Arijit Banerjee scite author profile

Energy consumption is a key issue in portable biomedical devices that require uninterrupted biomedical data processing. As the battery life is critical for the user, these devices impose stringent energy constraints on SRAMs and other system on chip (SoC) components. Prior work shows that operating CMOS circuits at subthreshold supply voltages minimizes energy per operation. However, at subthreshold voltages, SRAM bitcells are sensitive to device variations, and conventional 6T SRAM bitcell is highly vulnerable to readability related errors in subthreshold operation due to lower read static noise margin (RSNM) and half-select issue problems. There are many robust subthreshold bitcells proposed in the literature that have some improvements in RSNM, write static noise margin (WSNM), leakage current, dynamic energy, and other metrics. In this paper, we compare our proposed bitcell with the state of the art subthreshold bitcells across various SRAM design knobs and show their trade-offs in a column mux scenario from the energy and delay metrics and the energy per operation metric standpoint. Our 9T half-select-free subthreshold bitcell has 2.05× lower mean read energy, 1.12× lower mean write energy, and 1.28× lower mean leakage current than conventional 8T bitcells at the TT_0.4V_27C corner. Our bitcell also supports the bitline interleaving technique that can cope with soft errors. . Low Power Electron. Appl. 2014, 4 120 OPEN ACCESS J

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Ultra-Low-Power Embedded SRAM Design for Battery- Operated and Energy-Harvested IoT Applications

Banerjee¹

2018

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Internet of Things (IoT) devices such as wearable health monitors, augmented reality goggles, home automation, smart appliances, etc. are a trending topic of research. Various IoT products are thriving in the current electronics market. The IoT application needs such as portability, form factor, weight, etc. dictate the features of such devices. Small, portable, and lightweight IoT devices limit the usage of the primary energy source to a smaller rechargeable or non-rechargeable battery. As battery life and replacement time are critical issues in battery-operated or partially energy-harvested IoT devices, ultralow-power (ULP) system on chips (SoC) are becoming a widespread solution of chip makers' choice. Such ULP SoC requires both logic and the embedded static random access memory (SRAM) in the processor to operate at very low supply voltages. With technology scaling for bulk and FinFET devices, logic has demonstrated to operate at low minimum operating voltages (V MIN). However, due to process and temperature variation, SRAMs have higher V MIN in scaled processes that become a huge problem in designing ULP SoC cores. This chapter discusses the latest published circuits and architecture techniques to minimize the SRAM V MIN for scaled bulk and FinFET technologies and improve battery life for ULP IoT applications.

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A 130nm canary SRAM for SRAM dynamic write V<inf>MIN</inf> tracking across voltage, frequency, and temperature variations

Banerjee

Breiholz

Calhoun

2015

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Arijit Banerjee

A reverse write assist circuit for SRAM dynamic write V<inf>MIN</inf> tracking using canary SRAMs

A 256kb 6T self-tuning SRAM with extended 0.38V–1.2V operating range using multiple read/write assists and V<inf>MIN</inf> tracking canary sensors

An Ultra-Low Energy Subthreshold SRAM Bitcell for Energy Constrained Biomedical Applications

Ultra-Low-Power Embedded SRAM Design for Battery- Operated and Energy-Harvested IoT Applications

A 130nm canary SRAM for SRAM dynamic write V<inf>MIN</inf> tracking across voltage, frequency, and temperature variations

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