Published September 30, 2022 | Version CC BY-NC-ND 4.0
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Low-Power 6T SRAM Cell using 22nm CMOS Technology

Creators

  • 1. Department of Electronics & Communication Engineering, Indira Gandhi Delhi Technical University, Women Delhi, India.

Contributors

Contact person:

  • 1. Department of Electronics & Communication Engineering, Indira Gandhi Delhi Technical University, Women Delhi, India.

Description

Abstract: Static Random-Access Memory (SRAM) occupies approximately 90% of total area on a chip due to high number of transistors used for a single SRAM cell. Therefore, SRAM cell becomes a power-hungry block on a chip and it becomes more prominent at lower technologies from both dynamic and static perspective. Static power consumption is due to leakage current associated with the transistors that are off and dynamic power consumption is due to charging and discharging of the circuit capacitance. As gate length or channel length decreases gate oxide thickness also scales down. Scaling down of conventional transistor results in huge tunneling of electron from gate into channel leading to higher leakage power consumption. So, transistor with metal gate, high-k dielectric and strained-Si is used which shows better result in terms of low-power consumption, better performance with acceptable delay. Among various topologies of SRAM cell 6T is considered as a suitable choice for low power applications.

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Published By: Lattice Science Publication (LSP) © Copyright: All rights reserved.

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Journal article: 2582-8843 (ISSN)

References

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Subjects

ISSN: 2582-8843 (Online)
https://portal.issn.org/resource/ISSN-L/2582-8843
Retrieval Number: 100.1/ijvlsid.B1210092222
https://www.ijvlsi.latticescipub.com/portfolio-item/b1210092222/
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Publisher: Lattice Science Publication (LSP)
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