一种用于生物医学植入物的定时控制AC-DC转换器

Kim Fung Edward Lee
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引用次数: 29

摘要

许多生物医学植入物由外部磁源供电[1,2]。磁源与植入物内部的线圈电感耦合,产生交流电压,然后进一步整流为直流电压[1]。一般来说,模拟电路通常需要较高的电源电压,例如神经假肢应用中的刺激电路[2,3],而数字模块通常需要较低的电源电压[4]。因此,对于模拟电路,整流直流电压通常保持在较高的值。然后使用线性稳压器将整流直流电压转换为数字电路的较低电源电压,用于神经假肢应用的数字电路通常功耗在2 - 5mW范围内[3]。然而,这种方法不是很节能,由于从弱磁耦合接收的功率有限,需要一种更有效的方法[5]。降压变换器[6,7]和开关电容器(SC)变换器具有更高的功率效率,特别是在高负载条件下。然而,由于植入物内部的空间有限,它们可能不适合生物医学植入物,只能容纳几个小的离散组件。虽然使用键线电感[8]或片上电感[9]的降压变换器是可能的解决方案,但提出了一种基于将感应交流电压直接转换为调节直流电压的替代方法。采用单个220nF的片外电容即可实现高转换效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A timing controlled AC-DC converter for biomedical implants
Many biomedical implants are powered from an external magnetic source [1, 2]. The magnetic source is inductively coupled to a coil inside the implant to induce an AC voltage, which is then further rectified to a DC voltage [1]. In general, higher supply voltages are often required for analog circuits, such as stimulation circuits in neuroprosthetic applications [2, 3], and lower supply voltages are usually needed for the digital blocks [4]. Hence, the rectified DC voltage is typically kept at a higher value for the analog circuits. A linear regulator is then used to convert the rectified DC voltage to a lower supply voltage for the digital circuits, which typically have power dissipation in the range of 2 – 5mW for neuroprosthetic applications [3]. However, this approach is not very power efficient and a more efficient approach is desired due to the limited power received from the weak magnetic coupling [5]. Buck converters [6, 7] and switched-capacitor (SC) converters have higher power efficiency, especially for high load conditions. However, they may not be suitable for biomedical implants due to the limited space inside the implants, which can only accommodate a few small discrete components. Although buck converters that use a bond-wire inductor [8] or an on-chip inductor [9] are possible solutions, an alternative approach based on a direct conversion of the induced AC voltage to a regulated DC voltage is proposed. High conversion efficiency can be achieved using a single small 220nF off-chip capacitor.
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