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Low-power Chip-Scale Atomic Clocks (CSACs) enable crucial time-coherent processing for underwater acoustics. Optimal clock disciplining is vital for maintaining array coherence in acoustic oceanography applications.

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Area of Science:

  • Oceanography
  • Acoustics
  • Atomic Physics

Background:

  • Underwater acoustic arrays require precise timing for signal processing.
  • Chip-Scale Atomic Clocks (CSACs) offer a portable solution for time synchronization.
  • Lack of shared timing references limits current underwater acoustic array capabilities.

Purpose of the Study:

  • To evaluate the effectiveness of Chip-Scale Atomic Clocks (CSACs) in underwater acoustic applications.
  • To determine the importance of optimal clock disciplining for maintaining array coherence.
  • To assess the performance of CSAC-equipped arrays in various acoustic oceanography scenarios.

Main Methods:

  • Controlled laboratory experiments were conducted using a small acoustic array (N=4) equipped with CSACs.
  • The study analyzed clock drift and its impact on array coherence at different frequencies.
  • Experiments focused on time-coherent processing for directionality estimation.

Main Results:

  • CSACs enable time-coherent processing essential for directionality estimation in underwater acoustics.
  • Optimal disciplining of CSACs was found to be critical for sustained array coherence.
  • Clock drift reached a 10% wavelength error at 0.3, 1, and 10 kHz within 25, 10, and 3 days, respectively.

Conclusions:

  • CSAC technology enhances capabilities in acoustic thermometry, geoacoustic, biological, and under-ice oceanography.
  • The findings highlight the potential of CSACs for advancing underwater acoustic research and applications.
  • Careful clock disciplining strategies are necessary to maximize the benefits of CSACs in oceanographic studies.