Temperature compensated silicon resonators for space applications

Rais‐Zadeh, Mina; Thakar, Vikram; Wu, Zhengzheng; Peczalski, Adam

doi:10.1117/12.2001434

Cited by 5 publications

(3 citation statements)

References 13 publications

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“…Such resonators are especially suited for oven-controlled systems as the turnover temperature can be adjusted by the geometry of the structure. At the turnover point a frequency stability of ±0.1 ppm was demonstrated over a period of more than one hour [47].…”

Section: Siliconmentioning

confidence: 99%

Mechanical properties of MEMS materials: reliability investigations by mechanical- and HRXRD-characterization related to environmental testing

2014

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The performance and aging of MEMS often rely on the stability of the mechanical properties over time and under harsh conditions. An overview is given on methods to investigate small variations of the mechanical properties of structural MEMS materials by functional characterization, high-resolution x-ray diffraction methods (HR-XRD) and environmental testing. The measurement of the dynamical properties of micro-resonators is a powerful method for the investigation of elasticity variations in structures relevant to microtechnology. X-ray diffraction techniques are used to analyze residual strains and deformations with high accuracy and in a non-destructive manner at surfaces and in buried micro-structures. The influence of elevated temperatures and radiation damage on the performance of resonant microstructures with a focus on quartz and single crystal silicon is discussed and illustrated with examples including work done in our laboratories at CSEM and EPFL.

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Section: Siliconmentioning

confidence: 99%

Mechanical properties of MEMS materials: reliability investigations by mechanical- and HRXRD-characterization related to environmental testing

2014

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“…Typically, either a temperature-stable environment or a thermal-compensation scheme must be created. While most studies of thermal compensation address the stability of resonance frequency over temperature by reducing the Temperature Coefficient of Frequency (TCF), designing temperature-insensitive structure, or implementing a compensation algorithm [1], herein, we focus on the stabilization of Q-factor, a fundamental parameter of resonance devices. For ultra-high Q-factor resonators, Q-factor strongly depends on temperature [2].…”

Section: Introductionmentioning

confidence: 99%

Electrostatic stabilization of thermal variation in quality factor using anchor loss modulation

Han

Zotov

Simon

et al. 2014

IEEE SENSORS 2014 Proceedings

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We report an ultra-low energy dissipation silicon MEMS tuning fork resonator with a Q-factor of over 2 million at 570 Hz, with the ability of Q-factor stabilization throughout a temperature range of over 100 o C. This stabilization approach relies on the controlling of energy dissipation through regulating the stiffness misbalance of the tuning fork resonator. Without Q-factor regulation, the resonator demonstrates a Q-factor with a 25% drift from 2.14 million to 2.67 million, over a temperature range from 40 °C to +60 °C. With implementation of the proposed stabilization method, the experimental characterization reveals a stable Q-factor of 2.14 million within 0.3% (+1σ) variation for an identical temperature range ( 40 °C to +60 °C).

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“…However, the elastic properties of Si are strongly temperature-dependent, so temperature fluctuations degrade the long-term frequency stability of Si-based oscillators. A number of compensation methods have been reported for improving temperature stability [ 2 , 6 , 7 , 8 , 9 , 10 , 11 , 12 , 13 ]. For example, in [ 12 ], the authors implement a passive compensation method by utilizing silicon dioxide (SiO 2 ), which has an opposite TC f compared to the structural material of the main resonator (Si); this compensation technique results in a parabolic (second-order) frequency dependence versus temperature.…”

Section: Introductionmentioning

confidence: 99%

A Temperature-Compensated Single-Crystal Silicon-on-Insulator (SOI) MEMS Oscillator with a CMOS Amplifier Chip

et al. 2018

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Self-sustained feedback oscillators referenced to MEMS/NEMS resonators have the potential for a wide range of applications in timing and sensing systems. In this paper, we describe a real-time temperature compensation approach to improving the long-term stability of such MEMS-referenced oscillators. This approach is implemented on a ~26.8 kHz self-sustained MEMS oscillator that integrates the fundamental in-plane mode resonance of a single-crystal silicon-on-insulator (SOI) resonator with a programmable and reconfigurable single-chip CMOS sustaining amplifier. Temperature compensation using a linear equation fit and look-up table (LUT) is used to obtain the near-zero closed-loop temperature coefficient of frequency (TCf) at around room temperature (~25 °C). When subject to small temperature fluctuations in an indoor environment, the temperature-compensated oscillator shows a >2-fold improvement in Allan deviation over the uncompensated counterpart on relatively long time scales (averaging time τ > 10,000 s), as well as overall enhanced stability throughout the averaging time range from τ = 1 to 20,000 s. The proposed temperature compensation algorithm has low computational complexity and memory requirement, making it suitable for implementation on energy-constrained platforms such as Internet of Things (IoT) sensor nodes.

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Temperature compensated silicon resonators for space applications

Cited by 5 publications

References 13 publications

Mechanical properties of MEMS materials: reliability investigations by mechanical- and HRXRD-characterization related to environmental testing

Mechanical properties of MEMS materials: reliability investigations by mechanical- and HRXRD-characterization related to environmental testing

Electrostatic stabilization of thermal variation in quality factor using anchor loss modulation

A Temperature-Compensated Single-Crystal Silicon-on-Insulator (SOI) MEMS Oscillator with a CMOS Amplifier Chip

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