Modeling of power flow in multimode W-type photonic crystal fibers
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Date
2023-01-01Authors
Drljača, Branko
Savović, Svetislav
Kovačević, Milan S.
Simović, Ana
Kuzmanović, Ljubica
Djordjevich, Alexandar
Yussupova, Gulbakhar
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In this paper recent advances in application of power flow equation to Wtype photonic crystal fibers (PCF) is presented. As known for many years power flow
equation has been proven to be best solution when transmission characteristics of multimode
optical fibers are to be modeled. Transmission properties of multimode optical fibers depend
strongly upon modal dispersion, mode-dependent attenuation and the rate of mode coupling.
Throughout years different simulation models have been developed to model light
transmission in optical fibers. Electromagnetic wave model is usually used in modeling of
single mode and few mode fibers and it is not applicable to multimode fibers. The ray tracing
model, which calculates the trajectory for each ray through the fiber, enables the calculation
of the impulse response (and therefore frequency response and bandwidth) including the
process of mode-dependent attenuation and modal dispersion. Beside this model is
computationally intensive since it requires a large number of ray trajectories it can’t account
for mode coupling. In contrast, using the time-independent power flow equation, modedependent attenuation and mode coupling can be modeled effectively in order to calculate
their influence on transmission characteristics of an optical fiber. Furthermore, using the
time-dependent power flow equation, all three major fiber effects can be modeled. In this
work we describe application of time-independent power flow equation (TI PFE) on different
types of multimode optical fibers.
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