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An 800-ps Origami True-Time-Delay-Based CMOS Receiver Front End for 6.5–9-GHz Phased Arrays

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Abstract:

A true-time-delay-based (TTD-based) receiver front end with 800-ps time delay for 6.5-9-GHz wideband phased arrays has been designed for satellite communication in a 65-n...Show More

Topic: Asian Solid-State Circuits Conference (ASSCC)

Metadata

Abstract:

A true-time-delay-based (TTD-based) receiver front end with 800-ps time delay for 6.5-9-GHz wideband phased arrays has been designed for satellite communication in a 65-nm CMOS technology. The proposed receiver front end consists of a balanced low-noise amplifier (LNA), a 6-bit attenuator with 15.75-dB tuning range, a programmable TTD element featuring 800-ps delay with 25-ps delay step, and an output buffer amplifier. A differential origami inductor is proposed to boost the delay unit's quality factor and mitigate the insertion loss introduced by the artificial transmission line (ATL). A current-mode radio-frequency (RF) multiplexer is designed to ensure a rapid delay switching. The receiver front end demonstrates a 3.6-dB noise figure (NF) with an 18-dB typical gain and an input 1-dB compression point (IP1dB) of -17 dBm at 6.5-9 GHz. This TTD element allows for a low insertion loss and a small chip area per unit time delay of ATL-based RF TTDs.

Topic: Asian Solid-State Circuits Conference (ASSCC)

Published in: IEEE Solid-State Circuits Letters ( Volume: 3)

Page(s): 382 - 385

Date of Publication: 15 September 2020

Electronic ISSN: 2573-9603

DOI: 10.1109/LSSC.2020.3024250

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References is not available for this document.

Contents

I. Introduction

The wideband phased array has gained increasing attention in satellite communications due to its high data rate and great efficiency. In a 64- to 128-element phased array with a antenna spacing, a 4–6 programmable frequency-independent delay is required to compensate the path delay difference among different elements, where is the wavelength. Phase-shifter-based (PS-based) arrays support high-resolution phase adjustment. However, they are not suitable for wideband applications with the beam-squinting issue [1] in a large array, especially when the delay difference is much larger than one period. Hybrid architecture can be used to support wideband applications shown as the front-end radio-frequency (RF) beamformer in Fig. 1, where the front PSs are responsible for fine delay adjustment and the following RF true-time-delay (TTD) elements serve as coarse delay adjustment. For an even larger array, digital beamforming can be added after signal downconversion and quantization of each RF beamformer to generate large-scale TTDs digitally. This forms multiple beams within the field of view (FoV) constituted by front-end analog beamformers simultaneously, as shown in Fig. 1. Although the front PSs can greatly relax the resolution requirements of the following RF TTD elements down to a quarter or half of the signal period, it is fairly challenging to achieve a low-loss passive large TTD, which is often associated with frequency dependency deteriorating array performance [2]. Fig. 1.

Hybrid wideband phased array architecture combining front phase shifters, RF TTD elements, and digital beamformer. The RF TTD elements are highlighted in red.

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References is not available for this document.

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An 800-ps Origami True-Time-Delay-Based CMOS Receiver Front End for 6.5–9-GHz Phased Arrays

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An 800-ps Origami True-Time-Delay-Based CMOS Receiver Front End for 6.5–9-GHz Phased Arrays

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