LXI Optical Switching
Our LXI optical switching are fiber optic multiplexers that use MEMS (Micro Electro-Mechanical Systems) switching technology to ensure fast and reliable switching of single or multi-mode optical signals being carried on fiber connections. Our LXI optical switching can be offered for single or multi-mode fibers. This series is focused on multiplexer arrangements – if you are looking for matrix based solutions, please contact us with your requirements.
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Product
LXI Optical Switching - 8x8 Matrix Plugin Module
65-280-313
Matrix Switch Module
The 65-280-313 8x8 matrix is part of the 65-280 and 65-281 ranges of optical plug-in modules offering matrix & insert/bypass or multiplexer & SPST topologies respectively with all models based on MEMS fiber optic switches and available in various populations per plugin. In addition, a choice of different connector styles to suit most applications is offered: FC/APC (for optimal performance), FC/PC, SC/PC and ST for general applications and LC for high density applications. They use MEMS (Micro-Electro-Mechanical-Systems) based optical switches to route signals between terminals by redirecting the optical signal. This is achieved using micromechanical mirrors driven by a highly precise mechanism activated via an electrical control signal.
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Product
LXI Optical Switching - 16x16 Matrix Plugin Module
65-280-314
Matrix Switch Module
The 65-280-314 16x16 matrix is part of the 65-280 and 65-281 ranges of optical plug-in modules offering matrix & insert/bypass or multiplexer & SPST topologies respectively with all models based on MEMS fiber optic switches and available in various populations per plugin. In addition, a choice of different connector styles to suit most applications is offered: FC/APC (for optimal performance), FC/PC, SC/PC and ST for general applications and LC for high density applications. They use MEMS (Micro-Electro-Mechanical-Systems) based optical switches to route signals between terminals by redirecting the optical signal. This is achieved using micromechanical mirrors driven by a highly precise mechanism activated via an electrical control signal.
