Ultra-low power and 1.5 bit/cell ternary-SRAM stability modeling for always-on applications

Young-Eun Choi; Woo-Seok Kim; Myoung Kim; Min Woo Ryu; Kyung Rok Kim

doi:10.1587/elex.22.20250042

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Ultra-low power and 1.5 bit/cell ternary-SRAM stability modeling for always-on applications

Young-Eun Choi, Woo-Seok Kim, Myoung Kim, Min Woo Ryu, Kyung Rok Kim

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Keywords: ternary-CMOS, SRAM, ultra-low power, data retention, dynamic robustness

JOURNAL FREE ACCESS

2025 Volume 22 Issue 7 Pages 20250042

DOI https://doi.org/10.1587/elex.22.20250042

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Abstract

We present an ultra-low power ternary SRAM (T-SRAM) with a storage capacity of 1.5 bit/cell, using a commercial 110-nm CMOS foundry for always-on applications, along with an analysis of its stability. By designing T-CMOS with SPICE compact model parameters, which are body-effect coefficient (m), peak electric field coefficient (C_EP), and gate width (W), band-to band tunneling current (I_BTBT) can be reduced to hundreds of fA range and it allows V_DD to scale down to 0.55 V. Finally, we experimentally demonstrate T-SRAM cell which static and dynamic powers are decreased to 4.5 × 10^-2 and 1.3 × 10^-7, respectively.

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