Litcius/Paper detail

A novel approach for designing of variability aware low‐power logic gates

Vijay Kumar Sharma

2022ETRI Journal22 citationsDOIOpen Access PDF

Abstract

Metal-oxide-semiconductor field-effect transistors (MOSFETs) are continuously scaling down in the nanoscale region to improve the functionality of integrated circuits. The scaling down of MOSFET devices causes short-channel effects in the nanoscale region. In nanoscale region, leakage current components are increasing, resulting in substantial power dissipation. Very large-scale integration designers are constantly exploring different effective methods of mitigating the power dissipation. In this study, a transistor-level input-controlled stacking (ICS) approach is proposed for minimizing significant power dissipation. A low-power ICS approach is extensively discussed to verify its importance in low-power applications. Circuit reliability is monitored for process and voltage and temperature variations. The ICS approach is designed and simulated using Cadence's tools and compared with existing low-power and high-speed techniques at a 22-nm technology node. The ICS approach decreases power dissipation by 84.95% at a cost of 5.89 times increase in propagation delay, and improves energy dissipation reliability by 82.54% compared with conventional circuit for a ring oscillator comprising 5-inverters.

Topics & Concepts

DissipationElectronic engineeringTransistorMOSFETElectrical engineeringIntegrated circuitNMOS logicReliability (semiconductor)Propagation delayCMOSPower (physics)Field-effect transistorEngineeringMaterials scienceVoltagePhysicsThermodynamicsQuantum mechanicsLow-power high-performance VLSI designSemiconductor materials and devicesAdvancements in Semiconductor Devices and Circuit Design