A design methodology for low phase noise in LC tuned CMOS voltage-controlled oscillators

Li, Ye-Ming

12 1900

No description available.

Oscillators, Audio-frequency Noise

Wireless communication systems Noise

Tank circuits

Design and phase-noise modeling of temperature-compensated high frequency MEMS-CMOS reference oscillators

Miri Lavasani, Seyed Hossein

18 May 2010

Frequency reference oscillator is a critical component of modern radio transceivers. Currently, most reference oscillators are based on low-frequency quartz crystals that are inherently bulky and incompatible with standard micro-fabrication processes. Moreover, their frequency limitation (<200MHz) requires large up-conversion ratio in multigigahertz frequency synthesizers, which in turn, degrades the phase-noise. Recent advances in MEMS technology have made realization of high-frequency on-chip low phase-noise MEMS oscillators possible. Although significant research has been directed toward replacing quartz crystal oscillators with integrated micromechanical oscillators, their phase-noise performance is not well modeled. In addition, little attention has been paid to developing electronic frequency tuning techniques to compensate for temperature/process variation and improve the absolute frequency accuracy. The objective of this dissertation was to realize high-frequency temperature-compensated high-frequency (>100MHz) micromechanical oscillators and study their phase-noise performance. To this end, low-power low-noise CMOS transimpedance amplifiers (TIA) that employ novel gain and bandwidth enhancement techniques are interfaced with high frequency (>100MHz) micromechanical resonators. The oscillation frequency is varied by a tuning network that uses frequency tuning enhancement techniques to increase the tuning range with minimal effect on the phase-noise performance. Taking advantage of extended frequency tuning range, and on-chip temperature-compensation circuitry is embedded with the sustaining circuitry to electronically temperature-compensate the oscillator. Finally, detailed study of the phase-noise in micromechanical oscillators is performed and analytical phase-noise models are derived.

Phase-noise modeling

Phase-noise

Oscillator

VCO

Micromechanical oscillator

Capacitance cancellation

Negative capacitance

Negative impedance converter

Temperature compensation

Linear CMOS voltage to current converter

Piezoelectric resonator

Capacitive resonator

Tuning enhancement

TIA

Transimpedance amplifier

MEMS

Frequency tuning

Oscillators, Electric

Oscillators, Crystal

Radio frequency oscillators

Microelectromechanical systems

Oscillators, Audio-frequency Noise