Optical Sensing by Exposed Core Fiber using Self-Written Waveguide

被引:0
|
作者
Ibrahim, Amalina Athira [1 ]
Baharudin, Nurul Atiqah [1 ]
Mikami, Osamu [1 ]
Ambran, Sumiaty [1 ]
Ahmad, Fauzan [1 ]
Fujikawa, Chiemi [2 ]
Mahdi, Mohd Adzir [3 ]
Yaacobc, Mohd Hanif [3 ]
机构
[1] Univ Teknol Malaysia, Malaysia Japan Inst Technol, Dept Elect Syst Engn, Kuala Lumpur 54100, Malaysia
[2] Tokai Univ, Grad Sch Engn, 4-1-1 Kitakaname, Hiratsuka, Kanagawa 2591292, Japan
[3] Univ Putra Malaysia, Fac Engn, Wireless & Photon Network Res Ctr, Serdang 43400, Selangor, Malaysia
来源
2017 IEEE CPMT SYMPOSIUM JAPAN (ICSJ) | 2017年
关键词
Sensing application; UV-curable resin; Self-Written Waveguide (SWW); Exposed core; Ray-tracing simulation;
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
Recently, the importance of the optical fiber is increasing particularly in sensing application. Thus, this paper proposes optical sensing by exposed core fiber technology using Self-Written Waveguide (SWW) method. SWW method is fabrication of an optical channel waveguide using a UV-curable resin. As a UV light irradiated, A SWW with length of 800 micrometers is aligned between two fibers from the end of the multi-mode optical fiber. A several testing materials with different refractive index are being tested on the SWW. The output optical power is decreasing as the refractive indexes of testing materials are increasing. From these results, this makes the SWW technology is a reliable exposed core technology for sensing application.
引用
收藏
页码:135 / 136
页数:2
相关论文
共 50 条
  • [1] Self-Written Waveguide Approach for Optical Interconnects in Multi-Core Fiber Systems
    He, Liangjun
    Chan, Hau Ping
    2024 OPTICAL FIBER COMMUNICATIONS CONFERENCE AND EXHIBITION, OFC, 2024,
  • [2] Optical Trajectory Manipulations Using the Self-Written Waveguide Technique
    Malallah, Ra'ed
    Cassidy, Derek
    Wan, Min
    Muniraj, Inbarasan
    Healy, John J.
    Sheridan, John T.
    POLYMERS, 2020, 12 (07) : 1 - 12
  • [3] Low-Loss Connection of Embedded Optical Fiber Sensors Using a Self-Written Waveguide
    Missinne, Jeroen
    Luyckx, Geert
    Voet, Eli
    Van Steenberge, Geert
    IEEE PHOTONICS TECHNOLOGY LETTERS, 2017, 29 (20) : 1731 - 1734
  • [4] Self-written active waveguide for integrated optical amplifiers
    Yamashita, K.
    Fukuzawa, E.
    Kitanobou, A.
    Oe, K.
    APPLIED PHYSICS LETTERS, 2008, 92 (05)
  • [5] Optical amplification and lasing in self-written active waveguide
    Yamashita, K.
    Kitanobou, A.
    Fukuzawa, E.
    Itoh, M.
    Oe, K.
    2008 CONFERENCE ON LASERS AND ELECTRO-OPTICS & QUANTUM ELECTRONICS AND LASER SCIENCE CONFERENCE, VOLS 1-9, 2008, : 590 - 591
  • [6] Self-written waveguide connection between VCSEL and optical fiber with 45° mirror using green laser
    Ozawa, H
    Obata, Y
    Mimura, Y
    Mikami, O
    Shioda, T
    IEEE PHOTONICS TECHNOLOGY LETTERS, 2006, 18 (1-4) : 532 - 534
  • [7] Self-written waveguide optical pin fabricated using photomask transfer method
    Hanajima, Hiroshi
    Obata, Yusuke
    Ozawa, Hideaki
    Kanda, Masahiro
    Mikami, Osamu
    IEEE PHOTONICS TECHNOLOGY LETTERS, 2006, 18 (17-20) : 2020 - 2022
  • [8] Fiber-to-Fiber Optical Gain of Polymer-Based Amplifier with Self-Written Active Waveguide
    Yamashita, Kenichi
    Fukuzawa, Eshin
    Okada, Hiroyuki
    Oe, Kunishige
    JAPANESE JOURNAL OF APPLIED PHYSICS, 2009, 48 (10) : 1024061 - 1024064
  • [9] Flexible light-induced self-written optical waveguide with 50 μm core size
    Futawatari, Ryo
    Terasawa, Hidetaka
    Sugihara, Okihiro
    APPLIED PHYSICS EXPRESS, 2024, 17 (02)
  • [10] Waveguide Loss Measurement Method Using Self-Written Waveguide Technique
    Sugihara, O.
    Yasuda, S.
    Kaino, T.
    NONLINEAR OPTICS QUANTUM OPTICS-CONCEPTS IN MODERN OPTICS, 2007, 36 (3-4): : 239 - 242
12345