采用0.13 μm SiGe双cmos技术的集成三阶毫米波片上带通滤波器

2018 IEEE/MTT-S International Microwave Symposium - IMS Pub Date : 2018-06-01 DOI:10.1109/MWSYM.2018.8439325

Yang Yang, He Zhu, Xi Zhu, Q. Xue

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引用次数: 1

摘要

介绍了一种用于毫米波应用的片上三阶带通滤波器(BPF)。所提出的BPF由三个相同的宽侧耦合曲线谐振器(BCMLR)组成，它们由三个MIM电容器通过at形网络连接在一起。MIM电容器用作j逆变器，用于实现三阶BPF，从而相应地实现所需的跨通带和阻带的多个传输极和零。为了充分理解所提出的高阶结构的工作机制，利用LC等效电路模型对谐振器和所提出的BPF进行了分析，以进一步研究金属电感和MIM电容方面的传输极和零点分布。为了证明这一概念，提出的BPF原型在商用0.13-l中实现。m SiGe (Bi)-CMOS工艺。根据片上测量的结果，可以清楚地观察到三个传输极点和三个传输零点。值得注意的是，所提出的BPF具有出色的性能，包括在26.7 GHz至44.3 GHz范围内的平坦带内响应(衰减小于1 dB)，在中心频率为35.5 GHz时的测量插入损耗为3.1 dB，在59 GHz时的阻带衰减高达35 dB。芯片尺寸为0.016 mm2(0.066 × 0.236 mm-)，不包括GSG焊盘。

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Integrated Third-Order Millimeter-Wave On-Chip Bandpass Filter using 0.13-μm SiGe Bi-CMOS Technology

This paper introduces an on-chip third-order bandpass filter (BPF) for millimeter-wave (mm-wave) applications. The proposed BPF is composed of three identical broadside-coupled meander-line resonators (BCMLR) which are jointly connected by three MIM capacitors through aT-shape network. The MIM capacitors are used as J-inverters for the implementation of the third-order BPF in order to achieve the desired multiple transmission poles and zeros across the passband and stopband, correspondingly. To fully understand the operational mechanism of the proposed high-order structure, the resonator and the proposed BPF are analyzed using an LC- equivalent circuit model for further investigation of the distribution of the transmission poles and zeros in terms of the metal inductance and MIM capacitance. To prove the concept, the proposed BPF prototype is implemented in a commercial 0.13-l.lm SiGe (Bi)-CMOS process. According to the results obtained from on-wafer measurement, three transmission poles and three transmission zeros are clearly observed. Noticeably, the proposed BPF exhibits excellent performances including a flat in-band response (less than 1 dB attenuation) from 26.7 GHz to 44.3 GHz with a measured insertion loss of 3.1 dB at the center frequency of 35.5 GHz and stopband attenuation up to 35 dB at 59 GHz. The chip size is 0.016 mm2(0.066 × 0.236 mm-), excluding the GSG pads.

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2018 IEEE/MTT-S International Microwave Symposium - IMS

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