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Design and measurement of 0.1 – 4.5 GHz SiGe BiCMOS MMIC digital step attenuator

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Abstract:

The design and measurement of 0.1 – 4.5 GHz 5-bit MMIC digital step attenuator (DSA) are presented. The MMIC DSA is fabricated with 0.25 um SiGe BiCMOS process and includ...Show More

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Abstract:

The design and measurement of 0.1 – 4.5 GHz 5-bit MMIC digital step attenuator (DSA) are presented. The MMIC DSA is fabricated with 0.25 um SiGe BiCMOS process and includes integrated driver providing serial/parallel control. The main features of MMIC DSA are as follows: wideband performances (it covers L-, S- and partially C-band); a good input and output return losses (less than 12 dB and 14 dB, respectively); small phase variation (RMS phase error less than 5.3°); integrated driver; small size (1.4×0.6 mm²); low power consumption Performances of MMIC DSA designed are compared with its commercial counterparts.

Published in: 2016 13th International Scientific-Technical Conference on Actual Problems of Electronics Instrument Engineering (APEIE)

Date of Conference: 03-06 October 2016

Date Added to IEEE Xplore: 05 January 2017

ISBN Information:

DOI: 10.1109/APEIE.2016.7802221

Conference Location: Novosibirsk, Russia

Citations are not available for this document.

Contents

I. Introduction

Microwave digital step attenuators (DSA) are widely used in transmit/receive modules (TRMs) applied for radar and radio-relay systems [1]. Microwave TRMs usually use microwave monolithic integrated circuits (MMICs) manufactured with A3B5 semiconductors technologies (GaAs and GaN). However, now the circuits for controlling the microwave signal's amplitude and phase in TRM (attenuators, phase shifters, and switches) are increasingly fabricated with SiGe BiCMOS technology [2], [3]. In comparison with A3B5, this process provides a higher integration scale, smaller weight, size and cost, and lower power consumption. In addition, the important advantage of SiGe BiCMOS technology is the ability to combine analog and complex digital control circuits (drivers) in a single fabrication process. Contrary, the use of A3B5 manufacturing technology for implementing digital drivers is much more complicated, enlarges the development cost, increases MMIC size and limits control capabilities [2], [3].

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Cites in Papers - IEEE (8)

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Genyin Ma, Fanyi Meng, Keping Wang, Kaixue Ma, Kiat Seng Yeo, "A S/C-Band 5-Bit Passive Attenuator With Phase-Lead Compensation in 55-nm Bulk CMOS", IEEE Transactions on Circuits and Systems II: Express Briefs, vol.71, no.3, pp.1082-1085, 2024.

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Yudhbir, Ravi Khatri, Jolly Dhar, Ch. V.N Rao, "Design of a Wideband Digital Attenuator MMIC Over 1 to 10 GHz", 2023 IEEE Microwaves, Antennas, and Propagation Conference (MAPCON), pp.1-5, 2023.

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Yang He, Tiedi Zhang, Yichen Tang, Chao Fan, Bo Yan, "Wideband pHEMT Digital Attenuator With Positive Voltage Control Driver", IEEE Microwave and Wireless Technology Letters, vol.33, no.3, pp.295-298, 2023.

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Haohao Xiao, Jianquan Hu, Kaixue Ma, "A DC-6 GHz 7-Bit Digital Attenuator with Low Insertion Loss", 2021 IEEE 4th International Conference on Electronics Technology (ICET), pp.95-98, 2021.

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Yibing Wu, Jianquan Hu, Kaixue Ma, "A DC-4GHz 6-Bit Digital Attenuator with High Accuracy and Low Insertion Loss", 2021 IEEE 4th International Conference on Electronics Technology (ICET), pp.352-355, 2021.

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F.I. Sheyerman, I.M. Dobush, A.A. Kokolov, A.S. Salnikov, M.V. Cherkashin, L.I. Babak, M.L. Shevlyakov, Yu. A. Svetlichniy, E.V. Grigoriev, S. Yu. Uimanov, "Broadband IP-blocks for L- and S-band receiver SoC based on 0.25 um SiGe technology", 2017 Dynamics of Systems, Mechanisms and Machines (Dynamics), pp.1-4, 2017.

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I. M. Dobush, A. A. Kalentyev, D. A. Zhabin, A. E. Goryainov, A. S. Salnikov, F. I. Sheyerman, D. V. Garays, "Automated synthesis and measurement of broadband CMOS buffer amplifier 1–5 GHz", 2017 International Siberian Conference on Control and Communications (SIBCON), pp.1-4, 2017.

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Cites in Papers - Other Publishers (1)

Kangrui Wang, Zhiyu Wang, Gang Wang, Hua Chen, Qin Zheng, Faxin Yu, "Design of a low-insertion-phase-shift MMIC attenuator integrated with a serial-to-parallel converter", IEICE Electronics Express, 2017.

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Design and measurement of 0.1 – 4.5 GHz SiGe BiCMOS MMIC digital step attenuator

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Abstract:

I. Introduction

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Design and measurement of 0.1 – 4.5 GHz SiGe BiCMOS MMIC digital step attenuator

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Abstract:

Metadata

Abstract:

I. Introduction

Cites in Papers - IEEE (8) | Other Publishers (1)

Cites in Papers - IEEE (8)

Cites in Papers - Other Publishers (1)

References

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