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dc.contributor.authorGenovés Guzmán, Borja 
dc.contributor.authorTalavante, Javier 
dc.contributor.authorFrómeta Fonseca, Dayrene 
dc.contributor.authorMir, Muhammad Sarmad
dc.contributor.authorGiustiniano, Domenico 
dc.contributor.authorObraczka, Katia 
dc.contributor.authorLoik, Michael E.
dc.contributor.authorChildress, Sylvie
dc.contributor.authorWong, Darryl G.
dc.date.accessioned2023-01-17T15:31:55Z
dc.date.available2023-01-17T15:31:55Z
dc.date.issued2023-05
dc.identifier.citation[1] T. Ojha, S. Misra, and N. S. Raghuwanshi, “Internet of Things for Agricultural Applications: The State of the Art,” IEEE Internet Things J., vol. 8, no. 14, pp. 10 973–10 997, 2021. [2] E. Darko, P. Heydarizadeh, B. Schoefs, and M. R. Sabzalian, “Photosynthesis under artificial light: the shift in primary and secondary metabolism,” Philosophical Transactions of the Royal Society B: Biological Sciences, vol. 369, no. 1640, p. 20130243, 2014. [3] Y. S. Chang, Y. Hsiung Chen, and S. K. Zhou, “A smart lighting system for greenhouses based on Narrowband-IoT communication,” in Proc. 13th International Microsystems, Packaging, Assembly and Circuits Technology Conference (IMPACT), 2018, pp. 275–278. [4] K. Horomia and H. Gordon-Smith, “2021 Global CEA Census Report,” 2021. [5] I. Draganov, “Foodtech startups and venture capital - Q1 2022,” 2022. [6] M. S. Mir, B. G. Guzman, A. Varshney, and D. Giustiniano, “PassiveLiFi: Rethinking LiFi for low-power and long range RF backscatter,” in Proc. of the 27th Annual International Conference on Mobile Computing and Networking, ser. MobiCom ’21. New York, NY, USA: ACM, 2021, p. 697–709. [7] M. Naseer, T. Persson, I. Righini, C. Stanghellini, H. Maessen, and M. J. Verheul, “Bio-economic evaluation of greenhouse designs for seasonal tomato production in Norway,” Biosystems Engineering, vol. 212, pp. 413–430, 2021. [8] P. S. Nobel, Physicochemical and Environmental Plant Physiology (Fourth Edition). San Diego, USA: Academic Press, 2009. [9] T. Nonomura, Y. Matsuda, K. Kakutani, Y. Takikawa, J. Kimbara, K. Osamura, and H. Toyoda, “Prevention of whitefly entry from a greenhouse entrance by furnishing an airflow-oriented pre-entrance room guarded with electric field screens,” Journal of Agricultural Science, vol. 6, 2014. [10] A. Galisteo, A. Varshney, and D. Giustiniano, “Two to tango: Hybrid light and backscatter networks for next billion devices,” in Proc. of the 18th International Conference on Mobile Systems, Applications, and Services, ser. MobiSys ’20. New York, NY, USA: ACM, 2020, p. 80–93. [11] J. S. Broadhead and P. Pawełczak, “Data freshness in mixed-memory intermittently-powered systems,” in 2021 IEEE International Symposium on Information Theory (ISIT), 2021, pp. 3361–3366. [12] J. Wang, L. Chang, S. Aggarwal, O. Abari, and S. Keshav, “Soil moisture sensing with commodity RFID systems,” in Proc. of the 18th International Conference on Mobile Systems, Applications, and Services, ser. MobiSys ’20. New York, NY, USA: ACM, 2020, p. 273–285. [13] S. Kurth, S. Voigt, R. Zichner, F. Roscher, P. Weigel, and T. Großmann, “Technologies for biodegradable wireless plant monitoring sensors,” in 2021 Smart Systems Integration (SSI), 2021, pp. 1–4. [14] J. Talavante, B. Genoves, and D. Giustiniano, “Multi-cell deployment for experimental research in visible light communication-based internet of things,” in Proc. of the Workshop on Internet of Lights, ser. IoL ’21. New York, NY, USA: ACM, 2021, p. 27–32. [15] C. Chen, D. A. Basnayaka, and H. Haas, “Downlink performance of optical attocell networks,” J. Lightw. Technol., vol. 34, no. 1, pp. 137– 156, 2016.es
dc.identifier.urihttps://hdl.handle.net/20.500.12761/1667
dc.description.abstractAs the world faces a changing climate, agriculture needs to develop more efficient and sustainable food production systems. Traditional farming methods consume considerable amounts of energy and are largely manually controlled, which leads to sub-optimal production. Greenhouses, which enable year-round crop growth, can play an important role in efficient food production. Leveraging the need for artificial light in greenhouses when the natural sunlight available is not sufficient, we envision that recent progress in Internet of Things (IoT) technology, together with novel Light-Fidelity (LiFi)-based methods have the potential to significantly reduce energy and resources used in food production. In this paper we describe our work towards sustainable and precision greenhouses by using LiFi-enabled IoT. Here we present a battery-free wireless network of IoT sensor nodes that exploit LiFi for both communication and power harvesting, while monitoring environmental conditions for optimal greenhouse operation and plant production. We highlight the research challenges and the way forward to integrate LiFi to monitor and control greenhouses, as well as a proof-of-concept LiFi-enabled IoT system for a real-world greenhouse.es
dc.description.sponsorshipEuropean Uniones
dc.description.sponsorshipSpanish Ministry of Economic Affairs and Digital Transformationes
dc.description.sponsorshipUniversidad Carlos III de Madrides
dc.language.isoenges
dc.publisherIEEEes
dc.titleTowards sustainable greenhouses using battery-free LiFi-enabled Internet of Thingses
dc.typemagazinees
dc.journal.titleIEEE Communications Magazinees
dc.type.hasVersionAMes
dc.rights.accessRightsrestricted accesses
dc.identifier.doi10.1109/MCOM.001.2200489
dc.relation.projectIDinfo:eu-repo/grantAgreement/EC/MSCA/814215es
dc.relation.projectNameENLIGHT’EMes
dc.relation.projectNameRISC-6Ges
dc.relation.projectNameUNICO-5G R&Des
dc.relation.projectNameSantander UC3M Chair of Excellence Programes
dc.subject.keywordBattery-freees
dc.subject.keywordIoTes
dc.subject.keywordLiFies
dc.subject.keywordPrecision-greenhouseses
dc.subject.keywordSustainable-greenhouseses
dc.description.refereedTRUEes
dc.description.statuspubes


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