Presentation is loading. Please wait.

Presentation is loading. Please wait.

Frequency Domain Optical Coherence Tomography (FDOCT) Joon S Kim IMSURE Summer Research Fellow At Beckman Laser Institute University of California at Irvine.

Published byShawn Carr Modified over 9 years ago

Similar presentations

Presentation on theme: "Frequency Domain Optical Coherence Tomography (FDOCT) Joon S Kim IMSURE Summer Research Fellow At Beckman Laser Institute University of California at Irvine."— Presentation transcript:

1 Frequency Domain Optical Coherence Tomography (FDOCT) Joon S Kim IMSURE Summer Research Fellow At Beckman Laser Institute University of California at Irvine Irvine, CA 92612 Email: jkim627@mail.umd.edujkim627@mail.umd.edu

2 OCT Optical Coherence Tomography –New field of imaging technology that can complement conventional imaging techniques –Based on interference of EM wave –Provide high spatial resolution cross-sectional view of tissues without excision –Endless potential biomedical applications Non-invasive Diagnostics

3 OCT vs. Conventional Imag. Tech 1 mm1 cm10 cm Penetration depth (log) 1  m 10  m 100  m 1 mm Resolution (log) OCT Confocal microscopy Ultrasound Standard clinical High frequency

4 Two kinds of OCT TDOCT –Time Domain OCT –Use of Scanning Mirror FDOCT –Fourier (Frequency) Domain OCT –Use of laser source over band of optical frequency –Advantages over TDOCT

5 My research experience with FDOCT are in 2 phases… First phase: –Understanding and Replicating FDOCT experimental setting from scratch Second phase: –Learning the physical and mathematical reasoning behind the magical DSP algorithm which extract images out of OCT data!

6 Part 1 FDOCT experiment set up Swept source Phase Modulator Sample Probe Detector1 Detector2 2 x 2 Coupler Grating Mirror Collimator Attenuator Fiber Fabry-Perot interferometer

7 Current FDOCT System No human intervention required Everything controlled from execution module in host computer Host computer –houses NI-6112: A2D Conversion of OCT data –performs digital signal processing –controls peripherals

8 Scanning sample Surface of sample is divided into imaginary grid. Each block in grid: Pixel Scanning in X direction –Lateral scan Scanning in Z direction –A scan Z X Y

9 Scanning sample (cont.) 1600 samples / A-scan (pixel) 400 A-scan / Lateral scan Lateral scanning Frequency: 2 KHz A-scanning Frequency: 10 MHz –Limited by A2D converter (NI-6112) Pixel size: 10 micron Slow process => not applicable in Vivo

10 With NI-5122 Max. Sampling Frequency: 100 MS/sec A-scanning Frequency: 100 MHz –More time for DSP –Boost lateral scanning frequency to 20 KHz –One step closer to in Vivo application of FDOCT

Download ppt "Frequency Domain Optical Coherence Tomography (FDOCT) Joon S Kim IMSURE Summer Research Fellow At Beckman Laser Institute University of California at Irvine."

Similar presentations

An Alternative Method of Extending Imaging Window of Fourier Domain – Optical Coherence Tomography by Using a Complex Conjugate Removal Technique Amine.

An Alternative Method of Extending Imaging Window of Fourier Domain – Optical Coherence Tomography by Using a Complex Conjugate Removal Technique Amine.
Optical Coherence Tomography

Optical Coherence Tomography
 Mid-Infrared Optical Coherence Tomography System using a Room Temperature Quantum Cascade Superluminescent Emitter Ahmed Musse, Deborah Varnell, Mei.

 Mid-Infrared Optical Coherence Tomography System using a Room Temperature Quantum Cascade Superluminescent Emitter Ahmed Musse, Deborah Varnell, Mei.
POSTER TEMPLATE BY: www.PosterPresentations.com Image Processing in Spectral Domain Optical Coherence Tomography (SD-OCT) Vasilios Morikis 1,2, Dan DeLahunta.

