Your search keyword '"Holger Maune"' showing total 155 results

1. RF Glass Technology Is Going Mainstream: Review and Future Applications

Author

Tobias Chaloun, Susanne Brandl, Norbert Ambrosius, Kevin Krohnert, Holger Maune, and Christian Waldschmidt

Subjects

MTT 70th Anniversary Special Issue, glass technology, dielectrics, packaging, interposer, system-on-package, Telecommunication, TK5101-6720, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

Driven by the increasing demand for high-throughput communication links and high-resolution radar sensors, the development of future wireless systems pushes at ever greater operating frequencies. By analogy, high-performance computing (HPC) systems with high-bandwidth I/Os have become a mainstream solution to address multi Gbit/s data rates. Heterogeneous integration technologies play a vital role here in enhancing the performance and functional density, along with reducing the size and costs of such RF systems. In line with this trend, many passive components, which have once been monolithically integrated, are now implemented on ceramic or polymer-based packages. Besides these long-established material and process technologies, considerable efforts have also recently been devoted to the development of RF components on glass and glass-ceramics. Spurred by their low dielectric losses, extremely smooth surfaces, and excellent dimensional stability, glass technologies are emerging as a promising alternative for high-volume and high-performance RF applications. In this article, relevant glass materials and key enabling technologies are reviewed and put into context with well-established RF substrate technologies. Another focus is set on the latest glass-based packaging and interposer solutions ranging from MHz-to-THz frequencies. To showcase the development activities and practical accomplishments of the RF glass technology, also a large variety of key components is presented. Finally, the paper concludes by discussing future research and development directions of RF glass devices.

Published

2023

2. Novel Hybrid Electric/Magnetic Bias Concept for Tunable Liquid Crystal Based Filter

Author

Ersin Polat, Fynn Kamrath, Stipo Matic, Henning Tesmer, Alejandro Jimenez-Saez, Dongwei Wang, Holger Maune, Michael Hoft, and Rolf Jakoby

Subjects

K-band, liquid crystals, microwave filter, millimeter wave communication, tunable circuits and devices, Telecommunication, TK5101-6720, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

This paper presents a novel hybrid bias concept for liquid crystal (LC) filter by using simultaneously electric and magnetic bias fields. It enables continuous tuning with a simplified electrode design, decreased number of electrodes and reduced bias voltage. Furthermore, the tuning efficiency is increased, since the homogeneous bias fields enable a full exploitation of the LC's anisotropy. To demonstrate this concept, a novel reconfigurable gap waveguide two-pole bandpass filter with tunable center frequency and coupling elements is designed at $30 \,\mathrm{GHz}$. Liquid crystal technology is applied as tunable material, whereby tunability of the center frequency and coupling elements is obtained by controlling the LC's effective permittivity. The presented filter's center frequency can be tuned from $28.88 \,\mathrm{GHz}\,\mathrm{to}\, 29.88 \,\mathrm{GHz}$ with a maximum bias voltage of 100 V, with a return loss of 20 dB and low insertion loss of only 1.65 to 1.95 dB.

Published

2022

3. Fast and Miniaturized Phase Shifter With Excellent Figure of Merit Based on Liquid Crystal and Nanowire-Filled Membrane Technologies

Author

Dongwei Wang, Ersin Polat, Christian Schuster, Henning Tesmer, Gustavo P. Rehder, Ariana L. C. Serrano, Leonardo G. Gomes, Philippe Ferrari, Holger Maune, and Rolf Jakoby

Subjects

IP3, liquid crystal, microstrip line, nanowires, phase shifter, slow-wave, Telecommunication, TK5101-6720, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

This paper presents a highly miniaturized tuneable microstrip line phase shifter for 5 GHz to 67 GHz. The design takes advantage of the microstrip topology by substituting the ground plane by a metallic-nanowire-filled porous alumina membrane (NaM). This leads to a slow-wave (SW) effect of the transmission line; thus, the transmission line can be physically compact while maintaining its electric length. By applying a liquid crystal (LC) with its anisotropic permittivity as substrate between the transmission line and the NaM, a tuneable microstrip line phase shifter is realized. Three demonstrators are identically fabricated filled with different types of high-performance microwave LCs from three generations (GT3-23001, GT5-26001 and GT7-29001). The measurement results show good matching in a $50\ \Omega$ system with reflection less than −10 dB over a wide frequency range. These demonstrators are able to reach a maximum figure of merit (FoM) of 41 $^{\circ }$/dB, 48 $^{\circ }$/dB, and 70 $^{\circ }$/dB for different LCs (GT3-23001, GT5-26001 and GT7-29001, respectively). In addition, experiments show that all three LCs should be biased with square wave voltage at approximately 1 kHz to achieve maximum tuneability and response speed. The achieved response times with GT3-23001, GT5-26001 and GT7-29001 are 116 ms, 613 ms, and 125 ms, respectively, which are much faster than other reported LC phase shifter implementations. Large-signal analysis shows that these implementations have high linearity with third-order interception (IP3) points of approximately 60 dBm and a power handling capability of 25 dBm.

Published

2022

4. Bandwidth and Center Frequency Reconfigurable Waveguide Filter Based on Liquid Crystal Technology

Author

Fynn Kamrath, Ersin Polat, Stipo Matic, Christian Schuster, Daniel Miek, Henning Tesmer, Patrick Boe, Dongwei Wang, Rolf Jakoby, Holger Maune, and Michael Hoft

Subjects

Microwave filter, liquid crystals, millimeter wave communication, tunable circuits and devices, K-band, Telecommunication, TK5101-6720, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

This paper presents for the first time a fully electronically reconfigurable waveguide filter tunable in bandwidth and center frequency based on liquid crystal (LC) technology. A continuously reconfigurable two pole bandpass filter is designed and characterized in the Ka-band at $30 \,\mathrm{GHz}$. To be able to tune both center frequency and bandwidth independently, the resonators and coupling structures are filled with LC as tunable material. Hence, the filter’s center frequency and coupling strengths can be tuned and, furthermore, tuning with constant filter characteristic is possible. To tune the LC, a novel two-layer electrode design for waveguide structures is presented, which is simple to integrate and provides a high tuning efficiency with low insertion loss. By applying different bias configurations, the LC’s effective permittivity can be varied, and therefore, also the resonators’ electrical lengths. The presented two pole filter can adapt its center frequency from $29.8 \,\mathrm{GHz}\,{\rm to}\, 30.7 \,\mathrm{GHz}$ with a maximum $3 \,{\rm dB}$ bandwidth variation from $660 \,\mathrm{MHz}\,{\rm to}\, 870 \,\mathrm{MHz}$. The measurements are carried out with bias voltages up to $\pm$$250 \,\mathrm{V}$.

