Design of 32nm Forced Stack CNTFET SRAM cell for leakage power reduction

As silicon semiconductor device feature size scales down to the nanometer range, planar bulk CMOS design and fabrication encounter significant challenges nowadays. Carbon Nanotube Field Effect Transistor (CNTFET) has been introduced for high stability, high performance and low power SRAM cell design...

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Hauptverfasser:	Rajendra Prasad, S., Madhavi, B. K., Lal Kishore, K.
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Carbon nanotubes CNTFET CNTFETs Computational modeling Fabrication HSPICE Lead Leakage-Power Logic gates Random access memory SRAM Cell
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creator	Rajendra Prasad, S. Madhavi, B. K. Lal Kishore, K.
description	As silicon semiconductor device feature size scales down to the nanometer range, planar bulk CMOS design and fabrication encounter significant challenges nowadays. Carbon Nanotube Field Effect Transistor (CNTFET) has been introduced for high stability, high performance and low power SRAM cell design as an alternative material. Technology scaling demands a decrease in both V DD and V T to sustain historical delay reduction, while restraining active power dissipation. Scaling of V T however leads to substantial increase in the sub-threshold leakage power and is expected to become a considerable constituent of the total dissipated power. It has been observed that the stacking of two off devices has smaller leakage current than one off device. This paper proposes a SRAM cell circuit based on CNTFET that uses Forced Stack Technique to reduce leakage power. The advantage of this circuit compared to sleep-transistor technique is that it can save the state. This circuit is simulated using HSPICE with Stanford CNFET model at 32nm. The simulated results shows that this proposed Forced Stack CNTFET SRAM cell reduces a leakage-power by a significant amount compared to conventional 6T CNTFET SRAM cell with minimal Area and delay trade off.
doi_str_mv	10.1109/ICCEET.2012.6203904
format	Conference Proceeding
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The advantage of this circuit compared to sleep-transistor technique is that it can save the state. This circuit is simulated using HSPICE with Stanford CNFET model at 32nm. 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Technology scaling demands a decrease in both V DD and V T to sustain historical delay reduction, while restraining active power dissipation. Scaling of V T however leads to substantial increase in the sub-threshold leakage power and is expected to become a considerable constituent of the total dissipated power. It has been observed that the stacking of two off devices has smaller leakage current than one off device. This paper proposes a SRAM cell circuit based on CNTFET that uses Forced Stack Technique to reduce leakage power. The advantage of this circuit compared to sleep-transistor technique is that it can save the state. This circuit is simulated using HSPICE with Stanford CNFET model at 32nm. 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subjects	Carbon nanotubes CNTFET CNTFETs Computational modeling Fabrication HSPICE Lead Leakage-Power Logic gates Random access memory SRAM Cell
title	Design of 32nm Forced Stack CNTFET SRAM cell for leakage power reduction
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