TY - JOUR
T1 - Scalable optical switches for computing applications
AU - White, I.H.
AU - Aw, E.T.
AU - Williams, K.A.
AU - Wang, Haibo
AU - Wonfor, A.
AU - Penty, R.V.
PY - 2009
Y1 - 2009
N2 - A scalable photonic interconnection network architecture is proposed whereby a Clos network is populated with broadcast-and-select stages. This enables the efficient exploitation of an emerging class of photonic integrated switch fabric. A low distortion space switch technology based on recently demonstrated quantum-dot semiconductor optical amplifier technology, which can be operated uncooled, is used as the base switch element. The viability of these switches in cascaded networks is reviewed, and predictions are made through detailed physical layer simulation to explore the potential for larger-scale network connectivity. Optical signal degradation is estimated as a function of
data capacity and network size. Power efficiency and physical layer complexity are addressed for high end-to-end bandwidth, nanosecond-reconfigurable switch fabrics, to highlight the potential for scaling to several tens of connections The proposed architecture is envisaged to facilitate high-capacity, lowlatency switching suited to computing ystems, backplanes, and data networks. Broadband operation through wavelength division multiplexing is studied to identify practical interconnection networks scalable to 100 Gbits/s per path and a power consumption of the order of 20 mW/ ??Gbits/s?? for a 64
??64 size interconnection network.
AB - A scalable photonic interconnection network architecture is proposed whereby a Clos network is populated with broadcast-and-select stages. This enables the efficient exploitation of an emerging class of photonic integrated switch fabric. A low distortion space switch technology based on recently demonstrated quantum-dot semiconductor optical amplifier technology, which can be operated uncooled, is used as the base switch element. The viability of these switches in cascaded networks is reviewed, and predictions are made through detailed physical layer simulation to explore the potential for larger-scale network connectivity. Optical signal degradation is estimated as a function of
data capacity and network size. Power efficiency and physical layer complexity are addressed for high end-to-end bandwidth, nanosecond-reconfigurable switch fabrics, to highlight the potential for scaling to several tens of connections The proposed architecture is envisaged to facilitate high-capacity, lowlatency switching suited to computing ystems, backplanes, and data networks. Broadband operation through wavelength division multiplexing is studied to identify practical interconnection networks scalable to 100 Gbits/s per path and a power consumption of the order of 20 mW/ ??Gbits/s?? for a 64
??64 size interconnection network.
U2 - 10.1364/JON.8.000215
DO - 10.1364/JON.8.000215
M3 - Article
SN - 1536-5379
VL - 8
SP - 215
EP - 224
JO - Journal of Optical Networking
JF - Journal of Optical Networking
IS - 2
ER -