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Brillouin Fiber Laser Utilizing Nonlinear Birefringent Photonic Crystal Fiber (PCF)

Meri Algarni. Published in Circuits and Systems

International Journal of Applied Information Systems
Year of Publication: 2017
Publisher: Foundation of Computer Science (FCS), NY, USA
Authors: Meri Algarni
10.5120/ijais2017451674
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  1. Meri Algarni. Brillouin Fiber Laser Utilizing Nonlinear Birefringent Photonic Crystal Fiber (PCF). International Journal of Applied Information Systems 12(1):38-40, April 2017. URL, DOI BibTeX

    @article{10.5120/ijais2017451674,
    	author = "Meri Algarni",
    	title = "Brillouin Fiber Laser Utilizing Nonlinear Birefringent Photonic Crystal Fiber (PCF)",
    	journal = "International Journal of Applied Information Systems",
    	issue_date = "April 2017",
    	volume = 12,
    	number = 1,
    	month = "Apr",
    	year = 2017,
    	issn = "2249-0868",
    	pages = "38-40",
    	url = "http://www.ijais.org/archives/volume12/number1/982-2017451674",
    	doi = "10.5120/ijais2017451674",
    	publisher = "Foundation of Computer Science (FCS), NY, USA",
    	address = "New York, USA"
    }
    

Abstract

A Brillouin fiber laser utilizing an exceedingly nonlinear birefringent photonic precious stone fiber is accounted for. The center of the fiber was curved fit as a fiddle. A solitary longitudinal-mode high power fiber laser was utilized as a Brillouin pump, and the laser created multi-wave length yield with a 0.04 nm partition. Modifying the polarization controller plates made it conceivable to get a single wavelength laser. The impact of the little center birefringent photonic gem fiber on the yield of the laser was investigated. The laser was steady and demonstrated a power change of under 0.2 dB. The yield of the laser was checked utilizing an optical range analyzer of determination 0.01 nm.

Reference

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Keywords

Fiber Laser, Brillouin Fiber laser, photonic precious stone fiber, nonlinear optics, single-mode laser