A Large Piston Displacement MEMS Mirror With Electrothermal Ladder Actuator Arrays for Ultra-Low Tilt Applications

Samuelson, Sean R.; Xie, Huikai

doi:10.1109/jmems.2013.2290994

Cited by 45 publications

(30 citation statements)

References 21 publications

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“…The change in the bimorph temperature also alters the resistance R(T h ) of the Pt heater. Currently, analytical models can be obtained only for simple geometries, so numerical models such as finite element method are usually used for most practical problems [14], [16]. However, in order to design a closedloop control system analytically and attain ultra-low tilting, it is essential to develop a complete electrothermomechanical model in the form of transfer function.…”

Section: A Device Descriptionmentioning

confidence: 99%

“…Later, Wu et al employed a corner-cube retroreflector and a dual-reflective MEMS mirror and obtained an effective scan range of 308 μm [15], but this design only ensures the overlap of the two light beams respectively reflected back from the MEMS mirror and the fixed mirror while the wavefront distortion caused by the mirror tilt still exists. Samuelson et al proposed a laddered inverted-series-connected (ISC) electrothermal actuator design and demonstrated a low uncompensated tilt of 0.25°over its full 90 μm displacement range [16] and the mirror tilt was reduced to 0.004°using a pair of ratio optimized drive signals, but the achievable OPD was only 95 μm in a FTS setup [17]. To further reduce the uncompensated tilt, Xie et al reported an MEMS mirror with a three-level ladder ISC actuator design and an unique configuration of 16 ISC actuators and demonstrated a very small uncompensated tilting of less than 0.03°over the full actuation range [13] but this tilt angle is still one order of magnitude larger than the optimal tilt.…”

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confidence: 99%

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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: A Device Descriptionmentioning

confidence: 99%

mentioning

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.

Self Cite

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“…Recently, some new applications include response surface method [7] and ghost imaging [8]. On the basis of actuation method, torsional micromirrors can be classified into different types: electrothermal [9], electrostatic [10], electromagnetic [11,12], piezoelectric [13], and so forth. Recently, the electromagnetic micromirrors have attracted special attention owing to their ability to produce large scan angles with low voltage and remote actuation (meaning that the mirrors can be controlled by the non-contact force at a distance).…”

Section: Introductionmentioning

confidence: 99%

An Enhanced Robust Control Algorithm Based on CNF and ISM for the MEMS Micromirror against Input Saturation and Disturbance

2017

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Input saturation is a widespread phenomenon in the field of instrumentation, and is harmful to performance and robustness. In this paper, a control design framework based on composite nonlinear feedback (CNF) and integral sliding mode (ISM) technique is proposed for a MEMS micromirror to improve its performance under input saturation. To make the framework more effective, some essential improvements are supplied. With the application of the proposed design framework, the micromirror under input saturation and time-varying disturbances can achieve precise positioning with satisfactory transient performance compared with the open-loop performance.

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“…In this case, the speed of actuation will depend on the thermal dynamics of the system, making it the slowest mechanism of all for devices of similar size and thermal mass. The power consumed in this mechanism can be lower than the EM, but higher than the ES and PE, since the temperature increase depends on the amplitude of the applied current, which can be as high as 252 mA for maximum displacement [9]. …”

Section: Introductionmentioning

confidence: 99%

Modeling of MEMS Mirrors Actuated by Phase-Change Mechanism

et al. 2017

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Given the multiple applications for micro-electro-mechanical system (MEMS) mirror devices, most of the research efforts are focused on improving device performance in terms of tilting angles, speed, and their integration into larger arrays or systems. The modeling of these devices is crucial for enabling a platform, in particular, by allowing for the future control of such devices. In this paper, we present the modeling of a MEMS mirror structure with four actuators driven by the phase-change of a thin film. The complexity of the device structure and the nonlinear behavior of the actuation mechanism allow for a comprehensive study that encompasses simpler electrothermal designs, thus presenting a general approach that can be adapted to most MEMS mirror designs based on this operation principle. The MEMS mirrors presented in this work are actuated by Joule heating and tested using optical techniques. Mechanical and thermal models including both pitch and roll displacements are developed by combining theoretical analysis (using both numerical and analytical tools) with experimental data and subsequently verifying with quasi-static and dynamic experiments.

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A Large Piston Displacement MEMS Mirror With Electrothermal Ladder Actuator Arrays for Ultra-Low Tilt Applications

Cited by 45 publications

References 21 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

An Enhanced Robust Control Algorithm Based on CNF and ISM for the MEMS Micromirror against Input Saturation and Disturbance

Modeling of MEMS Mirrors Actuated by Phase-Change Mechanism

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