Title :
A 27% Active-Power-Reduced 40-nm CMOS Multimedia SoC With Adaptive Voltage Scaling Using Distributed Universal Delay Lines
Author :
Ikenaga, Yoshifumi ; Nomura, Masahiro ; Suenaga, Shuji ; Sonohara, Hideo ; Horikoshi, Yoshitaka ; Saito, Toshiyuki ; Ohdaira, Yukio ; Nishio, Yoichiro ; Iwashita, Tomohiro ; Satou, Miyuki ; Nishida, Koji ; Nose, Koichi ; Noguchi, Koichiro ; Hayashi, Yoshi
Author_Institution :
Renesas Electron. Corp., Kawasaki, Japan
fDate :
4/1/2012 12:00:00 AM
Abstract :
AVS technique for extremely scaled SoCs has been developed. To reduce design cost, we have developed a supply voltage control scheme employing universal delay line (UDL), rather than a replica delay line, for monitoring the critical path delay (TCRIT). The UDL can be used in any product without any need for customizing. In addition, averaging the results of distributed 4 monitors with a pitch of 3 mm in a chip can reduce errors due to within-die variation by half. With these techniques, proposed scheme produces equivalent or less error to TCRIT than does a conventional scheme that uses a single critical path replica as a delay monitor, even with simple monitor design. We have shown that 40-nm CMOS SoCs using our AVS can reduce active power by 27%.
Keywords :
CMOS digital integrated circuits; system-on-chip; voltage control; active-power-reduced CMOS multimedia SoC; adaptive voltage scaling technique; critical path delay monitoring; distributed universal delay lines; replica delay line; simple monitor design; single critical path replica; size 40 nm; supply voltage control scheme; Delay; Delay lines; Logic gates; Monitoring; System-on-a-chip; Systematics; Voltage control; Adaptive voltage scaling (AVS); CMOS; delay monitor; power reduction;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2012.2185340
