A 60%-Efficiency 20nW-500µW Tri-Output Fully Integrated Power Management Unit with Environmental Adaptation and Load-Proportional Biasing for IoT Systems.
Wanyeong Jung, Junhua Gu, Paul D Myers, Minseob Shim, Seokhyeon Jeong, Kaiyuan Yang, Myungjoon Choi, ZhiYoong Foo, Suyoung Bang, Sechang Oh, Dennis Sylvester, David Blaauw
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引用次数: 43
Abstract
As Internet-of-Things (IoT) systems proliferate, there is a greater demand for small and efficient power management units. Fully integrated switched-capacitor (SC) DC-DC converters are promising candidates due to their small form factor and low quiescent power, aided by dynamic activity scaling [1-3]. However, they offer a limited number of conversion ratios, making them challenging to use in actual systems since they often require multiple output voltages (to reduce power consumption) and use various input power sources (to maximize flexibility). In addition, maintaining both high efficiency and fast load response is difficult at low output current levels, which is critical for IoT devices as they often target low standby power to preserve battery charge. This paper presents a fully integrated power management system that converts an input voltage within a 0.9-to-4V range to 3 fixed output voltages: 0.6V, 1.2V, and 3.3V. A 7-stage binary-reconfigurable DC-DC converter [1-2] enables the wide input voltage range. Three-way dynamic frequency control maintains converter operation at near-optimum conversion efficiency under widely varying load conditions from 5nW to 500μW. A proposed load-proportional bias scheme helps maintain high efficiency at low output power, fast response time at high output power and retains stability across the entire operating range. Analog drop detectors improve load response time even at low output power, allowing the converter to avoid the need for external sleep/wakeup control signals. Within a range of 1-to-4V input voltage and 20nW-500μW output power, the converter shows >60% conversion efficiency, while maintaining responsiveness to a 100× sudden current increase.