High density packaging technologies for RF electronics in small spacecraft

2017 IEEE Aerospace Conference Pub Date : 2017-03-04 DOI:10.1109/AERO.2017.7943745

Fernando H. Aguirre, D. Schatzel

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引用次数: 7

Abstract

This paper will describe a few high density packaging technologies which we are currently exploring for use in current and future small spacecraft applications. The three categories of technologies include organic multichip modules (MCMs), ceramic leadless surface mount technology (SMT) and 3D printed waveguide structures. There are many other packaging technologies that currently exist but these three were selected in part due to their heritage in various commercial, military and space applications along with each having a relatively clear path to flight. For each of these technologies, detailed examples will be included in which hardware has been fabricated and tested for use in RF electronics for spacecraft transponders. The organic MCM example will be described in most detail and it utilizes a packaging technology by the name of CoreEZ which is a trademark of i3 Electronics. This MCM has shrunk a portion of our electronics down to 1/8th of its previous area. The CoreEZ technology has been shown to be rad hard beyond a total ionizing dose (TID) of 300kRad and the MCM which was fabricated has gone through thermal cycling and shown to have no degradation in performance. The ceramic leadless package examples include packages from high reliability manufactures by the name of KCB solutions and Barry Industries. In the case of KCB solutions, we have multiple products that will be described including a hermetic ceramic carrier which houses three microwave monolithic integrated circuits (MMICs) along with small discrete components. Finally, we will discuss the results of our search for a 3D printing process that allows us to reduce the cost and volume of our waveguide filters and diplexers for low cost small satellite applications. We have fabricated a few prototypes using direct metal laser sintering (DMLS) and metal coated plastics. Each of these packaging technology discussions will have a brief overview of its current and future use.

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小型航天器射频电子器件的高密度封装技术

本文将介绍一些高密度包装技术，我们目前正在探索使用在当前和未来的小型航天器应用。这三类技术包括有机多芯片模块(mcm)、陶瓷无引线表面贴装技术(SMT)和3D打印波导结构。目前存在许多其他包装技术，但选择这三种包装技术的部分原因是它们在各种商业、军事和空间应用中的传统，并且每种包装技术都有相对清晰的飞行路径。对于这些技术中的每一种，将包括详细的例子，其中硬件已经制造和测试用于航天器应答器的射频电子设备。有机MCM的例子将在最详细的描述，它利用的封装技术的名称CoreEZ，这是i3电子公司的商标。这个MCM使我们的电子元件的面积缩小到原来的八分之一。CoreEZ技术已被证明可以在超过300kRad的总电离剂量(TID)的情况下使用，并且所制备的MCM经过热循环，性能没有下降。陶瓷无引线封装的例子包括高可靠性制造商KCB solutions和Barry Industries的封装。在KCB解决方案的情况下，我们有多种产品将被描述，包括一个密封陶瓷载体，它容纳三个微波单片集成电路(mmic)以及小型分立元件。最后，我们将讨论我们搜索3D打印过程的结果，该过程使我们能够降低低成本小卫星应用的波导滤波器和双工器的成本和体积。我们已经用直接金属激光烧结(DMLS)和金属涂层塑料制造了一些原型。这些封装技术的讨论将简要概述其当前和未来的用途。

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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2017 IEEE Aerospace Conference

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