TY - GEN
T1 - Design and implementation of fine-grain power gating with ground bounce suppression
AU - Usami, Kimiyoshi
AU - Shirai, Toshiaki
AU - Hashida, Tasunori
AU - Masuda, Hiroki
AU - Takeda, Seidai
AU - Nakata, Mitsutaka
AU - Seki, Naomi
AU - Amano, Hideharu
AU - Namiki, Mitaro
AU - Imai, Masashi
AU - Kondo, Masaaki
AU - Nakamura, Hiroshi
PY - 2009
Y1 - 2009
N2 - This paper describes a design and implementation methodology for fine-grain power gating. Since sleep-in and wakeup are controlled in a fine granularity in run time, shortening the transition time between the sleep and active states is strongly required. In particular, shortening the wakeup time is essential because it affects the execution time and hence does the performance. However, this requirement makes suppression of the ground-bounce more difficult. We propose a novel technique to skew the wakeup timings of fine-grain local power domains to suppress the ground bounce. Delay of buffers driving power switches is skewed in the buffer tree by selectively downsizing them. We designed a MIPS R3000 based CPU core in a 90nm CMOS technology and applied our technique to internal function units. Simulation results showed that our technique reduces the rush current to 47% over the case to turn-on the power switches simultaneously. This resulted in suppressing the ground bounce to 53mV with 3.3ns wakeup time. Simulation results from running benchmark programs showed that the total power dissipation for the function units was reduced by up to 15% at 25°C and by 62% at 100°C. Effectiveness in power savings is discussed from the viewpoint of the temperature-dependent break-even points and the consecutive idle time in the program.
AB - This paper describes a design and implementation methodology for fine-grain power gating. Since sleep-in and wakeup are controlled in a fine granularity in run time, shortening the transition time between the sleep and active states is strongly required. In particular, shortening the wakeup time is essential because it affects the execution time and hence does the performance. However, this requirement makes suppression of the ground-bounce more difficult. We propose a novel technique to skew the wakeup timings of fine-grain local power domains to suppress the ground bounce. Delay of buffers driving power switches is skewed in the buffer tree by selectively downsizing them. We designed a MIPS R3000 based CPU core in a 90nm CMOS technology and applied our technique to internal function units. Simulation results showed that our technique reduces the rush current to 47% over the case to turn-on the power switches simultaneously. This resulted in suppressing the ground bounce to 53mV with 3.3ns wakeup time. Simulation results from running benchmark programs showed that the total power dissipation for the function units was reduced by up to 15% at 25°C and by 62% at 100°C. Effectiveness in power savings is discussed from the viewpoint of the temperature-dependent break-even points and the consecutive idle time in the program.
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U2 - 10.1109/VLSI.Design.2009.63
DO - 10.1109/VLSI.Design.2009.63
M3 - Conference contribution
AN - SCOPUS:62949189195
SN - 9780769535067
T3 - Proceedings: 22nd International Conference on VLSI Design - Held Jointly with 7th International Conference on Embedded Systems
SP - 381
EP - 386
BT - Proceedings
T2 - 22nd International Conference on VLSI Design - Held Jointly with 7th International Conference on Embedded Systems
Y2 - 5 January 2009 through 9 January 2009
ER -