A Fast, Large-Stroke Electrothermal MEMS Mirror Based on Cu/W Bimorph

Zhang, Xiaoyang; Zhou, Liang; Xie, Huikai

doi:10.3390/mi6121460

Cited by 39 publications

(27 citation statements)

References 24 publications

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“…To accomplish this, the photodiode-based tilting angle detector [23] and resonant inductive coupling position sensor [24] are two possible solutions. Further, considering that this LSF bimorph-based MEMS mirrors have large thermal response time (∼100 ms) which will limit the scan speed, our future work will focus on design, fabrication and control of a large-stroke electrothermal micromirror with faster thermal response [25].…”

Section: Discussionmentioning

confidence: 99%

Modeling and Control of a Large-Stroke Electrothermal MEMS Mirror for Fourier Transform Microspectrometers

Han

Wang

Zhang

et al. 2016

J. Microelectromech. Syst.

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A microelectromechanical systems (MEMS) mirror with large vertical displacement has been developed for Fourier transform microspectrometers, but there exists a large tilting during the large-stroke scanning of the MEMS mirror, which greatly compromises the usable range. In this paper, a closed-loop control method has been established to minimize the tilting of the MEMS mirror. According to experimental results, the tilting motion of the mirror plate can be modeled as a fourth-order system. A feedback controller consisting of a phase-lag compensator, a low-pass filter and a notch filter utilized to stabilize the closed-loop tilt system. A gain scheduling approach is also used to compensate the bias-dependent loop gain and thereby provide more consistent tilting rejection over a wide scan range. Compared with the open-loop drive approach, the closed-loop system offers a stable scan operation with much faster dynamic response and improved overall robustness. The experiments show that the residual tilting is reduced to below ±0.0015°during the full range scan of the MEMS mirror. With this control method, the MEMS mirror achieved a stable scan range up to 356.4 µm, so the measured spectral resolution reached 28 nm at 532 nm in a microspectrometer. The mirror tilting can be reduced dramatically by the proposed active control scheme, and thereby, the usable vertical scan range is increased significantly.[2016-0061]

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Section: Discussionmentioning

confidence: 99%

Modeling and Control of a Large-Stroke Electrothermal MEMS Mirror for Fourier Transform Microspectrometers

Han

Wang

Zhang

et al. 2016

J. Microelectromech. Syst.

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“…Heat conduction through the mirror was not significant; therefore, the thermal cross-talk between the two actuators was negligibly small. The total thermal resistance of the actuator was roughly estimated to be around 6×10 4 K/W which is higher than bimetal electrothermal actuators (Zhang et al, 2015) because of low thermal diffusivity of SU-8 (0.14 mm 2 /s). …”

Section: Characterization Of the Temperaturementioning

confidence: 93%

Decay time control of mass diffusion in a transient grating using a fringe-tunable electrothermal Fresnel mirror

Kiuchi

Taguchi

Nagasaka

2017

JTST

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“…Compared with electrostatic, piezoelectrical, and electromagnetic actuations, an electrothermal MEMS scanner can achieve large displacement (several hundred micrometers) without resonant operation. To date, various novel designs for electrothermal MEMS scanners with vertical out-of-plane actuation have been proposed [3][4][5][6]8,[14][15][16]. For example, Zhang et al [14] presented a lateral shift-free actuator design using three bimorph hinges and two multimorph segments to compensate for the lateral shift.…”

Section: Introductionmentioning

confidence: 99%

Design and Fabrication of a Kirigami-Inspired Electrothermal MEMS Scanner with Large Displacement

Hashimoto

Taguchi

2020

Micromachines

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Large-displacement microelectromechanical system (MEMS) scanners are in high demand for a wide variety of optical applications. Kirigami, a traditional Japanese art of paper cutting and folding, is a promising engineering method for creating out-of-plane structures. This paper explores the feasibility and potential of a kirigami-inspired electrothermal MEMS scanner, which achieves large vertical displacement by out-of-plane film actuation. The proposed scanner is composed of film materials suitable for electrothermal self-reconfigurable folding and unfolding, and microscale film cuttings are strategically placed to generate large displacement. The freestanding electrothermal kirigami film with a 2 mm diameter and high fill factor is completely fabricated by careful stress control in the MEMS process. A 200 μm vertical displacement with 131 mW and a 20 Hz responsive frequency is experimentally demonstrated as a unique function of electrothermal kirigami film. The proposed design, fabrication process, and experimental test validate the proposed scanner’s feasibility and potential for large-displacement scanning with a high fill factor.

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A Fast, Large-Stroke Electrothermal MEMS Mirror Based on Cu/W Bimorph

Cited by 39 publications

References 24 publications

Modeling and Control of a Large-Stroke Electrothermal MEMS Mirror for Fourier Transform Microspectrometers

Modeling and Control of a Large-Stroke Electrothermal MEMS Mirror for Fourier Transform Microspectrometers

Decay time control of mass diffusion in a transient grating using a fringe-tunable electrothermal Fresnel mirror

Design and Fabrication of a Kirigami-Inspired Electrothermal MEMS Scanner with Large Displacement

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