Title :
First Experimental Demonstration of a Remotely Powered Quasi-Passive Reconfigurable Node
Author :
Yingying Bi ; Jing Jin ; Kazovsky, Leonid G.
Author_Institution :
Dept. of Electr. Eng., Stanford Univ., Stanford, CA, USA
Abstract :
We experimentally demonstrated the first remotely powered quasi-passive reconfigurable (QPAR) node for optical access networks. The node is powered remotely using an optical source, and is designed to provide flexible power/wavelength allocation while keeping optical access networks passive. Using a photodiode (PD) array, two optical latching switches in a 1 × 2 × 2 QPAR (i.e., one wavelength, two power levels, and two output ports) are remotely powered. Both sequential and simultaneous operations have been demonstrated, with the optical feed of each PD being 4 and 9 dBm, respectively. Our bit error rate measurements show that the optical signal used for remote power causes no power penalty to the payload signal when transmitted along the same feeder fiber.
Keywords :
error statistics; flip-flops; optical switches; passive optical networks; photodiodes; time division multiplexing; wavelength assignment; wavelength division multiplexing; QPAR node; bit error rate measurements; feeder fiber; first experimental demonstration; flexible power allocation; flexible wavelength allocation; optical access networks; optical feed; optical latching switches; optical signal; optical source; passive optical networks; payload signal; photodiode array; remotely powered quasi-passive reconfigurable node; sequential operation; simultaneous operation; time-division multiplexing PON; wavelength division multiplexing PON; Arrays; Optical fibers; Optical pumping; Optical switches; Passive optical networks; PON; Photovoltaic power systems; optical latching switch; photovoltaic power systems;; reconfigurable optical components;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2015.2405068
