Impact of technology scaling on leakage reduction techniques

Ghafari, Parnian; Anis, Mohab; Elmasry, M.I.

doi:10.1109/newcas.2007.4488021

Cited by 6 publications

(1 citation statement)

References 29 publications

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“…Transistors stacking is also called forced n-type MOS (NMOS) or forced p-type MOS (PMOS) technique. 18 In stacking technique, the amount of leakage current varies with input signal pattern of the transistors stack. Proper selection of the best combination of input signal pattern minimizes leakage current during the standby mode.…”

Section: Forced Stack Techniquementioning

confidence: 99%

Techniques for Low Leakage Nanoscale Vlsi Circuits: A Comparative Study

Sharma

Pattanaik

2014

J CIRCUIT SYST COMP

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Since the last two decades, the trend of device miniaturization has increased to get better performance with a smaller area of the logic functions. In deep submicron regime, the demand of fabrication of nanoscale Complementary metal oxide semiconductor (CMOS) VLSI circuits has increased due to evaluation of modern successful portable systems. Leakage power dissipation and reliability issues are major concerns in deep submicron regime for VLSI chip designers. Power supply voltage has been scaled down to maintain the performance yield in future deep submicron regime. The threshold voltage is the critical parameter to trade-o® the performance yield and leakage power dissipation in nanoscaled devices. Low threshold voltage improves the device characteristics with large leakage power in nanoscaled devices. Several leakage reduction techniques at di®erent levels are used to mitigate the leakage power dissipation. Lower leakage power increases the reliability by reducing the cooling cost of the portable systems. In this article, we are presenting the explanatory general review of the commonly used leakage reduction techniques at circuit level. We have analyzed the NAND3 gate using HSPICE EDA tool for leakage power dissipation at di®erent technology nodes in active as well as standby modes. Process, voltage and temperature e®ects are checked for reliability purpose. Our comparative results and discussion of di®erent leakage reduction techniques are very useful to illustrate the e®ective technique in active and standby modes.

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Section: Forced Stack Techniquementioning

confidence: 99%