TY - GEN
T1 - An effective technique for simultaneous interconnect channel delay and noise reduction in nanometer VLSI design
AU - Moiseev, Konstantin
AU - Wimer, Shmuel
AU - Kolodny, Avinoam
PY - 2006
Y1 - 2006
N2 - Capacitive coupling is the primary source of noise in nanometer technology digital CMOS VLSI circuits. It becomes worse with technology scaling. The interconnect capacitive crosstalk noise can be characterized by two parameters: peak noise voltage, and delay uncertainty. Delay uncertainty optimization can be seen as a subset of interconnect delay optimization. This paper addresses the problem of ordering and sizing parallel wires in a single metal layer within an interconnect channel of a given width, such that cross-capacitances are optimally shared for simultaneous noise and delay minimization. Using an Elmore delay model including cross capacitances for a bundle of wires and well-known crosstalk models, we show that "symmetric hill" wire ordering according to the strength of signal drivers, which is known to optimize channel timing characteristics, can be used also for minimizing channel noise metrics. Examples using state-of-the-art circuits in 65-nanometer technology are analyzed and discussed.
AB - Capacitive coupling is the primary source of noise in nanometer technology digital CMOS VLSI circuits. It becomes worse with technology scaling. The interconnect capacitive crosstalk noise can be characterized by two parameters: peak noise voltage, and delay uncertainty. Delay uncertainty optimization can be seen as a subset of interconnect delay optimization. This paper addresses the problem of ordering and sizing parallel wires in a single metal layer within an interconnect channel of a given width, such that cross-capacitances are optimally shared for simultaneous noise and delay minimization. Using an Elmore delay model including cross capacitances for a bundle of wires and well-known crosstalk models, we show that "symmetric hill" wire ordering according to the strength of signal drivers, which is known to optimize channel timing characteristics, can be used also for minimizing channel noise metrics. Examples using state-of-the-art circuits in 65-nanometer technology are analyzed and discussed.
UR - http://www.scopus.com/inward/record.url?scp=50249094672&partnerID=8YFLogxK
U2 - 10.1109/eeei.2006.321062
DO - 10.1109/eeei.2006.321062
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AN - SCOPUS:50249094672
SN - 1424402301
SN - 9781424402304
T3 - IEEE Convention of Electrical and Electronics Engineers in Israel, Proceedings
SP - 236
EP - 240
BT - 2006 IEEE 24th Convention of Electrical and Electronics Engineers in Israel, IEEEI
T2 - 2006 IEEE 24th Convention of Electrical and Electronics Engineers in Israel, IEEEI
Y2 - 15 November 2006 through 17 November 2006
ER -