Methods for precisely controlling the residual stress and temperature coefficient of the frequency of a MEMS resonator based on an AlN cavity silicon-on-insulator platform

We present in this paper two new products for high-temperature, low-voltage (2.8V to 5.5V) power management applications. The first product is an original implementation of a monolithic low dropout regulator (XTR70010), able to deliver up to 1A at 230°C with less than 1V of dropout. This new voltage regulator can source an output current level up to 1.5A. The regulated output voltage can be selected among 32 preset values from 0.5V to 3.6V in steps of 100mV, or it can be obtained with a pair of external resistors. The circuit integrates complex analog and digital control blocks providing state of the art features such as UVLO protection, chip enable control, soft start-up and soft shut-down, hiccup short-circuit protection, customer selectable thermal shut-down, input power supply protection, output overshoot remover and stability over an extremely wide range of load capacitances. The circuit offers a fair ±2% absolute accuracy and is guaranteed latch-up free. The second product is an advanced high-temperature, low-power, digitally trimmable voltage reference (XTR75020). Thanks to a custom, 1-wire serial interface, the absolute precision and the temperature coefficient can be adjusted in order to obtain an accuracy better than 0.5% with a temperature coefficient bellow ±20ppm/°C. On-chip OTP memory for trimming of absolute value and temperature coefficient makes the circuit extremely accurate and almost insensitive to drifts over time and temperature. The circuit features a class AB output buffer able to source or sink up to 5mA and remains stable with any load capacitance up to 50μF. The XTR75020 has nine preset possible output voltages. The source and sink short circuit current always remains bellow 25mA. The quiescent current consumption is 300μA typical at 230°C while the standby current is, in all cases, under 20μA. Both devices are designed on a latch-up free silicon-on-insulator process.

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Evaluation of Residual Stress of C Oriented AlN/Si (111) and Its Impact on Mushroom Shaped Piezoelectric Resonator

10.21203/rs.3.rs-211735/v1 ◽

2021 ◽

Author(s):

AKHILESH PANDEY ◽

Shankar Dutta ◽

Nidhi Gupta ◽

Davinder Kaur ◽

R. Raman

Keyword(s):

Residual Stress ◽

Residual Stresses ◽

Mode Shapes ◽

Quality Factors ◽

Resonator Structure ◽

Resonator Design ◽

Mems Resonator ◽

Mems Resonators ◽

Quality Factor Q ◽

Preferred Oriented

Abstract Aluminum nitride-based MEMS resonators are one of the interesting recent research topics for its tremendous potential in a wide variety of applications. This paper focuses on the detrimental effect of residual stress on the AlN based MEMS resonator design for acoustic applications. The residual stress in the sputtered c axis (<001>) preferred oriented AlN layers on Si (111) substrates are studied as a function of layer thickness. The films exhibited compressive residual stresses at different thickness values: -1050 MPa (700 nm), -500 MPa (900 nm), and -230 MPa (1200 nm). A mushroom-shaped AlN based piezoelectric MEMS resonator structure has been designed for the different AlN layer thicknesses. The effect of the residual stresses on the mode shapes, resonant frequencies, and quality factor (Q) of the resonator structures are studied. The resonant frequency of the structures are altered from 235 kHz, 280 kHz, and 344 kHz to 65 kHz, 75 kHz and 371 kHz due to the residual stress of -1050 MPa (thickness: 700 nm), -500 MPa (thickness: 900 nm) and -230 MPa (thickness: 1200 nm) respectively. At no residual stress, the quality factors of the resonator structures are 248, 227, 241 corresponding to the 700 nm, 900 nm, and 1200 nm thick AlN layers respectively. The presence of the residual stress reduced the Q values from 248 (thickness: 700 nm), 227 (thickness: 900 nm), 241 (thickness: 1200 nm) to 28, 53, and 261 respectively.

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Effect of residual stress on modes of coupled MEMS resonator array

10.1109/3m-nano49087.2021.9599771 ◽

2021 ◽

Author(s):

Bo Peng ◽

Kaiming Hu ◽

Xiaoyong Fang ◽

Wenming Zhang

Keyword(s):

Residual Stress ◽

Mems Resonator

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Selective silicon-on-insulator (SOI) implant: a new micromachining method without footing and residual stress

Journal of Micromechanics and Microengineering ◽

10.1088/0960-1317/15/9/001 ◽

2005 ◽

Vol 15 (9) ◽

pp. 1607-1613 ◽

Cited By ~ 15

Author(s):

