A monolithic variable inductor network using microrelays with combined thermal and electrostatic actuation

Zhou, S. P.; Sun, Xi-Qing; Carr, W.N.

doi:10.1088/0960-1317/9/1/305

Cited by 57 publications

(28 citation statements)

References 13 publications

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“…The advantage of this switch over other alternatives (17)(18)(19)(20) is that it uses no latches, hinges, or residual stress to achieve its bistability.…”

Section: The Bistable Switchmentioning

confidence: 99%

Optimal design of a bistable switch

Brenner

Lang

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

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Determining optimally designed structures is important for diverse fields of science and engineering. Here we describe a procedure for calculating the optimal design of a switch and apply the method to a bistable microelectromechanical system relay switch. The approach focuses on characterizing the unstable transition state connecting the two stable equilibria to control the force displacements. Small modifications in component shape lead to a substantial improvement in device operation. Fabrication of the optimized devices confirms the predictions.

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“…The advantage of this switch over other alternatives (17)(18)(19)(20) is that it uses no latches, hinges, or residual stress to achieve its bistability.…”

Section: The Bistable Switchmentioning

confidence: 99%

Optimal design of a bistable switch

Brenner

Lang

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

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“…The most common approach toward discrete tuning, where only certain inductance values are achievable, is to have a set of pre-defined coils where switches select which coils are incorporated into the inductor. 2,3 This approach leads to compromised performance in the final tunable inductor since the switches add excessive resistance and also does not allow fine tuning desired for many RF applications such as channel selection.…”

Section: Introductionmentioning

confidence: 99%

Bubble inductors: Pneumatic tuning of a stretchable inductor

Lazarus

Bedair

2017

AIP Advances

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From adaptive matching networks in power systems to channel selectable RF filters and circuitry, tunable inductors are fundamental components for circuits requiring reconfigurability. Here we demonstrate a new continuously tunable inductor based on physically stretching the inductor traces themselves. Liquid-metal-based stretchable conductors are wrapped around a pneumatic bubble actuator, allowing the inductor to be collapsed or expanded by application of pressure. In vacuum the bubble collapses, bringing the loop area to nearly zero, while positive pressure brings a dramatic increase in area and loop inductance. Using this approach, the inductor demonstrated in this work was able to achieve a tuning ratio of 2.6 with 1-2 second response time. With conductors available that can stretch by hundreds of percent, this technique is promising for very large tuning ratios in continuously tunable inductors.

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“…Efforts have been devoted to developing electronically tunable inductors that have large tunability, high Q-factor, and low energy consumption. For example, microswitches (Park et al 2004) or microrelays (Zhou et al 1999) were utilized to increase or decrease the effective coil length of the inductor, thus to change the inductance of the inductors. But the combination of the microswitches or micorelays reduced much Q-factor of the inductors.…”

Section: Introductionmentioning

confidence: 99%

Electrostatically driven tunable radio frequency inductor

Fang

Yuan

et al. 2010

Microsyst Technol

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An electrostatically driven tunable radio frequency (RF) inductor with large inductance tuning range consisting of electroplated soft magnetic permalloy (Ni 80 Fe 20 alloy) plate was proposed in this paper. The fabricated tunable inductor exhibits a large tunable inductance range up to 77.8%, together with improved quality factor (Q-factor) at high frequencies. Such tunability of inductance and Q-factor was due to the magnetoelectric coupling effect between the soft magnetic permalloy plate and the spiral inductor, which lead to the magnetic flux of the inductor and mutual inductance change. The concept of tuning inductance by using electroplated soft magnetic permalloy has large potential for wide range RFIC applications.

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A monolithic variable inductor network using microrelays with combined thermal and electrostatic actuation

Cited by 57 publications

References 13 publications

Optimal design of a bistable switch

Optimal design of a bistable switch

Bubble inductors: Pneumatic tuning of a stretchable inductor

Electrostatically driven tunable radio frequency inductor

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