Embedded 3D-IPD Technology based on Conformal 3D-RDL: Application for Design and Fabrication of Compact, High-Performance Diplexer and Ultra-Wide Band Balun

2020 IEEE 70th Electronic Components and Technology Conference (ECTC) Pub Date : 2020-06-01 DOI:10.1109/ECTC32862.2020.00292

A. Ghannam, A. Magnani, D. Bourrier, T. Parra

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引用次数: 4

Abstract

In this paper, an embedded 3D-IPD technology based on conformal 3D-RDL that yields high performance, small-size and low-cost devices is presented. The technology relies on high-Q thin film capacitors and 3D inductors as well as on thru-mold-vias (TMV) and mold compound to form a surface mount 3D-IPD device (SMD). We demonstrate how to form TMVs simultaneously with 3D-inductors using 3D-RDL technology. Hence, no laser drilling nor tall Cu vias electroplating are required.A WLAN diplexer (2.4 & 5GHz) and an UWB balun (1.4 – 3GHz) where synthesized, fabricated and measured to demonstrate electrical performance of this technology. We first report the impact of 3D inductor’s Q-factor on electrical performance of these devices and how to use this data to accurately assess real-life performance of inductors. Then, we demonstrate that low-loss (0.3dB and 0.56dB), high attenuation (24dB and 28dB) and high isolation (25dB and 29dB) are achieved for a 0.38mm2 3D diplexer. Whereas, an insertion loss <0.85dB, amplitude unbalance <0.5dB and phase unbalance <3° are achieved for 2.5 mm2 UWB balun. Reliability result is also presented here.

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基于共形3D-RDL的嵌入式3D-IPD技术:在小型高性能双工器和超宽带Balun设计与制造中的应用

本文提出了一种基于共形3D-RDL的嵌入式3D-IPD技术，该技术可产生高性能、小尺寸和低成本的器件。该技术依靠高q薄膜电容器和3D电感器，以及通过模具通孔(TMV)和模具化合物来形成表面贴装3D- ipd器件(SMD)。我们演示了如何使用3D-RDL技术与3d电感器同时形成tmv。因此，不需要激光钻孔或高铜孔电镀。一个WLAN双工器(2.4 & 5GHz)和一个UWB平衡器(1.4 - 3GHz)在合成、制造和测量中展示了该技术的电气性能。我们首先报告了3D电感器的q因子对这些器件的电气性能的影响，以及如何使用这些数据来准确评估电感器的实际性能。然后，我们证明了在0.38mm2 3D双工器上实现了低损耗(0.3dB和0.56dB)、高衰减(24dB和28dB)和高隔离(25dB和29dB)。而对于2.5 mm2 UWB平衡器，插入损耗<0.85dB，幅度不平衡<0.5dB，相位不平衡<3°。文中还给出了可靠性结果。

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 IEEE 70th Electronic Components and Technology Conference (ECTC)

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