POSTER TEMPLATE BY: Image Processing in Spectral Domain Optical Coherence Tomography (SD-OCT) Vasilios Morikis 1,2, Dan DeLahunta.
Apertureless Scanning Near-field Optical Microscopy: a comparison between homodyne and heterodyne approaches Journal Club Presentation – March 26 th, 2007.

Apertureless Scanning Near-field Optical Microscopy: a comparison between homodyne and heterodyne approaches Journal Club Presentation – March 26 th, 2007.
Optical Coherence Tomography Zhongping Chen, Ph.D. Optical imaging in turbid media Coherence and interferometry Optical coherence.

Optical Coherence Tomography Zhongping Chen, Ph.D. Optical imaging in turbid media Coherence and interferometry Optical coherence.
1 Swept Source Frequency Domain Optical Coherence Tomography Swept Source Frequency Domain Optical Coherence Tomography Anurag Gupta University of Rochester,

1 Swept Source Frequency Domain Optical Coherence Tomography Swept Source Frequency Domain Optical Coherence Tomography Anurag Gupta University of Rochester,
Air Force Portable Device for Retinal Imaging Abdelhamid Jnane Mentors: Zhongping Chen Qiang Qiang Wang University of California, Irvine Beckman Laser.

Air Force Portable Device for Retinal Imaging Abdelhamid Jnane Mentors: Zhongping Chen Qiang Qiang Wang University of California, Irvine Beckman Laser.
Introduction to Medical Imaging

Introduction to Medical Imaging
Algorithm Optimization for Swept Source Fourier Domain Optical Coherence Tomography (OCT) with Galvo Scanner and Digital Signal Processor (DSP) Kevin Seekell.

Algorithm Optimization for Swept Source Fourier Domain Optical Coherence Tomography (OCT) with Galvo Scanner and Digital Signal Processor (DSP) Kevin Seekell.
What is OCT? Ultrahigh resolution optical coherence tomography (UHR OCT) is an upcoming new technology that allows non-invasive, optical medical diagnostic.

What is OCT? Ultrahigh resolution optical coherence tomography (UHR OCT) is an upcoming new technology that allows non-invasive, optical medical diagnostic.
Optical Coherence Tomography

Optical Coherence Tomography
Introduction to Biomedical Image Analysis BMI 705 Winter 2009 Kun Huang Department of Biomedical Informatics Ohio State University.

Introduction to Biomedical Image Analysis BMI 705 Winter 2009 Kun Huang Department of Biomedical Informatics Ohio State University.
Advanced Biomedical Imaging Dr. Azza Helal A. Prof. of Medical Physics Faculty of Medicine Alexandria University.

Advanced Biomedical Imaging Dr. Azza Helal A. Prof. of Medical Physics Faculty of Medicine Alexandria University.
1 Opto-Acoustic Imaging 台大電機系李百祺. 2 Conventional Ultrasonic Imaging Spatial resolution is mainly determined by frequency. Fabrication of high frequency.

1 Opto-Acoustic Imaging 台大電機系李百祺. 2 Conventional Ultrasonic Imaging Spatial resolution is mainly determined by frequency. Fabrication of high frequency.
Computed Tomography Physics, Instrumentation, and Imaging

Computed Tomography Physics, Instrumentation, and Imaging
MIT 2.71/2.710 Optics 12/06/04 wk14-a- 1 Holography Preamble: modulation and demodulation The principle of wavefront reconstruction The Leith-Upatnieks.

MIT 2.71/2.710 Optics 12/06/04 wk14-a- 1 Holography Preamble: modulation and demodulation The principle of wavefront reconstruction The Leith-Upatnieks.
Digital Communications

Digital Communications
Vasilios Aris Morikis Dan DeLahunta Dr. Hyle Park, Ph.D.

Vasilios Aris Morikis Dan DeLahunta Dr. Hyle Park, Ph.D.
Multi Frequency Laser Driver for Near Infrared Optical Spectroscopy in Biomedical Application Chenpeng Mu Department of Electrical and Computer Engineering,

Multi Frequency Laser Driver for Near Infrared Optical Spectroscopy in Biomedical Application Chenpeng Mu Department of Electrical and Computer Engineering,

Similar presentations

Ads by Google