An Optimal Polarization Tracking Algorithm for Lithium-Niobate-based Polarization Controllers
This work addresses polarization control in optical systems, but the results are only simulated and lack experimental validation, making it an incremental contribution.
The paper presents an optimal algorithm for three-stage polarization tracking using lithium-niobate-based controllers, including calibration, rotation, and stabilization, with numerical simulations in MATLAB.
We present an optimal algorithm for the three-stage arbitrary polarization tracking using Lithium-Niobate-based Polarization Controllers: device calibration, polarization state rotation, and stabilization. The theoretical model representing the lithium-niobate-based polarization controller is derived and the methodology is successfully applied. Results are numerically simulated in the MATLAB environment.