A partial coupling power of single mode fiber fusion

Coupled fibers are successfully fabricated by injecting hydrogen flow at 1bar and fused slightly by unstable torch flame in the range of 800-1350°C. Optical parameters may vary significantly over wide range physical properties. Coupling coefficient and refractive index are estimated from the experim...

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Main Authors: Saktioto, Toto, Ali, Jalil, Rahman, Rosly Abdul, Fadhali, M., Zainal, Jasman
Format: Conference or Workshop Item
Published: 2008
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Online Access:http://eprints.utm.my/id/eprint/9974/
http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:128020
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Institution: Universiti Teknologi Malaysia
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spelling my.utm.99742020-03-17T08:02:07Z http://eprints.utm.my/id/eprint/9974/ A partial coupling power of single mode fiber fusion Saktioto, Toto Ali, Jalil Rahman, Rosly Abdul Fadhali, M. Zainal, Jasman Q Science (General) Coupled fibers are successfully fabricated by injecting hydrogen flow at 1bar and fused slightly by unstable torch flame in the range of 800-1350°C. Optical parameters may vary significantly over wide range physical properties. Coupling coefficient and refractive index are estimated from the experimental result of the coupling ratio distribution from 1% to 75%. The change of structural and geometrical fiber affects the normalized frequency (V) even for single mode fibers. Coupling ratio as a function of coupling coefficient and separation of fiber axis changes with respect to V at coupling region. V is derived from radius, wavelength and refractive index parameters. Parametric variations are performed on the left and right hand side of the coupling region. At the center of the coupling region V is assumed constant. A partial power is modeled and derived using V, normalized lateral phase constant (u), and normalized lateral attenuation constant, (w) through the second kind of modified Bessel function of the l order, which obeys the normal mode, LP01 and normalized propagation constant (b). Total power is maintained constant in order to comply with the energy conservation law. The power is integrated through V, u and w over the pulling length range of 7500-9500 µm for 1-D where radial and angle directions are ignored. The core radius of fiber significantly affects V and power partially at coupling region rather than wavelength and refractive index of core and cladding. This model has power phenomena in transmission and reflection for industrial application of coupled fibers 2008 Conference or Workshop Item PeerReviewed Saktioto, Toto and Ali, Jalil and Rahman, Rosly Abdul and Fadhali, M. and Zainal, Jasman (2008) A partial coupling power of single mode fiber fusion. In: Optoelectronic Devices and Integration II, 12 November 2007, Beijing, China. http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:128020
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic Q Science (General)
spellingShingle Q Science (General)
Saktioto, Toto
Ali, Jalil
Rahman, Rosly Abdul
Fadhali, M.
Zainal, Jasman
A partial coupling power of single mode fiber fusion
description Coupled fibers are successfully fabricated by injecting hydrogen flow at 1bar and fused slightly by unstable torch flame in the range of 800-1350°C. Optical parameters may vary significantly over wide range physical properties. Coupling coefficient and refractive index are estimated from the experimental result of the coupling ratio distribution from 1% to 75%. The change of structural and geometrical fiber affects the normalized frequency (V) even for single mode fibers. Coupling ratio as a function of coupling coefficient and separation of fiber axis changes with respect to V at coupling region. V is derived from radius, wavelength and refractive index parameters. Parametric variations are performed on the left and right hand side of the coupling region. At the center of the coupling region V is assumed constant. A partial power is modeled and derived using V, normalized lateral phase constant (u), and normalized lateral attenuation constant, (w) through the second kind of modified Bessel function of the l order, which obeys the normal mode, LP01 and normalized propagation constant (b). Total power is maintained constant in order to comply with the energy conservation law. The power is integrated through V, u and w over the pulling length range of 7500-9500 µm for 1-D where radial and angle directions are ignored. The core radius of fiber significantly affects V and power partially at coupling region rather than wavelength and refractive index of core and cladding. This model has power phenomena in transmission and reflection for industrial application of coupled fibers
format Conference or Workshop Item
author Saktioto, Toto
Ali, Jalil
Rahman, Rosly Abdul
Fadhali, M.
Zainal, Jasman
author_facet Saktioto, Toto
Ali, Jalil
Rahman, Rosly Abdul
Fadhali, M.
Zainal, Jasman
author_sort Saktioto, Toto
title A partial coupling power of single mode fiber fusion
title_short A partial coupling power of single mode fiber fusion
title_full A partial coupling power of single mode fiber fusion
title_fullStr A partial coupling power of single mode fiber fusion
title_full_unstemmed A partial coupling power of single mode fiber fusion
title_sort partial coupling power of single mode fiber fusion
publishDate 2008
url http://eprints.utm.my/id/eprint/9974/
http://dms.library.utm.my:8080/vital/access/manager/Repository/vital:128020
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