Digitalna Holografija i Primjene

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Digitalna Holografija i Primjene Hrvoje Skenderović Institut za fiziku 5. PIF Radionica, IRB, 16.12.2014.

Holography Dennis Gabor invented holography in 1948 as a method for recording and reconstructing amplitude and phase of a wave field, (Nobel Prize, 1971.). He created the word holography from the Greek words 'holos' meaning whole or entire and 'graphein meaning to write. A holographically stored image or hologram is the photographically or otherwise recorded interference pattern between a wave field scattered from the object and a coherent background named reference wave. It is usually recorded on a flat surface, but contains the information about the entire three-dimensional wave field. This information is coded in form of interference stripes, usually not visible for the human eye due to the high spatial frequencies. The object wave can be reconstructed by illuminating the hologram with the reference wave again. An observer recognizes a three-dimensional image with all effects of perspective and depth of focus University Lund, Sweeden

Basic Principles Holographic Interferometry Digital Holography

Holographic recording of a point source object: I x, y = Ψ r + Ψ o 2 = a exp ik 0 z 0 + exp ik 0 z 0 ik 0 2πz 0 exp ik 0 2πz 0 (x + y) 2 2 = = a 2 + ik 0 2πz 0 2 + a ik 0 2πz 0 exp ik 0 2πz 0 (x + y) 2 + a ik 0 2πz 0 exp ik 0 2πz 0 (x + y) 2

To reconstruct the original light field from the hologram, I(x, y), we can simply illuminate the hologram with plane wave. Three light fields emerge from hologram: I. Plane wave which propagates without diffraction. Zeroth-order beam II. Real point source at z=z 0 (pseudoscopic) ik 0 ik 0 2πz 0 2πz exp ik 0 (x + y)2 2π(z 0 z) III. Virtual point source at z=-z 0 (orthoscopic) ik 0 ik 0 2πz 0 2πz exp ik 0 (x + y)2 2π(z 0 +z)

Application of holography in: 1. microscopy 2. 3D imaging 3. metrology 4. display technology 5. material processing 6. data storage 7. information processing

Holographic Interferometry Holographic Interferometry is a method to measure optical path length variations, which are caused by deformations of opaque bodies or refractive index variations in transparent media, e.g. fluids or gases. It is a non-contact, non-destructive method with very high sensitivity. Optical path changes up to one hundredth of a wavelength are resolvable. Recording Reconstruction Path length variations: 1. Static 2. Dynamic 3. Periodic

Digital holography In digital holography, the recording schemes are the same, but the recording material is replaced by an electronic device, such as a charge-coupled device (CCD). Optical interference fringes acquired by the CCD are digitized into a two-dimensional digital signal and then processed using digital image processing to reconstruct the object.

Problems: Spatial frequency : ν 1 2Δx Angle: θ MAX = sin 1 λν 2 Materials: Agfa 8E75 5000 lin/mm Thermoplastic film 1000 lin/mm CCD pixel 5 um θ MAX = 180 o θ MAX = 40 o θ MAX = 8 o, loss in 3D efficency Advantages: Fast data acquisition Direct data manipulation

Easy data manipulation - Subtraction digital holography Large zeroth-order noise [Demoli N, Mestrovic J, Sovic I (2003) Subtraction digital holography. Appl Opt 42(5):798-804]

Easy data manipulation - Subtraction digital holography Subtraction Large zeroth-order noise [Demoli N, Mestrovic J, Sovic I (2003) Subtraction digital holography. Appl Opt 42(5):798-804]

Static load on microscope, Schreiber

Static load on a machine, Abramson

Time Averaged Digital Holography vibrating membrane [Demoli N (2006) Real-time monitoring of vibrating fringe patterns... Opt Express 14(6): 2117-21223]

Subtraction digital holography with time averaging

Subtraction digital holography with time averaging

Dynamic change of object moving fringes

Dynamic change of object moving fringes

K=1 K=4 K=10 K=100

Holographic Microscopy (a) Scanning electron microscope image of the nanostructured template. (b) Image taken by a conventional optical microscope with NA 0.75, 100 objective. (c),(d) Reconstructed synthesized (c) amplitude and (d) phase of the object [W. Osten et al, Applied Optics, 2014]

Outlook: 1. Holographic microscope 2. Direct laser writing of computer generated holograms 3. Thanks to: Dr. Demoli Dr. Stipčević

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