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An ultra flat phased array Ku-band antenna with integrated receivers in SiGe BiCMOS

Published online by Cambridge University Press:  15 June 2015

Paul Klatser ,
Marc Van Der Vossen ,
Gerard Voshaar ,
Rinus Boot ,
Adriaan Hulzinga ,
Maikel Iven  and
Chris Roeloffzen
Paul Klatser*
Affiliation:
Bruco Integrated Circuits B.V., Oostermaat 2, 7623CS, Borne, The Netherlands. Phone: +31(0) 74 2406620
Marc Van Der Vossen
Affiliation:
Bruco Integrated Circuits B.V., Oostermaat 2, 7623CS, Borne, The Netherlands. Phone: +31(0) 74 2406620
Gerard Voshaar
Affiliation:
Bruco Integrated Circuits B.V., Oostermaat 2, 7623CS, Borne, The Netherlands. Phone: +31(0) 74 2406620
Rinus Boot
Affiliation:
Bruco Integrated Circuits B.V., Oostermaat 2, 7623CS, Borne, The Netherlands. Phone: +31(0) 74 2406620
Adriaan Hulzinga
Affiliation:
National Aerospace Laboratory (NLR), Voorsterweg 3, 8316 PR, Marknesse, The Netherlands
Maikel Iven
Affiliation:
V-PS, Kanaaldijk 8, 5735 SL, Aarle-Rixtel, The Netherlands
Chris Roeloffzen
Affiliation:
SATRAX Smart Antenna Satcom Sytems, Hengelosestraat 500, 7521 AN, Enschede, The Netherlands
*
Corresponding author: P. Klatser Email: paul.klatser@bruco.nl
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Abstract

A highly integrated Ku-band (10.7–12.75 GHz) planar phased array receiver of 64 antenna elements is presented. It features instantaneous reception of the full Ku-band (2.05 GHz wide) in two orthogonal polarizations with wide scan angles by using time delay instead of phase shift. The receiver is part of a system for satellite broadcast TV reception on board of moving vehicles. Two SiGe radio frequency integrated circuits (RFICs) were developed, packaged in ceramic BGAs and assembled onto a 15-layer printed circuit board (PCB) which integrates the antenna elements. An outline of the system is given along with a detailed description. It sets a new standard in integration density. The receiver has extensive analog signal processing at intermediate frequency (IF)-level. A novel bipolar implementation for true time delay is proposed, with a continuous programmable delay range of 0…80 ps with less than 2.5 ps group-delay variation in 2 GHz bandwidth (BW). The wide BW calls for a constant group-delay implementation in the IF chain. The receiver (RFIC) consumes only 132 mW per channel. Each channel has 40 dB gain.

Keywords

Phased arrayIntegratedKu-bandSatellite receiverTrue time delayLow powerFlat
Type
Industrial and Engineering Paper
Information
International Journal of Microwave and Wireless Technologies , Volume 7 , Special Issue 3-4: European Microwave Week 2014 , June 2015 , pp. 379 - 389
Copyright
Copyright © Cambridge University Press and the European Microwave Association 2015 

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References

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