Browse > Article
http://dx.doi.org/10.5573/ieie.2016.53.11.03

Design of 10 GbE Optical Communication System Using Multi Carrier Generation Module  

Kim, Hyung Hwan (Department of Electronic Engineering, Kwangwoon University)
Kang, Eun Kyun (Department of Information and Communication Engineering, Dongyang Mirae University)
Publication Information
Journal of the Institute of Electronics and Information Engineers / v.53, no.11, 2016 , pp. 3-8 More about this Journal
Abstract
In this paper, we design to generate 12.5 GHz spaced 256 number of multi-carrier generation module using 32 laser diodes. We modulate the generated multi-carrier generation module by 12.4 Gbps, and confirm the performance of optical channels passing through recirculating loop up to 1000km distance. An experimental result shows that the carrier away from the laser diode is significantly influence by noise effect.
Keywords
Fiber optics communications; Fiber optics components; high power RF amplifier;
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
연도 인용수 순위
1 Lam, Cedric F. "Fiber to the Home: Getting Beyond 10 Gb/s," Optics and Photonics News., Vol. 27.3, pp. 22-29, 2016.
2 Yamada, E., et al. "106 channel${\time}$ 10 Gbit/s, 640km DWDM transmission with 25 GHz spacing with supercontinuum multi-carrier source," Electronics Letters., Vol. 37.25, pp. 1, 2001.   DOI
3 Takara, Hidehiko. "Multiple optical carrier generation from a supercontinuum source," Optics and Photonics News., Vol. 13.3, pp. 48-51, 2002.
4 Manandhar, Dipen, et al. "25-GHz spaced spectrum-sliced WDM PON using 50-GHz AWGs," IEEE Photonics Technology Letters., Vol 27.13, pp. 1383-1386, 2015.   DOI
5 Li, Xinying, and Jianjun Yu. "W-band RoF transmission based on optical multi-carrier generation by cascading one directly-modulated DFB laser and one phase modulator," Optics Communications., Vol 345, pp. 80-85, 2015.   DOI
6 Fujiwara, Masamichi, et al. "Optical carrier supply module using flattened optical multicarrier generation based on sinusoidal amplitude and phase hybrid modulation," Journal of lightwave technology., Vol 21.11, pp. 2705-2714, 2003.   DOI
7 Cripps, Steve C. "RF power amplifiers for wireless communications," Artech House., 1999.
8 Healy, Tadhg, et al. "Multi-wavelength source using low drive-voltage amplitude modulators for optical communications," Optics express., Vol 15.6, pp. 2981-2986, 2007.   DOI
9 Eggleton, Benjamin J., et al. "Electrically tunable power efficient dispersion compensating fiber Bragg grating," IEEE Photonics Technology Letters., Vol 11.7, pp. 854-856, 1999.   DOI
10 Batsuren, Budsuren, et al. "Optical VSB filtering of 12.5-GHz spaced 64${\time}$12.4 Gb/s WDM channels using a pair of Fabry-Perot filters," Journal of the Optical Society of Korea., Vol. 17.1, pp. 63-67, 2013.   DOI
11 Seung-Jun Yang, Jaewoong Yeon, Hanho Lee. "High-Performance Low-Complexity Iterative BCH Decoder Architecture for 100 Gb/s Optical Communications," Journal of The Institute of Electronics Engineers of Korea Vol. 50(7), pp. 140-148, 2013.7.
12 Chae-Dong Lee, Woo-Seop Shin, Chan Gon Jo, Suk-Chan Kim. "Design and Implementation of the Integrated Communication System based on The Optical Network for The Naval Ship," Journal of the Institute of Electronics Engineers of Korea-TC, Vol. 47(8), pp. 91-98, 2010.8.
13 Kyung Hyun Park, Jung Kee Lee, Jung Hee Hahn, Ho Sung Cho, Dong Hoon Jang, Chul Soon Park "Effects of the external optical feedback on the DFB-LD modules for 2.5 Gbps optical communication system," Jounnal of the Korea institute of telematics and electronics-A, Vol. 33(7), pp. 1199-1212, 1996.
14 Sang-Heung Lee, Jin-Yeong Kang, ANDg-Ryeol Ryu. "Design of Multiplexer and Demultiplexer for Optical Communication System," The Institute of Electronics Engineers of Korea-IE, Vol. 38(4), pp. 14-20, 2001.