Optical Signal Channel Power Stability in a Transparent Optical Network Using Large-Scale Photonic Cross Connects and Automatic Gain Control EDFAs

We discuss the change in the number of optical signal channels transmitted through wavelength division multiplexing links in a transparent optical network and report detailed measurement results of optical signal channel power variation in an experimental setup configured with realistic large-scale photonic cross-connect (PXC) switches fabricated using three-dimensional microelectromechanical system (3D MEMS) technology. The scale of the PXC-based network ranges from 100 to 300 km to simulate a realistic long-haul optical network using 100-km-long dispersion-shifted fibers and L-band erbium-doped fiber amplifiers with a high-speed automatic gain control circuit. The measurement results demonstrate the feasibility of stable operation of a transparent optical network by using these state-of-the-art technologies with proper parameter settings.

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