Sangjun Park ◽

Donghun Kwak ◽

Hyoungho Ko ◽

Taeyong Song ◽

Dong-il Cho

Keyword(s):

Residual Stress ◽

Silicon On Insulator

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Analysis of Frequency Drift of Silicon MEMS Resonator with Temperature

Micromachines ◽

10.3390/mi12010026 ◽

2020 ◽

Vol 12 (1) ◽

pp. 26

Author(s):

Bo Jiang ◽

Shenhu Huang ◽

Jing Zhang ◽

Yan Su

Keyword(s):

Temperature Coefficient ◽

Intrinsic Property ◽

Micro Electro Mechanical System ◽

Frequency Drift ◽

Distribution Law ◽

Sensors And Actuators ◽

Temperature Range ◽

Thermal Expansion Coefficients ◽

Mems Resonator ◽

Mems Resonators

High-quality-factor Micro-Electro-Mechanical System (MEMS) resonators have been widely used in sensors and actuators to obtain great mechanical sensitivity. The frequency drift of resonator with temperature is a problem encountered practically. The paper focuses on the resonator frequency distribution law in the temperature range of—40 to 60 °C. The four-layer models were established to analyze thermal stress caused by temperature due to the mismatch of thermal expansion coefficients. The temperature variation leads to the transformation of stress, which leads to the shift of resonance frequency. The paper analyzes the influence of hard and soft adhesive package on the temperature coefficient of frequency. The resonant accelerometer was employed for the frequency measurements in the paper. In experiments, three types of adhesive dispensing patterns were implemented. The results are consistent with the simulation well. The optimal packaging method achieves −24.1 ppm/°C to −30.2 ppm/°C temperature coefficient of the resonator in the whole temperature range, close to the intrinsic property of silicon (−31 ppm).

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Online Test Structure for Measuring Young’s Modulus and Residual Stress of the Top Silicon Layer of Silicon-On-Insulator by a Pull-in Approach

Sensors and Materials ◽

10.18494/sam.2015.1070 ◽

2015 ◽

pp. 1

Keyword(s):

Residual Stress ◽

Silicon Layer ◽

Test Structure ◽

Silicon On Insulator ◽

Online Test

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Effects of silicon-on-insulator substrate on the residual stress within 3C-SiC/Si thin films

Applied Physics Letters ◽

10.1063/1.1608495 ◽

2003 ◽

Vol 83 (10) ◽

pp. 1989-1991 ◽

Cited By ~ 9

Author(s):

J.-H. Park ◽

J. H. Kim ◽

Y. Kim ◽

B.-T. Lee ◽

S.-J. Jang ◽

...

Keyword(s):

Thin Films ◽

Residual Stress ◽

Silicon On Insulator ◽

Insulator Substrate

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Intelligent Detector of Internal Combustion Engine Cylinder Pressure and Sensitivity Temperature Coefficient Compensation

Advances in Materials Science and Engineering ◽

10.1155/2013/107582 ◽

2013 ◽

Vol 2013 ◽

pp. 1-6

Author(s):

Beirong Zheng ◽

Chen Zhou ◽

Xiaomin Pan ◽

Quan Wang ◽

Wei Xue

Keyword(s):

Internal Combustion Engine ◽

Temperature Coefficient ◽

Combustion Engine ◽

Internal Combustion ◽

Silicon On Insulator ◽

Constant Current ◽

Cylinder Pressure ◽

Compression Pressure ◽

Engine Cylinder ◽

Individual Adjustment

The detecting device based on mechanical mechanism is far from the measurement of internal combustion engine cylinder explosion and compression pressure. This pressure detection is under the environment of pulsed gas (over 500 times per one minute) and mechanical impactive vibration. Piezoresistive detection with silicon on insulator (SOI) strain gauges to pressure seems to be a good solution to meet such special applications. In this work, separation by implanted oxygen (SIMOX) wafer was used to fabricate the high temperature pressure sensor chip. For high accuracy and wide temperature range application, this paper also presents a novel pressure sensitivity temperature coefficient (TCS) compensation method, using integrated constant current network. A quantitative compensation formula is introduced in mathematics. During experiments, the absolute value of the compensated TCS is easy to be 10 × 10−6/°C~100 × 10−6/°C by individual adjustment and calibration of each device’s temperature compensation. Therefore, the feasibility and practicability of this technology are tested. Again, the disadvantages are discussed after the research of the experiment data and the improvement methods are also given in the designing period. This technology exhibits the great potential practical value of internal combustion engine cylinder pressure with volume manufacturing.

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