利用米勒电容消除的宽带输入阻抗不变有源移相器用于 5G 通信

0 ENGINEERING, ELECTRICAL & ELECTRONIC
Yongjun Kwon;Songcheol Hong
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引用次数: 0

摘要

本文提出了一种用于毫米波 5G 通信的宽带输入阻抗不变有源移相器,并在 28 纳米 CMOS 工艺中实现。它由一个 IQ 发生器、一个基于 Gilbert 单元的矢量夏和一个数模转换器 (DAC) 组成。根据移相器的状态,矢量夏的输入阻抗会发生变化,从而导致 IQ 失配,而这种变化在宽带宽内得到了大幅抑制。这是通过引入交叉耦合中和电容器来抵消矢量相加电路输入晶体管的米勒电容器($C_{\text {gd}}$)而有效实现的。实现的移相器在 24.9 GHz 时的最大增益为 0.613 dB,3-dB 带宽为 21.7-28.6 GHz (27.4%)。对于 6 位 360° 相位和 4 位 10 dB 增益控制,测量得出的均方根相位和增益误差分别小于 1.5° 和 0.25 dB。内核面积和功耗分别为 0.47~text {mm}^{2}$ 和 14.4 mW。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Wideband Input Impedance-Invariant Active Phase Shifter Using Miller Capacitor Cancellation for 5G Communication
A wideband input impedance-invariant active phase shifter for millimeter-wave 5G communication is proposed and implemented in a 28-nm CMOS process. It consists of an IQ generator, a Gilbert cell-based vector summer, and a digital-to-analog converter (DAC). Input impedance variations of the vector summer according to the states of the phase shifter, which give rise to IQ mismatches, are substantially suppressed in a wide bandwidth. This is effectively achieved by introducing cross-coupled neutralization capacitors to cancel out the Miller capacitors ( $C_{\text {gd}}$ ) of the input transistors of the vector summing circuit. The implemented phase shifter shows a maximum gain of 0.613 dB at 24.9 GHz and 3-dB bandwidths of 21.7–28.6 GHz (27.4%). The root mean square (rms) phase and gain errors are measured to be less than 1.5° and 0.25 dB, respectively, for 6-bit 360° phase and 4-bit 10-dB gain controls. The core area and power consumption are $0.47~\text {mm}^{2}$ and 14.4 mW, respectively.
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