An Empirical Phase-Noise Model for MEMS Oscillators Operating in Nonlinear Regime

Pardo, Mauricio; Sorenson, Logan; Ayazi, Farrokh

doi:10.1109/tcsi.2012.2195129

Cited by 30 publications

(15 citation statements)

References 35 publications

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This tutorial distills the salient phase-noise analysis concepts and key equations developed over the last 75 years relevant to integrated circuit oscillators. This resonator can take the form of an LC tank circuit, dielectric puck, quartz crystal, SAW or bulk acoustic wave transducer, yttrium iron garnet resonator, or ceramic disk resonator to name a few [43,147,148]. Furthermore, we demonstrate that all these methods boil down to obtaining three things: (1) noise modulation function; (2) noise transfer function; and (3) current-controlled oscillator gain.

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confidence: 90%

Survey of integrated‐circuit‐oscillator phase‐noise analysis

Pankratz

Sánchez-Sinencio

2013

Circuit Theory & Apps

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This tutorial distills the salient phase-noise analysis concepts and key equations developed over the last 75 years relevant to integrated circuit oscillators. Oscillator phase and amplitude fluctuations have been studied since at least 1938 when Berstein solved the Fokker-Planck equations for the phase/amplitude distributions of a resonant oscillator.The principal contribution of this work is the organized, unified presentation of eclectic phase-noise analysis techniques, facilitating their application to integrated circuit oscillator design. Furthermore, we demonstrate that all these methods boil down to obtaining three things: (1) noise modulation function; (2) noise transfer function; and (3) current-controlled oscillator gain. For each method, this paper provides a short background explanation of the technique, a step-by-step procedure of how to apply the method to hand calculation/computer simulation, and a worked example to demonstrate how to analyze a practical oscillator circuit with that method.This survey article chiefly deals with phase-noise analysis methods, so to restrict its scope, we limit our discussion to the following: (1) analyzing integrated circuit metal-oxide-semiconductor/bipolar junction transistor-based LC, delay, and ring oscillator topologies; (2) considering a few oscillator harmonics in our analysis; (3) analyzing thermal/flicker intrinsic device-noise sources rather than environmental/parametric noise/ wander; (4) providing mainly qualitative amplitude-noise discussions; and (5) omitting measurement methods/phase-noise reduction techniques.We categorize oscillators into one of three varieties, as illustrated in Figure 3: resonant, delay line, or relaxation. First, the resonant oscillator consists of a nonlinear amplifier and a lumped frequencyselective network or resonator, which typically has a band-pass frequency response with a single magnitude peak as indicated conceptually in the figure. This resonator can take the form of an LC tank circuit, dielectric puck, quartz crystal, SAW or bulk acoustic wave transducer, yttrium iron garnet resonator, or ceramic disk resonator to name a few [43,147,148]. IC resonant oscillators typically use LC tanks, although they are often designed to work in concert with an external 874 E. PANKRATZ AND E. SÁNCHEZ-SINENCIO ! ss t ð Þ correspond to the roughly circular trajectory in the figure called a limit cycle [150].Figure 4. Optoelectronic delay-line oscillator. 876 E. PANKRATZ AND E. SÁNCHEZ-SINENCIO For some subtleties of amplitude-noise behavior, see [50,143], where [50] also points out effects of not employing Floquet normalization (cf. Section 4.7).½ =fVoigt ð Þ 2(Gaussian) at small offsets [78,151,152,154]. Chorti also observed that, in general, noise processes with long correlation times tend to create such 'Gaussian' voltage spectra for small frequency offsets f m [151,152]. 4 Note well that, technically, defining spectra for f proves problematic, as it is not stationary and, what is worse, not bounded. This is in fact one reason why the ...

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Survey of integrated‐circuit‐oscillator phase‐noise analysis

Pankratz

Sánchez-Sinencio

2013

Circuit Theory & Apps

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“…The Formula (13), and (14), shows that both the low-frequency or high-frequency current injection will cause the original stable phase of drive signal changes. When the phase changes by the injection current is contained, the drive frequency excitation signal can be expressed as:…”

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Phase Noise Analysis for the Drive Loop of Capacitive MEMS Gyroscopes

Li¹,

Wang²,

Liu³

2017

IJSIP

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“…Because one particular electrode configuration can excite several modes in piezoelectric resonators, gain and phase conditions are often met for many frequencies. Therefore, both adequate compensation of resonator electrical loading [14] and spurious mode suppression are crucial in safeguarding the circuit from locking into oscillations at undesired frequencies.…”

Section: B Device Fabrication and Optimizationmentioning

confidence: 99%

High-<inline-formula> <tex-math notation="LaTeX">$Q$ </tex-math></inline-formula> AlN-on-Silicon Resonators With Annexed Platforms for Portable Integrated VOC Sensing

Ayazi

2015

J. Microelectromech. Syst.

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Aluminum nitride (AlN) thin-film piezoelectric-onsilicon resonators optimized for gravimetric gas sensing are presented in this paper. Sensors with polyisobutylenefunctionalized annexed platforms exhibit a linear sensitivity of −0.09 Hz/ppm to toluene and −0.18 Hz/ppm to xylene. The annexed platform design enables the sensor to maintain a high Q of 3700 in air and low motional resistance of 1.1 k during operation, which ensures low-power oscillator interfacing and readout. AlN-on-Si resonators with annexed platforms are suitable for array implementation in environmental sensing microsystems that measure temperature, humidity, and various gases of importance to health and safety.[2013-0175]

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An Empirical Phase-Noise Model for MEMS Oscillators Operating in Nonlinear Regime

Cited by 30 publications

References 35 publications

Survey of integrated‐circuit‐oscillator phase‐noise analysis

Survey of integrated‐circuit‐oscillator phase‐noise analysis

Phase Noise Analysis for the Drive Loop of Capacitive MEMS Gyroscopes

High-<inline-formula> <tex-math notation="LaTeX">$Q$ </tex-math></inline-formula> AlN-on-Silicon Resonators With Annexed Platforms for Portable Integrated VOC Sensing

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