A full-duplex receiver with 80MHz bandwidth self-interference cancellation circuit using baseband Hilbert transform equalization

2017 IEEE Radio Frequency Integrated Circuits Symposium (RFIC) Pub Date : 2017-06-04 DOI:10.1109/RFIC.2017.7969092

A. El Sayed, A. Ahmed, A. K. Mishra, A. H. M. Shirazi, Sang-Pil Woo, Y.S. Choi, S. Mirabbasi, S. Shekhar

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引用次数: 14

Abstract

To enable simultaneous full-duplex radios, self-interference (SI) cancellation (SIC) circuits that attain large cancellation bandwidths (BWs) are needed to support modern standards such as Long-Term Evolution (LTE). For mobile applications, SIC should be linear, tunable, fully monolithic (compact form factor) and must be implemented at the radio-frequency (RF) front-end. Emulating the group delay (GD) and complex impedance of the SI channel, an SIC circuit is proposed that achieves an 80 MHz of SIC BW using just a single tap delay. GD is estimated using frequency translations and baseband (BB) low pass filtering, and complex impedance is emulated using a vector modulator (VM). We prove that the combination of GD and VM results in a time-domain Hilbert transform equalization (HTE), enabling broadband cancellation and reducing the number of GD taps needed, thereby saving area. Implementing HTE at BB using passive circuits further reduces area, power consumption and maintains linearity. A prototype in 0.13-µm CMOS process occupies 0.4 mm2 and attains 23 dB of SIC measured over an 80-MHz signal BW, while consuming 13 mW. Total power and area including the receiver is 64.4 mW and 0.72mm2, respectively.

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采用基带希尔伯特变换均衡的80MHz带宽全双工接收机自干扰消除电路

为了同时实现全双工无线电，需要实现大消除带宽(BWs)的自干扰(SI)消除(SIC)电路来支持现代标准，如长期演进(LTE)。对于移动应用，SIC应该是线性的、可调的、全单片的(紧凑的外形因素)，并且必须在射频(RF)前端实现。模拟SI通道的群延迟(GD)和复杂阻抗，提出了一种仅使用单抽头延迟即可实现80 MHz SIC BW的SIC电路。使用频率平移和基带(BB)低通滤波估计GD，使用矢量调制器(VM)模拟复杂阻抗。我们证明了GD和VM的组合导致时域希尔伯特变换均衡(HTE)，实现宽带抵消并减少所需的GD抽头数量，从而节省面积。在BB使用无源电路实现HTE进一步减少面积，功耗和保持线性。0.13µm CMOS工艺的原型占地0.4 mm2，在80 mhz信号BW下测量到23 dB的SIC，同时消耗13 mW。包括接收器在内的总功率和面积分别为64.4 mW和0.72mm2。

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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2017 IEEE Radio Frequency Integrated Circuits Symposium (RFIC)

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