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Beschreibung |
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Datei |
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Style Guide for Book
Please use this templates for your contributions. |
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C.-A. Bunge, H. Poisel: Welcome to POF Modelling 2007
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H. Poisel, C.A. Bunge: POF Modelling 2007
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H. Poisel: Measurement Techniques at POF-AC
An overview of the measurement set-ups that are available at the POF Application Centre. Besides the explanation of the measurements themselves their advantages, short comings, boundary conditions and applications will be presented. |
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T. Ishigure: WKB Method for POF Modelling
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G. Aldabaldetreku: Numerical implementation of the ray-tracing method in the propagation of light through multimode optical fibres
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L. Poladian: Modelling of Holey Fibres
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M. Eguchi: Large-scale Numerical Analysis of Optical Waveguides including Large-Core Multimode Optical Fibers
Plastic optical fibers (POFs) that are a typical large core multimode optical fiber support a great number of guided modes.
Numerical analysis approaches are very effective for designs of optical fibers having various arbitrary core profiles. Here I introduce details of the modelling of large-core fibers including POFs and holey fibers by numerical techniques. |
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A. Bachmann/K. Klein: Measurement of mPOF – Pitfalls and Problems
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G. Durana: Practical applications of the numerical simulations
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M. Bloos: Launching, Fibre Coupling etc. by Ray Tracing
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H. Poisel: POF Bending Sensor Modelling
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S. Savovic: Power-Flow Equation
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F. Breyer: Getting the impulse response of SI-POF by solving the time-dependent power-flow equation using the Crank-Nicholson scheme
In this presentation the calculation of the impulse response of step-index polymer optical fibre (SI-POF) is shown by solving the time-dependent power-flow equation applying the Crank Nicholson scheme. There arbitrary angle-dependant input functions
can be used for the attenuation, dispersion, diffusion, and launching condition. |
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R. Kruglov: Determination of Mode Coupling Matrix used by Split-Step Algorithm
This paper presents the results of the complex investigation of
mode-mixing effects in the multimode optical fibres, which are
caused by the roughness of the core-cladding interface. This
model is based on the matrix model for multiple scattering of
modes in an optical fibre. |
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C. Bunge: Statistical Modelling of Propagation Characteristics with Mode Coupling
A different approach for the determination of the mode-coupling
coefficients will be presented. This model is based on statistics in
order to calculate the ray distribution at the fibre end, which is
estimated by a histogram in the ray-tracing analysis. |
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O. Ziemann: POF characterisation – Measurement Techniques
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T. Bierhoff: Simulation of Fibre-Optical Bending Sensors
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A. Gavrilov: Improvement of OTDR Measurements using POF Propagation Model
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G. Friedrich: Reasons for a KTI research Project
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Pictures from the workshop
If you need high resolution, please let us know... |
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FINAL DRAFT: POF Modelling: Theory, Measurement and Application
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Style_guides.zip
Bunge_Welcome_Mo.pdf