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Interferometric Laser Scanner for Direction Determination.

Gennady Kaloshin1, Igor Lukin2

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Summary
This summary is machine-generated.

This study presents a new laser scanning method for direction determination using partially coherent beams in turbulent atmospheres. The technique ensures reliable operation up to 10 km, even with moderate atmospheric turbulence.

Keywords:
atmospheric turbulenceinterferencelaser beamlaser scanning

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Area of Science:

  • Optics and Photonics
  • Atmospheric Physics
  • Laser Technology

Background:

  • Direction determination methods often struggle with atmospheric turbulence.
  • Existing methods for fully coherent beams are limited in turbulent environments.
  • Partially coherent sources present unique challenges for interference pattern analysis.

Purpose of the Study:

  • To extend laser scanning-based direction determination to partially coherent sources in turbulent atmospheres.
  • To identify conditions for stable interference pattern formation over extended atmospheric paths.
  • To develop a method for selecting laser scanner parameters for reliable operation in varying turbulence.

Main Methods:

  • Theoretical analysis of interference pattern formation by two partially coherent sources.
  • Investigation of pattern stability on propagation paths from 0.5-10 km.
  • Analysis of mean intensity of interference patterns to select scanner parameters.
  • Estimation of interference pattern visibility as a function of pathlength, turbulence, and source spacing.

Main Results:

  • Conditions for stable interference pattern formation in turbulent atmospheres were identified.
  • A method for laser scanner parameter selection was developed for robust atmospheric operation.
  • Interference pattern visibility was quantified concerning atmospheric turbulence and pathlength.
  • The laser scanner method demonstrated applicability up to 10 km in moderately strong turbulence.

Conclusions:

  • The extended laser scanning method is viable for direction determination with partially coherent sources in turbulent atmospheres.
  • Parameter selection based on mean intensity analysis ensures operability across diverse turbulence conditions.
  • The method's effectiveness is validated for ranges up to 10 km, enhancing remote sensing capabilities.