A dual-axis pointing mirror with moving-magnet actuation

Ataman, Çağlar; Lani, Sébastien; Noell, Wilfried; Rooij, Nico de

doi:10.1088/0960-1317/23/2/025002

Cited by 49 publications

(32 citation statements)

References 19 publications

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“…However, electromagnetic actuators require the integration of either metallic coil or magnetic material with the micromirror structure and assembly to create magnetic force. The electromagnetically actuated scanning micromirrors with moving-magnet type driving scheme have been reported for the application to the LIDAR system (Aoyagi et al 2011;Ataman et al 2013). However, the moving magnet mounted on the micromirror structure increases moment of inertia of the mirror and requires large size package for external coil, in addition to difficulty in assembling magnets on the micromirror.…”

Section: Introductionmentioning

confidence: 99%

Electromagnetically actuated biaxial scanning micromirror fabricated with silicon on glass wafer

et al. 2016

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Section: Introductionmentioning

confidence: 99%

Electromagnetically actuated biaxial scanning micromirror fabricated with silicon on glass wafer

et al. 2016

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“…By using permanent magnets, high energy densities can be achieved. Such devices have been demonstrated for a wide range of applications, including labon-a-chip valves arrays [2], micromirrors arrays [3] and tactile displays [4,5]. While much research has focused on single microdevices or small arrays of magnetic actuators, electromagnetic (EM) actuation scales well to very large arrays of microdevices by using arrays of microfabricated planar coils driving arrays of small permanent magnets.…”

Section: Introductionmentioning

confidence: 99%

“…The method can be applied to a wide range of electromagnetic actuators involving permanent magnets and planar coils, whenever a reduction of the power consumption is required, e.g. valves arrays [2] and micromirrors arrays [3].…”

Section: Introductionmentioning

confidence: 99%

Optimization of the force and power consumption of a microfabricated magnetic actuator

Zárate

Tosolini

Petroni

et al. 2015

Sensors and Actuators A: Physical

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a b s t r a c tThe force (F) and the power consumption (P) of a magnetic actuator are modeled, measured and optimized in the context of developing micro-actuators for large arrays, such as in portable tactile displays for the visually impaired. We present a novel analytical approach complemented with finite element simulation (FEM) and experiment validation, showing that the optimization process can be performed considering a single figure of merit F/ √ P. The magnetic actuator is a disc-shaped permanent magnet displaced by planar microcoil. Numerous design parameters are evaluated, including the width and separation of the coil traces, the trace thickness, number of turns and the maximum and minimum radius of the coil. We obtained experimental values of F/ √ P ranging from 2 to 12 mN/ √ W using up to 2-layer coils of both microfabricated and commercial printed circuit board (PCB) technologies. This performance can be further improved by a factor of two by adopting a 6-layer technology. The method can be applied to a wide range of electromagnetic actuators.

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“…This can be achieved optically [1] with a PSD or a 4 quadrant diode, electrostatically [2] or with an integrated piezoresistive sensor [3]. In previous work [4], we had reported the fabrication and testing of a biaxial electromagnetically actuated moving-magnet scanning mirror achieving a tilt of 8.6° with a squared shape mirror of 4mm width. This system worked in open loop mode and was composed of a mirror surface coated on both sides, a silicon compliant membrane acting as the MEMS deformable part, a magnet glued to the center of the membrane and a ceramic based coil for the actuation ( Figure 1).…”

Section: Introductionmentioning

confidence: 99%

2D MEMS scanner integrating a position feedback

Lani

Bayat

Despont

2015

MATEC Web of Conferences

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Abstract. An integrated position sensor for a dual-axis electromagnetic tilting mirror is presented. This tilting mirror is composed of a silicon based mirror directly assembled on a silicon membrane supported by flexible beams. The position sensors are constituted by 4 Wheatstone bridges of piezoresistors which are fabricated by doping locally the flexible beams. A permanent magnet is attached to the membrane and the scanner is mounted above planar coils deposited on a ceramic substrate to achieve electromagnetic actuation. The performances of the piezoresistive sensors are evaluated by measuring the output signal of the piezoresistors as a function of the tilt of the mirror and the temperature. White light interferometry was performed for all measurement to measure the exact tilt angle. The minimum detectable angle with such sensors was 30µrad (around 13bits) in the range of the minimum resolution of the interferometer. The tilt reproducibility was 0.0186%, obtained by measuring the tilt after repeated actuations with a coil current of 50mA during 30 min and the stability over time was 0.05% in 1h without actuation. The maximum measured tilt angle was 6° (mechanical) limited by nonlinearity of the MEMS system.

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A dual-axis pointing mirror with moving-magnet actuation

Cited by 49 publications

References 19 publications

Electromagnetically actuated biaxial scanning micromirror fabricated with silicon on glass wafer

Electromagnetically actuated biaxial scanning micromirror fabricated with silicon on glass wafer

Optimization of the force and power consumption of a microfabricated magnetic actuator

2D MEMS scanner integrating a position feedback

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