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A CNTFET-Based 10T Static Memory Design Immune to Read and Half-Select Disturbs for Low-Power Wearable Biomedical Systems

Shams Ul Haq, Erfan Abbasian, Imran Ahmed Khan, Owais Ahmad Shah, Arun Balodi, Manoj Tolani, Vakkalakula Bharath Sreenivasulu

2025IEEE Access9 citationsDOIOpen Access PDF

Abstract

This paper introduces a novel 10T SRAM cell optimized for low-power, high-reliability biomedical wearable systems. The proposed design features a read-assist mechanism to suppress read disturbs, enhancing read static noise margin (RSNM), while a decoupled pull-down path for the ‘0’ storage node improves write SNM (WSNM). Leveraging Stanford CNTFET models, HSPICE simulations reveal a 1.12× and 14.02× enhancement in RSNM and WSNM, respectively, at 0.3V over the conventional 6T cell. Additionally, the design achieves substantial power savings—3.02× (read), 1.97× (write), and 1.89× (leakage)—compared to state-of-the-art 9T/10T CNTFET SRAMs. Monte Carlo analysis further demonstrates superior robustness, with 2.38× and 6.62× higher yield in RSNM and WSNM at 0.3V, validating its reliability for energy-constrained biomedical applications.

Topics & Concepts

Computer scienceStatic random-access memoryNode (physics)Wearable computerMonte Carlo methodNoise marginReliability (semiconductor)Random access memoryPath (computing)Embedded systemTransistorLogic gateIntegrated circuit designMargin (machine learning)Power (physics)Electronic engineeringComputer hardwareSystem on a chipNoise (video)Wearable technologySimulationSpiceSchmitt triggerCarbon nanotube field-effect transistorNeuroscience and Neural EngineeringMolecular Communication and NanonetworksCCD and CMOS Imaging Sensors
A CNTFET-Based 10T Static Memory Design Immune to Read and Half-Select Disturbs for Low-Power Wearable Biomedical Systems | Litcius