Title :
Split of phase shifts in a phase mask for fiber Bragg gratings
Author :
Sheng, Yunlong ; Rothenberg, Joshua E. ; Li, Hongpu ; Wang, Ying ; Zweiback, Jason
Author_Institution :
Phaethon Commun., Fremont, CA, USA
fDate :
5/1/2004 12:00:00 AM
Abstract :
Using rigorous finite-difference in time-domain analysis for near field diffraction of a phase-shifted phase mask, we discover that the phase shift is not replicated in the fiber by side-writing through the mask, but is split into two half-magnitude phase shifts with a separation proportional to the fiber-to-phase mask spacing. We show by a physical model for cumulated phase that spectral asymmetry observed in a multichannel fiber Bragg grating (FBG) with a binary phase Dammann sampling function is caused by this split. We propose a new binary phase-only sampling design, which precompensates the phase-shift splitting effect and produces high channel count FBGs without asymmetry in the channel spectrum.
Keywords :
Bragg gratings; diffractive optical elements; finite difference time-domain analysis; light diffraction; optical fibre theory; phase shifting masks; photolithography; binary phase Dammann sampling function; binary phase-only sampling design; channel spectrum; fiber Bragg gratings; fiber-to-phase mask spacing; finite difference analysis; half-magnitude phase shifts; high channel count FBGs; multichannel fiber Bragg grating; near-field diffraction; phase shift; phase-shift splitting effect; phase-shifted phase mask; side-writing; spectral asymmetry; time-domain analysis; Bragg gratings; Diffraction; Distributed feedback devices; Fiber gratings; Fiber lasers; Finite difference methods; Optical fiber communication; Physics; Sampling methods; Time domain analysis;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2004.826059
