Title :
Fully-Passive Optical Switch Introducing Dynamicity and Flexibility to Metro-Access
Author :
Schrenk, Bernhard ; Poppe, Andreas ; Stierle, Martin ; Leopold, Helmut
Author_Institution :
Dept. of Digital Safety & Security, Austrian Inst. of Technol., Vienna, Austria
Abstract :
We experimentally demonstrate a tool for dynamic reconfigurability at the physical layer infrastructure through optically powered switches based on micro-opto-electro-mechanical system technology. Energy scavenging at the optical network layer is exploited to feed this switching element. Up to 13 consecutive switching operations are shown for a full energy reservoir in addition to endless continuous switching operation with a recharge time of 24 s between operations for an optical feed of 6 dBm. A fast switching mode with 120 ms is also supported. Crosstalk robustness, penalty-free switching, and compatibility with reflective networking schemes are achieved and guarantee scalable node technology that is, from a network point-of-view, fully passive.
Keywords :
energy harvesting; micro-optomechanical devices; microswitches; optical crosstalk; optical switches; passive optical networks; continuous switching operation; crosstalk robustness; dynamic reconfigurability; energy scavenging; full energy reservoir; fully-passive optical switch; metro-access dynamicity; metro-access flexibility; microoptoelectromechanical system technology; optical feed; optical network layer; penalty-free switching; physical layer infrastructure; reflective networking schemes; scalable node technology; switching element; time 120 ms; time 24 s; Optical crosstalk; Optical fibers; Optical pumping; Optical reflection; Optical switches; Passive optical networks; Energy harvesting; Optical fiber communication; Optical switches; Passive optical networks; Switching systems; energy harvesting; optical switches; passive optical networks; switching systems;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2382479
