Charge‐sharing read port with bitline pre‐charging and sensing scheme for low‐power SRAMs

Maroof, Naeem; Sohail, Muhammad; Shin, Hyunchul

doi:10.1002/cta.2311

Cited by 5 publications

(3 citation statements)

References 12 publications

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“…A provision to reduce the leakage power was also incorporated whereby the stacking devices in each of the inverter. In Maroof et al, 16 a 10T cell using the charge sharing mechanism between the bit lines has been proposed, which avoids the need of bit line to be precharged up to complete V DD voltage. Hence, the cells become prone towards the leakage current and noise occurrence.…”

Section: Introductionmentioning

confidence: 99%

“…But it demands for an additional boosted supply and also involved extra processing steps during fabrication. In Maroof et al, 16 a 10T cell using the charge sharing mechanism between the bit lines has been proposed, which avoids the need of bit line to be precharged up to complete V DD voltage. It results in the improved low-power memory cell, but there is no specific strategy incorporated to improve the write stability.…”

Section: Introductionmentioning

confidence: 99%

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A write‐improved low‐power 12T SRAM cell for wearable wireless sensor nodes

Sharma

Vishvakarma

Chouhan

et al. 2018

Circuit Theory & Apps

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In this work, a data-dependent feedback-cutting-based bit-interleaved 12T static random access memory (SRAM) cell is proposed, which enhances the write margin in terms of write trip point (WTP) and write static noise margin (WSNM) by 2.14× and 8.99× whereas read stability in terms of dynamic read noise margin (DRNM) and read static noise margin (RSNM) by 1.06× and 2.6 ×, respectively, for 0.4 V when compared with a conventional 6T SRAM cell. The standby power has also been reduced to 0.93× with an area overhead of 1.49× as that of 6T. Monte Carlo simulation results show that the proposed cell offers a robust write margin when compared with the state-of-the-art memory cells available in the literature. An analytical model of WSNM for 12T operating in subthreshold region is also proposed, which has been verified using the simulation results.Finally, a small SRAM macro along with its independent memory controller has been designed. KEYWORDS circuit design, low-power, SRAM, stability, write ability 2314

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A write‐improved low‐power 12T SRAM cell for wearable wireless sensor nodes

Sharma

Vishvakarma

Chouhan

et al. 2018

Circuit Theory & Apps

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“…Many designs and techniques have been introduced to: lower the

P_{w}

[7–10], the

P_{r}

[11–14], improve the

I_{on} / I_{off}

of the RBL [15–19] which allows more cells to be integrated on a single BL column, and others [20–22] provide alternative cells and techniques for robust read operation. Less of the work has been done on WDs and conventional SRAM WD has few variants [3].…”

Section: Introductionmentioning

confidence: 99%

Charge sharing write driver and half‐ pre‐charge 8T SRAM with virtual ground for low‐power write and read operation

Maroof

Kong

2017

IET Circuits, Devices & Systems

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A novel write bitline (BL) charge sharing write driver (CSWD) and a half-V DD read BL (RBL) pre-charge scheme is presented for a single-ended 8T static random access memory (SRAM). Before write enable (WE) signal assertion, CSWD equalises the write BLs by allowing their charge sharing. Both write BLs are equalised at the middle value of supply voltage using leakage current compensation block. Afterwards, as WE signal is asserted, CSWD produces the rail-to-rail levels at write BL pair. Charging of a BL from half-V DD to V DD essentially reduces the write dynamic power dissipation by 50%. Half-V DD precharging is used for RBL to achieve low-power read operation. Read port is powered by virtual ground rail to improve the RBL leakages. The authors compare the proposed 8T design (P8T) with conventional 6T (C6T) and 8T (C8T) designs in a 45 nm technology node. Write power dissipation is reduced by 42% and dynamic read power is reduced by more than 39%. Overall leakages are reduced by more than 18% compared with C6T and I on /I off ratio of the RBL is improved by more than two orders of magnitude compared with conventional 8T (C8T).

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