Optimized Design of a Miniaturized Irregular Spherical Resonator with Enhanced Subtractive/Additive Manufacturing Process Compatibility

2020 IEEE MTT-S International Wireless Symposium (IWS) Pub Date : 2020-09-20 DOI:10.1109/IWS49314.2020.9360168

Jin Li, Zhe Chen, Tao Yuan

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引用次数: 1

Abstract

RF design and structural optimization of an air-filled spherical-cavity-based miniaturized irregular resonator is presented. The irregular spherical cavity resonator is squeezed non-uniformly in horizontal orientations, and is miniaturized by capacitive loading using a geometrically shaped mushroom-head rod. The design differs from the conventional in the shaping of the cavity geometry, simultaneously taking into account 1) size compactness and miniaturization, 2) enhanced power handling capability, 3) maximized spurious-free region at lowest cost, and 4) most significantly, improved process compatibility with subtractive and additive manufacturing technologies. A prototype of the shaped irregular resonator with a fundamental-mode frequency of 3 GHz is fabricated in size of 0.3 \lambda_{\mathrm{g}} \times 0.2 \lambda_{\mathrm{g}} \times 0.33 \lambda_{\mathrm{g}}$, demonstrating an unloaded quality factor of 2610 and a spuri-ous-free region of >4 octaves. The resonator is a good candidate for new generations of miniaturized coaxial cavity filters with flexible manufacturing schemes.

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增强减/增材制造工艺兼容性的小型化不规则球形谐振器优化设计

介绍了一种基于充气球腔的小型化不规则谐振器的射频设计与结构优化。不规则球形腔谐振器在水平方向上进行非均匀挤压，并采用几何形状的蘑菇头棒电容加载实现微型化。该设计与传统的腔体几何形状不同，同时考虑了1)尺寸紧凑和小型化，2)增强功率处理能力，3)以最低成本最大化无杂散区域，以及4)最重要的是，改进了与减法和增材制造技术的工艺兼容性。制作了基模频率为3ghz的异形谐振器原型，其尺寸为0.3 \lambda_{\ mathm {g}} \乘以0.2 \lambda_{\ mathm {g}} \乘以0.33 \lambda_{\ mathm {g}}$，其空载品质因子为2610，无杂散区域>4个八度。该谐振器是具有柔性制造方案的新一代小型化同轴腔滤波器的理想选择。

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2020 IEEE MTT-S International Wireless Symposium (IWS)

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