A Novel Self-Temperature Compensation Method for Mode-Localized Accelerometers

Cai, Pengcheng; Xiong, Xingyin; Wang, Kunfeng; Ma, Liangbo; Wang, Zheng; Liu, Yunfei; Zou, Xudong

doi:10.3390/mi13030437

Cited by 4 publications

(2 citation statements)

References 30 publications

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“…However, temperature affects the performance of silicon-based sensors, so temperature compensation is crucial for providing reliable output. It is now commonly established that temperature compensation can be realized by device structure optimization at the hardware level [ 4 , 5 , 6 ], and frequency-temperature (f-T) modelling at the software level [ 7 , 8 , 9 ]. The hardware compensation methods usually require special structural topology and sophisticated fabrication technology [ 10 ], which suffer from high cost and power consumption.…”

Section: Introductionmentioning

confidence: 99%

Input–Output-Improved Reservoir Computing Based on Duffing Resonator Processing Dynamic Temperature Compensation for MEMS Resonant Accelerometer

et al. 2023

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An MEMS resonant accelerometer is a temperature-sensitive device because temperature change affects the intrinsic resonant frequency of the inner silicon beam. Most classic temperature compensation methods, such as algorithm modeling and structure design, have large errors under rapid temperature changing due to the hysteresis of the temperature response of the accelerometer. To address this issue, we propose a novel reservoir computing (RC) structure based on a nonlinear silicon resonator, which is specifically improved for predicting dynamic information that is referred to as the input–output-improved reservoir computing (IOI-RC) algorithm. It combines the polynomial fitting with the RC on the input data mapping ensuring that the system always resides in the rich nonlinear state. Meanwhile, the output layer is also optimized by vector concatenation operation for higher memory capacity. Therefore, the new system has better performance in dynamic temperature compensation. In addition, the method is real-time, with easy hardware implementation that can be integrated with MEMS sensors. The experiment’s result showed a 93% improvement in IOI-RC compared to raw data in a temperature range of −20–60 °C. The study confirmed the feasibility of RC in realizing dynamic temperature compensation precisely, which provides a potential real-time online temperature compensation method and a sensor system with edge computing.

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Section: Introductionmentioning

confidence: 99%

Input–Output-Improved Reservoir Computing Based on Duffing Resonator Processing Dynamic Temperature Compensation for MEMS Resonant Accelerometer

et al. 2023

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“…However, due to the existing MEMS processing conditions and structural design, the performance of resonant temperature sensors such as the sensitivity has encountered bottlenecks in improvement. For the past few years, a new sensitive mechanisms of mode localization effects have been used to the resonant sensors such as force sensors 8 , accelerometers 9 , displacement sensors 10 , mass sensors 11 , and charge sensors 12 , which have been proven to have ultra-high sensitivity and can effectively improve the performance of resonant sensors [13][14][15] . Mode localization effect refers to the fact that weak changes of system parameters can alter the state of the original uniform energy distribution, resulting in energy redistribution and being limited to a certain region in a tuned system 16,17 .…”

Section: Introductionmentioning

confidence: 99%

Mode-localized temperature sensor with ultrahigh sensitivity

Kang,

2023

Fifth International Conference on Artificial Intelligence and Computer Science (AICS 2023)

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In order to significantly improve the performance of resonant temperature sensor the mode localization phenomenon is first applied to the resonant temperature sensor and a resonate temperature sensor composed of 2-DoF (degree-offreedom) resonator is proposed in this paper. The sensing scheme and 2-DoF resonator of the sensor were analyzed theoretically. The temperature response and model shape were analyzed by finite software. The simulation results showed the AR (amplitude ratio) based sensitivity was enhanced by four orders of magnitude compared with the frequency-based sensitivity

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