Title :
Modeling Dissimilar Optical Fiber Splices With Substantial Diffusion
Author_Institution :
Clemson Univ., Clemson
Abstract :
Optical losses of dissimilar fiber fusion splices are modeled using a combination of diffusion simulation and beam propagation method; open-source codes are provided. It is demonstrated that an optimal amount of diffusion is required to achieve the minimum splice loss. Additional annealing beyond the optimal level is detrimental. Furthermore, oscillation of splice loss with the geometrical parameters of the heat zone due to an optical interference effect is revealed, which can be intentionally utilized to reduce dissimilar fiber splice losses. Understanding these diffusion-related splice loss mechanisms is important for splicing process optimization, as well as design of fusion splicers and novel postsplicing heat treatment devices.
Keywords :
light interference; light propagation; light scattering; optical fibre fabrication; optical fibre losses; splicing; beam propagation method; diffusion simulation; dissimilar fiber fusion splices; dissimilar fiber splice losses; dissimilar optical fiber splices; heat treatment devices; open-source codes; optical interference effect; optical losses; splicing process optimization; Annealing; Geometrical optics; Interference; Open source software; Optical fiber devices; Optical fiber losses; Optical fibers; Optical losses; Optical propagation; Propagation losses; Beam propagation method (BPM); diffusion equation; dissimilar fiber splices; optical fibers; splice loss;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2007.907788
