CET Bhubaneswar, Odisha, and a B.Tech. in Electronics and Communication (2015). With over 15 years of academic and mentoring experience at Silicon University, India. His research interests include AI-integrated wireless systems for IoT, optical sensor network design, and emerging technologies in industrial control, particularly PLC and DCS systems for Industry 5.0.

Jitendra Kumar Das, School of Electronics Engineering, KIIT University, Bhubaneswar, India

Jitendra Kumar Das has received his Ph. D. degree in Electronics and Communication from NIT, Rourkela in 2011. He received his B. E. (Electronics and Telecommunication) from Utkal University in 1992. He received his M. Tech in EE (Electronics System and Communication) from NIT, Rourkela in 2004. He is now working as Associate Professor, School of Electronics Engineering, KIIT Deemed to be University, Bhubaneswar. He successfully guided 3 Ph. D. student and 20 MTECH students. He has got more than 15 years teaching experience in the field of VLSI Design, Embedded Systems and Signal Processing.

Antoni Ivanov, Faculty of Telecommunications, Technical University of Sofia, Sofia, Bulgaria

Antoni Ivanov received the PhD degree in Communication Networks and Systems from the Technical University of Sofia (TUS), Bulgaria. He holds a Master degree in Innovative Communication Technologies and Entrepreneurship from TUS, and Aalborg University, Denmark in 2016. He is currently a Postdoctoral researcher at the “Teleinfrastructure Lab”, Faculty of Telecommunications, TUS. His research interests include cognitive radio networks, adaptive algorithms for dynamic spectrum access, deep learning-based solutions for cognitive radio applications, volumetric spectrum occupancy assessment, and graph signal processing for resource allocation in current and future wireless networks.

Vladmir Poulkov, Faculty of Telecommunications, Technical University of Sofia, Sofia, Bulgaria

Vladimir Poulkov has received the M.Sc. and Ph.D. degrees from the Technical University of Sofia (TUS), Sofia, Bulgaria. He has more than 30 years of teaching, research, and industrial experience in the field of Telecommunications. He has successfully managed numerous industrial, engineering, R&D and educational projects. He has been Dean of the Faculty of the Telecommunications at TUS and Vice Chairman of the General Assembly of the European Telecommunications Standardization Institute (ETSI). Currently the Head of the “Teleinfrastructure” R&D Laboratory at TUS and Chairman of Cluster for Digital Transformation and Innovation, Bulgaria. He is Fellow of the European Alliance for Innovation; Senior IEEE Member. He has authored many scientific publications and is tutoring BSc, MSc, and PhD courses in the field of Information Transmission Theory and Wireless Access Networks.

Albena Mihovska, Research and Development and Innovation Consortium, Sofia, Bulgaira

Albena Mihovska is currently a distinguished Senior Academic Research Professional with a versatile role in the realm of technology and research. She is the CTO with SmartAvatar B.V., where her visionary leadership drives innovation and fosters the creation of cutting-edge solutions. Concurrently, she holds the position of Research Director with CGC, where she actively shapes the future of telecommunications. Her influence extends to her role as WG3 Vice Chair with one6G and her dedicated involvement as a Board Member with EUROMERSIVE. In a testament to her leadership and expertise, she was elected as the President of the INFORMS Telecommunications and Network Analytics Cluster for the year 2023. Previously, within the CGC Research Group, BTECH, she leads the 6G Knowledge Research Lab and acts as the Technical Manager for multiple EU-funded projects in Beyond 5G networks coordinated by Aarhus University. Her extensive and impactful contributions are mirrored by her impressive portfolio of more than 150 publications. As a member of both IEEE and INFORMS, she underscores her unwavering dedication to advancing knowledge and technology in her field.

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Published

2025-12-19

How to Cite

Pattnaik, S. K. ., Samal, S. R. ., Bandopadhaya, S. ., Pradhan, D. P. ., Das, J. K. ., Ivanov, A. ., Poulkov, V. ., & Mihovska, A. . (2025). Urban Agriculture through IoT-based Resilient Hydroponic Farming – A Machine Learning Approach. Journal of Mobile Multimedia, 21(06), 1049–1070. https://doi.org/10.13052/jmm1550-4646.2163

Issue

2025: Vol 21 Iss 6

Section

Articles

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