“Green” and energy-efficient wireless communication schemes have recently experienced rapid development and garnered much interest. One such scheme is visible light communication (VLC) which is being touted as one of the next generation wireless communication systems. VLC allows communication using multi-color channels that provide high data rates and illumination simultaneously. Even though VLC has many advantageous features compared with RF technologies, including visibility, ubiquitousness, high speed, high security, harmlessness for the human body and freedom of RF interference, it suffers from some problems on the receiver side, one of them being photo sensitivity dissimilarity of the receiver. The photo sensitivity characteristics of a VLC receiver such as Si photo-detector depend on the wavelength variation. The performance of the VLC receiver is not uniform towards all channel colors, but it is desirable for receivers to have the same performance on each color channel. In this paper, we propose a mitigation technique for reducing the performance variation of the receiver on multi-color channels. We show received power, SNR, BER, output current, and outage probability in our simulation for different color channels. Simulation results show that, the proposed scheme can reduce the performance variation of the VLC receiver on multi-color channels.
References
[1]
Kim, W-C; Bae, C-S; Jeon, S-Y; Pyun, S-Y; Cho, D-H. Efficient Resource Allocation for Rapid Link Recovery and Visibility in Visible-Light Local Area Networks. IEEE Trans. Consum. Electron 2010, 56, 524–531.
[2]
IEEE P802.15.7 Draft D4, Part 15.7: PHY and MAC Standard for Short-Range Wireless Optical Communication Using Visible Light, Available online: http://ieeexplore.ieee.org/servlet/opac?punumber=5658205 (accessed on 6 April 2011).
[3]
Chen, MG; Nicolas, D. Design of a Multi-Wvelength Network with Dynamic Channel Sharing. Proceedings of IEEE Global Telecommunications Conference, GLOBECOM’1994, San Francisco, CA, USA, December 1994; pp. 1920–1924.
[4]
Elgala, H; Raed, M; Haas, H. Indoor Broadcasting via White LEDs and OFDM. IEEE Trans. Consum. Electron 2009, 55, 1127–1134.
[5]
Kumar, N; Nuno, L; Spieez, M; Rui, AL. Visible Light Communication System Conception and VIDAS. IETE Technol. Rev 2008, 25, 359–367.
[6]
Li, X; Mardling, R; Armstrong, J. Channel Capacity of IM/DD Optical Communication Systems and of ACO-OFDM. Proceedings of IEEE International Conference on Communications (ICC’07), Glasgow, UK, 24–28 June 2007; pp. 2128–2133.
[7]
Elgala, H; Mesleh, R; Haas, H. An LED Model for Intensity-Modulated Optical Communication Systems. IEEE Photonic. Technol. Lett 2010, 22, 835–837.
[8]
Ding, D; Ke, X; Xu, L. An Optimal Lights Layout Scheme for Visible-Light Communication System. Proceedings of the 18th International Conference on Electronic Measurement and Instruments, ICEMI’2007, Xi’an, China, 16–18 August 2007.
[9]
Komine, T; Nakagawa, M. Fundamental Analysis for Visible Light Communication System Using LED Lights. IEEE Trans. Consum. Electron 2004, 50, 100–107.
[10]
Lee, IE; Sim, ML; Kung, FWL. Performance Enhancement of Outdoor Visible-Light Communication System Using Selective Combining Receiver. IET Optoelectron 2009, 3, 30–39.
[11]
Grubor, J; Randel, S; Langer, K; Walewski, J. Bandwidth Efficient Indoor Optical Wireless Communications with White Light Emitting Diode. Proceedings of the 6th International Symposium on Communication Systems, Networks and Digital Signal Processing, Graz, Austria, July 2008; pp. 165–169.
[12]
Kahn, JM; Barry, JR. Wireless Infrared Communications. Proc. IEEE 1997, 85, 265–298.
[13]
Hashemi, SK; Ghassemlooy, Z; Chao, L; Benhddou, D. Orthogonal Frequency Division Multiplexing for Indoor Optical Wireless Communications Using Visible Light LEDs. Proceedings of the 6th International Symposium on Communication Systems, Networks and Digital Signal Processing, Graz, Austria, July 2008; pp. 174–178.
[14]
Shaoji, N; Yong, L; Haggman, S-G. Outage Probability for GPRS over GSM Voice Services. Preceedings of IEEE VTS Vehicular Technology Conference (VTC 1999), Amsterdam, The Netherlands, September 1999; pp. 839–843.
[15]
Ni, S. GPRS Network Planning on the Existing GSM System. Proceedings of IEEE Global Telecommunications Conference. GLOBECOM’2000, San Francisco, CA, USA, November 2000; pp. 1432–1438.
