Title :
Realistic monomode air-core honeycomb photonic bandgap fiber with pockets
Author :
Haas, Thomas ; Belau, Stefan ; Doll, Theodor
Author_Institution :
Dept. of Solid State Electron., Tech. Univ. of Ilmenau, Germany
Abstract :
We present a photonic bandgap calculation of monomode air-core fibers with a realistic treatment of "pocket" interstitials that are formed in a honeycomb cladding. The analytic Fourier transformations of different honeycomb-lattice unit cells are used for plane-wave calculations. The consideration of the true pocket geometry within the cladding shifts the fundamental bandgap to higher frequencies and leads to a hollow-core fiber. The core radius necessary for a monomode fiber is approximated and then proved via the full-vectorial solution. The field distribution and polarization state of the fundamental mode for a real honeycomb photonic-crystal fiber (PCF) are given.
Keywords :
Fourier transform optics; interstitials; optical fibre cladding; optical fibre polarisation; photonic band gap; photonic crystals; Fourier transformations; air-core fiber; cladding; field distribution; full-vectorial solution; fundamental mode; hollow-core fiber; honeycomb cladding; honeycomb fiber; honeycomb-lattice unit cells; monomode fiber; photonic bandgap fiber; photonic crystal fiber; plane-wave calculations; pocket interstitials; polarization state; true pocket geometry; Lattices; Optical fiber polarization; Optical microscopy; Photonic band gap; Photonic bandgap fibers; Photonic crystal fibers; Preforms; Pulse width modulation; Scanning electron microscopy; Shape; Air-core fiber; hollow-core fiber; honeycomb lattice; photonic bandgap fiber; plane-wave method (PWM);
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2005.850794