Published

2022

5. Ridge Gap Waveguide Based Liquid Crystal Phase Shifter

Author

Matthias Nickel, Alejandro Jimenez-Saez, Prannoy Agrawal, Ahmed Gadallah, Andrea Malignaggi, Christian Schuster, Roland Reese, Henning Tesmer, Ersin Polat, Dongwei Wang, Peter Schumacher, Rolf Jakoby, Dietmar Kissinger, and Holger Maune

Subjects

Liquid crystals (LC’s), tunable phase shifter, phased array, gap waveguide, bed of nails, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this paper, the gap waveguide technology is examined for packaging liquid crystal (LC) in tunable microwave devices. For this purpose, a line based passive phase shifter is designed and implemented in a ridge gap waveguide (RGW) topology and filled with LC serving as functional material. The inherent direct current (DC) decoupling property of gap waveguides is used to utilize the waveguide surroundings as biasing electrodes for tuning the LC. The bed of nails structure of the RGW exhibits an E-field suppression of 76 dB in simulation, forming a completely shielded device. The phase shifter shows a maximum figure of merit (FoM) of 70 °/dB from 20 GHz to 30 GHz with a differential phase shift of 387° at 25 GHz. The insertion loss ranges from 3.5 dB to 5.5 dB depending on the applied biasing voltage of 0 V to 60 V.

Published

2020

6. Concept for Continuously Tunable Output Filters for Digital Transmitter Architectures

Author

Christian Schuster, Lukas Schynol, Andreas Wentzel, Florian Huhn, Ersin Polat, Sonke Schmidt, Rolf Jakoby, Wolfgang Heinrich, and Holger Maune

Subjects

Tunable circuits and devices, microwave power amplifiers, digital amplifiers, GaN, tunable filters, BST, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a novel output filter approach for continuously frequency-tunable digital power amplifiers, suitable for future seamless and band-less applications in 5G, e.g. for cognitive radios (CR). The presented tunable output filter is based on a multi-bandstop lowpass response to regenerate the original microwave signal at the output of the digital amplifier stage by suppressing unwanted frequency components. Compared to conventional tunable bandpass solutions, it offers higher tunability, higher linearity, good power handling capability and moderate losses especially around the carrier frequency. A tunable power amplifier (PA) demonstrator consisting of a 4-stage digital GaN PA MMIC and the novel tunable filter, is designed and fabricated for a carrier frequency range from 1 GHz to 3 GHz. Tunability is achieved by using commercial barium strontium titanate (BST) varactors. Small signal measurements were performed to evaluate tunability and suppression capabilities of the novel filter structure, which reveal a frequency tunability of 67% with a suppression level of at least 13 dB for the undesired frequency components. The proposed filter structure exhibits a linearity over the tuning range with an OIP3 between 66 dBm to 70 dBm and high power handling capability. Finally, the performance analysis of the tunable PA demonstrator shows an peak efficiency of 70%. Due to frequency limitations of the used PA stage, the efficiency slowly degrades to 20% at the upper frequency band edge. Simultaneously, the output power varies between 27 dBm to 31 dBm.

Published

2019

7. Liquid Crystal Based Dielectric Waveguide Phase Shifters for Phased Arrays at W-Band

Author

Roland Reese, Ersin Polat, Henning Tesmer, Jonathan Strobl, Christian Schuster, Matthias Nickel, Angel Blanco Granja, Rolf Jakoby, and Holger Maune

Subjects

Phased array, millimeter wave devices, microwave liquid crystal, dielectric waveguide, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this work, the feasibility of microwave liquid crystal based dielectric waveguide phased shifters is investigated in a phased rod antenna array for the first time. For this, a 1×4 rod antenna array is designed including the phase shifters as well as a cascaded E-plane power divider network. As core elements, the phase shifter are designed as continuously tunable subwavelength fibers, partially filled with a newly specifically synthesized microwave liquid crystal, exhibiting a maximum FoM 145°/dB at 102.5GHz. As proof-of-concept, a simplified electric biasing network is developed, demonstrating its beam steering capability by changing the scanning angle between 0°, -25° and +15° with three different voltage distributions. The antenna array is well matched throughout the complete W-band with a input reflection below -10 dB. The measured antenna gain is between 11.5 to 9.1 dBi at 85 GHz accompanied with a side lobe level between -12 to -7 dB, depending on the steering configuration.

Published

2019

8. Suppression of Acoustic Resonances in BST-Based Bulk-Ceramic Varactors by Addition of Magnesium Borate

Author

Prannoy Agrawal, Daniel Kienemund, Dominik Walk, Stipo Matic, Nicole Bohn, Kevin Häuser, Thomas Fink, Mike Abrecht, Walter Bigler, Joachim R. Binder, Rolf Jakoby, and Holger Maune

Subjects

barium strontium titanate (BST), magnesium borate, acoustic resonances, electrostriction, bulk-ceramics, Crystallography, QD901-999

Abstract

This work presents a method for reducing acoustic resonances in ferroelectric barium strontium titanate (BST)-based bulk ceramic varactors, which are capable of operation in high-power matching circuits. Two versions of parallel-plate varactors are manufactured here: one with pure BST and one with 10 vol-% magnesium borate, Mg3B2O6 (MBO). Each varactor includes a 0.85-mm-thick ferroelectric layer. Acoustic resonances that are present in the pure BST varactor are strongly suppressed in the BST-MBO varactor and, hence, the Q-factor is increased over a wide frequency range by the addition of small amounts of a low-dielectric-constant (LDK) MBO. Although the tunability is reduced due to the presence of non-tunable MBO, the increased Q-factor extends the varactor’s availability for low-loss and high-power applications.

