High performance low swing clock tree synthesis with custom D flip-flop design

Low swing clocking is a low power design methodology that scales the clock voltage to decrease power consumption of the clock distribution networks, with an expected degradation in the performance. In this work, a novel low swing clock tree synthesis methodology is combined with a custom low swing clock-aware D flip-flop (DFF) design. The low swing clocking serves to reduce the power dissipation whereas the custom low swing-aware DFF serves to preserve the performance of the IC. The experimental results performed on the three largest circuits of ISCAS'89 benchmarks operating at 1GHz in the 32nm technology show that the proposed methodology can achieve an average of 16% power savings in the clock tree compared to its full swing counterpart, while satisfying the same clock skew (50ps) and slew (150ps) constraints at the worst case corner of operation. Moreover, the clock-to-output delay of the low swing DFF does not increase compared to traditional full swing DFF, while consuming only 1% more power.