[1] [1] Yuanquan Wang, Yiguang Wang, Chi Nan, et al.. Demonstration of 575-Mb/s downlink and 225-Mb/s uplink bi-directional SCM-WDM visible light communication using RGB-LED and phosphor-based LED [J]. Opt Express, 2013, 21(1): 1203-1208.

[2] [2] H Minh, D O′Brien, G Faulkner, et al.. 80 Mbit/s visible light communications using pre-equalized white LED[C]. European Conference Optical communication, 2008. 1-2.

[3] [3] H Le Minh, D O′Dominic. 100-Mb/s NRZ visible light communications using a post equalized white LED [J]. IEEE Photon Technol Lett, 2009, 21(15): 1063-1065.

[4] [4] Li Rongling, Shang Huiliang, Lei Yu, et al.. Research of key enabling technologies for high-speed visible-light communication [J]. Laser & Optoelectronics Progress, 2013, 50(5): 050003.

[5] [5] R Mesleh, H Elgala, H Haas. On the performance of different OFDM based optical wireless communication systems [J]. J Opt Commun Netw, 2011, 3(8): 620-628.

[6] [6] J Grubor, S Randel, K D Langer. Broadband information broadcasting using LED-based interior lighting [J]. IEEE J Lightwave Technol, 2008, 26(24): 3883-3892.

[7] [7] Ma Xiao, Li Ping. Coded modulation using superimposed binary codes [J]. IEEE Transaction on Information Theory, 2004, 50(12):3331-3343.

[8] [8] Li Ping, Lihai Liu, Wu Keying. Interleave division multiple access [J]. IEEE Transactions on Wireless Communication, 2006, 5(4): 938-947.

[9] [9] Zhao Guhao, Zhao Shanghong, Meng Wen, et al.. Analysis of free space optical multiple input multiple output communication based on intensity superposition coding at different modulations [J]. Acta Optica Sinica, 2012, 32(2): 0206001.

[10] [10] Zhao Guhao, Zhao Shanghong, Li Yongjun, et al.. Free space optical multiple-input multiple-output communication based on intensity superposition code [J]. Acta Optica Sinica, 2011, 31(7): 0706002.

[11] [11] Hu Hao, Wang Hongxing, Xu Jianwu, et al.. Bit interleaved product coded pulse position modulation with iterative demodulation for free-space optical communication [J]. Acta Optica Sinica, 2011, 31(8): 0806004.

[12] [12] Fu Hongshuang, Zhu Yijun. Analysis of the correlation of optical multiple-input multiple-output channel using white LED lighting in indoor line of sight environments [J]. Acta Optica Sinica, 2013, 33(9): 0906002.

[13] [13] Li Xia, J Vucic, V Jungnickek. On the capacity of intensity-modulated direct-detection systems and the information rate of ACO-OFDM for indoor optical wireless applications [J]. IEEE Transactions on Communication, 2012, 60(3): 799-809.

[14] [14] D Lee, K Choi. K-D Kim, et al.. Visible light wireless communications based on predistorted OFDM [J]. Opt Commun, 2012, 285(7): 1767-1770.

[15] [15] I E Lee, M L Sim, F W L Kung. Performance enhancement of outdoor visible light communication system using selective combining receiver[J]. The Institution of Engineering and Technology Optoelectron, 2009, 3(1): 30-39.

[16] [16] T Komine, M Nakagawa. Fundamental analysis for visible light communications system using LED lights [J]. IEEE Transactions on Consumer Electronics, 2004, 50(1): 100-107.

[17] [17] J M Kahn, J R Barry. Wireless infrared communications [J]. Proceedings of IEEE, 1997, 85(2): 265-298.

[18] [18] R Mesleh, H Elgala, H Haas. LED nonlinearity mitigation techniques in optical wireless OFDM communication systems [J]. J Opt Commun Netw, 2012, 4(11): 865-875.

[19] [19] X X Ma, K Lee, K Lee. Appropriate modulation scheme for visible light communication systems considering illumination [J]. Electron Lett, 2012, 48(18): 1137-1139.

[20] [20] J Tong, P Li, X Ma. Superposition coding with peak-power limitation [C]. IEEE International Conference on Communications, 2006, 4: 1718-1723.

[21] [21] J Vucic, C Kottke, S Nerreter. 513 Mbit/s visible light communications link based on DMT-modulation of a white LED [J]. IEEE J Lightwave Technol, 2010, 28(24): 3512-3518.

[22] [22] H Elgala, R Mesleh, H Haas, et al.. OFDM visible light wireless communication based on white LEDs [C]. IEEE Vehicular Technology Conference, 2007. 2185-2189.

[23] [23] H Wu, P Ling, A Perotti. User-specific chip-level interleaver design for IDMA systems [J]. Electron Lett, 2012, 42(4): 233-234.