一个59-fs-rms 35-GHz锁相环，FoM为- 241-dB，采用$0.18-\mu \mathrm{m}$ BiCMOS/SiGe技术

2022 IEEE Radio Frequency Integrated Circuits Symposium (RFIC) Pub Date : 2022-06-19 DOI:10.1109/RFIC54546.2022.9863116

Rajath Bindiganavile, Asif Wahid, Jacob Atkinson, A. Tajalli

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引用次数: 0

摘要

设计并实现了一种宽带超低噪声锁相环(PLL)电路，该电路采用$0.18\ \mu \mathrm{m}$ BiCMOS/SiGe技术，工作频率为35.68 GHz。结合多相相位频率检测器和高频参考信号，锁相环的带宽被最大化，以减少感兴趣频带内正向路径环路分量的相位噪声和抖动贡献。多相相位比较器还放宽了锁相环采样特性所施加的限制，允许更方便的性能优化，减少抖动峰值和更优化的环路特性。在偏移频率为1mhz时，锁相环的相位噪声为- 113.3 dBc/Hz，从1khz到100mhz的总集成抖动为59 fs-rms，抖动功率为- 241.6 dB，消耗194.6 mW。所提出的锁相环的功耗低于类似技术节点的实现，而明显高于先进CMOS/FinFET技术的设计。该锁相环采用BiCMOS/SiGe $0.18 \mu \ maththrm {m}$设计，旨在与功率放大器集成在针对下一代5G系统的3D结构中。

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A 59-fs-rms 35-GHz PLL with FoM of −241-dB in $0.18-\mu \mathrm{m}$ BiCMOS/SiGe Technology

A wideband and ultra low-noise Phase-Locked Loop (PLL) circuit is designed and implemented in a $0.18\ \mu \mathrm{m}$ BiCMOS/SiGe technology to operate at a nominal frequency of 35.68 GHz. Incorporating a multi-phase phase frequency detector along with a high frequency reference signal, the bandwidth of the PLL was maximized to reduce the phase noise and jitter contribution of the forward path loop components within the frequency band of interest. A multi-phase phase comparator also relaxes the constraints imposed by the sampling nature of the PLL, allowing for a more convenient performance optimization with reduced jitter peaking and more optimal loop characteristics. The PLL was measured to have a Phase Noise of −113.3 dBc/Hz at an offset frequency of 1 MHz, and a total integrated jitter of 59 fs-rms integrated from 1 kHz to 100 MHz, consuming 194.6 mW with a jitter-power FoM −241.6 dB. The power dissipation of the proposed PLL is lower than implementations in similar technology nodes, while obviously higher than designs made in advanced CMOS/FinFET technologies. The PLL has been designed in BiCMOS/SiGe $0.18 \mu \mathrm{m}$, aiming to be integrated together with power amplifiers in a 3D structure targeted for the next generation 5G systems.

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2022 IEEE Radio Frequency Integrated Circuits Symposium (RFIC)

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