1. An integrated capacitive sensing method for electrostatic comb-drive micromirrors.
- Author
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Zhang, Ruihao, Qu, Jiasheng, Cao, Yingchao, Zhang, Xinchao, Jia, Yilong, Wang, Xiaoyi, Zhou, Wenbiao, and Xie, Huikai
- Subjects
- *
MICROMIRRORS , *DETECTOR circuits , *PHASE transitions , *TEMPERATURE effect - Abstract
In this work, a real-time capacitive sensing scheme based on electromechanical amplitude modulation is developed to detect the scanning angle and phase of a uniaxial electrostatic comb-drive micromirror for close loop control. In this scheme, a sine-wave voltage signal superimposed with a high frequency carrier signal is applied to the shared comb drives of the micromirror for both sensing and driving. The driving/sensing circuit is fully analyzed in both frequency and time domain for feedthrough elimination and signal distortion minimization. Experimental results have shown that using a carrier signal with 2.5 V pp and 1 MHz, the measurement accuracy of the scanning angle of the micromirror reaches 0.15° and the time delay can be controlled within 0.47 μs. The effect of the temperature change on the phase response of the micromirror is also investigated for a better understanding of the micromirror's scanning stability. When the temperature changes from 25 °C to 35 °C, the measured time delay of the micromirror actuated at 3840 Hz changes from 0 to 2.4 μs. The proposed capacitive sensing scheme can be used to effectively measure the angular position and phase of electrostatic comb-drive MEMS mirrors simultaneously without the need of adding any external components. [Display omitted] • A capacitive angular sensing circuit developed for electrostatic micromirrors. • Simultaneous real-time detection of the angle and phase of the micromirror has been achieved. • The phase change of the scanning micromirror on the temperature variation has been investigated experimentally. • The relation between the scan angle and the circuit output voltage can be accurately modelled through piecewise fitting. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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