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Year 2020, Volume: 3 Issue: 3, 95 - 102, 31.12.2020

Abstract

References

  • [1] Khan, L. U. (2017). Visible light communication: applications, architecture, standardization and research challenges, Digital communications and networks, pp. 378–88.
  • [2] Şenyer, D. & Ünaldı, N. & Akan, Ö. B. (2016). Kablosuz yeşil haberleşmenin önemi ve görünür ışıkla haberleşmede led teknolojisi uygulamaları, Havacılık ve uzay teknolojileri dergisi, vol. 9, pp. 65-79.
  • [3] Shamsudheen, P. & Sureshkumar, E. & Chunkath, J. (2016). Performance analysis of visible light communication system for free space optical communication link, Procedia technology, vol. 24, p. 827 – 833.
  • [4] Kocharoen, P. “Visible light communication: importance and Thai preparations,” Procedia computer science, vol. 86, pp. 51–54, 2016.
  • [5] Haas, H. (2018). LiFi is a paradigm-shifting 5G technology, Reviews in physics, vol. 3, p. 26–31. [6] Blinowski, G. (2015). Security issues in visible light communication systems, IFAC-PapersOnLine, vol. 48, p. 234–239.
  • [7] Singha, V. & Patela, K. & Dalala, U. D. (2016). A 100mbps visible light communication system using optical wireless channel for indoor application based on composite white light generated using rgb leds,” Procedia computer science, vol. 93, p. 655–661.
  • [8] Ding, W. & Yang, F. & Yang, H. & Wanga, J. & Wang, X. & Zhang, X. & Song, J. (2015). A hybrid power line and visible light communication system for indoor hospital applications, Computers in industry, vol. 68, p. 170–178.
  • [9] Hoon Kim, J. & Yon Kang, S. & TaekLee, S. (2017) VLC-based location data transferal for smart devices, Optical switching and networking, vol. 23, p. 250–258.
  • [10] Goswami, P. & Shukla, M. K. (2017). Design of a li-fi transceiver, Wireless engineering and technology, vol. 8, p. 71-86.
  • [11] Nguyen, D. & Park, T. S. & Chae, Y. & Park, Y. (2019). Vlc/Occ hybrid optical wireless systems for versatile indoor applications, IEEE, vol. 7, p. 22371-22376.
  • [12] Yeh , C. & Chow, H. C. & Wei, W. Y. (2019). 1250 mbit/s ook wireless white-light vlc transmission based on phosphor laser diode, IEEE Photonics journal, vol. 11, p. 3.
  • [13] Aguirre, D. & Navarrete, R & Soto, I. & Gutierrez, S. (2017). Implementation of an emitting LED circuit in a Visible Light communications positioning system, 1st South American Colloquium on Visible Light Communications.
  • [14] Sandoval-Reyes, S. (2019). Image Transmission & Reception Using Visible Light, IEEE International Fall Meeting on Communications.
  • [15] Kodama, M. & Haruyama, S. (2019). Pulse Width Modulated Visible Light Communication using Digital Micro-mirror Device Projector for Voice Information, Guidance System 9th Annual Computing and Communication Workshop and Conference.
  • [16] Li, S. & Pandharipa, A. & Willems, F. M. J. (2017). Adaptive visible light communication LED receiver, Proceedings of IEEE Sensors.
  • [17] Doo Jeong, J. & Sang-Kyu L. & Il-Soon J. & Myung-Soon K. & Tae-Gyu K. & Jong-wha C. (2014). Novel Architecture for Efficient Implementation of Dimmable VPPM in VLC Lightings, ETRI Journal, vol. 36, p. 905-912.
  • [18] Mathias, L. C. & Melo, L. & Abrão, F. T. (2019). 3-D localization with multiple leds lamps in OFDM-VLC system, IEEE access, vol. 7, p. 6249-6261.
  • [19] Suzan, M. & Heba, F. & Aly, M. (2019). Power distribution and ber in indoor vlc with ppm based modulation schemes: a comparative study, Optical and quantum electronics, vol. 51, p. 257.
  • [20] Noh, J. & Lee, S. & Kim, J. & Ju, M. & Park, Y. (2015). A dimming controllable VPPM-based VLC system and its implementation, In Optics Communications, vol. 343, p. 34-37.
  • [21] Basha, M. & Sibley, M. J. & Mather, P. J. (2019). Design and implementation of a long range indoor vlc system using pwm, Annals of Emerging Technologies in Computing, vol. 3, p. 20-27.

Realization of Microprocessor Based Visible Light Communication

Year 2020, Volume: 3 Issue: 3, 95 - 102, 31.12.2020

Abstract

The increase in data and number of users used in wireless communication is the biggest cause of the bottleneck in today's wireless communication environment. In particular, the rise in the number of devices connected to the Internet is one of the reasons. The current Radio Frequency spectrum is insufficient to respond to these needs. Visible light communication, although not an alternative to all radio frequency communication, can greatly relieve the communication load, especially in short-distance building communications. The LED lamps currently used for illumination are the transmitting elements to be used in visible light communication. It is an excellent alternative in terms of energy efficiency as it is low in installation rate and it is used as both lighting and communication element. Especially in the field of green communication, radio frequency communication, health hazards, the use of CO2 gas largely to reduce electricity consumption significantly, to provide an efficient communication alternative is not to be among the future communication technologies. The apparent frequency of light (430-770 THz) is larger than the current radio frequency band (3 kHz-300GHz) it also much faster than RF. Low frequency band range problem in radio frequency can be solved by visible light communication. Furthermore, the fact that the visible light cannot get out of the closed space seems to be disadvantageous according to the intended use, but also provides extra security in the application areas.