Published

2021

9. Temperature Characterization of Liquid Crystal Dielectric Image Line Phase Shifter for Millimeter-Wave Applications

Author

Henning Tesmer, Rani Razzouk, Ersin Polat, Dongwei Wang, Rolf Jakoby, and Holger Maune

Subjects

millimeter wave, microwave liquid crystal, temperature coefficient, characterization, dielectric image line, phase shifter, Crystallography, QD901-999

Abstract

In this paper we investigate the temperature dependent behavior of a liquid crystal (LC) loaded tunable dielectric image guide (DIG) phase shifter at millimeter-wave frequencies from 80 GHz to 110 GHz for future high data rate communications. The adhesive, necessary for precise fabrication, is analyzed before temperature dependent behavior of the component is shown, using the nematic LC-mixture GT7-29001. The temperature characterization is conducted by changing the temperature of the LC DIG’s ground plane between −10∘C and 80 ∘C. The orientation of the LC molecules, and therefore the effective macroscopic relative permittivity of the DIG, is changed by inserting the temperature setup in a fixture with rotatable magnets. Temperature independent matching can be observed, while the insertion loss gradually increases with temperature for both highest and lowest permittivity of the LC. At 80 ∘C the insertion loss is up to 1.3dB higher and at −10∘C it is 0.6dB lower than the insertion loss present at 20 ∘C. In addition, the achievable differential phase is reduced with increasing temperature. The impact of molecule alignment to this reduction is shown for the phase shifter and an estimated 85% of the anisotropy is still usable with an LC DIG phase shifter when increasing the temperature from 20 ∘C to 80 ∘C. Higher reduction of differential phase is present at higher frequencies as the electrical length of the phase shifter increases. A maximum difference in differential phase of 72∘ is present at 110 GHz, when increasing the temperature from 20 ∘C to 80 ∘C. Nevertheless, a well predictable, quasi-linear behavior can be observed at the covered temperature range, highlighting the potential of LC-based dielectric components at millimeter wave frequencies.

Published

2021

10. Microwave Liquid Crystal Technology

Author

Holger Maune

Subjects

liquid crystal, 5G communications, millimeter wave devices, steerable antennas, tunable filters, Crystallography, QD901-999

Abstract

Information and communication technologies (ICT) are the foundation of growth and development in the modern global economy [...]

Published

2020

11. Reconfigurable Millimeter-Wave Components Based on Liquid Crystal Technology for Smart Applications

Author

Ersin Polat, Henning Tesmer, Roland Reese, Matthias Nickel, Dongwei Wang, Peter Schumacher, Rolf Jakoby, and Holger Maune

Subjects

liquid crystal, millimeter wave devices, steerable antennas, dielectric waveguide, tunable filters, Crystallography, QD901-999

Abstract

This paper presents recent development of tunable microwave liquid crystal (LC) components in the lower millimeter wave (mmW) regime up to the W-band. With the utilization of increasing frequency, conventional metallic waveguide structures prove to be impractical for LC-based components. In particular, the integration of the electric bias network is extremely challenging. Therefore, dielectric waveguides are a promising alternative to conventional waveguides, since electrodes can be easily integrated in the open structure of dielectric waveguides. The numerous subcategories of dielectric waveguides offer a high degree of freedom in designing smart millimeter wave components such as tunable phase shifters, filters and steerable antennas. Recent research resulted in many different realizations, which are analyzed in this paper. The first demonstrators of phased array antennas with integrated LC-based phase shifters are reviewed and compared. In addition, beam steering with a single antenna type is shown. Furthermore, the possibility to realize tunable filters using LC-filled dielectric waveguides is demonstrated.

Published

2020

12. Microwave Liquid Crystal Technology

Author

Holger Maune, Matthias Jost, Roland Reese, Ersin Polat, Matthias Nickel, and Rolf Jakoby

Subjects

liquid crystal, millimeter wave devices, steerable antennas, dielectric waveguide, rectangular waveguides, communication systems, Crystallography, QD901-999

Abstract

Tunable Liquid Crystal (LC)-based microwave components are of increasing interest in academia and industry. Based on these components, numerous applications can be targeted such as tunable microwave filters and beam-steering antenna systems. With the commercialization of first LC-steered antennas for Ku-band e.g., by Kymeta and Alcan Systems, LC-based microwave components left early research stages behind. With the introduction of terrestrial 5G communications systems, moving to millimeter-wave communication, these systems can benefit from the unique properties of LC in terms of material quality. In this paper, we show recent developments in millimeter wave phase shifters for antenna arrays. The limits of classical high-performance metallic rectangular waveguides are clearly identified. A new implementation with dielectric waveguides is presented and compared to classic approaches.

Published

2018

13. A Planar Quasi Yagi-Uda Antenna Designed For Liquid Crystal Based End-Fire Phased Arrays.

Author

Dongwei Wang, Matthias Nickel, Peter Schumacher, Ersin Polat, Henning Tesmer, Rolf Jakoby, and Holger Maune

Published

2021

14. Cross-coupled open-loop resonator bandpass filter with independently tunable center frequency and bandwidth.

Author

Christian Schuster, Ran Hu, Alex Wiens, Matthias Maasch, Rolf Jakoby, and Holger Maune

Published

2018

15. IMS2023 Paper Competitions

Author

Holger Maune, Michael Roberg, Freek van Straaten, R. Neil Braithwaite, Jonas Urbonas, and Paolo de Falco

Subjects

Radiation, Electrical and Electronic Engineering, Condensed Matter Physics

Published

2023

16. RWW 2023 Technical Program Chair’s Message [RWW 2023]

Author

Holger Maune

Subjects

Radiation, Electrical and Electronic Engineering, Condensed Matter Physics

Published

2022

17. Moving Toward an MTT-S Payload in Space: Progress and Status of the MTT-Sat Challenge

Author

Markus Gardill and Holger Maune

Subjects

Radiation, Electrical and Electronic Engineering, Condensed Matter Physics

Published

2022

18. Switched and Steered Beam End-Fire Antenna Array Fed by Wideband Via-Less Butler Matrix and Tunable Phase Shifters Based on Liquid Crystal Technology

Author

Dongwei Wang, Ersin Polat, Henning Tesmer, Holger Maune, and Rolf Jakoby

Subjects

Electrical and Electronic Engineering

Published

2022

19. IEEE Radio and Wireless Week 2022 [Conference Report]

Author

Kevin Chuang, Alexander Koelpin, Changzhi Li, and Holger Maune

Subjects

Radiation, Electrical and Electronic Engineering, Condensed Matter Physics

Published

2022

20. Highly Miniaturized Continuously Tunable Phase Shifter Based on Liquid Crystal and Defected Ground Structures

Author

Dongwei Wang, Ersin Polat, Henning Tesmer, Rolf Jakoby, and Holger Maune

Subjects

Electrical and Electronic Engineering, Condensed Matter Physics

Published

2022

21. Compact DC to 110 GHz Crossover Based on Metallic-Nanowire-Filled Membrane

Author

Rolf Jakoby, Holger Maune, Bruno M. Verona, Dongwei Wang, Philippe Ferrari, Gustavo P. Rehder, and Ariana L. C. Serrano

