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Related Concept Videos

Aliasing01:18

Aliasing

Accurate signal sampling and reconstruction are crucial in various signal-processing applications. A time-domain signal's spectrum can be revealed using its Fourier transform. When this signal is sampled at a specific frequency, it results in multiple scaled replicas of the original spectrum in the frequency domain. The spacing of these replicas is determined by the sampling frequency.
If the sampling frequency is below the Nyquist rate, these replicas overlap, preventing the original signal...
Upsampling01:22

Upsampling

Managing signal sampling rates is essential in digital signal processing to maintain signal integrity. A decimated signal, characterized by a reduced frequency range due to its lower sampling rate, can be upsampled by inserting zeros between each sample. This upsampling process expands the original spectrum and introduces repeated spectral replicas at intervals dictated by the new Nyquist frequency. To refine this zero-inserted sequence, it is passed through a lowpass filter with a cutoff...
Linear Approximation in Frequency Domain01:26

Linear Approximation in Frequency Domain

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IR Frequency Region: Fingerprint Region01:03

IR Frequency Region: Fingerprint Region

IR spectra are divided into two main regions: the diagnostic region and the fingerprint region. The diagnostic region of the spectrum lies above 1500 cm−1. The absorptions resulting from single-bond vibrations of the N–H, C–H, and O–H stretch at higher wavenumbers and appear on the left side of the spectrum. The stretching absorptions of the C≡C and C≡N occur between 2100–2300 cm−1. In contrast, those arising from stretching absorptions of the C=O, C=N, and C=C occur between 1600–1850 cm−1.
The...
Cut-off Frequency of BJT01:17

Cut-off Frequency of BJT

Cut-off frequencies in Bipolar Junction Transistors (BJTs) mark the transition between the signal's pass band and stop band, influencing their performance in amplifying or attenuating frequencies. These frequencies are crucial for designing BJTs to meet specific operational requirements in electronic circuits.
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Related Experiment Video

Updated: Jun 15, 2026

Implementation of a Reference Interferometer for Nanodetection
16:11

Implementation of a Reference Interferometer for Nanodetection

Published on: April 26, 2014

A digitally compensated 1.5 GHz CMOS/FBAR frequency reference.

Shailesh Rai1, Ying Su, Wei Pang

  • 1Department of Electrical Engineering, University of Washington, Seattle, WA, USA. shailesh@u.washington.edu

IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control
|March 10, 2010
PubMed
Summary
This summary is machine-generated.

A novel temperature-compensated 1.5 GHz film bulk acoustic wave resonator (FBAR) oscillator offers a compact, low-power alternative to quartz crystal references. This CMOS-integrated device achieves excellent frequency stability across a wide temperature range.

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Last Updated: Jun 15, 2026

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Area of Science:

  • Electrical Engineering
  • Materials Science
  • Physics

Background:

  • Quartz crystal oscillators are traditional frequency references but are often bulky and power-intensive.
  • Miniaturization and lower power consumption are critical for modern electronic devices.
  • Film Bulk Acoustic Wave Resonators (FBARs) offer potential for smaller, more efficient frequency control.

Purpose of the Study:

  • To present a temperature-compensated 1.5 GHz FBAR-based frequency reference.
  • To demonstrate its feasibility using a standard 0.35 micrometer CMOS process.
  • To evaluate its performance as a replacement for quartz crystal references.

Main Methods:

  • Implementation of a 1.5 GHz FBAR oscillator within a 0.35 micrometer CMOS fabrication process.
  • Integration of temperature compensation circuitry.
  • Characterization of frequency drift over a 0-100 degrees C temperature range.
  • Measurement of oscillator phase noise.

Main Results:

  • Achieved an ultra-small form factor of 0.79 mm x 1.72 mm.
  • Demonstrated low power dissipation of 515 microA with a 2 V supply.
  • Measured post-compensation frequency drift below +/- 10 ppm over 0-100 degrees C.
  • Obtained oscillator phase noise of -133 dBc/Hz at 100 kHz offset.

Conclusions:

  • The developed temperature-compensated FBAR oscillator is a viable, compact, and low-power alternative to quartz crystal frequency references.
  • CMOS integration enables scalable and cost-effective production.
  • The device meets stringent frequency stability and phase noise requirements for advanced applications.