A new technical paper titled “An Ultra-Low-Leakage Microcontroller with Configurable Power Management for Energy Harvesting IoT Devices” was published by researchers at Eindhoven University of Technology and Innatera Nanosystems.
Abstract
“This paper presents a power management unit (PMU) architecture designed for energy-harvesting IoT devices, integrating a dual-capacitor system, an ultra-low-leakage balloon-based microcontroller (MCU), and a fully digital controller. The PMU dynamically switches between an active capacitor, an idle capacitor, and a backup battery, optimizing energy use in different operational modes. This configuration optimizes capacitor voltages for various operational modes, applying a higher voltage to the active capacitor for enhanced performance and a lower voltage to the idle capacitor for ultra-low-leakage data retention. Additionally, a fully digital PMU controller replaces conventional analog components, leveraging a digital voltage monitor and converter-free voltage regulation. The test chip is designed and fabricated using a 28-nm FD-SOI technology. The balloon-based MCU measurement shows that it can retain data during idle mode with a power consumption of only 3nW at 0.6V, achieving a 4400× reduction in leakage power compared to conventional MCUs without balloon memory. Furthermore, the results of the system measurement demonstrate a substantial reduction in battery usage from 88% in traditional setups to 0%, while ensuring continuous operation and data retention.”
Find the technical paper here. March 2025.
S. Sedighiani et al., “An Ultra-Low-Leakage Microcontroller with Configurable Power Management for Energy Harvesting IoT Devices,” in IEEE Access, doi: 10.1109/ACCESS.2025.3552943.
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