Sistem Kendali Irigasi Otomatis Pada Pertanian Hidroponik Vertikal Berbasis Internet Of Things (IoT)
DOI:
https://doi.org/10.52158/jasens.v4i2.915
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I will put the dimension here
Keywords:
Internet of Things (IoT), Sensor Ultrasonic, Sensor Waterflow, Vertikal Farming
Abstract
Vertical hydroponic farming is an innovative method of cultivating plants efficiently in urban environments. However, the main challenge in managing hydroponic farming is monitoring and regulating appropriate water levels for plants, especially on a large scale or in remote locations. To overcome this problem, an automatic irrigation control system based on the Internet of Things (IoT) is a potential solution. This study proposes the development of an automatic irrigation control system integrated with IoT technology to increase the efficiency and productivity of vertical hydroponic farming. This system consists of ultrasonic sensors and water flow sensors which are connected directly to a microcontroller, which is then connected to the IoT platform via a wireless network. Data obtained from these sensors is sent to the IoT platform for processing and analysis in real-time.
References
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[22] A. S. Pascaris, C. Schelly, L. Burnham, and J. M. Pearce, Integrating solar energy with agriculture: Industry perspectives on the market, community, and socio-political dimensions of agrivoltaics, Energy Research & Social Science, Vol. 75, p. 102023, 2021. https://doi.org/10.1016/j.erss.2021.102023.
[23] M.P.M. Meuwissen, P.H. Feindt, T. Slijper, A. Spiegel, R. Finger, Y. de Mey, W. Paas, K.J.A.M. Termeer, P.M. Poortvliet, M. Peneva, J. Urquhart, M. Vigani, J.E. Black, P. Nicholas-Davies, D. Maye, F. Appel, F. Heinrich, A. Balmann, J. Bijttebier, I. Coopmans, E. Wauters, E. Mathijs, H. Hansson, C.J. Lagerkvist, J. Rommel, G. Manevska-Tasevska, F. Accatino, C. Pineau, B. Soriano, I. Bardaji, S. Severini, S. Senni, C. Zinnanti, C. Gavrilescu, I.S. Bruma, K.M. Dobay, D. Matei, L. Tanasa, D.M. Voicilas, K. Zawalińska, P. Gradziuk, V. Krupin, A. Martikainen, H. Herrera, P. Reidsma, Impact of Covid-19 on farming systems in Europe through the lens of resilience thinking, Agricultural Systems, Vol. 191, p. 103152, 2021. https://doi.org/10.1016/j.agsy.2021.103152.
[24] M. S. Gumisiriza, P. Ndakidemi, A. Nalunga, E. R. Mbega, Building sustainable societies through vertical soilless farming: A cost-effectiveness analysis on a small-scale non-greenhouse hydroponic system, Sustainable Cities and Society, Vol. 83, p. 103923, 2022, https://doi.org/10.1016/j.scs.2022.103923.
[25] M. S. Gumisiriza, J. M.L. Kabirizi, M. Mugerwa, P. A. Ndakidemi, E. R. Mbega, Can soilless farming feed urban East Africa? An assessment of the benefits and challenges of hydroponics in Uganda and Tanzania, Environmental Challenges, p. 100413, Vol. 6, 2022, https://doi.org/10.1016/j.envc.2021.100413.
[26] V. Mamatha, J.C. Kavitha, Machine learning based crop growth management in greenhouse environment using hydroponics farming techniques, Measurement: Sensors, Vol. 25, p. 100665, 2023, https://doi.org/10.1016/j.measen.2023.100665.
[27] P. Chen, H. Kim, L. R. Thatcher, J. M. Hamilton, M. L. Alva, Z. Zhou, P. B. Brown, Maximizing nutrient recovery from aquaponics wastewater with autotrophic or heterotrophic management strategies, Bioresource Technology Reports, Vol. 21, p. 101360, 2023, https://doi.org/10.1016/j.biteb.2023.101360.
[28] F. Septiarini, T. Dewi, and Rusdianasari, Design of a solar-powered mobile manipulator using fuzzy logic controller of agriculture application, International Journal of Computational Vision and Robotics, Vol. 12, No. 5, pp 506–531, 2022. https://doi.org/10.1504/IJCVR.2022.
[2] Peraturan Presiden Republik Indonesia, Nomor 22, Tentang Rencana Umum Energi Nasional, Tahun 2017 (Indonesian).
[3] Outlook Energi Indonesia 2018, Badan Pengkajian dan Penerapan Teknologi, 2018 (Indonesian).
