Startseite Modeling of imaging fiber bundles and adapted signal processing for fringe projection
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Modeling of imaging fiber bundles and adapted signal processing for fringe projection

  • Steffen Matthias

    Steffen Matthias is a research associate at the Institute of Measurement and Automatic Control at Leibniz Universität Hannover.

     ORCID logo EMAIL logo     , Markus Kästner

    Markus Kästner is the head of the department for production metrology at the Institute of Measurement and Automatic Control at Leibniz Universität Hannover.

         und Eduard Reithmeier

    Eduard Reithmeier is the head of the Institute of Measurement and Automatic Control at Leibniz Universität Hannover.
Veröffentlicht/Copyright: 9. November 2016
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Advanced Optical Technologies
Aus der Zeitschrift Advanced Optical Technologies Band 5 Heft 5-6

Abstract

Fringe projection profilometry is an established technique for capturing three-dimensional (3-D)-geometry data with high-point densities in short time. By combining fringe projection with endoscopy techniques, it is possible to perform inline inspection of industrial manufacturing processes. A new fringe projection system is presented, which uses flexible image fiber bundles to achieve versatile positioning of a compact sensor head. When measuring specimens with highly varying reflectivity, such as technical surfaces on tool geometries, measurement errors increase especially due to the crosstalk between individual fibers in the bundle. A detailed analysis of the transmission properties of the utilized fiber bundles is presented. It is shown that aliasing is avoided due to the non-regular grid structure of a bundle. Different techniques are demonstrated to reduce the effect of crosstalk on the phase evaluation. Measurements of highly reflective technical surfaces with different geometrical properties are shown.

Keywords: crosstalk; fringe projection; heterodyne; image fibers; modeling

Funding source: Deutsche Forschungsgemeinschaft

Award Identifier / Grant number: SFB/TR 73

Funding statement: Funding: Deutsche Forschungsgemeinschaft, (Grant/Award Number: ‘SFB/TR 73’).

About the authors

Steffen Matthias

Steffen Matthias is a research associate at the Institute of Measurement and Automatic Control at Leibniz Universität Hannover.

Markus Kästner

Markus Kästner is the head of the department for production metrology at the Institute of Measurement and Automatic Control at Leibniz Universität Hannover.

Eduard Reithmeier

Eduard Reithmeier is the head of the Institute of Measurement and Automatic Control at Leibniz Universität Hannover.

Acknowledgment

The authors would like to thank the German Research Foundation (DFG) for funding the project B6 “Endoscopic geometry inspection” within the Collaborative Research Center (CRC)/TR 73. Thanks to Dominic Stangier from TU Dortmund for providing the coated specimens used for the measurements in this article.

References

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Received: 2016-9-7
Accepted: 2016-10-4
Published Online: 2016-11-9
Published in Print: 2016-12-1

©2016 THOSS Media & De Gruyter

Artikel in diesem Heft

  1. Cover and Frontmatter
  2. Community
  3. Conference Notes
  4. Conference Calendar
  5. News from the European Optical Society EOS
  6. Topical Issue: Optical 3D Sensing
  7. Review Articles
  8. High-speed optical 3D sensing and its applications
  9. Infrared deflectometry for the inspection of diffusely specular surfaces
  10. Multi-scale referencing and coordinate unification of optical sensors in multi-axis machines
  11. Research Articles
  12. 3D shape measurement with thermal pattern projection
  13. A new form measurement system based on subaperture stitching with a line-scanning interferometer
  14. Evaluation of pixel-wise geometric constraint-based phase-unwrapping method for low signal-to-noise-ratio (SNR) phase
  15. Single-shot phase-measuring deflectometry for cornea measurement
  16. Modeling of imaging fiber bundles and adapted signal processing for fringe projection
  17. Noncontact three-dimensional quantitative profiling of fast aspheric lenses by optical coherence tomography
  18. Tutorial
  19. Aspherics in spectacle lenses
  20. Research Article
  21. Structural noise tolerance of photonic crystal optical properties
https://doi.org/10.1515/aot-2016-0050
Schlagwörter für diesen Artikel
crosstalk; fringe projection; heterodyne; image fibers; modeling

Artikel in diesem Heft

  1. Cover and Frontmatter
  2. Community
  3. Conference Notes
  4. Conference Calendar
  5. News from the European Optical Society EOS
  6. Topical Issue: Optical 3D Sensing
  7. Review Articles
  8. High-speed optical 3D sensing and its applications
  9. Infrared deflectometry for the inspection of diffusely specular surfaces
  10. Multi-scale referencing and coordinate unification of optical sensors in multi-axis machines
  11. Research Articles
  12. 3D shape measurement with thermal pattern projection
  13. A new form measurement system based on subaperture stitching with a line-scanning interferometer
  14. Evaluation of pixel-wise geometric constraint-based phase-unwrapping method for low signal-to-noise-ratio (SNR) phase
  15. Single-shot phase-measuring deflectometry for cornea measurement
  16. Modeling of imaging fiber bundles and adapted signal processing for fringe projection
  17. Noncontact three-dimensional quantitative profiling of fast aspheric lenses by optical coherence tomography
  18. Tutorial
  19. Aspherics in spectacle lenses
  20. Research Article
  21. Structural noise tolerance of photonic crystal optical properties
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