Power Flow in Multimode Graded-Index Microstructured Polymer Optical Fibers

We investigate mode coupling in a multimode graded-index microstructured polymer optical fiber (GI mPOF) with a solid core by solving the time-independent power flow equation (TI PFE). Using launch beams with various radial offsets, it is possible to calculate for such an optical fiber the transients of the modal power distribution, the length L-c at which an equilibrium mode distribution (EMD) is reached, and the length z(s) for establishing a steady-state distribution (SSD). In contrast to the conventional GI POF, the GI mPOF explored in this study achieves the EMD at a shorter length L-c. The earlier shift to the phase of slower bandwidth decrease would result from the shorter L-c. These results are helpful for the implementation of multimode GI mPOFs as a part of communications and optical fiber sensory systems.

Automated summary

Mode coupling in a multimode graded-index microstructured polymer optical fiber (GI mPOF) is investigated using the time-independent power flow equation (TI PFE). By using launch beams with various radial offsets, the transient modal power distribution, the equilibrium mode distribution (EMD) length L-c, and the steady-state distribution (SSD) length z(s) can be calculated. The GI mPOF achieves the EMD at a shorter length L-c compared to conventional GI POF. These findings are important for the application of multimode GI mPOFs in communication and optical fiber sensory systems.