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ECEN 5606  Colorado Study Resources
 Colorado
 Staff
 Digital Holography: Digital Hologram Recording, Numerical Reconstruction, and Related Techniques, Optical Scanning Holography with MATLAB®, Digital Holography and ThreeDimensional Display: Principles and Applications, The Fractional Fourier Transform: with Applications in Optics and Signal Processing, Photorefractive Nonlinear Optics

Lecture13
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
2/23/2012 1 2/23/2012 Spectral domain OCT Optical coherence tomography Optical signals Electronic signals Schematic of a generic fiberoptic OCT system 2 2/23/2012 3 2/23/2012 4 2/23/2012 5 2/23/2012 6 2/23/2012 7 2/23/2012 8 2/23/2012 Optical coherence t

Lecture12
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Thoery Computational Imaging Lab Point Spread Function Engineering for the Advanced Optics Lab Tony Barsic University of Colorado at Boulder Department of Electrical, Computer, and Energy Engineering Dr. Piestuns Research Group anthony.barsic@colorado.edu

Lecture11
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
ECEE 5606 Advanced Optics Lab Bragg holography and holographic polymers Outline Thin holography Holographic photopolymers Bragg holography Efficiency Selectivity Robert R. McLeod, University of Colorado 1 Bragg holography and materials Basics via th

Lecture10
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Photorefractive Eect 1. Photorefractive eect 2. Volume Holography 3. Kuktarev band transport equations 4. Twowave mixing 5. Anistropic Electrooptic eect 6. Photorefractive Grating Recording and Readout Bragg matching a red probe beam 7. Photorefractive

Lecture8
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Acoustooptic modulators and deectors Historical overview of Acoustooptic devices 1922  Brillouin predicted the light diraction by an acoustic wav e 1932  Debye and Sears, Lucas and Biquard carried out rst AO expe riments 1937  Raman and Nath analy

Lecture7
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Crystal optics lecture ECE 5606 Adv. Optics Lab Outline Classes of polarizing devices Polarization states Eigenpolarization of crystals Momentum matching at boundaries Polarization calculations Mueller matrices Jones matrices Anisotropic power walk

Lecture6
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Consider an elliptically polarized wave Polarization Ellipse Right handed clockwise looking towards source. Follows left handed thread. (seems backwards: opposite from RF convention) Transverse EM plane wave in free space Ex(z, t) = E0x cos(t kz + x) = 1

Lecture5
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Consider an elliptically polarized wave Right handed clockwise looking towards source. Follows left handed thread. (seems backwards: opposite from RF convention) y Ex = a1 cos t Ey = a2 cos(t + ) 2a2 phase dierence a x (a1,a2cos) 2a1 tan 2 = tan 2 cos

Lecture4
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Spectroscopy Frequency and Wavelength Wavelength [nm=10A] and Frequency [Hz,THz,PHz] c c = c = = When refracting into a medium, the frequency is constant, but the wavelength and velocity decrease by n 1. Dispersing Prism Low resolution Prism spectrosco

Lecture3
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
Interferometers and Interferometry Plane Waves direction cosines of a plane wave Plane wave interference. n i 2 (x+y +z ) E (x, y, z ) = E0pe Spherical wave interference 2 + 2 + 2 = 1 Division of Wavefront Interferometers 2slit interference, Lloyds m

Lecture14
School: Colorado
Course: Advanced Optics Lab Organizational Meeting
2/27/2012 Wave phenomena  Diffraction Adaptive Optics Lab AOL 2012 Adaptive Optics refers to optical systems which adapt to compensate for optical effects introduced by the medium between the object and its image. Diffraction Resolution Limit Modulation