A 90 nm leakage control transistor based clock gating for low power flip flop applications

The continuous growing demand of portable battery-powered electronics devices hunts for Nano-electronic circuit design for ultra-low power applications by reducing dynamic power, static power and short circuit power. In sequential circuit elements of an IC, a notable amount of power dissipation occurs due to the rapid switching of high frequency clock signals, which do not fetch any data bit or information. The needless switching of clock, during the HOLD phase of either ‘logic 1’ or ‘logic 0’, may be abolished using gated clock. In this paper, we have presented a new clock gating technique incorporating Leakage Control Transistor. The improvised technique is employed to trigger a D-Flip Flop using 90nm PTM technology at 1.1V power supply. We have observed an impressive reduction in power, delay and latency using the proposed gating logic, which has outsmarted the existing works. The simulation is also performed in smaller technology nodes such as 65nm, 45nm and 32 nm to notice the change in delay, dynamic power and static power of the circuit.

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