Subjects

Materials science, business.industry, Crossover, Nanowire, Condensed Matter Physics, High isolation, Microstrip, Line (electrical engineering), Membrane, Phase imbalance, Insertion loss, Optoelectronics, Electrical and Electronic Engineering, business

Abstract

This letter presents an ultra-wideband crossover based on metallic-nanowire-filled membrane (MnM) from dc to 110 GHz. Two designs are proposed with reduced insertion loss and high isolation. Design Type 1 presents a 1.2 dB insertion loss and 19 dB isolation up to 80 GHz, with a phase imbalance of 14° at 80 GHz. This important phase imbalance is due to CPW that passes under the top microstrip (MS) line. To improve the device, a CPW was used in both paths. The improved design Type 2 shows a 1.5 dB insertion loss, 0.2 dB insertion loss imbalance, and 3.3° phase imbalance at 110 GHz. The latter presents a measured isolation of 38 dB up to 70 GHz and a simulated isolation better than 30 dB up to 110 GHz.

Published

2022

22. Network-Structured BST/MBO Composites Made from Core-Shell-Structured Granulates

Author

Kevin Häuser, Zhiren Zhou, Prannoy Agrawal, Rolf Jakoby, Holger Maune, and Joachim R. Binder

Subjects

FEM, Technology, ceramic composite, tunability, dielectric behavior, General Materials Science, ddc:600

Abstract

A finite element method (FEM)-based simulation approach to predict the tunability in composite materials was developed and tested with analytical data. These tests showed good prediction capabilities of the simulation for the test data. The simulation model was then used to predict the tunability of a network-structured composite, where the dielectric phase formed clusters in a paraelectric network. This was achieved by simulating a reciprocal core-shell unit cell of said network. The simulation showed a high tunability for this network model, exceeding the tunability of the analytically evaluated layered, columnar, and particulate model. The simulation results were experimentally verified with a Ba0.6Sr0.4TiO3/Mg3B2O6 (BST/MBO) composite, where core-shell granulates were made with a two-step granulation process. These structured samples showed higher tunability and dielectric loss than the unstructured samples made for comparison. Overall, the structured samples showed higher tunability to loss ratios, indicating their potential for use in tunable radio frequency applications, since they may combine high performance with little energy loss.

Published

2023

23. International Conference on Microwave Acoustics & Mechanics [Conference Reports]

Author

Amelie Hagelauer, Holger Maune, and Publica

Subjects

IEEE Microwave Magazine, Radiation, International Conference on Microwave Acoustics & Mechanics, IC-MAM 2022, Electrical and Electronic Engineering, Condensed Matter Physics

Abstract

After being postponed for two years, the inaugural edition of the IEEE Microwave Theory and Technology Society (MTT-S) International Conference on Microwave Acoustics & Mechanics (IC-MAM) was held from 18 to 20 July 2022 in the Training Center of Rohde & Schwarz in Munich, Germany. It was financially sponsored by the IEEE MTT-S (Figure 1) and technically cosponsored by the European Microwave Association.

Published

2023

24. Electromagnetic modeling of tunability of Barium Strontium Titanate and Magnesium Borate composites

Author

Prannoy Agrawal, Stipo Matic, Kevin Häuser, Joachim R. Binder, Holger Maune, Ersin Polat, and Rolf Jakoby

Subjects

EM modeling, Technology, Composite tunability model, Process Chemistry and Technology, Materials Chemistry, Ceramics and Composites, ddc:600, Barium Strontium Titanate (BST), Magnesium Borate (MBO), Ferroelectric-composites, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

A complete tunability electromagnetic simulation model for the Ba$_{0.6}$Sr$_{0.4}$TiO$_3$ (BST), with 𝜀𝑟 ≈ 2000, and Mg$_2$B$_2$O$_6$ (MBO), with 𝜀𝑟 ≈ 7, composites is proposed here. The model is based on electrostatics, to simulate the effects of bias fields distribution in the composite varactor at the unbiased state to create the biased state for all volumetric mixture compositions. A bulk-ceramic varactor approach is chosen for the fabricated varactors. Varactors are fabricated with different volume compositions of BST and MBO, ranging from 10 to 100 vol-% of BST. Simulated results of the varactor model are then verified with the measured results of the varactor. The simulated and measured tunability shows considerable discrepancy at room temperature, which leads to Curie temperature 𝑇$_𝐶$ investigation of the fabricated varactors. It has been observed that a shift in 𝑇$_𝐶$ is directly proportional to the discrepancies in the simulated and measured tunability. After incorporating the 𝑇$_𝐶$ shifts in the model, the results show close proximity between measured and 𝑇$_𝐶$ -shifted simulated tunabilities with differences being reduced from around 32% to 2% for 80 vol-% BST varactor.

Published

2023

25. Reconfigurable radio frontends for cooperative sensor networks: Tasks and challenges.

Author

Erick Gonzalez-Rodriguez, Holger Maune, Lufei Shen, Ibrahim A. Shah, Dirk Dahlhaus, Klaus Hofmann, and Rolf Jakoby

Published

2013

26. Impact of group delay on tunable impedance matching networks based on Barium-Strontium-Titanate varactors.

Author

Erick Gonzalez-Rodriguez, Holger Maune, Yuliang Zheng 0002, Lufei Shen, Ibrahim Asghar Shah, Klaus Hofmann, Dirk Dahlhaus, and Rolf Jakoby

Published

2012

27. A coherent multi-reader approach to increase the working range of passive RFID systems.

Author

Bernd Kubina, Martin Schussler, Christian Mandel, Holger Maune, Dominikus Muller, Andreas Ziroff, and Rolf Jakoby

Published

2012

28. Sintering behavior and electrical properties of the paraelectric/dielectric composite system BST/MBO

Author

Prannoy Agrawal, Rolf Jakoby, Kevin Hauser, Joachim R. Binder, Michael J. Hoffmann, Holger Maune, and R. Azmi

