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Fully Integrable BiCMOS Classical Rat-Race Coupler Based on Coplanar Striplines | IEEE Conference Publication | IEEE Xplore
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Fully Integrable BiCMOS Classical Rat-Race Coupler Based on Coplanar Striplines

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Sherif R. Zahran; Luigi Boccia; Florence Podevin; Giandomenico Amendola; Philippe Ferrari
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Abstract:

In this paper, a classical rat-race coupler based on coplanar stripline is presented. It was built using BiCMOS 55nm technology. Parametrical analysis targeting the posit...Show More

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Abstract:

In this paper, a classical rat-race coupler based on coplanar stripline is presented. It was built using BiCMOS 55nm technology. Parametrical analysis targeting the position of additive compulsory dummies from selected high quality coplanar stripline is carried out. Two versions of the rat-race couplers are compared: without and with metallic dummies. Simulation results show that isolation and reflection coefficients are preserved under 20 dB. With dummies considered, insertion loss value is 4.2 dB at 118 GHz. With the addition of metallic dummies coupler performance is down shifted in frequency with value of 2 GHz. Maximum amplitude imbalance is 0.4 dB reported at 140 GHz while phase imbalance difference between both cases doesn't exceed 3.1° for the whole bandwidth of interest.
Published in: 2023 International Microwave and Antenna Symposium (IMAS)
Date of Conference: 07-09 February 2023
Date Added to IEEE Xplore: 20 March 2023
ISBN Information:
DOI: 10.1109/IMAS55807.2023.10066879
Conference Location: Cairo, Egypt
References is not available for this document.
Contents

I. Introduction

Development of millimeter-wave (mm-wave) subsystems has grown very significantly [1], [2]. Compared with standard CMOS technology, advanced SiGe-based ones can support higher operation frequencies to realize mm-wave power amplifiers (PAs) [3]. Moreover, SiGe-based technologies can be used to realize full system on chip (SoC) with reduced cost when compared with III/V technology [4]. Many passive circuits are necessary to achieve complete systems in this technology, like directional couplers (including rat-races), power dividers, filters. These circuits mainly depend on transmission lines (TLs) when dealing with frequencies exceeding about 100 GHz.

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