Quantifying the Coupling and Degeneracy of OAM Modes in High-Index-Contrast Ring Core Fiber

We study orbital angular momentum (OAM) mode coupling in ring-core fibers (RCFs) due to elliptical shape deformation. We introduce a coupling model based on numerical mode solver outputs of perturbation. We show improved predictions in calculating coupling strength compared to the classical modeling approach. Our model captures and quantifies the disparate behaviors of coupling in lower and higher order degenerate OAM modes. The ideal orthogonality of modes is undermined by fiber imperfections. Our model predicts the OAM order at which the orthogonality within OAM mode pair is maintained despite elliptical deformation. We use our coupling model to simulate propagation effects and compare the performance of two fibers (thin and thick RCF) designed under the same constraints. Our numerical propagation results show different performance for the two fibers under the same level of elliptical deformation. This model uncovers distinct digital signal processing requirements for these two types of fiber, and predicts their signal-to-noise ratio penalty. For each fiber, we examine the large number of supported modes and find the optimal subset of mode groups, i.e., the groups with the lowest penalty. We show that this optimal subset is different from that predicted during the fiber design optimization.

Automated summary

This study investigates the coupling of OAM modes in ring-core fibers due to elliptical shape deformation, introducing a coupling model that shows improved predictions compared to classical modeling approaches. The model captures the disparate behaviors of coupling in lower and higher order degenerate OAM modes, and predicts the OAM order at which orthogonality is maintained despite elliptical deformation. The study also reveals different performance and signal processing requirements for thin and thick RCFs under the same level of elliptical deformation.