Subjects

Permittivity, Materials science, Passivation, Composite number, Sintering, chemistry.chemical_element, Dielectric, Microstructure, Third phase, chemistry, Materials Chemistry, Ceramics and Composites, Composite material, Titanium

Abstract

The composite system Ba0.6Sr0.4TiO3/Mg3B2O6 (BST/MBO) was investigated in regard to the influence of sintering temperature and composition on the dielectric properties. Dilatometry measurements were carried out at up to 1200 °C. At 1050 °C, all composites with an MBO content of 22.0 vol% or more showed densities over 90 % of the theoretical value. An in-situ XRD study was conducted at up to 1200 °C. The formation of Mg2TiO4 was detected starting at 1120 °C. These data sets were used to make a set of compositions ranging from 17.8–79.7 vol% MBO. At 1050 °C, the element distribution at the BST/MBO interfaces was investigated via EDX and ToF-SIMS. It was observed that titanium migrates from the BST into the MBO, mostly in the interface region. The microstructure of the different compositions was determined via SEM and image analysis. Traces of a third phase were found even for samples sintered at 1050 °C. The dielectric properties of the samples were measured at 13.56 MHz and compared to the expected behavior from the literature. It was found that compositions in the middle of the spectrum showed reduced permittivity, loss, and tunability, resulting in an overall increase in the material quality factor when compared to the chosen model. This was attributed to the passivation of the BST at the interfaces.

Published

2021

29. A Compact and Fast $1 \times 4$ Continuously Steerable Endfire Phased-Array Antenna Based on Liquid Crystal

Author

Holger Maune, Henning Tesmer, Ersin Polat, Rolf Jakoby, and Dongwei Wang

Subjects

Physics, High impedance, DC block, Planar, Optics, business.industry, Phased array, Phase (waves), Electrical and Electronic Engineering, Antenna (radio), business, Phase shift module, DC bias

Abstract

This letter presents a planar endfire Yagi-Uda antenna phased array fed by a corporate network. The phase of each radiating element is controlled by a loaded line phase shifter based on liquid crystal technology. The phase shifters are meandered to minimize the dimension of the array and are measured to provide maximum differential phase shift of 400 ${^\circ }$ with a figure-of-merit of ${54}{{^\circ }\rm {dB}^{-1}}$ at 28.4 GHz. Each phase shifter is tuned individually by applying bias voltage through high impedance chromium line together with dc blocks. The array is designed for full-range scanning in E -plane with $>\!{360}{^\circ }$ phase shifters. Measurements show that it can be steered from −40 ${^\circ }$ to 40 ${^\circ }$ by applying dc bias in the range of 0–5 V and from −50 ${^\circ }$ to 60 ${^\circ }$ with degraded patterns. The maximum gain of the phased array antennas is measured to be 4.5 dBi. The array beam is able to be fast steered within approximately 1 s.

Published

2021

30. Universal wideband reconfigurable transceiver with extended frequency range up to 6 GHz.

Author

Erick Gonzalez-Rodriguez, Holger Maune, Yuliang Zheng 0002, and Rolf Jakoby

Published

2014

31. All-Oxide Varactor Electromechanical Properties Extracted by Highly Accurate Modeling Over a Broad Frequency and Electric Bias Range

Author

Alexey Arzumanov, Stefan J. Rupitsch, Philipp Komissinskiy, Lukas Zeinar, Rolf Jakoby, Dominik Walk, Prannoy Agrawal, Patrick Salg, Holger Maune, and Lambert Alff

Subjects

Materials science, Acoustics and Ultrasonics, business.industry, Biasing, Dielectric, Ferroelectricity, Piezoelectricity, Resonator, Electric field, Optoelectronics, Electrical and Electronic Engineering, business, Instrumentation, Electrical impedance, Microwave

Abstract

Since the dielectric permittivity of ferroelectric materials depends on the electric field, they allow designing switchable and continuously tunable devices for adaptive microwave front ends. Part of the ongoing research is the field of all-oxide devices, where epitaxial oxide conductors are used instead of polycrystalline metal electrodes, leading to epitaxial ferroelectric layers and resulting in high device performance. In particular, they allow engineering the acoustic properties separated from the electric ones due to the structural similarity between the dielectric and conducting oxide films. Two major results are reported in this work. First, a highly accurate model for the microwave impedance of ferroelectric varactors is derived that tracks the superposition of induced piezoelectricity and field extrusion into the substrate caused by thin electrodes. In difference to previous works, this model covers both a wide frequency and biasing range up to 12 GHz and 100 V/ [Formula: see text]. Second, the high model accuracy enables the determination of all relevant electric and mechanic properties based on a mere microwave characterization. This approach will be especially valuable when independent measurements of mechanical properties of the thin-film materials are impeded by a high integration of the devices. Though derived for all-oxide varactors, the presented model can as well be adapted for thin-film bulk acoustic wave resonators (FBARs) and varactors with conventional metal electrodes when eventual dead layers at the interface are modeled correctly.

Published

2021

32. Feasibility of Additively Manufactured Tunable Liquid Crystal Loaded Dielectric Waveguides

Author

Rolf Jakoby, Gerald Gold, Martin Vossiek, M. Sippel, Felix Bachbauer, Holger Maune, Henning Tesmer, and Ersin Polat

Subjects

Permittivity, Waveguide (electromagnetism), Materials science, business.industry, Attenuation, Microwave transmission, Condensed Matter Physics, Differential phase, Liquid crystal, Electrode, Optoelectronics, Electrical and Electronic Engineering, business, Dielectric waveguides

Abstract

This letter investigates the feasibility of the combination of additive manufacturing and liquid crystal (LC) loaded dielectric waveguides (DWGs) at ${W}$ -band (75–110 GHz). The waveguide is extruded such that it has a cavity in its center, used for LC hosting. Reproducible cross sections are achieved along the DWG and high agreement between differential phase shift and figure-of-merit (FoM) is obtained when the DWG is biased electrically or magnetically. Deembedding the structure shows attenuation constants between 0.12 and 0.33 dB/cm which lead to a high FoM in the range of 100°/dB to 160°/dB. According to simulations, higher values are obtainable if larger LC cavities are realized.

