• DocumentCode
    1280861
  • Title

    Single Step Generation of Micro and Radio Wave Signals in a Short Cavity Fiber Laser

  • Author

    Basnayaka, U. ; Fernando, Xavier ; Xijia Gu

  • Author_Institution
    Dept. of Electr. & Comput. Eng., Ryerson Univ., Toronto, ON, Canada
  • Volume
    23
  • Issue
    20
  • fYear
    2011
  • Firstpage
    1445
  • Lastpage
    1447
  • Abstract
    Generation of stable micro or radio waves by frequency down-conversion has always been a challenging but rewarding task in radio over fiber systems. In this letter, a novel method for such a generation using a short-cavity fiber laser is demonstrated. For this purpose, an all-fiber laser is designed to have two stable longitudinal laser modes, each of them having two orthogonal polarization modes. Hence, four microwave signals, two in 1.2 GHz range and the other two in 14 GHz range, and one radio wave signal were generated by beating these lasing modes on a square law detector. Various measurements show high level of stability in generated micro/radio waves because they originate from the single laser cavity. According to the authors´ knowledge, this is the first demonstration of the dual longitudinal mode operation of a short-cavity fiber laser for down-conversion from optical frequency directly to radio frequency.
  • Keywords
    fibre lasers; laser cavity resonators; laser modes; laser stability; light polarisation; microwave photonics; optical frequency conversion; optical pulse generation; optical variables measurement; frequency 1.2 GHz; frequency 14 GHz; laser stability; lasing modes; microwave signal generation; optical frequency down-conversion; orthogonal polarization modes; radio-over-fiber systems; radiowave signal generation; short cavity fiber laser; square law detector; stable longitudinal laser modes; Cavity resonators; Fiber lasers; Laser modes; Laser stability; Masers; Microwave measurements; Optical fiber polarization; All-optical microwave generation; dual polarization laser; radio over fiber;
  • fLanguage
    English
  • Journal_Title
    Photonics Technology Letters, IEEE
  • Publisher
    ieee
  • ISSN
    1041-1135
  • Type

    jour

  • DOI
    10.1109/LPT.2011.2162827
  • Filename
    5960768