A 3D-Printed Fourth-Order Stacked Filter for Integrated DC-DC Converters

2023 IEEE International Symposium on Circuits and Systems (ISCAS) Pub Date : 2023-05-21 DOI:10.1109/ISCAS46773.2023.10182210

Jin-Hui Lee, V. Adrian, S. Tay, Yanshan Xie, B. Gwee, J. Chang

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Abstract

The passive devices in state-of-the-art miniaturized switched-mode DC-DC converters are generally integrated by means of on-chip and in-package methods. Nevertheless, the quality is poor-to-moderate, thereby compromising the power-efficiency. In this paper, we propose the miniaturization of the DC-DC converter by means of realizing its passive devices as embedded devices that are printed within a high-density 3D inkjet printed-circuit-board (PCB). We propose a fourth-order stacked LC filter embodying passive components with small values-effectively at no additional cost because they are embedded through 3D-printing. For the inductor and capacitor, we propose to adopt a high- $Q$ solenoidal structure and the metal-insulator-metal planar structure, respectively. The proposed filter is printed within the 3D-PCB with a compact 124 mm3volume due to the stacked arrangement. The measured AC attenuation is 21.2 dB at 200 MHz. The filter is further verified by means of computer simulations of a DC-DC buck converter. Simulation results of the converter employing the filter show a low output voltage ripple at 146 mV and a high peak power-efficiency of ~78% at 200 MHz switching frequency with 150 mA load current.

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用于集成DC-DC转换器的3d打印四阶堆叠滤波器

目前最先进的小型化开关模式DC-DC变换器中的无源器件通常采用片上和封装的方式集成。然而，质量差到中等，从而影响了功率效率。在本文中，我们提出了通过实现其无源器件作为嵌入式器件在高密度3D喷墨印刷电路板(PCB)内印刷的DC-DC转换器的小型化。我们提出了一种四阶堆叠LC滤波器，包含具有小值的无源元件-有效地无需额外成本，因为它们通过3d打印嵌入。对于电感和电容，我们建议分别采用高Q的螺线管结构和金属-绝缘体-金属平面结构。由于堆叠排列，所提出的滤波器在3D-PCB内打印，体积紧凑，为124 mm3。测量到的交流衰减在200mhz时为21.2 dB。通过对DC-DC降压变换器的计算机仿真，进一步验证了该滤波器的有效性。仿真结果表明，采用该滤波器的变换器在146 mV时输出纹波较低，在200 MHz开关频率和150 mA负载电流下的峰值功率效率高达78%。

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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2023 IEEE International Symposium on Circuits and Systems (ISCAS)

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