Monolithically-Integrated 3D Printed Bandpass Filters Using Highly-Miniaturized Dome-Shaped Resonators

Abstract

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A new class of highly-miniaturized “dome”-shaped 3D bandpass filters (BPFs) are presented. Size reduction is achieved by using: i) capacitively-loaded hemispherical resonators that are significantly smaller than a conventional spherical resonator, ii) stereolithography apparatus (SLA)-based 3D printing facilitating monolithic integration, and by iii) vertically-stacked resonators. A comprehensive design methodology is provided and applied to the realization of high order BPFs. An RF excitation scheme allowing for wideband out-of-band suppression is also proposed. For proof-of-concept validation purposes, a second- and a third-order BPF prototypes operating at 5.8 GHz, and a compact vertically-stacked second-order BPF were designed, manufactured, and tested. The measurement results exhibit the following characteristics: second-order BPF: center frequency fc = 5.8 GHz, fractional bandwidth (FBW) = 5.5%, effective quality factor (Qeff) = 890, 20 dB upper stopband suppression up to 10.14 GHz (1.7.3fc); third-order BPF: fc = 5.8 GHz, FBW = 6.5%, Qeff = 1,230, and 20 dB upper stopband suppression up to 10.1 GHz (1.74fc); vertically-stacked second-order BPF: fc = 5.9 GHz, FBW = 10.0%, Qeff = 720, and 20 dB upper stopband suppression up to 8.9 GHz (1.5fc)

Keywords

• Additive manufacturing
• high-Q resonator
• miniaturized filter
• spherical resonator
• 3D filter