References

  • [1] Khan, L. U. (2017). Visible light communication: applications, architecture, standardization and research challenges, Digital communications and networks, pp. 378–88.
  • [2] Şenyer, D. & Ünaldı, N. & Akan, Ö. B. (2016). Kablosuz yeşil haberleşmenin önemi ve görünür ışıkla haberleşmede led teknolojisi uygulamaları, Havacılık ve uzay teknolojileri dergisi, vol. 9, pp. 65-79.
  • [3] Shamsudheen, P. & Sureshkumar, E. & Chunkath, J. (2016). Performance analysis of visible light communication system for free space optical communication link, Procedia technology, vol. 24, p. 827 – 833.
  • [4] Kocharoen, P. “Visible light communication: importance and Thai preparations,” Procedia computer science, vol. 86, pp. 51–54, 2016.
  • [5] Haas, H. (2018). LiFi is a paradigm-shifting 5G technology, Reviews in physics, vol. 3, p. 26–31. [6] Blinowski, G. (2015). Security issues in visible light communication systems, IFAC-PapersOnLine, vol. 48, p. 234–239.
  • [7] Singha, V. & Patela, K. & Dalala, U. D. (2016). A 100mbps visible light communication system using optical wireless channel for indoor application based on composite white light generated using rgb leds,” Procedia computer science, vol. 93, p. 655–661.
  • [8] Ding, W. & Yang, F. & Yang, H. & Wanga, J. & Wang, X. & Zhang, X. & Song, J. (2015). A hybrid power line and visible light communication system for indoor hospital applications, Computers in industry, vol. 68, p. 170–178.
  • [9] Hoon Kim, J. & Yon Kang, S. & TaekLee, S. (2017) VLC-based location data transferal for smart devices, Optical switching and networking, vol. 23, p. 250–258.
  • [10] Goswami, P. & Shukla, M. K. (2017). Design of a li-fi transceiver, Wireless engineering and technology, vol. 8, p. 71-86.
  • [11] Nguyen, D. & Park, T. S. & Chae, Y. & Park, Y. (2019). Vlc/Occ hybrid optical wireless systems for versatile indoor applications, IEEE, vol. 7, p. 22371-22376.
  • [12] Yeh , C. & Chow, H. C. & Wei, W. Y. (2019). 1250 mbit/s ook wireless white-light vlc transmission based on phosphor laser diode, IEEE Photonics journal, vol. 11, p. 3.
  • [13] Aguirre, D. & Navarrete, R & Soto, I. & Gutierrez, S. (2017). Implementation of an emitting LED circuit in a Visible Light communications positioning system, 1st South American Colloquium on Visible Light Communications.
  • [14] Sandoval-Reyes, S. (2019). Image Transmission & Reception Using Visible Light, IEEE International Fall Meeting on Communications.
  • [15] Kodama, M. & Haruyama, S. (2019). Pulse Width Modulated Visible Light Communication using Digital Micro-mirror Device Projector for Voice Information, Guidance System 9th Annual Computing and Communication Workshop and Conference.
  • [16] Li, S. & Pandharipa, A. & Willems, F. M. J. (2017). Adaptive visible light communication LED receiver, Proceedings of IEEE Sensors.
  • [17] Doo Jeong, J. & Sang-Kyu L. & Il-Soon J. & Myung-Soon K. & Tae-Gyu K. & Jong-wha C. (2014). Novel Architecture for Efficient Implementation of Dimmable VPPM in VLC Lightings, ETRI Journal, vol. 36, p. 905-912.
  • [18] Mathias, L. C. & Melo, L. & Abrão, F. T. (2019). 3-D localization with multiple leds lamps in OFDM-VLC system, IEEE access, vol. 7, p. 6249-6261.
  • [19] Suzan, M. & Heba, F. & Aly, M. (2019). Power distribution and ber in indoor vlc with ppm based modulation schemes: a comparative study, Optical and quantum electronics, vol. 51, p. 257.
  • [20] Noh, J. & Lee, S. & Kim, J. & Ju, M. & Park, Y. (2015). A dimming controllable VPPM-based VLC system and its implementation, In Optics Communications, vol. 343, p. 34-37.
  • [21] Basha, M. & Sibley, M. J. & Mather, P. J. (2019). Design and implementation of a long range indoor vlc system using pwm, Annals of Emerging Technologies in Computing, vol. 3, p. 20-27.
There are 20 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Original Research Articles
Authors

Özkan Sezer 0000-0001-9194-9200

Nihat Daldal 0000-0001-7345-2727

İbrahim Yücedağ 0000-0003-2975-7392

Publication Date December 31, 2020
Acceptance Date December 27, 2020
Published in Issue Year 2020 Volume: 3 Issue: 3

Cite

APA Sezer, Ö., Daldal, N., & Yücedağ, İ. (2020). Realization of Microprocessor Based Visible Light Communication. Scientific Journal of Mehmet Akif Ersoy University, 3(3), 95-102.