[4] IRENA, Renewable Energy Prospects: Indonesia, a REmap analysis, International Renewable Energy Agency (IRENA), Abu Dhabi, 2017, www.irena.org/remap
[5] R. B. Yuliandi, T. Dewi, and Rusdianasari, “Comparison of Blade Dimension Design of a Vertical Wind Turbine Applied in Low Wind Speed,” In proceeding of E3S Web of Conferences EDP Sciences, Vol. 68, p. 01001, 2018.
[6] A. T. Wardhana, A. Taqwa and T. Dewi, “Design of Mini Horizontal Wind Turbine for Low Wind Speed Area,” In Proceeding of Journal of Physics: Conference Series Vol. 347, No. 1, p. 01202, 2019.
[7] Sarwono, T. Dewi, and RD Kusumanto, "Geographical Location Effects on PV Panel Output - Comparison Between Highland and Lowland Installation in South Sumatra, Indonesia," Technology Reports of Kansai University, Vol. 63, No. 02, pp. 7229–7243, 2021. ISSN: 04532198.
[8] K. Junaedi, T. Dewi, and M. S. Yusi, "The Potential Overview of PV System Installation at the Quarry Open Pit Mine PT. Bukit Asam, Tbk Tanjung Enim," Kinetik: Game Technology, Information System, Computer Network, Computing, Electronics, and Control, Vol. 6, No. 1, pp. 41–50, 2021. https://doi.org/10.22219/kinetik.v6i1.1148.
[9] S. Nurjanah, T. Dewi, and Rusdianasari (2021). Dusting and Soiling Effect on PV Panel Performance: Case Study Open-pit Mining in South Sumatra, Indonesia. Paper presented at the Proceedings of 2021 International Conference on Electrical and Information Technology (IEIT), 251-256.
[10] Indrayani, Y. Dinata, T. Dewi. A Study of Archimedes Screw Turbine Scheme of Pico-Hydro Power Plant Using the Utilized Irrigation Water, Technology Reports of Kansai University, Vol. 64, No. 6, pp. 8075-8086, 2022.
[11] Dewi, T., P. Risma, Y. Oktarina, M.T. Roseno, H.M. Yudha, A. S. Handayani, and Y. Wijanarko, "A Survey on Solar Cell; The Role of Solar Cell in Robotics and Robotic Application in Solar Cell industry," in Proceeding Forum in Research, Science, and Technology (FIRST), 2016. Retrieved from http://eprints.polsri.ac.id/3576/3/C4.pdf.
[12] C. N. L. Dos Santos, Agrivoltaic system: a possible synergy between agriculture and solar energy, MSc Thesis, Dept. of Energy Tech., KTH, School of Industrial Engineering Management, 2020.
[13] S. Kim and S. Kim, Performance Estimation Modeling via Machine Learning of an Agrophotovoltaic System in South Korea, Energies, Vol. 14, No 20, pp. 6274, 2021. https://doi.org/10.3390/en14206724.
[14] S. Amaducci, X. Yin, and M. Colauzzi, Agrivoltaic systems to optimize land use for electric energy production, Applied Energy, Vol. 220, pp. 545–561, 2018. https://doi.org/10.1016/j.apenergy.2018.03.081
[15] P. E. Campana, B. Stridh, S. Armaducci, and M. Colauzzi, Optimisation of vertically mounted agrivoltaic systems, Journal of Cleaner Production, Vol. 325, pp. 129091, 2021. https://doi.org/10.1016/j.jclepro.2021.129091.
[16] A. Feuerbacher, M. Laub, P. Högy, C. Lippert, L. Pataczek, S. Schindele, C. Wieck, and S. Zikeli, An analytical framework to estimate the economics and adoption potential of dual land-use systems: The case of agrivoltaics, Agricultural Systems, Vol. 192, p. 103193, 2021. https://doi.org/10.1016/j.agsy.2021.103193
[17] S. Gorjian, E. Bousi, Ö. E. Özdemir, M. Trommsdorff, N. M. Kumar, A. Anand, K. Kant, and S. S. Chopra, Progress and challenges of crop production and electricity generation in agrivoltaic systems using semi-transparent photovoltaic technology, Renewable and Sustainable Energy Reviews, Vol. 158, p. 112126, 2022. https://doi.org/10.1016/j.rser.2022.112126.
[18] M. Alam, T. Dewi, and Rusdianasari, "Performance Optimization of Solar Powered Pump for Irrigation in Tanjung Raja, Indonesia," 2022 International Conference on Electrical and Information Technology (IEIT), Malang, Indonesia, 2022, pp. 196–201, doi: 10.1109/IEIT56384.2022.9967873.
