A Low-Profile and High-Gain Frequency Beam Steering Subterahertz Antenna Enabled by Silicon Micromachining

Gomez-Torrent, Adrian; Garcia-Vigueras, María; Coq, Laurent Le; Mahmoud, Adham; Ettorre, Mauro; Sauleau, Ronan; Oberhammer, Joachim

doi:10.1109/tap.2019.2943328

Cited by 62 publications

(49 citation statements)

References 27 publications

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“…1. The frequency beam steering frontend is based on a parallel plate waveguide (PPW) leaky wave antenna (LWA) operating between 220 to 300 GHz and provides a continuous beam scanning in a 45° field of view (FoV) [4]. The LWA generates an unbound radiating mode with the periodic slot array on the top plate of the PPW [5].…”

Section: Methodsmentioning

confidence: 99%

Ultra-Compact Micromachined Beam-Steering Antenna Front-End for High-Resolution Sub-Terahertz Radar

Shah

Gómez

Oberhammer

2019

2019 44th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz)

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Section: Methodsmentioning

confidence: 99%

Ultra-Compact Micromachined Beam-Steering Antenna Front-End for High-Resolution Sub-Terahertz Radar

Shah

Gómez

Oberhammer

2019

2019 44th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz)

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“…A promising alternative fabrication technology is siliconmicromachining using deep reactive-ion-etching (DRIE), which allows for batch fabrication, has superior (micrometer) precision, enables high-complexity geometries, as well as nanometer surface roughness and thus better insertion loss. Impressive device performance has been achieved by micromachining in various sub-THz frequency bands, for instance, for waveguides [3]- [5], couplers [6], low-loss filters [7], [8], OMTs [9], antennas [10], [11], and MEMSreconfigurable devices such as waveguide switches [12] and phase shifters [13].…”

Section: Introductionmentioning

confidence: 99%

Micromachined Silicon-Core Substrate-Integrated Waveguides at 220–330 GHz

Krivovitca

Shah

Glubokov

et al. 2020

IEEE Trans. Microwave Theory Techn.

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In this article, we present a new technology platform for creating compact and loss-efficient wafer-scale integrated micromachined substrate-integrated waveguides with silicon-core (Si-SIWs) for the 230-330-GHz frequency range. The silicon dielectric core enables highly integrated sub-millimeter-wave systems, since it allows for downscaling the waveguide's cross section by a factor of 11.6, and the volume of components by a factor of 39.3, as compared to an air-filled waveguide. Moreover, geometrical control during fabrication of this type of waveguides is significantly better as compared to micromachined hollow waveguides. The measured waveguide's insertion loss (IL) is 0.43 dB/mm at 330 GHz (0.14 dB/λ g , normalized to the guided wavelength). A low-loss ultrawideband coplanar-waveguide (CPW) transition is implemented to enable direct measurements of devices and circuits in this waveguide platform, and this is also the very first CPW-to-SIW transition in this frequency range. The measured IL of the transition is better than 0.5 dB (average 0.43 dB above 250 GHz), which is lower than for previously reported CPW-to-SIW transitions even at 3 times lower frequencies; the return loss is better than 14 dB for 75% of the band. As devices examples implemented in this platform, a filter and H-plane waveguide bends are shown. The waveguides and the devices are manufactured by deep-silicon etching using a cost-efficient two-mask micromachining process.

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“…These optical systems can achieve high-gain values and wideband operation, but they tend to be heavy, bulky, and involve careful alignment of the feed antenna. Quasi-optical systems have been developed as an alternative solution to optical systems [6], [7], [11]. They can integrate 1-D reflectors or lenses in parallel plate waveguide (PPW) technology, thus reducing the total volume and mass of the system but limiting the beamforming to one plane.…”

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confidence: 99%

“…They can integrate 1-D reflectors or lenses in parallel plate waveguide (PPW) technology, thus reducing the total volume and mass of the system but limiting the beamforming to one plane. Therefore, quasi-optical systems need an additional beamforming network (BFN) in PPW technology to generate a pencil-shaped beam [11], making their fabrication still challenging in the THz range.…”

mentioning

confidence: 99%

“…Silicon micromachining is a promising alternative to classical machining techniques for the implementation of waveguide components in the sub-THz frequency range. Silicon micromachining can be used to fabricate low-loss waveguides [12], high quality factor filters [13], and complex waveguide 3-D geometries such as turnstile orthomode transducers [14], switches and phase shifters [15]- [17], or antennas [5], [11], [18]. Campion et al [19] have also recently demonstrated the integration of monolithic microwave integrated circuits (MMICs) in a silicon micromachined platform where the RF, IF, and dc networks are homogeneously integrated.…”

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confidence: 99%

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A 38 dB Gain, Low-Loss, Flat Array Antenna for 320–400 GHz Enabled by Silicon-on-Insulator Micromachining

Gomez-Torrent

Tomura

Kuramoto

et al. 2020

IEEE Trans. Antennas Propagat.

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Two high-gain flat array antenna designs operating in the 320-400 GHz frequency range are reported in this article. The two antennas show the measured gains of 32.8 and 38 dBi and consist of a 16 × 16 (256) element array and a 32 × 32 (1024) element array, respectively, which are fed by a corporate H-tree beamforming network. The measured operation bandwidth for both antennas is 80 GHz [22% fractional bandwidth (FBW)], and the total measured efficiency is above −2.5 dB and above −3.5 dB for the two designs in the whole bandwidth. The low measured loss and large bandwidth are enabled by optimizing the designs to the process requirements of the silicon on insulator (SOI) micromachining technology used in this article. The total height of the antennas is 1.1 mm (1.2 λ at the center frequency), with sizes of 15 mm × 18 mm and 27 mm × 30 mm for both arrays. The antennas are designed to be directly mounted onto a standard WM-570 waveguide flange. The design, fabrication, and measurements of eight prototypes are discussed in this article and the performance of the antennas compared to the simulated data, as well as manufacturability and fabrication repeatability are reported in detail.

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A Low-Profile and High-Gain Frequency Beam Steering Subterahertz Antenna Enabled by Silicon Micromachining

Cited by 62 publications

References 27 publications

Ultra-Compact Micromachined Beam-Steering Antenna Front-End for High-Resolution Sub-Terahertz Radar

Ultra-Compact Micromachined Beam-Steering Antenna Front-End for High-Resolution Sub-Terahertz Radar

Micromachined Silicon-Core Substrate-Integrated Waveguides at 220–330 GHz

A 38 dB Gain, Low-Loss, Flat Array Antenna for 320–400 GHz Enabled by Silicon-on-Insulator Micromachining

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