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Leakage power analysis and reduction: models, estimation and tools

Leakage power analysis and reduction: models, estimation and tools

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The high leakage current in the nanometre regime is becoming a significant proportion of power dissipation in CMOS circuits as threshold voltage, channel length and gate oxide thickness are scaled. Consequently, the identification and estimation of different leakage currents are very important in designing low power circuits. In the paper a methodology for accurate estimation of the total leakage in a logic circuit based on the compact modelling of the different leakage currents in nanoscaled bulk CMOS devices is demonstrated. Different leakage currents are modelled based on the device geometry, 2-D doping profile and operating temperature. A circuit level model of subthreshold, junction band-to-band tunnelling (BTBT) and gate leakage is described. The presented model includes the impact of quantum mechanical behaviour of substrate electrons on the circuit leakage. Using the compact current model, a transistor has been modelled as a sum of current sources (SCS). The SCS transistor model has been used to estimate the total leakage in simple logic gates and complex logic circuits (designed with transistors of 25 nm effective length) at room and elevated temperatures.

Inspec keywords: transistors; integrated circuit modelling; logic CAD; low-power electronics; circuit analysis computing; leakage currents; semiconductor doping; doping profiles; logic gates; CMOS logic circuits

Other keywords: quantum mechanical behaviour; compact current model; transistor model; subthreshold junction band-to-band tunnelling; substrate electrons; power dissipation; 2D doping profile; low power circuit design; leakage power reduction; threshold voltage; leakage power analysis; gate oxide thickness; 25 nm; device geometry; gate leakage; leakage current modelling; operating temperature; channel length; CMOS circuits; logic circuit

Subjects: Logic and switching circuits; Semiconductor integrated circuit design, layout, modelling and testing; Electronic engineering computing; Logic elements; Computer-aided logic design; Semiconductor doping; Logic circuits; Digital circuit design, modelling and testing; CMOS integrated circuits; Computer-aided circuit analysis and design

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