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

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

doi:10.3390/cryst11010063

Cited by 14 publications

(7 citation statements)

References 28 publications

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“…14. Since the adhesives are not characterized in the operating frequency range, the material properties of the UV and epoxy glue are taken for W-band from [45]. The insertion loss is increased from the initial simulation model from 1.2 dB to 2.2 dB.…”

Section: Fabrication and Characterizationmentioning

confidence: 99%

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

Kamrath¹,

Polat²,

Matic³

et al. 2022

IEEE J. Microw.

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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 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 GHz to 30.7 GHz with a maximum 3 dB bandwidth variation from 660 MHz to 870 MHz. The measurements are carried out with bias voltages up to ±250 V.INDEX TERMS Microwave filter, liquid crystals, millimeter wave communication, tunable circuits and devices, K-band.This article has been accepted for inclusion in a future issue of this journal. Content is final as presented, with the exception of pagination.

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Section: Fabrication and Characterizationmentioning

confidence: 99%

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

Kamrath¹,

Polat²,

Matic³

et al. 2022

IEEE J. Microw.

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“…In our pioneering work combining coaxial transmission lines with LCs [25] at 60 GHz, we achieved a phase shifter by filling the coaxial transmission line with LCs in two Over the past two decades, various demonstrations have showcased LC-enabled tunable phase shifting [20,22,23] and reconfigurable frequency filtering [27,28], exhibiting commendable performance across microwave and millimeter-wave frequency ranges, typically up to V band [20] and W band [29,30]. The state of the art in this field has also witnessed the expansion towards a wider portfolio of LC-based photonic devices, e.g., [31] on THz tunable metamaterial with LCs for modulations of phase, intensity, and polarization, leading to potential applications in THz modulators, filters, and switches.…”

Section: Introductionmentioning

confidence: 99%

Modeling 0.3 THz Coaxial Single-Mode Phase Shifter Designs in Liquid Crystals with Constitutive Loss Quantifications

Li,

2024

Crystals

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This work proposes and examines the feasibility of next-generation 0.3 THz phase shifters realized with liquid crystals (LCs) as tunable dielectrics coaxially filled in the transmission line. The classic coaxial transmission line topology is robust to electromagnetic interference and environmental noise, but is susceptible to higher-order modes from microwave to millimeter-wave towards terahertz (THz) wavelength ranges, which impedes the low-insertion-loss phase-shifting functionality. This work thus focuses primarily on the suppression of the risky higher-order modes, particularly the first emerging TE11 mode impacting the dielectric loss and metal losses in diverse manners. Based on impedance matching baselines at diverse tuning states of LCs, this work analytically derives and models two design geometries; i.e., design 1 for the coaxial geometry matched at the isotopically referenced state of LC for 50 Ω, and design 2 for geometry matched at the saturated bias of LC with the maximally achievable permittivity. The Figure-of-Merit for design 1 and design 2 reports as 35.15°/dB and 34.73°/dB per unit length, respectively. We also propose a constitutive power analysis method for understanding the loss consumed by constitutive materials. Notably, for the 0.3 THz design, the isotropic LC state results in an LC dielectric loss of 63.5% of the total input power (assuming 100%), which becomes the primary constraint on achieving low-loss THz operations. The substantial difference in the LC dielectric loss between the isotropic LC state and saturated bias state for the 0.3 THz design (35.76% variation) as compared to that of our past 60 GHz design (13.5% variation) indicates that the LC dielectric loss’s escalating role is further enhanced with the rise in frequency, which is more pronounced than the conductor losses. Overall, the results from analytical and finite-element optimization in this work shape the direction and feasibility of the unconventional THz coaxial phase shifting technology with LCs, actioned as continuously tunable dielectrics.

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“…The phase shifter is used for each resonator element of the reflectarray, by adjusting the phase change of each element to adjust its scattering phase with respect to the incident wave, thereby realizing the beam control function [ 12 ] . The commonly used phase shifters are mainly manufactured using microelectromechanical systems (MEMS) [ 13 ] , ferroelectric thin films [ 14 ] , and liquid crystals (LCs) [ 15 ] . However, the first two possess large loss and complex structure as shortcomings, which hamper their large‐scale manufacturing.…”

Section: Introductionmentioning

confidence: 99%

Design and Fabrication of Reflective Phase Shifter for Two‐Dimensional Terahertz Beam‐Scanning Reflectarray

Yang

YIN

Gao

et al. 2022

Chinese J of Electronics

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A reflective phase shifter is proposed to realize the two‐dimensional beam‐scanning reflectarray. The reflectarray is composed of double‐dipole resonant elements in which the phase shift is implemented by applying a driving voltage to the liquid crystal (LC). A 30 × 30 phase shifter sample is fabricated on a quartz substrate with a 480 μm thickness and a 4 cm × 4 cm area. According to the experimental results, 0 to 360° phase shift can be achieved within the bandwidth of 5 GHz. In order to accomplish two‐dimensional beam‐scanning and reduce the negative impact of driving lines on the reflectarray, a new LC driving method is developed. To verify the accuracy of the proposed approach, three samples of different driving line numbers are designed using the above‐mentioned phase shifter, which all have achieved a 0−360° phase shift in the bandwidth of 4 GHz. Considering the influence of LC anisotropy and inhomogeneity, an improved calculation result is obtained and compared with experimental data.

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

Cited by 14 publications

References 28 publications

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

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

Modeling 0.3 THz Coaxial Single-Mode Phase Shifter Designs in Liquid Crystals with Constitutive Loss Quantifications

Design and Fabrication of Reflective Phase Shifter for Two‐Dimensional Terahertz Beam‐Scanning Reflectarray

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