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| Study on Color Rendering of Light Communication Source Based on Multi-Chromatic LED |
| XU Yi-qi, BAI Ting-zhu*, TANG Yi |
| MOE Key Laboratory of Photoelectronic Imaging Technology and System, School of Optoelectroniocs, Beijing Institute of Technology, Beijing 100081, China |
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Abstract Visible Light Communication (VLC) is an emerging technology which combines LED lighting engineering and optical communication technique. In this article, we aim at the problems of bad color rendering, low luminous efficacy and non-adjustable color temperature of white LED lighting communication source. We did some researches according to the multi-chromatic white LED communication theory. Meanwhile, we used the Gaussian distribution put forward by Yoshi as the spectral model of chromatic LED, and made use of the general color rendering index (Ra) which is recommended by CIE and the general color quality scale (Qa) recommended by National Institute of Standards and Technology (NIST) to evaluate the color rendering of light source. We adopted Genetic Algorithm to optimize single color temperature and adjustable color temperature scope 2 700 to 6 500 K based on principle that Ra and Qa are greater than 80 to optimize the best combination of spectra of adjustable color temperature light source. At last, according to the result of the experiment, we analyzed the relationship among the color rendering, luminous efficacy of radiation (LER) and adjustable color temperature of the light source. It turned out that tri-chromatic adjustable color temperature white LED’s peak wavelength combination which satisfies the best color rendering is 613 nm/541 nm/464 nm. Meanwhile, when the minimum of Ra and Qa are 81.2 and 81 respectively, it can meet the demand of lighting communication in the general situation. And the tetra-chromatic adjustable color temperature white LED’s peak wavelength combination which meets the best color rendering is 620 nm/562 nm/505 nm/449 nm. The minium of Ra and Qa are 96.7 and 92.2 at the same time. When in a spot which requires special lighting or higher communication rate, we should use tetra-chromatic LED white light as the lighting communication source. In the article, we have simulated the best spectral combination of LED. And it can provide some references for the design of visible communication light source used in the wide channels.
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Received: 2015-09-11
Accepted: 2016-03-06
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Corresponding Authors:
BAI Ting-zhu
E-mail: tzhubai@bit.edu.cn
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[1] CHEN Te,LIU Lu,HU Wei-wei(陈 特,刘 璐,胡薇薇). ZTE Communications(中兴通讯技术),2013,19(1):49.
[2] KANG Ye,KE Xi-zheng(亢 烨,柯熙政). Chinese Journal of Lasers(中国激光),2015,42(2):138.
[3] Chow Chi-wai,Yang Liu,Chien-Hung Yeh et al. Optics Communiction,2015,344:81.
[4] Luo Huajie,Zhang Shengdong,Jin Peng. 2011 International Conference on Electronics and Optoelectrons (ICEOE 2011),2011,V3:287.
[5] LI Ning, JIN Peng(李 宁,金 鹏). Semiconductor Optoelectronics(半导体光电),2015,36(1):28.
[6] JIN Yu-zhang,HAN Qiu-yi,ZHANG Shan-duan(金宇章,韩秋漪,张善端). China Illuminating Engineering Journal(照明工程学报),2015,26(2):54.
[7] YU Chun-yu,JIN Peng,ZHOU Qi-feng(喻春雨,金 鹏,周奇峰). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2015,35(5):1316.
[8] Ohno Y. Optical Engineering, 2005, 44(11): 111302.
[9] Davis W,Ohno Y. Opt. Engineering,2010,49(3):033602.
[10] General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China(中华人民共和国国家质量监督检验检疫总局). GB 50034—2013 Standard for Lighting Design of Buildings(GB 50034—2013建筑照明设计标准),2013. |
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