SleepRider: a 5.5μW/MHz Cortex-M4 MCU in 28nm FD-SOI with ULP SRAM, Biomedical AFE and Fully-Integrated Power, Clock and Back-Bias Management

2021 Symposium on VLSI Circuits Pub Date : 2021-06-13 DOI:10.23919/VLSICircuits52068.2021.9492365

R. Dekimpe, Maxime Schramme, M. Lefebvre, Adrian Kneip, R. Saeidi, Mathieu Xhonneux, Ludovic Moreau, Marco Gonzalez, Thibault Pirson, D. Bol

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引用次数: 6

Abstract

Ultra-low-power microcontrollers (ULP MCUs) face a performance trade-off between energy-efficient computing during activity periods and low sleep power, associated with limited wake-up time and energy. Adaptive back-biasing in FD-SOI, along with near-threshold operation at ultra-low voltage, has brought significant improvements by dynamically shifting the minimum energy point (MEP) along the frequency axis. This work introduces a highly-integrated 64-MHz ULP Cortex-M4 MCU with 96-kB SRAM in 28nm FD-SOI. A clock and power management unit (CPMU) generates all internal supplies and clocks from a 1.8-V supply, while unified frequency and back-bias regulation (UFBBR) performs PVT compensation. Custom 16-kB ULP SRAMs achieve low read/write access energy, 1.2/0.84pJ/32-bit access respectively, and provide 0.98nW/kB ultra-low-leakage data retention. A low-power biomedical analog front-end enables biopotential monitoring. The MEP is 5.5μW/MHz (8.2μW/MHz including conversion losses). Sleep power is 7.7μW with retention of logic state and 32-kB memory.

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SleepRider:一款5.5μW/MHz Cortex-M4 MCU，采用28nm FD-SOI芯片，具有ULP SRAM、生物医学AFE和完全集成的电源、时钟和反向偏置管理

超低功耗微控制器(ULP mcu)面临着在活动期间的节能计算和低睡眠功率(与有限的唤醒时间和能量相关)之间的性能权衡。FD-SOI中的自适应反向偏置，以及超低电压下的近阈值工作，通过沿着频率轴动态移动最小能量点(MEP)，带来了显著的改进。本工作介绍了一种高度集成的64-MHz ULP Cortex-M4 MCU，该MCU在28nm FD-SOI中具有96 kb SRAM。时钟和电源管理单元(CPMU)从1.8 v电源产生所有内部电源和时钟，而统一频率和反向偏置调节(UFBBR)执行PVT补偿。自定义16kb ULP sram实现低读/写访问能量，分别为1.2/0.84pJ/32位访问，并提供0.98nW/kB的超低泄漏数据保留。低功耗生物医学模拟前端实现生物电位监测。MEP为5.5μW/MHz(含转换损耗为8.2μW/MHz)。睡眠功率为7.7μW，保持逻辑状态，内存为32kb。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 Symposium on VLSI Circuits

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