Published

2021

33. Slow-Wave MEMS phase shifter with Liquid Crystal for Reconfigurable 5G

Author

Leonardo Gomes, Dongwei Wang, Gustavo Palomino, Joao Le, Rolf Jakoby, Holger Maune, Philippe Ferrari, Ariana L.C. Serrano, and Gustavo P. Rehder

Published

2022

34. Introduction and Motivation

Author

Rolf Jakoby and Holger Maune

Published

2022

35. Microwave Liquid Crystal Technology

Author

Rolf Jakoby, Matthias Jost, Onur Hamza Karabey, Holger Maune, Matthias Nickel, Ersin Polat, Roland Reese, Henning Tesmer, and Christian Weickhmann

Published

2022

36. Reconfigurable Devices and Smart Antennas

Author

Holger Maune and Matthias Nickel

Published

2022

37. Considerations for V- and W-Band Inter-Satellite Links

Author

Holger Maune, Karl-Heinz Hubner, and Gerald Gold

Published

2022

38. RWW Mini Special Issue of IEEE Transactions on Microwave Theory and Techniques [RWW 2021]

Author

Holger Maune

Subjects

Radiation, Computer science, Electronic engineering, Electrical and Electronic Engineering, Microwave theory, Condensed Matter Physics

Published

2020

39. Ridge Gap Waveguide Based Liquid Crystal Phase Shifter

Author

Peter Schumacher, Christian Schuster, Dongwei Wang, Ahmed Gadallah, Roland Reese, Matthias Nickel, Prannoy Agrawal, Rolf Jakoby, Alejandro Jimenez-Saez, Ersin Polat, Andrea Malignaggi, Dietmar Kissinger, Henning Tesmer, and Holger Maune

Subjects

tunable phase shifter, Materials science, General Computer Science, 02 engineering and technology, gap waveguide, law.invention, Liquid crystal, law, 0202 electrical engineering, electronic engineering, information engineering, Figure of merit, Insertion loss, General Materials Science, Liquid crystals (LC’s), bed of nails, business.industry, 020208 electrical & electronic engineering, Direct current, General Engineering, 020206 networking & telecommunications, Biasing, Optoelectronics, phased array, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, lcsh:TK1-9971, Waveguide, Phase shift module, Microwave

Abstract

In this paper, the gap waveguide technology is examined for packaging liquid crystal (LC) in tunable microwave devices. For this purpose, a line based passive phase shifter is designed and implemented in a ridge gap waveguide (RGW) topology and filled with LC serving as functional material. The inherent direct current (DC) decoupling property of gap waveguides is used to utilize the waveguide surroundings as biasing electrodes for tuning the LC. The bed of nails structure of the RGW exhibits an E-field suppression of 76 dB in simulation, forming a completely shielded device. The phase shifter shows a maximum figure of merit (FoM) of 70 °/dB from 20 GHz to 30 GHz with a differential phase shift of 387° at 25 GHz. The insertion loss ranges from 3.5 dB to 5.5 dB depending on the applied biasing voltage of 0 V to 60 V.

Published

2020

40. Liquid-Crystal-Based Fully Dielectric Lateral Wave Beam-Steering Antenna

Author

Rolf Jakoby, Ersin Polat, Matthias Nickel, Holger Maune, Henning Tesmer, and Roland Reese

Subjects

Permittivity, Fabrication, Materials science, business.industry, Beam steering, 020206 networking & telecommunications, 02 engineering and technology, Dielectric, Optics, Liquid crystal, Electrode, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Antenna (radio), business, Beam (structure)

Abstract

This letter presents a fully dielectric beam-steering lateral antenna operating at the V-band (50 GHZ). The antenna consists of a semicircular Rexolite body with an embedded liquid crystal (LC) cavity. An electrode network is used in order to align the LC molecules such that they form reconfigurable areas of high and low permittivity. The area of high permittivity is used to steer the direction of the beam. Due to the dielectric nature of the antenna, it shows enhanced fabrication simplicity and a weight reduction factor of 21 when compared to previous work. In addition, the bias electrodes may have arbitrary shape and are easily accessible, ensuring a high versatility for future designs. The steering mechanism is nearly frequency-independent, and the antenna is matched throughout the whole frequency range. Beam-steering angles of 17 $^\circ$ are reported with a gain of 16 dBi and a maximum sidelobe level of $-$ 7.6 dB.

Published

2019

41. Fully Dielectric Rod Antenna Arrays with Integrated Power Divider

Author

Roland Reese, and Holger Maune, Rolf Jakoby, Henning Tesmer, Matthias Nickel, and Ersin Polat

Subjects

Materials science, business.industry, 020208 electrical & electronic engineering, 020206 networking & telecommunications, 02 engineering and technology, Dielectric, Power (physics), Antenna array, 0202 electrical engineering, electronic engineering, information engineering, Miniaturization, Optoelectronics, Power dividers and directional couplers, Multimode interference, Electrical and Electronic Engineering, Antenna (radio), business, Realization (systems)

Abstract

This paper presents an overview of fully dielectric antenna arrays with integrated dielectric power dividers developed at Technische Universität Darmstadt as an extension of previous work. The power dividers are based on the principle of multimode interference and offer one- and two-dimensional power division in a single step, which allows the realization of small and lightweight devices. In order to prove the concept, 1 × 4 and 4 × 4 fully dielectric antenna arrays with integrated power dividers milled from Rexolite are designed, realized and characterized, operating between 90 GHz and 105 GHz. To assess miniaturization and beamsteering capabilities, three 1 × 4 arrays composed of different materials, Rexolite, Preperm L300 and Preperm L440, are compared regarding gain, size, weight and element spacing. Depending on array size and material, gain is between 12.5 dBi and 22 dBi, accompanied with sidelobe levels below - 7.5. All demonstrators are realized by milling, but the designs show the potential to be 3D printed or injection molded for large scale manufacturing.

