A Current-Mode Multiphase Digital Transmitter With a Single-Footprint Transformer-Based Asymmetric Doherty Output Network

IEEE Open Journal of the Solid-State Circuits Society Pub Date : 2023-06-28 DOI:10.1109/OJSSCS.2023.3290550

Jay R. Sheth;Linsheng Zhang;Xiaochuan Shen;Vinay Iyer;Steven M. Bowers

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Abstract

This article introduces a current-mode multiphase digital transmitter with a single-footprint transformer-based asymmetric Doherty output network. The proposed multiphase architecture overcomes the bandwidth expansion associated with the polar power amplifier (PA), while still achieving relatively constant output power and drain efficiency (DE) profiles. Additionally, to achieve efficiency enhancement in deep power back-off (PBO), and to simultaneously achieve a compact form factor, an asymmetric series Doherty output matching network using a transformer-within-transformer structure is also proposed. A proof-of-concept eight-phase digital transmitter using the proposed single-footprint Doherty network is implemented in a general-purpose 65-nm CMOS process. The transmitter achieves more than 20-dBm output power

$(P_{\mathrm{ out}})$

and more than 31% DE from 4.5 to 6.7 GHz. At 8-dB PBO, it achieves a DE of 23% and 24% at 6.5 and 7.0 GHz, which corresponds to a

$1.76\times $

and

$1.93\times $

improvement compared to normalized class B PA, respectively. The transmitter also achieves a 21% DE and an average

$P_{\mathrm{ out}}$

of 14 dBm with an r.m.s. error vector magnitude

$({\mathrm{ EVM}}_{\mathrm{ rms}})$

of 4.1% for a 20-MSym/s 64-quadrature amplitude modulation waveform at 6.5 GHz.

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基于非对称Doherty输出网络的电流型单相数字变送器

本文介绍了一种基于非对称Doherty输出网络的电流模式多相数字变送器，该变送器具有单足迹变压器。所提出的多相架构克服了与极性功率放大器（PA）相关的带宽扩展，同时仍然实现相对恒定的输出功率和漏极效率（DE）分布。此外，为了实现深度功率回退（PBO）中的效率提高，并同时实现紧凑的形状因子，还提出了一种使用变压器内变压器结构的非对称串联多尔蒂输出匹配网络。在通用65nm CMOS工艺中实现了使用所提出的单足迹Doherty网络的概念验证八相数字发射机。该发射机在4.5至6.7 GHz范围内实现了超过20 dBm的输出功率$（P_｛\mathrm｛out｝｝）$和超过31%的DE。在8-dB PBO下，它在6.5和7.0 GHz下实现了23%和24%的DE，与标准化B类PA相比，这分别对应于$1.76\times$和$1.93\times$。对于6.5 GHz的20 MSym/s 64正交幅度调制波形，发射机还实现了21%的DE和14 dBm的平均$P_｛\mathrm｛out｝｝$以及4.1%的r.m.s.误差矢量幅度$（｛\math rm｛EVM｝｝_｛\marthrm｛rms｝）$。

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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IEEE Open Journal of the Solid-State Circuits Society

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