TY - JOUR
T1 - Is 25 Gb/s on-board signaling viable?
AU - Kam, Dong G.
AU - Ritter, Mark B.
AU - Beukema, Troy J.
AU - Bulzacchelli, John F.
AU - Pepeljugoski, Petar K.
AU - Kwark, Young H.
AU - Shan, Lei
AU - Gu, Xiaoxiong
AU - Baks, Christian W.
AU - John, Richard A.
AU - Hougham, Gareth
AU - Schuster, Christian
AU - Rimolo-Donadio, Renato
AU - Wu, Boping
PY - 2009
Y1 - 2009
N2 - What package improvements are required for dense, high-aggregate bandwidth buses running at data rates beyond 10 Gb/s per channel, and when might optical interconnects on the board be required? We present a study of distance and speed limits for electrical on-board module-to-module links with an eye to answering these questions. Hardware-validated models of advanced organic modules and printed circuit boards were used to explore these limits. Simulations of link performance performed with an internal link modeling tool allowed us to explore the effect of equalization and modulation formats at different data rates on link bit error rate and eye opening. Our link models have been validated with active, high-speed differential bus measurements utilizing a 16-channel link chip with programmable equalization and a per-channel data rate of up to 11 Gb/s. Electrical signaling limits were then determined by extrapolating these hardware-correlated models to higher speeds, and these limits were compared to the results of recent work on on-board optical interconnects.
AB - What package improvements are required for dense, high-aggregate bandwidth buses running at data rates beyond 10 Gb/s per channel, and when might optical interconnects on the board be required? We present a study of distance and speed limits for electrical on-board module-to-module links with an eye to answering these questions. Hardware-validated models of advanced organic modules and printed circuit boards were used to explore these limits. Simulations of link performance performed with an internal link modeling tool allowed us to explore the effect of equalization and modulation formats at different data rates on link bit error rate and eye opening. Our link models have been validated with active, high-speed differential bus measurements utilizing a 16-channel link chip with programmable equalization and a per-channel data rate of up to 11 Gb/s. Electrical signaling limits were then determined by extrapolating these hardware-correlated models to higher speeds, and these limits were compared to the results of recent work on on-board optical interconnects.
KW - Channel equalization
KW - Electrical signaling limit
KW - High-speed bus measurement
KW - High-speed serial link
KW - Link modeling
KW - Multilevel signaling
UR - http://www.scopus.com/inward/record.url?scp=67349192202&partnerID=8YFLogxK
U2 - 10.1109/TADVP.2008.2011138
DO - 10.1109/TADVP.2008.2011138
M3 - Artículo
AN - SCOPUS:67349192202
SN - 1521-3323
VL - 32
SP - 328
EP - 344
JO - IEEE Transactions on Advanced Packaging
JF - IEEE Transactions on Advanced Packaging
IS - 2
ER -