Published

2019

42. A Millimeter-Wave Beam-Steering Lens Antenna With Reconfigurable Aperture Using Liquid Crystal

Author

Jonathan Strobl, Holger Maune, Henning Tesmer, Rolf Jakoby, Ersin Polat, Christian Schuster, Roland Reese, Matthias Nickel, and Matthias Jost

Subjects

Permittivity, Physics, business.industry, Beam steering, 020206 networking & telecommunications, Biasing, 02 engineering and technology, Electromagnetic radiation, Radiation pattern, Beamwidth, Optics, Extremely high frequency, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, business, Beam (structure)

Abstract

For the first time, a liquid crystal (LC) filled lens antenna is investigated for beam steering in this paper. The LC’s anisotropy is applied inside a semicircular shaped parallel-plate waveguide to achieve a deflection of the propagating electromagnetic wave at the interface of lower and higher permittivities. Using an electrode network, the direction of the sector of higher permittivity can be adjusted and, therefore, so can the beam direction. The main advantage of this antenna concept is that neither phase shifters nor switching networks are needed, resulting in a very simple approach for beam steering. Operating at $V$ -band, from 50 to 75 GHz, the first demonstrator proves the antenna concept by reconfiguring the beam in predefined directions of −30°, 0°, and +30° to simplify the electrode biasing network. Furthermore, it is feasible and being demonstrated to adjust the beamwidth and to generate multiple beams. In the measurements, the antenna exhibits a measured input reflection below −10 dB over the complete frequency range. For the unsteered radiation pattern, the sidelobe level is between −8 and −12 dB, whereas these values degrade to −4.5 to −6 dB for the steered radiation pattern at ±30°. The measured gain is between 13 and 15 dBi.

Published

2019

43. Low loss, fully-printed, ferroelectric varactors for high-power impedance matching at low ISM band frequency

Author

Nicole Bohn, Thomas Fink, Holger Maune, Daniel Kienemund, Joachim R. Binder, Walter Bigler, Rolf Jakoby, and Mike Abrecht

Subjects

Quality (physics), Materials science, business.industry, Impedance matching, Optoelectronics, Biasing, Electrical and Electronic Engineering, business, Interference (wave propagation), Ferroelectricity, ISM band, Voltage, Power (physics)

Abstract

Low loss, ferroelectric, fully-printed varactors for high-power matching applications are presented. Piezoelectric-induced acoustic resonances reduce the power handling capabilities of these varactors by lowering the Q-factor at the operational frequency of 13.56 MHz. Here, a quality factor of maximum 142 is achieved with an interference-based acoustic suppression approach utilizing double metal–insulator–metal structures. The varactors show a tunability of maximum 34% at 300 W of input power. At a power level of 1 kW, the acoustic suppression technique greatly reduces the dissipated power by 62% from 37 W of a previous design to 14.2 W. At this power level, the varactors remain tunable with maximum 18.2% and 200 V of biasing voltage.

Published

2019

44. A Planar Quasi Yagi-Uda Antenna Designed For Liquid Crystal Based End-Fire Phased Arrays

Author

Henning Tesmer, Peter Schumacher, Dongwei Wang, Holger Maune, Matthias Nickel, Ersin Polat, and Rolf Jakoby

Subjects

Materials science, business.industry, 020208 electrical & electronic engineering, Bandwidth (signal processing), 020206 networking & telecommunications, Near and far field, 02 engineering and technology, Optics, Planar, Liquid crystal, 0202 electrical engineering, electronic engineering, information engineering, Scattering parameters, Standing wave ratio, Antenna (radio), business, Broadside

Abstract

This paper presents a planar quasi Yagi-Uda antenna based on liquid crystal (LC) technology for millimeter-wave applications. The antenna is built on the inner surfaces of two parallel glass substrates, with thin layer of LC filled in the feed part. It is fed by a two-step coaxial-to-microstrip transition. The antenna achieves a measured bandwidth of 31 % with a VSWR < 2, better than 15 dB front-to-back ratio, better than –13 dB cross polarization and 9.0 dBi gain at 28 GHz. Measured scattering parameters, as well as far field patterns agree very well with the simulation results. The planar quasi Yagi-Uda antenna is compatible with existing planar reconfigurable feed network based on LC technology, complementary to the broadside radiating array.

Published

2021

45. Liquid Crystal Based Parallel-Polarized Dielectric Image Guide Phase Shifter at W-Band

Author

Rolf Jakoby, Roland Reese, Holger Maune, Henning Tesmer, and Ersin Polat

Subjects

Guided wave testing, Materials science, business.industry, 020208 electrical & electronic engineering, 020206 networking & telecommunications, Biasing, 02 engineering and technology, Dielectric, W band, 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, Insertion loss, Propagation constant, business, Phase shift module, Ground plane

Abstract

This paper presents a continuously tunable parallel-polarized dielectric image guide phase shifter, operating at W-Band (75 GHz to 110 GHz). The core material of the image guide is liquid crystal (LC), which is used to change the propagation constant of the guided wave. Four bias electrodes provide the field necessary to tune the LC. The parallel polarization reduces parasitic coupling to DC structures processed on the ground plane. Therefore, no stepped-impedance structure is necessary for the bias electrodes. Due to the image guide topology, the phase shifter can be used in substrate integrated environments. A maximum differential phase shift of 520° at 110 GHz is achieved with a bias voltage of ±150 V while the insertion loss is between 3.7 dB to 4.3dB. From 87GHz on, the resulting maximum Figure-of-Merit (FoM) is higher than 100°/dB, reaching a maximum of 125°/dB at 103 GHz.

Published

2020

46. Suppression of Acoustic Resonances in All-Oxide Varactors

Author

Lambert Alff, Prannoy Agrawal, Holger Maune, Patrick Salg, Lukas Zeinar, Philipp Komissinskiy, Rolf Jakoby, Dominik Walk, and Daniel Kienemund

Subjects

Materials science, business.industry, Oxide, 020206 networking & telecommunications, Biasing, 02 engineering and technology, 021001 nanoscience & nanotechnology, Ferroelectricity, chemistry.chemical_compound, Quality (physics), chemistry, Electrode, 0202 electrical engineering, electronic engineering, information engineering, Degradation (geology), Optoelectronics, 0210 nano-technology, Acoustic impedance, business, Acoustic resonance

Abstract

Barium strontium titanate (BST) thin-film varactors promise very good performance in RF frontends in terms of low loss and high tunability. However, their application is commonly limited to lower GHz frequencies. For higher frequencies, acoustic resonances drastically reduce the device quality in metal-insulator-metal (MIM) structures under bias voltage. In this work, this limitation is overcome by replacing the metal electrodes with conducting oxides that structurally match to BST and, therefore, avoid acoustic impedance mismatch. A detailed analytic model is derived, incorporating electric and acoustic behavior. Four samples with an oxide bottom electrode and varying BST thickness are characterized and fitted by the derived model with very high accuracy. Each shows a significantly reduced degradation due to acoustic loss. A model-wise comparison of stacks with metal and oxide electrodes demonstrates the strong benefit of all-oxide varactors, the possibility of complete suppression of acoustic resonances.

