High Quality Factor Resonant MEMS Accelerometer With Continuous Thermal Compensation

Zotov, Sergei A.; Simon, Brenton R.; Trusov, Alexander A.; Shkel, Andrei M.

doi:10.1109/jsen.2015.2432021

Cited by 105 publications

(30 citation statements)

References 23 publications

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“…a 20ḡ (gravity units) FSR acceleration on a typical MEMS accelerometer [10], [11]. It is also at least one order of magnitude lower than Coriolis forces on a MEMS gyroscope driven with a 5 µm amplitude around 20 kHz, for typical FSR angular rates of 2000 dps [12], [13].…”

Section: Introductionmentioning

confidence: 95%

A 3-D Micromechanical Multi-Loop Magnetometer Driven Off-Resonance by an On-Chip Resonator

Laghi

Marra

Minotti

et al. 2016

J. Microelectromech. Syst.

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Abstract-The work presents the principle and the complete characterization of a single-chip unit formed by MEMS magnetometers to sense the 3D magnetic field vector, and a Tang resonator. The three sensors, nominally with the same resonance frequency, are operated 200 Hz off-resonance through an AC current whose reference frequency is provided by the resonator, embedded in an oscillating circuit. The sensors gain is increased by adopting a current recirculation strategy using metal strips directly deposited on the structural polysilicon. At a driving value of 100 µArms flowing in series through the three devices, the magnetometers show a sub 185 nT/ √ Hz resolution with a selectable bandwidth up to 50 Hz. Over a ± 5 mT full-scale range, the sensitivity curves show linearity errors lower than 0.2%, with high cross-axis rejection and immunity to external accelerations. Under temperature changes, stability of the 200-Hz difference between the magnetometers and the resonator frequency is within 55 ppm/K. Offset is trimmed down to the µT range, with an overall measured Allan stability of about 100 nT at 20 s observation time.

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Section: Introductionmentioning

confidence: 95%

A 3-D Micromechanical Multi-Loop Magnetometer Driven Off-Resonance by an On-Chip Resonator

Laghi

Marra

Minotti

et al. 2016

J. Microelectromech. Syst.

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“…A successful excitation of resonant microaccelerometers is crucial to achieve high performance. Many methods to control these accelerometers have been published [1][2][3][4][5]. A nonlinear operator-theoretical approach based on the describing function technique was used to design the feedback parameters and characterize the analog loop performance [1,2].…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies [3,4,6,7] proposed an analog control circuit based on automatic amplitude control (AGC) technology. Recently, a phase lock loop (PLL) combined with AGC was utilized to lock the natural frequency of the resonator and maintain a stable resonant amplitude [5,8,9]. However, most of the previous control technologies for microaccelerometers that adopted the analog circuitry were characterized by a large temperature drift, a complex adjustment in circuit parameters, difficulties in compensation, and other disadvantages.…”

Section: Introductionmentioning

confidence: 99%

Digital Closed-Loop Driving Technique Using the PFD-Based CORDIC Algorithm for a Biaxial Resonant Microaccelerometer

Yang

Wang

et al. 2017

Journal of Sensors

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A digital closed-loop driving technique is presented in this paper that uses the PFD-(phase frequency detector-) based CORDIC (coordinate rotation digital computer) algorithm for a biaxial resonant microaccelerometer. A conventional digital closed-loop selfoscillation system based on the CORDIC algorithm is implemented and simulated using Simulink software to verify the system performance. The system performance simulations reveal that the incompatibility between the sampling frequency and effective bits of AD and DA convertors limits further performance improvements. Therefore, digital, closed-loop self-oscillation using the PFD-based CORDIC algorithm is designed to further optimize the system performance. The system experimental results illustrate that the optimized system using the PFD-based CORDIC improves the bias stability of the resonant microaccelerometer by more than 5.320 times compared to the conventional system. This demonstrates that the optimized digital closed-loop driving technique using the PFD-based CORDIC for the biaxial resonant microaccelerometer is effective.

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“…An accurate evaluation of the thermal effects of accelerometers, more specifically the deformation and rise time (related to the response speed of the sensor), is critical for realizing reliable and stable devices. There have been many reports that study thermally induced deformation on traditional accelerometers including capacitive [13,14], resonant [15,16], and piezoelectric accelerometers [17,18], among others [19]. Their thermally induced deformation mainly stems from the temperature variation in their operating environments, or the contribution of their electric elements [20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Determination of thermally induced effects and design guidelines of optomechanical accelerometers

Bai

Wang

et al. 2017

Meas. Sci. Technol.

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Thermal effects, including thermally induced deformation and warm up time, are ubiquitous problems for sensors, especially for inertial measurement units such as accelerometers. Optomechanical accelerometers, which contain light sources that can be regarded as heat sources, involve a different thermal phenomenon in terms of their specific optical readout, and the phenomenon has not been investigated systematically. This paper proposes a model to evaluate the temperature difference, rise time and thermally induced deformation of optomechanical accelerometers, and then constructs design guidelines which can diminish these thermal effects without compromising other mechanical performances, based on the analysis of the interplay of thermal and mechanical performances. In the model, the irradiation of the micromachined structure of a laser source is considered a dominant factor. The experimental data obtained using a prototype of an optomechanical accelerometer approximately confirm the validity of the model for the rise time and response tendency. Moreover, design guidelines that adopt suspensions with a flat cross-section and a short length are demonstrated with reference to the analysis. The guidelines can reduce the thermally induced deformation and rise time or achieve higher mechanical performances with similar thermal effects, which paves the way for the design of temperature-tolerant and robust, high-performance devices.

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High Quality Factor Resonant MEMS Accelerometer With Continuous Thermal Compensation

Cited by 105 publications

References 23 publications

A 3-D Micromechanical Multi-Loop Magnetometer Driven Off-Resonance by an On-Chip Resonator

A 3-D Micromechanical Multi-Loop Magnetometer Driven Off-Resonance by an On-Chip Resonator

Digital Closed-Loop Driving Technique Using the PFD-Based CORDIC Algorithm for a Biaxial Resonant Microaccelerometer

Determination of thermally induced effects and design guidelines of optomechanical accelerometers

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