Computationally Enabled Minimum Total Energy Tracking for a Performance Regulated Sub-Threshold Microprocessor in 65-nm CMOS
IEEE Journal of Solid-State Circuits(2020)
摘要
This article describes an architecture that auto- nomously sets the operating supply voltage (
$V_{dd}$
) of a digital system for minimum total energy dissipation, inclusive of regulator loss. The technique directly computes the energy per cycle (EPC) delivered by the supply to the system, to guide
$V_{dd}$
adjustment for minimum energy-per-cycle point (MEP; voltage:
$V_{MEP}$
and frequency:
$f_{MEP}$
) tracking. The proposed approach avoids significant
$V_{dd}$
margins typically required for system operation near-threshold and at sub-threshold
$V_{dd}$
levels by employing a unified clock and power (
UniCaP
) architecture that regulates target performance across process, voltage, and temperature (PVT) variation with minimal guardband requirements. Measurement results from a 65-nm CMOS test chip demonstrate the
$V_{MEP}$
tracking with less than 5 mV of error within the operating voltage range of 0.38–0.58 V. Measurement results also demonstrate the MEP tracking with temperature variation from −30 °C to 105 °C across varied loading conditions over 20 different test chips.
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关键词
Energy per cycle (EPC),leakage energy,minimum energy-per-cycle point (MEP),near-/sub-threshold system,performance regulation,process,voltage,and temperature (PVT) variation,supply droop,switched-capacitor (SC) voltage regulator,ultra-low-power (ULP) system,voltage margin
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