[19] Mases, Y., Dewi, T., & Rusdianasari (2021). Solar Radiation Effect on Solar Powered Pump Performance of an Automatic Sprinkler System. Paper presented at the Proceedings of 2021 International Conference on Electrical and Information Technology (IEIT), 246-250.
[20] P. P. Putra, T. Dewi, Rusdianasari, "MPPT Implementation for Solar-powered Watering System Performance Enhancement," Technology Reports of Kansai University, Vol. 63, No. 01, pp. 6919–6931, 2021. ISSN: 04532198.
[21] E. V. Novaldo, T. Dewi and Rusdianasari, "Solar Energy as an Alternative Energy Source in Hydroponic Agriculture: A Pilot Study," 2022 International Conference on Electrical and Information Technology (IEIT), Malang, Indonesia, 2022, pp. 202–205, doi: 10.1109/IEIT56384.2022.9967806.
[22] A. S. Pascaris, C. Schelly, L. Burnham, and J. M. Pearce, Integrating solar energy with agriculture: Industry perspectives on the market, community, and socio-political dimensions of agrivoltaics, Energy Research & Social Science, Vol. 75, p. 102023, 2021. https://doi.org/10.1016/j.erss.2021.102023.
[23] M.P.M. Meuwissen, P.H. Feindt, T. Slijper, A. Spiegel, R. Finger, Y. de Mey, W. Paas, K.J.A.M. Termeer, P.M. Poortvliet, M. Peneva, J. Urquhart, M. Vigani, J.E. Black, P. Nicholas-Davies, D. Maye, F. Appel, F. Heinrich, A. Balmann, J. Bijttebier, I. Coopmans, E. Wauters, E. Mathijs, H. Hansson, C.J. Lagerkvist, J. Rommel, G. Manevska-Tasevska, F. Accatino, C. Pineau, B. Soriano, I. Bardaji, S. Severini, S. Senni, C. Zinnanti, C. Gavrilescu, I.S. Bruma, K.M. Dobay, D. Matei, L. Tanasa, D.M. Voicilas, K. Zawalińska, P. Gradziuk, V. Krupin, A. Martikainen, H. Herrera, P. Reidsma, Impact of Covid-19 on farming systems in Europe through the lens of resilience thinking, Agricultural Systems, Vol. 191, p. 103152, 2021. https://doi.org/10.1016/j.agsy.2021.103152.
[24] M. S. Gumisiriza, P. Ndakidemi, A. Nalunga, E. R. Mbega, Building sustainable societies through vertical soilless farming: A cost-effectiveness analysis on a small-scale non-greenhouse hydroponic system, Sustainable Cities and Society, Vol. 83, p. 103923, 2022, https://doi.org/10.1016/j.scs.2022.103923.
[25] M. S. Gumisiriza, J. M.L. Kabirizi, M. Mugerwa, P. A. Ndakidemi, E. R. Mbega, Can soilless farming feed urban East Africa? An assessment of the benefits and challenges of hydroponics in Uganda and Tanzania, Environmental Challenges, p. 100413, Vol. 6, 2022, https://doi.org/10.1016/j.envc.2021.100413.
[26] V. Mamatha, J.C. Kavitha, Machine learning based crop growth management in greenhouse environment using hydroponics farming techniques, Measurement: Sensors, Vol. 25, p. 100665, 2023, https://doi.org/10.1016/j.measen.2023.100665.
[27] P. Chen, H. Kim, L. R. Thatcher, J. M. Hamilton, M. L. Alva, Z. Zhou, P. B. Brown, Maximizing nutrient recovery from aquaponics wastewater with autotrophic or heterotrophic management strategies, Bioresource Technology Reports, Vol. 21, p. 101360, 2023, https://doi.org/10.1016/j.biteb.2023.101360.
[28] F. Septiarini, T. Dewi, and Rusdianasari, Design of a solar-powered mobile manipulator using fuzzy logic controller of agriculture application, International Journal of Computational Vision and Robotics, Vol. 12, No. 5, pp 506–531, 2022. https://doi.org/10.1504/IJCVR.2022.
Published
2023-12-31
How to Cite
Permata Sari, D., Dewi Permata sari, RD. Kusumanto, & Mardiyansah. (2023). Sistem Kendali Irigasi Otomatis Pada Pertanian Hidroponik Vertikal Berbasis Internet Of Things (IoT). Journal of Applied Smart Electrical Network and Systems, 4(2), 60-67. https://doi.org/10.52158/jasens.v4i2.915
Section
Articles
Copyright (c) 2024 Dewi Permata Sari, Dewi Permata sari, RD. Kusumanto, Mardiyansah
This work is licensed under a Creative Commons Attribution 4.0 International License.
