Optimization of Hybrid Raman-Brillouin-EDF Amplification Fiber Laser in Long Distance FBG Sensor System

被引:0
|
作者
Noura, A. [1 ]
Mamdoohi, G. [1 ]
Yaacob, M. H. [1 ]
Bakar, M. H. A. [1 ]
Anas, S. B. A. [1 ]
机构
[1] Univ Putra Malaysia, Fac Engn, Wireless & Photon Networks Res Ctr Excellence WiP, Dept Comp & Commun Syst Engn, Upm Serdang 43400, Selangor, Malaysia
来源
2014 IEEE 5TH INTERNATIONAL CONFERENCE ON PHOTONICS (ICP) | 2014年
关键词
FBG sensor; Raman amplification; Fiber optic sensor; Erbium doped fiber; long distance sensor; DOPED FIBER;
D O I
暂无
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
We present a hybrid Raman-Brillouin-Erbium Doped Fiber (EDF) amplification based Fiber Bragg Grating (FBG) sensor system capable of transmitting over long reach Single Mode Fiber (SMF). The performance of output spectra has been optimized and realized by the best effective placement of EDF and Raman pump power. An optimized combination of Raman, Brillouin and Erbium gain brings forth an optical signal-to-noise ratio of 16.34 dB in 100 km long distance FBG sensor system
引用
收藏
页码:204 / 206
页数:3
相关论文
共 50 条
  • [31] Cable television monitoring system based on fiber laser and FBG sensor
    Peng, Peng-Chun
    Huang, Jun-Han
    Wu, Shin-Shian
    Yang, Wei-Yuan
    Shen, Po-Tso
    OPTICAL SENSORS 2015, 2015, 9506
  • [32] Long-Distance Sensing Fiber Sensor System Using Broadband Source and Raman Amplifier
    Guo, B. Y.
    Tang, W. C.
    Manie, Y. C.
    Bitew, M. A.
    Lu, H. K.
    Peng, P. C.
    2017 IEEE INTERNATIONAL CONFERENCE ON CONSUMER ELECTRONICS - TAIWAN (ICCE-TW), 2017,
  • [33] Long-distance fiber grating sensor system using a fiber ring laser with EDWA and SOA
    Peng, PC
    Feng, KM
    Peng, WR
    Chiou, HY
    Chang, CC
    Chi, S
    OPTICS COMMUNICATIONS, 2005, 252 (1-3) : 127 - 131
  • [34] Design and performance of low-loss submarine optical fiber cable for long-distance submarine repeaterless transmission system employing remotely pumped EDF and distributed Raman amplification
    Toge, Kunihiro
    Hogari, Kazuo
    Kurokawa, Kenji
    Yoshizawa, Nobuyuki
    Haibara, Tadashi
    IEICE TRANSACTIONS ON COMMUNICATIONS, 2006, E89B (06) : 1733 - 1737
  • [35] Fast and Long-Distance Brillouin Optical Time-Domain Reflectometry Based on Raman Amplification
    Ma Xiangjie
    Zhou Liming
    Cheng Linghao
    Liu Weimin
    LASER & OPTOELECTRONICS PROGRESS, 2019, 56 (17)
  • [36] Long-range hybrid network with point and distributed Brillouin sensors using Raman amplification
    Zornoza, Ander
    Ana Perez-Herrera, Rosa
    Elosua, Cesar
    Diaz, Silvia
    Bariain, Candido
    Loayssa, Alayn
    Lopez-Amo, Manuel
    OPTICS EXPRESS, 2010, 18 (09): : 9531 - 9541
  • [37] Ultralong Raman fiber laser and sensor with optimized remotely optical pump amplification
    Ran, Zherui
    Dong, Shisheng
    Liu, Yang
    Deng, Kangye
    Wang, Junhang
    Rao, Yunjiang
    OPTICS AND LASER TECHNOLOGY, 2024, 175
  • [38] Stable dual-wavelength fiber laser utilizing tapered-EDF as comb filter in hybrid Raman-EDF gains
    Ali, M. I. Md
    Noor, A. S. M.
    Anas, S. B. Ahmad
    Abu Bakar, M. H.
    Mahdi, M. A.
    2014 IEEE 5TH INTERNATIONAL CONFERENCE ON PHOTONICS (ICP), 2014, : 87 - 89
  • [39] Long-distance remote simultaneous measurement of strain and temperature based on a Raman fiber laser with a single FBG embedded in a quartz plate
    Han, Young-Geun
    Tran, Thi Van Anh
    Lee, Ju Han
    Lee, Sang Bae
    PASSIVE COMPONENTS AND FIBER-BASED DEVICES III, PTS 1 AND 2, 2006, 6351
  • [40] Pump power optimization for linear cavity multiwavelength Brillouin-Raman fiber laser
    Abass, A. K.
    Jamaludin, M. Z.
    Al-Mansoori, M. H.
    Abdullah, F.
    Al-Mashhadani, T. F.
    Ali, M. H.
    OPTIK, 2015, 126 (18): : 1731 - 1734
12345