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

Han, Fengtian; Wang, Wei; Zhang, Xiaoyang; Xie, Huikai

doi:10.1109/jmems.2016.2565388

Cited by 18 publications

(15 citation statements)

References 26 publications

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“…In recent years, most of the scanning micrograting has been developed and fabricated using MEMS technology. The actuation mechanisms can be mainly divided into four categories: electrostatic [9], electrothermal [10,11], electromagnetic [12][13][14][15], and piezoelectric [16]. The electromagnetic actuation mechanism is widely used for its large driving torque, linear mechanical properties, and low driving voltage.…”

Section: Introductionmentioning

confidence: 99%

A Compound Control System for FR4-Based Electromagnetic Scanning Micrograting

Wen

Lei

et al. 2019

Electronics

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This paper presents a compound control system for precise control of the flame-retardant 4 (FR4)-based electromagnetic scanning micrograting. It mainly consists of a frequency controller and an angle controller. A dual closed-loop structure consisting of a current loop and an angle loop was designed in the angle controller. In addition, the incremental proportional–integral–derivative (PID) control algorithm was designed in the current loop, and the fuzzy-PID control algorithm was employed in the angle loop. From the experimental results, the frequency controller can effectively track the real-time resonant frequency of the scanning micrograting with a tracking accuracy of 0.1 Hz. The overshoot of the scanning micrograting is eliminated. Compared to an open-loop control system, the control system presented in this work reduces the steady-state error of the scanning micrograting from 1.122% to 0.243%. The control accuracy of the compound control system is 0.02°. The anti-interference recovery time of the scanning micrograting was reduced from 550 ms to 181 ms, and the long-term stability was increased from 2.94% to 0.12%. In the compound control system presented in this paper, the crucial parameters of the FR4-based electromagnetic scanning micrograting, including motion accuracy, anti-interference ability, and long-term stability, were effectively improved.

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Section: Introductionmentioning

confidence: 99%

A Compound Control System for FR4-Based Electromagnetic Scanning Micrograting

Wen

Lei

et al. 2019

Electronics

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“…External optical sensors may be a good solution to provide a real-time feedback signal [4,16,17]. However, this requires a complex assembly, and inevitably increases the system's volume and cost.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Electromagnetic Angle Sensor Integrated in FR4-Based Scanning Micromirror

Wen

Lei

et al. 2018

Applied Sciences

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This paper performs a detailed investigation on the electromagnetic angle sensor integrated in the flame retardant 4 (FR4)-based scanning micromirror. An accurate theoretical model is presented, especially considering the coupling effect between the driving and sensing coils. Experimental results agree well with the theoretical results, and show a sensitivity of 55.0 mVp/° and a high signal-to-noise ratio (SNR) of 71.9 dB. Moreover, the linearity of the angle sensor can still reach 0.9995, though it is affected slightly by the coupling effect. Finally, the sensor’s good feasibility for feedback control has been further verified through a simple closed-loop control circuit. The micromirror operated with closed-loop control possesses better long-term stability and temperature stability than that operated without closed-loop control.

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“…Drabe et al [12], Ataman et al [13], and Ferhanoglu et al [14] have used resonant inplane comb drives. Wang et al [15,16] and Han et al [17] are based on nonresonant electrothermal actuation. These translatory MOEMS devices could be used for instance to adjust an optical path length/optical path difference, something which is of interest for a range of applications, including confocal microscopy, optical coherence tomography, and also for FTIR spectroscopy.…”

Section: Introductionmentioning

confidence: 99%

The Designing of Magnetic-Driven Micromirror for Portable FTIRs

Wang

Xuan

2018

Journal of Sensors

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Fourier transform infrared spectroscopy is a widely used instrument to analyze and test different materials including organic and inorganic. Most of current commercial Fourier transform infrared spectrometers are limited in miniaturization and scanning velocity by their macroscopic components. MEMS FTIR spectroscopy is one of the important applications of translational actuator-driven systems by using MEMS technology. The critical component in MEMS FTIRs is the large displacement translating micromirror and its actuator. The paper presents a large displacement and high-surface quality micromirror. The micromirror consists of a micromagnetic actuator and a micromirror plate. The mirror plate and the actuator are fabricated separately and bonded together afterwards, and its size is 3.6 × 3.6 mm2 high-surface quality square mirror plate and a 1cm2 moving part. The microactuator’s moving part is fabricated using MetalMUMPS, and its fixed part includes a ring permanent magnet and a solenoid to realize a large displacement. The mirror plate is fabricated using polished silicon coated with metal layer with high-surface prototypes that are fabricated and experimentally tested. A maximum stroke of 400 μm has been achieved in pull-in whereas only 140 μm stroke have been measured for a 4 to 5-volt DC-controlled displacement, and the resonance frequency is 10 Hz.

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

Cited by 18 publications

References 26 publications

A Compound Control System for FR4-Based Electromagnetic Scanning Micrograting

A Compound Control System for FR4-Based Electromagnetic Scanning Micrograting

Investigation of Electromagnetic Angle Sensor Integrated in FR4-Based Scanning Micromirror

The Designing of Magnetic-Driven Micromirror for Portable FTIRs

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