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Versatile Multimodality Imaging System Based on Detectorless and Scanless Optical Feedback Interferometry-A

Massimo Brambilla1, Lorenzo Luigi Columbo1, Maurizio Dabbicco1

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Optical feedback interferometry offers versatile sensing and imaging applications. This review highlights its potential for new developments across various wavelengths and laser types.

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Area of Science:

  • Optics and Photonics
  • Interferometry
  • Sensing and Imaging Technologies

Background:

  • Fifteen years of research in optical feedback interferometry (OFI) are reviewed.
  • OFI demonstrates significant versatility and largely untapped potential.
  • The compendium aims to guide readers toward new OFI developments.

Purpose of the Study:

  • To provide a comprehensive overview of optical feedback interferometry research.
  • To highlight the broad applicability of OFI in sensing and imaging.
  • To inspire specialists with novel applications and future research directions.

Main Methods:

  • Review of research spanning fifteen years in optical feedback interferometry.
  • Exploration of diverse wavelengths (0.4-120 μm) and semiconductor laser types (Fabry-Perot, DFB, VCSEL, QCL).
  • Investigation of unconventional applications including multi-axis displacement, ablation front monitoring, and self-referenced measurements.

Main Results:

  • Demonstration of OFI's adaptability across a wide spectrum of wavelengths and laser sources.
  • Successful implementation of OFI in advanced sensing and imaging techniques.
  • Identification of novel applications such as structured light feedback imaging and compressive sensing.

Conclusions:

  • Optical feedback interferometry is a highly versatile technology with extensive potential for sensing and imaging.
  • The diverse range of wavelengths, laser types, and applications showcases OFI's adaptability.
  • Further research in OFI promises significant advancements in scientific and technological fields.