Literature DB >> 19424297

Numerical dispersion compensation for Partial Coherence Interferometry and Optical Coherence Tomography.

A Fercher, C Hitzenberger, M Sticker, R Zawadzki, B Karamata, T Lasser.   

Abstract

Dispersive samples introduce a wavelength dependent phase distortion to the probe beam. This leads to a noticeable loss of depth resolution in high resolution OCT using broadband light sources. The standard technique to avoid this consequence is to balance the dispersion of the sample byarrangingadispersive materialinthereference arm. However, the impact of dispersion is depth dependent. A corresponding depth dependent dispersion balancing technique is diffcult to implement. Here we present a numerical dispersion compensation technique for Partial Coherence Interferometry (PCI) and Optical Coherence Tomography (OCT) based on numerical correlation of the depth scan signal with a depth variant kernel. It can be used a posteriori and provides depth dependent dispersion compensation. Examples of dispersion compensated depth scan signals obtained from microscope cover glasses are presented.

Year:  2001        PMID: 19424297     DOI: 10.1364/oe.9.000610

Source DB:  PubMed          Journal:  Opt Express        ISSN: 1094-4087            Impact factor:   3.894


  16 in total

1.  Design and validation of an angle-resolved low-coherence interferometry fiber probe for in vivo clinical measurements of depth-resolved nuclear morphology.

Authors:  Yizheng Zhu; Neil G Terry; John T Woosley; Nicholas J Shaheen; Adam Wax
Journal:  J Biomed Opt       Date:  2011 Jan-Feb       Impact factor: 3.170

2.  Co-localized confocal Raman spectroscopy and optical coherence tomography (CRS-OCT) for depth-resolved analyte detection in tissue.

Authors:  Jason R Maher; Oranat Chuchuen; Marcus H Henderson; Sanghoon Kim; Matthew T Rinehart; Angela D M Kashuba; Adam Wax; David F Katz
Journal:  Biomed Opt Express       Date:  2015-05-08       Impact factor: 3.732

3.  Fiber-based polarization-sensitive optical coherence tomography of a minimalistic system configuration.

Authors:  Sucbei Moon; Yusi Miao; Zhongping Chen
Journal:  Opt Lett       Date:  2019-06-15       Impact factor: 3.776

4.  Computational optical coherence tomography [Invited].

Authors:  Yuan-Zhi Liu; Fredrick A South; Yang Xu; P Scott Carney; Stephen A Boppart
Journal:  Biomed Opt Express       Date:  2017-02-16       Impact factor: 3.732

5.  Guide-star-based computational adaptive optics for broadband interferometric tomography.

Authors:  Steven G Adie; Nathan D Shemonski; Benedikt W Graf; Adeel Ahmad; P Scott Carney; Stephen A Boppart
Journal:  Appl Phys Lett       Date:  2012-11-29       Impact factor: 3.791

6.  Laser applications and system considerations in ocular imaging.

Authors:  Ann E Elsner; Matthew S Muller
Journal:  Laser Photon Rev       Date:  2008-10-01       Impact factor: 13.138

7.  Design of a Swept-Source, Anatomical OCT System for Pediatric Bronchoscopy.

Authors:  Kushal C Wijesundara; Nicusor V Iftimia; Amy L Oldenburg
Journal:  Proc SPIE Int Soc Opt Eng       Date:  2013-03-20

8.  Wide-field Ophthalmic Space-Division Multiplexing Optical Coherence Tomography.

Authors:  Jason Jerwick; Yongyang Huang; Zhao Dong; Adrienne Slaudades; Alexander J Brucker; Chao Zhou
Journal:  Photonics Res       Date:  2020-04       Impact factor: 7.080

9.  Automated assessment of the remineralization of artificial enamel lesions with polarization-sensitive optical coherence tomography.

Authors:  Robert C Lee; Hobin Kang; Cynthia L Darling; Daniel Fried
Journal:  Biomed Opt Express       Date:  2014-08-01       Impact factor: 3.732

10.  A handheld microscope integrating photoacoustic microscopy and optical coherence tomography.

Authors:  Wei Qin; Qian Chen; Lei Xi
Journal:  Biomed Opt Express       Date:  2018-04-16       Impact factor: 3.732
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