Can Sitik scite author profile

A low-voltage/swing clocking methodology is developed through both circuit and algorithmic innovations. The primary objective is to significantly reduce the power consumed by the clock network while maintaining the circuit performance the same. The methodology consists of two primary components: 1) a novel D-flip-flop (DFF) cell that maximizes power savings by enabling low-voltage/swing operation throughout the entire clock network and 2) a novel clock tree synthesis algorithm to ensure that the same timing constraints (i.e., clock frequency, skew, and slew) are satisfied. The proposed methodology is integrated within an industrial design flow. Experimental results on ISCAS'89 benchmark circuits demonstrate that the overall power consumed by the clock tree can be reduced by up to 27% and 44% in, respectively, 32-and 45-nm technologies while satisfying the same timing constraints. Furthermore, the proposed low-swing DFF cell maintains the clock-to-Q delay the same while achieving up to 32% and 15% power savings in the overall flip-flop power of the benchmark circuits at, respectively, 1-and 1.5-GHz clock frequencies.Index Terms-Clock network, clock tree synthesis (CTS), D-flip-flop (DFF), low power, low-voltage/swing clocking.

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FinFET-Based Low-Swing Clocking

Sitik

Salman

Filippini

et al. 2015

J. Emerg. Technol. Comput. Syst.

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A low-swing clocking methodology is introduced to achieve low-power operation at 20nm FinFET technology. Low-swing clock trees are used in existing methodologies in order to decrease the dynamic power consumption in a trade-off for 3 issues: (1) the effect of leakage power consumption, which is becoming more dominant when the process scales sub-32nm; (2) the increase in insertion delay, resulting in a high clock skew; and (3) the difficulty in driving the existing DFF sinks with a low-swing clock signal without a timing violation. In this article, a FinFET-based low-swing clocking methodology is introduced to preserve the dynamic power savings of low-swing clocking while minimizing these three negative effects, facilitated through an efficient use of FinFET technology. At scaled performance constraints, the proposed methodology at 20nm FinFET leads to 42% total power savings (clock network+DFF) compared to a FinFET-based full-swing counterpart at the same frequency (3 GHz), thanks to the dynamic power savings of low-swing clocking and 3% power savings compared to a CMOS-based low-swing implementation running at the half frequency (1.5 GHz), thanks to the leakage power savings of FinFET technology.

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Can Sitik

Multi-voltage domain clock mesh design

Skew-bounded low swing clock tree optimization

Timing characterization of clock buffers for clock tree synthesis

Design Methodology for Voltage-Scaled Clock Distribution Networks

FinFET-Based Low-Swing Clocking

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