Wideband Dispersion Compensation in Square Lattice Photonic Crystal Fibe

Authors

  • Esmat Jafari Department of Electrical and Electronics, Faculty of Electrical and Computer Engineering, University of Sistan and Baluchestan, Zahedan, Iran
  • Mohammad Ali Mansouri-Birjandi Department of Electrical and Electronics, Faculty of Electrical and Computer Engineering, University of Sistan and Baluchestan, Zahedan, Iran.
Abstract:

In this paper, a new structure is provided for the dispersion compensating photonic crystal fibers in order to broaden the chromatic dispersion and increase the dispersion compensating capability in a wide wavelength range. In the structure, putting a combination of circular holes and a star structure in the inner core clad causes the dispersion coefficient profile to be broadened, and additionally causes the fiber to have a negative dispersion coefficient in the whole S to U telecommunication bands. In this fiber, the minimal dispersion coefficient will be -653ps/(nm.km). Furthermore, with the diameter of the circular holes of the inner clad in this structure increased, a relatively flat dispersion profile will be obtained in the whole E to U telecommunication bands with a dispersion variation equal to 46ps/(nm.km). In the S to C telecommunication bands, the dispersion variation is 17ps/(nm.km). The simulations are all done using the finite difference time domain numerical (FDTD) method.

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Journal title

volume 7  issue 1

pages  49- 61

publication date 2018-06-01

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