采用可重构低噪声放大器的宽带毫米波CMOS接收机，带3绕组变压器负载

IF 4.5 1区工程技术 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Microwave Theory and Techniques Pub Date : 2024-12-11 DOI:10.1109/TMTT.2024.3506657

Mohammad Ghaedi Bardeh;Mohamad Mahdi Rajaei Rizi;Navid Naseh;Jeyanandh Paramesh;Kamran Entesari

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引用次数: 0

摘要

本文介绍了一种采用可重构低噪声放大器（LNA）的CMOS毫米波（mm-wave）宽带图像抑制（IR）接收器，该接收器带有3绕组变压器负载，采用22nm完全耗尽绝缘体上硅（FDSOI）。本文对所提出的三绕组变压器负载进行了全面的分析，计算了极点和零点的位置以及第一端口自阻抗（$Z_{11}$）的方程，并提出了设计策略，并与传统的双调谐变压器负载进行了比较。基于该方法，提出了一种毫米波宽带/可重构接收机，其主要贡献包括：1)宽带/可重构频率模式操作；2)取消LNA后的干扰信号，放宽混频器线性度要求；3)片上图像抑制，采用三级电阻-电容(RC)-电容-电阻（CR）滤波器，电阻可调，以达到最佳运行。宽带模式下的3db带宽为21.5 ~ 32.5 GHz， 22.5 GHz时的峰值增益为45.5 dB，低频和高频可重构模式下的3db带宽为21.5 ~ 26.5 GHz， 22 GHz时的峰值增益为45.45 dB， 29 GHz时的峰值增益为46.58 dB。测得的噪声系数（NF）值在30ghz时最小为2.9 dB。在19 - 34 ghz范围内，图像抑制优于30 dB，在相同频率范围内，最小$\text {OP}_{\text {1dB}}$为-2.8 dBm。整个芯片的功耗为94.8 mW，不包括焊盘的尺寸为2.331 × 0.756 mm。

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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A Wideband Millimeter-Wave CMOS Receiver Using a Reconfigurable Low-Noise Amplifier With a 3-Winding Transformer Load

This article presents a CMOS millimeter-wave (mm-wave) wideband image-reject (IR) receiver using a reconfigurable low-noise amplifier (LNA) with a 3-winding transformer load in 22-nm fully depleted silicon-on-insulator (FDSOI). The complete analysis of the proposed 3-winding transformer load is presented, where the location of the poles and zeros and also the equation for the first port, self-impedance (

$Z_{11}$

) are calculated and a design strategy along with a comparison with the conventional double-tuned transformer load is performed. Based on this approach, an mm-wave wideband/reconfigurable receiver is presented with three major contributions including: 1) wideband/reconfigurable frequency mode operation; 2) canceling interfere signals right after LNA to relax mixer linearity requirements; and 3) on-chip image-rejection using a three-stage resistor-capacitor (RC)-capacitor-resistor (CR) filter with tunable resistors for optimum operation. The 3-dB bandwidth in wideband mode is from 21.5 to 32.5 GHz with a peak gain of 45.5 dB at 22.5 GHz, and for both low-frequency and high-frequency reconfigurable modes, it is from 21.5 to 26.5 GHz with a peak gain of 45.45 dB at 22 GHz and from 27 to 32 GHz with a peak gain of 46.58 dB at 29 GHz, respectively. The measured noise figure (NF) value shows a minimum of 2.9 dB at 30 GHz. The image rejection is better than 30 dB for the 19–34-GHz range and the minimum

$\text {OP}_{\text {1dB}}$

is -2.8 dBm over the same frequency range. The entire chip has a power consumption of 94.8 mW with the dimensions of

$2.331\times 0.756$

mm excluding the pads.

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来源期刊

IEEE Transactions on Microwave Theory and Techniques 工程技术-工程：电子与电气

CiteScore

8.60

自引率

18.60%

发文量

486

审稿时长

6 months

期刊介绍： The IEEE Transactions on Microwave Theory and Techniques focuses on that part of engineering and theory associated with microwave/millimeter-wave components, devices, circuits, and systems involving the generation, modulation, demodulation, control, transmission, and detection of microwave signals. This includes scientific, technical, and industrial, activities. Microwave theory and techniques relates to electromagnetic waves usually in the frequency region between a few MHz and a THz; other spectral regions and wave types are included within the scope of the Society whenever basic microwave theory and techniques can yield useful results. Generally, this occurs in the theory of wave propagation in structures with dimensions comparable to a wavelength, and in the related techniques for analysis and design.