Sascha A. Figur scite author profile

Abstract-This paper describes the concept and the development of key components of a novel multiple-beam antenna for satellite applications. The antenna is designed to be used in a transparent high-rate data relay system that links several low earth orbit (LEO) satellites to a single ground station via a satellite positioned on a geostationary orbit (GEO). The proposed antenna is based on the concept of an array-fed reflector. The antenna can track LEO satellites by switching between different subarrays of a bigger multifeed array using a reconfigurable switch matrix based on radio frequency micro-electromechanical system (RF MEMS) switches. The radiation characteristic of the antenna is further improved by combining digital beamforming with beam switching. In order to validate the proposed antenna concept and to show its suitability for space applications a demonstrator has been built. Measurements of the antenna's key components and of the demonstration system are given.

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RF-MEMS variable matching networks and switches for multi-band and multi-mode GaN power amplifiers

Figur¹,

Raay²,

Quay³

et al. 2014

Int. J. Microw. Wireless Technol.

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This work presents radio-frequency-microelectromechanical-system (RF-MEMS)-based tunable matching networks for a multi-band gallium nitride (GaN) power amplifer (PA) application. In the frequency range from 3.5-8.5GHz return losses of 5-10dB were measured for the input network, matching impedances close to the border of the Smith chart. For the output matching network return losses of 10-20dB and insertion losses of 1.3-2dB were measured. The matching networks can tune the PA to four different operating frequencies, as well as changing the transistor's mode of operation from maximum delivered-output-power to maximum power-added-efficiency (PAE), while keeping the operating frequency constant. Furthermore, different single pole double throw (SPDT)-switches are designed and characterized, to be used in frequency-agile transmit/receive-modules (T/R modules)

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Simulation of RF MEMS based matching networks and a single pole double throw switch for Multiband T/R Modules

Figur¹,

Raay

Quay

et al. 2013

Adv. Radio Sci.

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Abstract. This work presents concepts and designs for two essential components of a frequency agile transmit and receive module based on Radio Frequency Micro Electro Mechanical System (RF MEMS) switches for the frequency range from 3.5 GHz up to 8.5 GHz. The advantages of a variable power amplifier (PA) matching compared to a fixed broadband solution are examined and discussed in context with the designed components. To demonstrate the principle functionality, an assembly concept is presented, which allows for the integration of a frequency agile 6 W power amplifier with surrounding components like phase shifters, switches and antennas. An RF MEMS switching element is introduced as a high isolation polarization switch, featuring low insertion loss as well as almost no DC power consumption.

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The low-complexity RF MEMS switch at EADS: an overview

Schoenlinner¹,

Stehle²,

Siegel

et al. 2011

Int. J. Microw. Wireless Technol.

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This paper gives an overview of the low-complexity radio frequency microelectromechanical systems (RF MEMS) switch concept and technology of EADS Innovation Works in Germany. Starting in 2003, a capacitive switch concept, which is unique in several aspects, was developed to address specific needs in the aeronautic and space. Thermally grown silicon oxide as dielectric layer, the silicon substrate as actuation electrode, and a conductive zone realized by ion implantation make the EADS RF MEMS switch a very simple, low-cost, and reliable approach. In this document, data on experimental investigations are presented, which demonstrate outstanding performance figures in terms of insertion loss, isolation, frequency range, bandwidth, RF-power handling, and robustness with respect to thermal load. Based on this concept, numerous different circuits in particular single-pole single-throws (SPSTs), single-pole multi-throws (SPMTs), tunable filters, phase shifters, and electronically steerable antennas between 6 and 100 GHz have been designed, fabricated, and characterized.

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Sascha A. Figur

Design and characterization of a simplified planar 16×8 RF MEMS switch matrix for a GEO-stationary data relay

A Satellite Multiple-Beam Antenna for High-Rate Data Relays

RF-MEMS variable matching networks and switches for multi-band and multi-mode GaN power amplifiers

Simulation of RF MEMS based matching networks and a single pole double throw switch for Multiband T/R Modules

The low-complexity RF MEMS switch at EADS: an overview

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