Energy-Efficient Start-up Dickson Charge Pump for Batteryless Biomedical Implant Devices

2020 27th IEEE International Conference on Electronics, Circuits and Systems (ICECS) Pub Date : 2020-11-23 DOI:10.1109/ICECS49266.2020.9294827

Kaung Oo Htet, H. Heidari, F. Moradi, R. Ghannam

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引用次数: 1

Abstract

This paper presents a power management concept for solar energy harvesting power management using an on-chip switched-capacitor (SC) DC-DC converter for biomedical implantable applications. This design eliminates potential reversion losses caused by the switching scheme. It also mitigates the bottom plate loss by employing the charge recycling technique. Moreover, instead of using a single step clock pulse, the two-step adiabatic charge sharing clock helps reduce the energy drawn from the PV cell by 65%. Furthermore, with the help of clock disabler scheme, the power dissipation has been further reduced by disabling the entire start-up charge pump once the desired reference output voltage was reached. However, due to additional circuitry for the clock disabler, there is a tradeoff between power efficiency and power dissipation. The proposed system was implemented and fabricated in a standard 0.18-µm TSMC RF CMOS technology. The proposed converter has achieved a maximum efficiency of 73%.

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用于无电池生物医学植入装置的节能启动迪克森电荷泵

本文提出了一种利用片上开关电容(SC) DC-DC转换器进行太阳能采集电源管理的电源管理概念，用于生物医学植入式应用。这种设计消除了由开关方案引起的潜在的反转损失。它还通过采用电荷回收技术减轻了底板损失。此外，与使用单步时钟脉冲不同，两步绝热电荷共享时钟有助于减少从光伏电池中获取的能量65%。此外，在时钟禁用方案的帮助下，一旦达到所需的参考输出电压，通过禁用整个启动电荷泵，进一步降低了功耗。然而，由于时钟禁用器的额外电路，在功率效率和功耗之间存在权衡。该系统采用标准的0.18µm TSMC RF CMOS技术实现和制造。该变换器的效率最高可达73%。

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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2020 27th IEEE International Conference on Electronics, Circuits and Systems (ICECS)

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