True-Time-Delay Mechanical Phase Shifter in Gap Waveguide Technology for Slotted Waveguide Arrays in <i>Ka</i>-Band

Sánchez‐Escuderos, Daniel; Herranz-Herruzo, Jose I.; Ferrando-Rocher, Miguel; Valero‐Nogueira, Alejandro

doi:10.1109/tap.2020.3030993

Cited by 32 publications

(17 citation statements)

References 25 publications

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“…Despite achieving literally unlimited phase shift, high powerhandling, and relatively low insertion loss, the proposed phase shifter in the previous section (as well as those presented in [11], [12]) have an important practical limitation. In the presented structures, the input or output port is mounted on a moving conductive plate.…”

Section: Multi-layer Tunable Phase Shiftermentioning

confidence: 99%

“…Therefore, the overall path of the guided wave, and thereby the phase of the transmitted wave from Port 1 to Port 2 is changed. It is very important to note that in contrast to the phase shifters presented in [11], [12], in this configuration both input and output ports are stationary, thus no need for flexible cables or expensive rotary joints. It is also worth highlighting that, in this structure, when the middle plate is displaced for a distance x, the variation of the waveguide's length l is twice that, i.e., l = 2 x.…”

Section: Multi-layer Tunable Phase Shiftermentioning

confidence: 99%

“…This is because changing the length of a waveguide to achieve a mechanically tunable resonator or phase shifter, while a theoretically trivial method, its practical implementation is not as trivial, and may result in the leak of EM power from the structure and need for a movable output port. To address this issue, recently an array of mechanical phase shifters based on changes in the length of a vertical GGWG has been proposed in [11] and [12]. However, the work is thoroughly focused on the realization of an array of phase shifters for feeding a waveguide slot array antenna, resulting in the following limitations and complexities: 1) To achieve a phase shift, the lower metallic surface and as a result, the input feed port needs to be rotatable.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Low-Loss Mechanically Tunable Resonator and Phase Shifters in Groove Gap Waveguide Technology

2022

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This research is focused on the design and realization of high-performance high-power variable phase shifters in groove gap waveguide technology. Specifically, it is shown that the unique characteristic of groove gap waveguides, which is its proper operation without the need for electrical connection between the top and bottom sections of the waveguide, can be used to design mechanically tunable devices. Using the proposed method, a mechanically tunable cavity resonator and phase shifters with a wide range of achievable phase shifts are presented. To validate the concept, a phase shifter with 540 degrees relative phase shift at 15 GHz is designed, fabricated, and measured. Moreover, a multi-layer version of the proposed phase shifter with stationary feed ports and improved performance is presented.

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Section: Multi-layer Tunable Phase Shiftermentioning

confidence: 99%

Section: Multi-layer Tunable Phase Shiftermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Low-Loss Mechanically Tunable Resonator and Phase Shifters in Groove Gap Waveguide Technology

2022

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“…Such antennas are good candidates for mm-wave bands because of their several important advantages compared with antennas with linear polarization, such as combating multipath interferences or fading, no strict orientation requirement between transmitting and receiving radiators and polarization mismatch reduction. Additionally, dual band (with two non-adjacent working bands) [66,67] and dual linear polarization WSAs [66,68] are interesting candidates for 5G applications, which also call for wideband [69][70][71][72], high-gain [73][74][75] and beam-steerable [76,77] antennas.…”

Section: Waveguide Slot Modelsmentioning

confidence: 99%

A Review on Improved Design Techniques for High Performance Planar Waveguide Slot Arrays

et al. 2021

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Planar waveguide slot arrays (WSAs) have been used since 1940 and are currently used as performing antennas for high frequencies, especially in applications such as communication and RADAR systems. We present in this work a review of the most typical waveguide slot array configurations proposed in the literature, describing their main limitations and drawbacks along with possible effective countermeasures. Our attention has been focused mainly on the improved available design techniques to obtain high performance WSAs. In particular, the addressed topics have been reported in the following. Partially filled WSAs, or WSAs covered with single or multilayer dielectric slabs, are discussed. The most prominent second-order effects in the planar array feeding network are introduced and accurately modeled. The attention is focused on the T-junction feeding the array, on the effect of interaction between each slot coupler of the feeding network and the radiating slots nearest to this coupler, and on the waveguide bends. All these effects can critically increase the first sidelobes if compared to the ideal case, causing a sensible worsening in the performance of the array.

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“…Alternatively, LC circuits [37], phase shifters [38,39], and phase shifters with diodes can be used to achieve beam angle switching [40][41][42][43]. The main beam can be mechanically steered using hardware devices such as motors or drivers with control software [44] to steer the radiation field pattern emitted by the guided antenna.…”

Section: Introductionmentioning

confidence: 99%

Near Field Sensing Applications with Tunable Beam Millimeter Wave Antenna Sensors in an All-in-One Chip Design

Chung

Lin

2022

Electronics

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In this paper, a single-band beam control antenna is designed with a parallel coupler to realize a microstrip patch antenna passive wireless sensor in the form of a chip. It has a phase shift characteristic of the antenna radiation direction in the positive and negative directions. The antenna includes an orthogonal direction coupler design with a 90° parallel coupler in phase using a special structure that allows the whole chip area to be miniaturized while allowing the main beam angle to have a directivity function. The coupler is designed for the 28 GHz millimeter wave band. After feeding the patch antenna at the output port of the coupler and simultaneously feeding the excitation at the input port, the beam phase changes to +45° and +135° with a phase difference of 90°. The designed antenna size is 1160 μm × 790 m, and the overall IC size is 1.2 mm × 1.2 mm. The power density simulation shows that the maximum power density is only 0.00797 W/kg for a 1 human sampling area, which means that the antenna sensor is suitable for use on human surfaces.

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True-Time-Delay Mechanical Phase Shifter in Gap Waveguide Technology for Slotted Waveguide Arrays in Ka-Band

Cited by 32 publications

References 25 publications

Low-Loss Mechanically Tunable Resonator and Phase Shifters in Groove Gap Waveguide Technology

Low-Loss Mechanically Tunable Resonator and Phase Shifters in Groove Gap Waveguide Technology

A Review on Improved Design Techniques for High Performance Planar Waveguide Slot Arrays

Near Field Sensing Applications with Tunable Beam Millimeter Wave Antenna Sensors in an All-in-One Chip Design

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