Microwave MEMS devices designed for process robustness and operational reliability

Sterner, Mikael; Somjit, Nutapong; Shah, Umer; Dudorov, Sergey; Chicherin, Dmitry; Räisänen, Antti V.; Oberhammer, J.

doi:10.1017/s1759078711000845

Cited by 12 publications

(6 citation statements)

References 63 publications

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“…Neither the stoppers nor other actuator elements showed any signs of wear when inspected in the SEM after the lifetime measurements. The life-time characterization agrees very well with other silicon-core, allmetal RF MEMS devices developed by the authors [38].…”

Section: Characterization Of Design IIIsupporting

confidence: 85%

Multi-Position RF MEMS Tunable Capacitors Using Laterally Moving Sidewalls of 3-D Micromachined Transmission Lines

Shah

Sterner

Oberhammer

2013

IEEE Trans. Microwave Theory Techn.

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Section: Characterization Of Design IIIsupporting

confidence: 85%

Multi-Position RF MEMS Tunable Capacitors Using Laterally Moving Sidewalls of 3-D Micromachined Transmission Lines

Shah

Sterner

Oberhammer

2013

IEEE Trans. Microwave Theory Techn.

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“…5. A number of probe prototypes with different tip sizes were fabricated simultaneously from a 4-in 600-m-thick high-resistivity silicon substrate (HRSS) wafer ( 4000 cm, , of 6 10 measured at 100 GHz [40]). A 3-m-high thermal oxide layer, which is patterned by a standard photolithography process and silicon dioxide dry etching, is used as a masking layer.…”

Section: Fabricationmentioning

confidence: 99%

Millimeter-Wave Near-Field Probe Designed for High-Resolution Skin Cancer Diagnosis

Töpfer

Dudorov

Oberhammer

2015

IEEE Trans. Microwave Theory Techn.

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This paper presents a detailed technical characterization of a micromachined millimeter-wave near-field probe developed for skin cancer diagnosis. The broadband probe is optimized for frequencies from 90 to 104 GHz and consists of a dielectric-rod waveguide, which is metallized and tapered towards the tip to achieve high resolution by concentrating the electric field in a small sample area. Several probes with different tip sizes were fabricated from high-resistivity silicon by micromachining and were successfully characterized using silicon test samples with geometry-defined tailor-made permittivity. The probes show a high responsivity for samples with permittivities in the range of healthy and cancerous skin tissue at 100 GHz (from to , loss tangent of approximately 1.26). The sensing depth was determined by simulations and measurements from 0.3 to 0.4 mm, which is adapted for detecting early-stage skin tumors before they metastasize. The lateral resolution was determined to 0.2 mm for a tip size of 0.6 0.3 mm, which allows for resolving small skin tumors and inhomogeneities within a tumor.

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“…The Eigenmode Solver implemented in [24] was used for this simulation. Since the relative permeability of silicon is very close to 1 in the W-band [15], we have n = √ eff where n is the calculated refractive index. Based on the simulated dispersion relation (i.e., the relation between the wave number k and the angular frequency ω), the permittivity was extracted according to eff = (ck/ω) 2 where c is the speed of light in vacuum.…”

Section: Tailor-made Effective Permittivity Regions In a Silicon Wafermentioning

confidence: 99%

“…Planar lenses have many similarities with non-planar lenses, where there are many good references, see e.g., [8][9][10][11][12][13]. High-resistivity silicon is an excellent dielectric material for millimeter-wave planar lenses, due to its very small losses and accurate micromaching fabrication processes [14,15]. However, homogeneous lenses of high permittivity materials, such as silicon, suffer from reflections at the airdielectric interface caused by the large difference in impedance compared to free-space (see e.g., [9]).…”

Section: Introductionmentioning

confidence: 99%

Optimization of Micromachined Millimeter-Wave Planar Silicon Lens Antennas With Concentric and Shifted Matching Regions

Frid¹,

Töpfer²,

Bhowmik³

et al. 2017

PIER C

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Abstract-This paper presents a study of planar silicon lens antennas with up to three steppedimpedance matching regions. The effective permittivity of the matching regions is tailor-made by etching periodic holes in the silicon substrate. The optimal thickness and permittivity of the matching regions were determined by numerical optimization to obtain the maximum wideband aperture efficiency and smallest side-lobes. We introduce a new geometry for the matching regions, referred to as shifted matching regions. The simulation results indicate that using three shifted matching regions results in twice as large aperture efficiency as compared to using three conventional concentric matching regions. By increasing the number of matching regions from one to three, the band-averaged gain is increased by 0.3 dB when using concentric matching regions, and by 3.7 dB when using shifted matching regions, which illustrates the advantage of the proposed shifted matching region design.

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Microwave MEMS devices designed for process robustness and operational reliability

Cited by 12 publications

References 63 publications

Multi-Position RF MEMS Tunable Capacitors Using Laterally Moving Sidewalls of 3-D Micromachined Transmission Lines

Multi-Position RF MEMS Tunable Capacitors Using Laterally Moving Sidewalls of 3-D Micromachined Transmission Lines

Millimeter-Wave Near-Field Probe Designed for High-Resolution Skin Cancer Diagnosis

Optimization of Micromachined Millimeter-Wave Planar Silicon Lens Antennas With Concentric and Shifted Matching Regions

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