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Realistic Rendering of Atmospheric Phenomena
Sabela, Ondřej ; Karas, Matej (referee) ; Vlnas, Michal (advisor)
The aim of this thesis is to develop a GPU accelerated computer program which is able to simulate light scattering in the Earth's atmosphere and clouds using the simplest possible combination of various realistic rendering techniques. A detailed explanation of the physical and phenomenological background of the basic characteristics of both solid and translucent materials is included. Physically based rendering methods which are able to simulate such phenomena are presented along with several optimizations, including precomputation and lookup tables, with a focus on functional fidelity to real-world principles. The presented solution is based on data from real-world microphysical measurements. The resulting outdoor scene images can be used as background environment maps in 3D modelling and design software. The open source code can also serve as a starting point for describing the implementation of the presented rendering techniques.
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Procedurally Generated Landscape in Fragment Shader
Leitner, Denis ; Milet, Tomáš (referee) ; Chlubna, Tomáš (advisor)
This thesis deals with rendering of procedurally generated landscape without the use of input geometry or textures. It describes techniques for generation and realistic rendering of natural outdoor scenes. These techniques include terrain generation and realistic atmosphere and cloud rendering. Thesis also describes the use of raymarching for terrain and shadow rendering and realistic lighting for terrain which includes ambient and indirect light approximation.
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Measurement of the local phase of metasurfaces using digital holographic microscopy
Weiss, Vlastimil ; Bouchal, Petr (referee) ; Dvořák, Petr (advisor)
This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.
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Optoelectronic sensor of polarization state of light from biological samples
Mikláš, Jan ; Brüstlová, Jitka (referee) ; Tománek, Pavel (advisor)
The living body tissues consist of cells which dimensions are bigger than a wavelength of visible light. Therefore a Mie scattering of reflected of backscaterred light occurs and different polarization states arise. The changes of polarization state due to the multiple scattering of light in the biological cellular tissues allow measure the aging of biological tissue. The reflected or backscattered polarized laser light exhibits multiple scattering on the sample surface and in its subsurface area.
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Procedurally Generated Landscape in Fragment Shader
Leitner, Denis ; Milet, Tomáš (referee) ; Chlubna, Tomáš (advisor)
This thesis deals with rendering of procedurally generated landscape without the use of input geometry or textures. It describes techniques for generation and realistic rendering of natural outdoor scenes. These techniques include terrain generation and realistic atmosphere and cloud rendering. Thesis also describes the use of raymarching for terrain and shadow rendering and realistic lighting for terrain which includes ambient and indirect light approximation.
|
|
|
Realistic Rendering of Atmospheric Phenomena
Sabela, Ondřej ; Karas, Matej (referee) ; Vlnas, Michal (advisor)
The aim of this thesis is to develop a GPU accelerated computer program which is able to simulate light scattering in the Earth's atmosphere and clouds using the simplest possible combination of various realistic rendering techniques. A detailed explanation of the physical and phenomenological background of the basic characteristics of both solid and translucent materials is included. Physically based rendering methods which are able to simulate such phenomena are presented along with several optimizations, including precomputation and lookup tables, with a focus on functional fidelity to real-world principles. The presented solution is based on data from real-world microphysical measurements. The resulting outdoor scene images can be used as background environment maps in 3D modelling and design software. The open source code can also serve as a starting point for describing the implementation of the presented rendering techniques.
|
|
|
Measurement of the local phase of metasurfaces using digital holographic microscopy
Weiss, Vlastimil ; Bouchal, Petr (referee) ; Dvořák, Petr (advisor)
This bachelor's thesis consists of research studies of optical metasurfaces that are capable of modifying and governing incident radiation via the shift of a local phase. It also discusses experimental microscopic techniques with the ability to measure the distribution of the said phase. Experimental results of the phase distribution of the electromagnetic wave impinging on metal metasurface presented in this thesis are captured through quantitative in-line and off-axis digital holographic microscopy. These metasurfaces utilize both geometrical phase and localised surface plasmon resonance (LSPR). Measured results are in accordance with previous scientific studies. Finally, the successful outcome in the form of measurement of the geometrical phase introduced by the single building block is presented as well as the application of an analytical model for characterization of phase response generated by interaction with optical metasurfaces.
|
|
|
Optoelectronic sensor of polarization state of light from biological samples
Mikláš, Jan ; Brüstlová, Jitka (referee) ; Tománek, Pavel (advisor)
The living body tissues consist of cells which dimensions are bigger than a wavelength of visible light. Therefore a Mie scattering of reflected of backscaterred light occurs and different polarization states arise. The changes of polarization state due to the multiple scattering of light in the biological cellular tissues allow measure the aging of biological tissue. The reflected or backscattered polarized laser light exhibits multiple scattering on the sample surface and in its subsurface area.
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