Analyzing and minimizing effects of temperature variation and NBTI on active leakage power of power-gated circuits

Power-gating (PG) techniques have been widely used in modern digital ICs to reduce their standby leakage power during idle periods. Meanwhile, virtual supply voltage (VVDD) of a power-gated IC is a function of strength of a PG device and total current flowing through it. Thus, the VVDD level becomes susceptible to 1) negative bias temperature instability (NBTI) degradation that weakens the PG device over time and 2) temporal temperature variation that affects active leakage current (thus total current) of the IC. To account for the NBTI degradation, the PG device must be upsized such that it guarantees a minimum VVDD level that prevents any timing failure over chip lifetime. Moreover, the PG device is also sized for the worst-case voltage drop partly resulted by a large amount of active leakage current at high temperature. However, increasing the size of the PG device to consider both effects leads to higher VVDD (thus active leakage power) than necessary at low temperature and/or in early chip lifetime. To minimize active leakage power increase due to these effects, we propose two techniques that adjust strength of a PG device based on its usage and IC's temperature at runtime. Both techniques are applied to an experimental setup modeling total current consumption of an IC in 32nm technology and their efficacy is demonstrated in the presence of within-die spatial process and temperature variations. On average of 100 die samples, they can reduce active leakage power by up to 10% in early chip lifetime.

[1]  C.H. Kim,et al.  Silicon Odometer: An On-Chip Reliability Monitor for Measuring Frequency Degradation of Digital Circuits , 2007, 2007 IEEE Symposium on VLSI Circuits.

[2]  Young-Hyun Jun,et al.  CMOS temperature sensor with ring oscillator for mobile DRAM self-refresh control , 2007, Microelectron. J..

[3]  Vivek De,et al.  Design and reliability challenges in nanometer technologies , 2004, Proceedings. 41st Design Automation Conference, 2004..

[4]  Massoud Pedram,et al.  Analysis of jitter due to power-supply noise in phase-locked loops , 2000, Proceedings of the IEEE 2000 Custom Integrated Circuits Conference (Cat. No.00CH37044).

[5]  Asen Asenov,et al.  Evaluation of statistical variability in 32 and 22 nm technology generation LSTP MOSFETs , 2009, ESSDERC 2009.

[6]  David Howard,et al.  Challenges in sleep transistor design and implementation in low-power designs , 2006, 2006 43rd ACM/IEEE Design Automation Conference.

[7]  Nam Sung Kim,et al.  Frequency and yield optimization using power gates in power-constrained designs , 2009, ISLPED.

[8]  Srikanth Balasubramanian Power delivery for high performance microprocessors , 2008, Proceeding of the 13th international symposium on Low power electronics and design (ISLPED '08).

[9]  Kevin J. Nowka,et al.  Adaptive MTCMOS for dynamic leakage and frequency control using variable footer strength , 2005, Proceedings 2005 IEEE International SOC Conference.

[10]  Yu Cao,et al.  Predictive Modeling of the NBTI Effect for Reliable Design , 2006, IEEE Custom Integrated Circuits Conference 2006.