Abstract
The design and performance characteristics of a beam steering optical switch for multicore fibers (MCFs) are reported. Port count, core count, transmission crosstalk, or a combination thereof can be optimized for the required application. Decreasing port separation or increasing the maximum steering angle both increase port count, whilst a higher core count or larger mode field diameter increase port capacity or port count, respectively, at the expense of greater intercore crosstalk. Potential losses from system misalignments and fiber fabrication variations in the core pitch are also estimated. A 50 port switch is possible for a 25 $\mu$ m core pitch 7 core hexagonal trench assisted MCF (TA-MCF) with a total mean statistical crosstalk on the central core of $-$ 25 dB after 1 km, assuming an operational wavelength of 1550 nm and maximum collimator actuator angle of 10 $^{\circ }$ . In contrast, a high capacity 25 $\mu$ m core pitch 61 core hexagonal TA-MCF can still offer up to a 5 port switch for the same level of crosstalk. For longer link distances, $-$ 25 dB crosstalk after 100 km (metro network) is achievable for a 50 port switch using a 35 $\mu$ m core pitch 7 core TA-MCF. Similar levels of crosstalk can be accomplished at 1000 km (core network) for a 41 port switch using a 25 $\mu$ m core pitch 7 core TA-MCF.
Highlights
T HE persistent growth of internet protocol traffic means that traditional single mode fibers (SMF) are reaching their fundamental capacity limit [1]
−25 db crosstalk after 100 km is achievable for a 50 port switch using a 7 core trench assisted (TA)-multicore fibers (MCFs)
This paper has detailed the design and performance characteristics of a free space beam steering switch for multi core fibers that have become of increasing interest for space division multiplexing applications
Summary
T HE persistent growth of internet protocol traffic means that traditional single mode fibers (SMF) are reaching their fundamental capacity limit [1]. The deployment of MCFs as spatial superchannels to meet traffic demands in core networks or DCNs would require highly scalable photonic cross connects [11] Switches for these MCF systems often rely on single mode switching technologies with additional stages for SDM multiplexing/demultiplexing [12]–[15]. DEAKIN et al.: DESIGN AND ANALYSIS OF BEAM STEERING MULTICORE FIBER OPTICAL SWITCHES traveling between ports passes through the center of a lens in the array. Intra-data center applications require high throughput and connectivity at the expense of increased crosstalk, whilst long haul communications cannot tolerate high crosstalk fiber designs and must sacrifice fiber capacity or connectivity This is in addition to the loss induced by the switch which, depending on the loss mechanism, may or may not depend on how these parameters have been configured.
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