Title :
Broadband Silicon Photonic Packet-Switching Node for Large-Scale Computing Systems
Author :
Zhang, Wenjia ; Xu, Lin ; Li, Qi ; Lira, Hugo L R ; Lipson, Michal ; Bergman, Keren
Author_Institution :
Dept. of Electron. Eng., Columbia Univ., New York, NY, USA
fDate :
4/15/2012 12:00:00 AM
Abstract :
We present a broadband packet-switching node that utilizes silicon photonic technology. The node design uses a silicon microring for switching functionality, leverages in-flight header processing for arbitration, and has a tunable driving circuit for thermal-effect mitigation. Moreover, these integrated microring switches are capable of scaling to tremendously high port counts in a compact area, which are attractive for data-center networks. We experimentally characterize the extinction ratio of the switch for varying packet durations, interarrival times, and driving voltages and demonstrate an error-free routing of 10-Gb/s wavelength-striped packets with lengths of up to 1536 ns. We further study the resonance thermal drifting for long- hold-time packet switching through carrier injection and show thermal-effect mitigation using a pre-emphasized gating signal.
Keywords :
elemental semiconductors; integrated optoelectronics; micro-optics; optical communication equipment; packet switching; silicon; telecommunication network routing; Si; bit rate 10 Gbit/s; broadband silicon photonic packet switching node; carrier injection; data center networks; error free routing; extinction ratio; in-flight header processing; interarrival times; large-scale computing systems; packet durations; preemphasized gating signal; resonance thermal drifting; thermal effect mitigation; time 1536 ns; tunable driving circuit; Adaptive optics; Optical attenuators; Optical packet switching; Optical switches; Photonics; Silicon; Electrooptic devices; interconnections; microresonators; packet switching;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2012.2186796
