Hostname: page-component-78c5997874-j824f Total loading time: 0 Render date: 2024-11-14T05:26:58.075Z Has data issue: false hasContentIssue false

Design and qualification of Ku-band-radiating chains for receive active array antennas of flexible telecommunication satellites

Published online by Cambridge University Press:  05 May 2020

Vincenzo Pascale*
Affiliation:
AIRBUS Italia S.p.A., Via dei Luxardo 22-24, Rome00156, Italy
Davide Maiarelli
Affiliation:
AIRBUS Italia S.p.A., Via dei Luxardo 22-24, Rome00156, Italy
Luciano D'Agristina
Affiliation:
AIRBUS Italia S.p.A., Via dei Luxardo 22-24, Rome00156, Italy
Nicola Gatti
Affiliation:
AIRBUS Italia S.p.A., Via dei Luxardo 22-24, Rome00156, Italy
*
Author for correspondence: Vincenzo Pascale, E-mail: vincenzo.pascale@airbus.com

Abstract

Airbus Italia recently developed enhanced passive components as key elements for its telecommunication Ku-band antenna product lines, tailored to reconfigurable payloads. This paper describes the design and qualification of a dual linear polarization Ku-band-radiating chain, developed for the DRA receive (Rx) active antennas embarked on the Eutelsat Quantum satellite. The feed chain covers the entire Ku-band frequency range allocated for fixed satellite services providing receive functionality and embedding sharp rejection features over the adjacent transmit band. The proposed design provides high radiation efficiency (>90%) and polarization purity (XPD > 33 dB), together with low RF losses and flat group-delay variation over a 13% fractional bandwidth, keeping a compact size and reduced axial length. The unit has been optimized for high reproducibility in high volume productions, typical of large DRA applications, for which stringent mass and dimensional constraints, as well as excellent amplitude and phase tracking among similar units, are key features. Details of the feed chain design and an overview of RF and environmental qualification test results are presented.

Type
Industrial and Engineering Paper
Copyright
Copyright © Cambridge University Press and the European Microwave Association 2020

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Jacomb-Hood, A and Lier, E (2000) Multibeam active phased arrays for communications satellites. IEEE Microwave Magazine 1, 4047.CrossRefGoogle Scholar
Lier, E and Melcher, R (2009) A modular and lightweight multibeam active phased receiving array for satellite applications: design and ground testing. IEEE Antennas and Propagation Magazine 51, 8090.CrossRefGoogle Scholar
Fenech, H, Amos, S and Waterfield, T (2016) The role of array antennas in commercial telecommunication satellites. 10th European Conference on Antennas and Propagation (EuCAP), 10 April 2016, pp. 14.CrossRefGoogle Scholar
Fenech, H, Amos, S, Moltzau, E and Guilleux, W (2017) How commercial satellites satisfy military-like requirements. 35th AIAA International Communications Satellite Systems Conference, p. 5431.CrossRefGoogle Scholar
Fenech, H, Amos, S, Tomatis, A, Soumpholphakdy, V and Serrano Merino, JL (2015) Eutelsat Quantum: a game changer. 33rd AIAA International Communications Satellite Systems Conference and Exhibition, p. 4318.CrossRefGoogle Scholar
Montesano, A ELSA+ Enhanced active Rx antenna system ELSA (Electronically Steerable Antenna)+: enhanced active Rx antenna system. Available at https://artes.esa.int/projects/elsa-enhanced-active-rx-antenna-system (As of 10 September 2018).Google Scholar
Montesano, A, de la Fuente, A, Bustamante, M, Arenas, S, Peña, D, Gonzalez, E, Herrera, I, Pacheco, F, Martin, A, Naranjo, M, Dirube, C, Gualo, A, Marcos, A, Rodriguez, JA, Gomez, J, Fenech, H, Amos, S, Piro, F, Le Pera, A, Roberts, I, Weinberg, S, Roux, JP, Polegre, AM, Otero, DG, Gidney, P and Granell, E (2017) ELSA+: An enabling technology for the flexibility and SW defined mission. 38th ESA “Antenna Workshop on Innovative Antenna Systems and Technologies for Future Space Missions”, 3–6 October 2017. Noordwijk, The Netherlands: ESA/ESTEC.Google Scholar
Alvarez, D, Peña, D, Montesano, A, Zornoza, A, Rubio, A, Acevedo, D, Lopez-Mateos Paino, J, de la Fuente, LF, Arenas, S, Mique, C and Villete, E (2011) HispaSat AG1 DRA-ELSA active antenna: RF design and performance. 33rd ESA Antenna Workshop on Challenges for Space Antenna Systems, 18–21 October 2011. Noordwijk, The Netherlands: ESA/ESTEC.Google Scholar
Gehring, R, Hartmann, J, Hartwanger, C, Hong, U, Ratkorn, N, Reiche, E and Wolf, H (2007) Trade-off for overlapping feed array configurations. 29th ESA Antenna Workshop on Multiple Beams and Reconfigurable Antennas, 18 April 2007. Noordwijk, The Netherlands: ESA/ESTEC, pp. 1820.Google Scholar
Pascale, V, Maiarelli, D, D'Agristina, L and Gatti, N (2019) Design and qualification of Ku-band radiating chains for receive active array antenna of flexible telecommunication satellites. In 2019 13th European Conference on Antennas and Propagation (EuCAP). IEEE, pp. 15.Google Scholar
Granet, C, James, GL, Bolton, R, and Moorey, G (2004) A smooth-walled spline-profile horn as an alternative to the corrugated horn for wide band millimeter-wave applications. IEEE Transactions on Antennas and Propagation 52, 848854.CrossRefGoogle Scholar
Bornemann, J and Yu, SY (2010) Circular waveguide TM11-mode resonators and their application to polarization-preserving bandpass and quasi-highpass filters. Proceedings of the IEEE “German Microwave Conference (GeMiC)”, Institute of Electrical and Electronics Engineers, Berlin, Germany, 15–17 March 2010, pp. 202205.Google Scholar
Rosenberg, U, Amari, S and Bornemann, J (2003) Inline TM110-mode filters with high design flexibility by utilizing bypass couplings of non-resonating TE10/01 modes. IEEE Transactions on Microwave Theory and Techniques 51, 17351742.CrossRefGoogle Scholar
Amari, S and Bornemann, J (2000) Design of mode converters using the coupled-integral-equations technique. Proceedings of the AP2000 Millennium Conference Antennas Propagation, April 2000, Davos, Switzerland, 3A1, 4p.Google Scholar
Uher, J, Bornemann, J and Rosenberg, U (1983) Waveguide Components for Antenna Feed Systems. Theory and CAD. Norwood, UK: Artech House.Google Scholar