MEMS Sensors - Design and Application 2018

DOI: 10.5772/intechopen.76445

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RF-MEMS Switches Designed for High-Performance Uniplanar Microwave and mm-Wave Circuits

David Girbau²,

et al.

Abstract: Radio frequency microelectromechanical system (RF-MEMS) switches have demonstrated superior electrical performance (lower loss and higher isolation) compared to semiconductor-based devices to implement reconfigurable microwave and millimeter (mm)-wave circuits. In this chapter, electrostatically actuated RF-MEMS switch configurations that can be easily integrated in uniplanar circuits are presented. The design procedure and fabrication process of RF-MEMS switch topologies able to control the propagating modes … Show more

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Iterative Meandering Technique1

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“…The width of each block in meanders is taken as 5 µm having thickness of 0.5 µm. Thus, the spring stiffness of each block is given as [12]:…”

Section: Iterative Meandering Techniquementioning

confidence: 99%

Low Pull-in-Voltage RF-MEMS Shunt Switch for 5G Millimeter Wave Applications

¹

,

²

,

³

et al. 2021

Trans. Electr. Electron. Mater.

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RF MEMS switches have been employed in many commercial and defense applications due to their high potentiality at microwave and millimeter wave frequencies. In this paper, an RF MEMS shunt switch is designed with perforations and without perforations and simulated using iterative meanders for millimeter wave 5G applications. The proposed iterative meander offers a low spring-constant of 0.68 N/m and reduces the pull-in-voltage upto 1.8 V. The proposed perforated switch design is more reliable which operates with less transition time of 11.2 µs with a quality factor of 1.69. The switch possesses high capacitance ratio of 63. During ON condition, the switch shows low insertion loss of − 0.24 dB at 41 GHz and high isolation of − 46.7 dB at 38 GHz. The performance of the switch is analyzed by simulating it using COMSOL Multiphysics 5.2v (FEM tool). The obtained simulation results shows close approximation with the theoretical results and the switch is efficiently used for 5G millimeter wave applications.

“…The width of each block in meanders is taken as 5 µm having thickness of 0.5 µm. Thus, the spring stiffness of each block is given as [12]:…”

Section: Iterative Meandering Techniquementioning

confidence: 99%

Low Pull-in-Voltage RF-MEMS Shunt Switch for 5G Millimeter Wave Applications

¹

,

²

,

³

et al. 2021

Trans. Electr. Electron. Mater.

View full text Add to dashboard Cite

RF MEMS switches have been employed in many commercial and defense applications due to their high potentiality at microwave and millimeter wave frequencies. In this paper, an RF MEMS shunt switch is designed with perforations and without perforations and simulated using iterative meanders for millimeter wave 5G applications. The proposed iterative meander offers a low spring-constant of 0.68 N/m and reduces the pull-in-voltage upto 1.8 V. The proposed perforated switch design is more reliable which operates with less transition time of 11.2 µs with a quality factor of 1.69. The switch possesses high capacitance ratio of 63. During ON condition, the switch shows low insertion loss of − 0.24 dB at 41 GHz and high isolation of − 46.7 dB at 38 GHz. The performance of the switch is analyzed by simulating it using COMSOL Multiphysics 5.2v (FEM tool). The obtained simulation results shows close approximation with the theoretical results and the switch is efficiently used for 5G millimeter wave applications.

Designing of RF-MEMS Capacitive Contact Shunt Switch and Its Simulation for S-band Application

¹

,

²

,

³

et al. 2021

Lecture Notes in Electrical Engineering

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Investigations on beam membrane and dielectric materials using Ashby’s methodology and their impact on the performance of a MEMS capacitive switch

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2021

Microsyst Technol

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