• DocumentCode
    1434855
  • Title

    Fiber Bragg grating-based large nonblocking multiwavelength cross-connects

  • Author

    Chen, Yung-Kuang ; Lee, Chien-Chung

  • Author_Institution
    Inst. of Electro-Opt. Eng., Nat. Sun Yat-Sen Univ., Kaohsiung, Taiwan
  • Volume
    16
  • Issue
    10
  • fYear
    1998
  • fDate
    10/1/1998 12:00:00 AM
  • Firstpage
    1746
  • Lastpage
    1756
  • Abstract
    Multiwavelength cross-connects (WXCs) will play a key role to provide mare reconfiguration flexibility and network survivability in wavelength division multiplexing (WDM) transport networks. In this paper, we utilize three different fiber Bragg grating (FBG)-based P-type, S-type, and N-type building blocks with optical circulators and related control devices for constructing large rearrangeably nonblocking N×N WXCs. The P-type building block is composed of certain “parallel” FBG-element chains plated between the control devices of two large mechanical optical switches (OSWs). The S-type building block consists of a “series” of FBG elements and the control device of 2×2 OSWs. The nonswitched N-type building block includes a “series” of FBG elements with appropriate stepping motor or PZT control devices. All FBG elements, each with central wavelength corresponding to equally or unequally spared WDM channel wavelengths, with high-reflectivity are required. Large N×N WXC structures, with minimum number of required constitutive elements, based on a three-stage Clos network are then constructed. We investigate their relevant characteristics, compare the required constitutive elements, and estimate the dimension limits for these WXC architectures. Other related issues such as capacity expansion, wavelength channel spacing, and multiwavelength amplification are also addressed
  • Keywords
    diffraction gratings; optical circulators; optical fibre networks; optical interconnections; optical switches; reflectivity; telecommunication network reliability; wavelength division multiplexing; FBG-element; P-type building block; PZT; PZT control devices; PbZrO3TiO3; S-type building block; WDM transport networks; WXC architectures; building blocks; capacity expansion; control devices; fiber Bragg grating-based large nonblocking multiwavelength cross-connects; high-reflectivity; large mechanical optical switches; large rearrangeably nonblocking WXCs; multiwavelength amplification; multiwavelength cross-connects; network survivability; nonswitched N-type building block; optical circulators; reconfiguration flexibility; stepping motor; three-stage Clos network; unequally spared WDM channel wavelengths; wavelength channel spacing; wavelength division multiplexing; Bragg gratings; Channel capacity; Channel spacing; Circulators; Fiber gratings; Optical control; Optical devices; Optical switches; WDM networks; Wavelength division multiplexing;
  • fLanguage
    English
  • Journal_Title
    Lightwave Technology, Journal of
  • Publisher
    ieee
  • ISSN
    0733-8724
  • Type

    jour

  • DOI
    10.1109/50.721061
  • Filename
    721061