Published

2020

47. Fully Dielectric Phased Array for Beamsteering Using Liquid Crystal Technology at W-Band

Author

Henning Tesmer, Roland Reese, Ersin Polat, Holger Maune, Matthias Nickel, and Rolf Jakoby

Subjects

Materials science, Phased array, business.industry, 020208 electrical & electronic engineering, Physics::Optics, 020206 networking & telecommunications, 02 engineering and technology, Dielectric, W band, Side lobe, 0202 electrical engineering, electronic engineering, information engineering, Power dividers and directional couplers, Optoelectronics, Antenna gain, Antenna (radio), business, Phase shift module

Abstract

In this work, we present a liquid crystal based fully dielectric phased array for beamsteering at W-Band. The array consists of 1 x 4 tapered dielectric rod antennas, including liquid crystal phase shifters and a single multimode interference power divider as feeding network. With this approach, a fully dielectric beamsteering antenna is realized in a very lightweight, compact and low-loss design. Each rectangular phase shifter has a tapered dielectric rod antenna at its end. For beamsteering, dielectric subwavelength phase shifters are filled with a novel liquid crystal mixture. The realized demonstrator achieved a maximum scanning range of ± 10°. Moreover, the measured antenna gain is ranging between 13dB to 14dB with a side lobe level below – dB. The input reflection coefficient is below –10 dB over the whole W-band.

Published

2020

48. A Compact Two-dimensional Power Divider for a Dielectric Rod Antenna Array Based on Multimode Interference

Author

Ersin Polat, Rolf Jakoby, Henning Tesmer, Holger Maune, Matthias Nickel, Roland Reese, and Matthias Jost

Subjects

Physics, Waveguide (electromagnetism), Radiation, business.industry, 020206 networking & telecommunications, 02 engineering and technology, Dielectric, Modular design, Condensed Matter Physics, 01 natural sciences, 010309 optics, Optics, Proof of concept, 0103 physical sciences, Extremely high frequency, 0202 electrical engineering, electronic engineering, information engineering, Power dividers and directional couplers, Insertion loss, Electrical and Electronic Engineering, Antenna (radio), business, Instrumentation

Abstract

In this work, multimode interference is investigated for the design of a two-dimensional fully dielectric power divider, well suited for the usage of dielectric waveguides. Most important, power division is achieved in a single device without the need of cascading multiple dividers. This allows to design a very compact and lightweight power divider, well applicable for dielectric rod antenna arrays. As a proof of concept for the used technique, a 16-way power divider with 4 × 4 output ports, made out of Rexolite, is realized, working in a frequency range between 90 and 105 GHz. For the S-parameter measurements, a special measurement setup, including a modular pin probe technique as well as radiation taper for waveguide termination, is proposed. The measurements are in good agreement with the simulations with a power split of − 15 dB for all output ports within the desired frequency range. This is equal to an additional insertion loss of 3 dB. To demonstrate the usability for antenna arrays, a fully dielectric rod antenna array is realized based on the proposed power divider. With this array, a gain of 22.5 dBi at 97.5 GHz was achieved.

Published

2018

49. Design and demonstration of acoustically optimized, fully-printed, BST MIM varactors for high power matching circuits

Author

Walter Bigler, Daniel Kienemund, Joachim R. Binder, Nicole Bohn, Thomas Fink, Rolf Jakoby, Holger Maune, and Mike Abrecht

Subjects

Materials science, business.industry, Capacitive sensing, 020206 networking & telecommunications, Biasing, 02 engineering and technology, Acoustic wave, 021001 nanoscience & nanotechnology, Capacitance, Narrowband, 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, Electrical and Electronic Engineering, 0210 nano-technology, business, Varicap, Voltage, Acoustic resonance

Abstract

This work addresses the piezoelectric induced reduction of quality factor in fully-printed metal-insulator-metal (MIM) barium strontium titanate (BST) thick film varactors designed for high power operation. An acoustically optimized varactor design is presented and compared to a non-optimized high-power varactor. The design is utilized to present a narrowband acoustic suppression technique based on defined weights. The acoustically optimized varactor consists of 162 varactor cells in a capacitive matrix. The cells in the matrix are interconnectable allowing for a variable unbiased capacitance and power rating. Due to this setup, surface acoustic waves are interrupted, and the reduced size of the cells allows for a reduced BST layer thickness, shifting the acoustic resonance away from the operational frequency. Therefore, an inverted behavior in comparison to the high-power varactor is observed with an increasing quality factor with biasing voltage. Compared to the high-power varactor, the acoustically optimized varactor design shows a 40% increased quality factor in biased state. By applying the narrowband acoustic suppression technique, an increase in quality factor of 145% is achieved compared to the unsuppressed design. In comparison to the high-power varactor, the acoustical suppressed design shows an increase in quality factor of 480% at the first acoustic resonance frequency.

Published

2018

50. Fully dielectric interference‐based SPDT with liquid crystal phase shifters

Author

Holger Maune, Rolf Jakoby, Matthias Nickel, Matthias Jost, and Roland Reese

Subjects

Materials science, business.industry, 020208 electrical & electronic engineering, Phase (waves), 020206 networking & telecommunications, Topology (electrical circuits), 02 engineering and technology, Dielectric, Signal, Transmission (telecommunications), Interference (communication), Liquid crystal, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Optoelectronics, Insertion loss, Electrical and Electronic Engineering, business

Abstract

This study presents the first continuously tuneable, interference-based W-band single-pole double-throw (SPDT), fully implemented in subwavelength (sWL) dielectric fibre topology. Key components are the phase shifters in the two branches of the SPDT, which are realised as line sections filled with liquid crystal. They allow not only to adjust the signal ratios at the two output ports but also to tune the operating frequency between 93 and 110 GHz with isolation >25 dB. The first proof-of-concept SPDT demonstrator is realised and characterised at W-band. However, concept and technology are scalable to higher frequencies. The complete SPDT with the WR10-to-sWL fibre transitions exhibits an insertion loss (IL) at the thru-port between 5 and 7 dB in the frequency range from 85 to 110 GHz, where back-to-back measurements of the transitions itself already indicate an IL of up to 1.6 dB. The measurements at the isolated port of the SPDT exhibit transmission coefficients of less than -25 dB between 93 and 110 GHz with a minimum of -40 dB.

Published

2018