| Code |
17555
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| Year |
1
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| Semester |
S1
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| ECTS Credits |
6
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| Workload |
TP(60H)
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| Scientific area |
Physics
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Entry requirements |
N/A
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Learning outcomes |
The main objective of this course is to disseminate the principles of Computational Optics and its applications, as well as the basic concepts of physical and geometric optics that allow for its understanding. By the end of this course, the student should be able to understand the physical, mathematical, and computational fundamentals applied to the analysis and processing of different image modalities. The student should be able to create optical and optoelectronic assemblies, mainly based on digital holography, for the analysis of biological samples and the non-destructive analysis of surfaces. The student should also be able to use image processing techniques in the optical phase reconstruction of different types of samples.
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Syllabus |
THEORETICAL AND PRACTICAL
1 MATHEMATICAL FOUNDATIONS
1.1 - Fourier Analysis
1.2 - Principles of Image Analysis and Processing
1.3 - Stochastic Methods applied to Image Processing
1.4 - Image Compression Methods
2 OPTOMETRONIC EQUIPMENT
2.1 - Laboratory Safety Standards
2.2 - Optical Components and Optical Fibers
2.3 - LASERs, LEDs, and Detectors
2.4 - Data Acquisition Systems
3 TOPICS IN OPTICS
3.1 - Matrix Optics
3.2 - Radiometry
3.3 - Computational Fourier Optics: Diffraction and Numerical Methods of Light Propagation
3.4 - Polarization and Coherence
3.5 - Python/MATLAB Programming applied to Computational Optics
4 SYSTEMS OF Computational Optics
4.1 - Introduction to Digital Holography
4.2 - Methods for Reconstructing the Amplitude and Phase of the Optical Field
4.3 - Intensity Transport Equation
4.4 - Plenotic Function: Lightfield Cameras, Point Clouds
4.5 - Super-resolution Techniques
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Main Bibliography |
1. COMPUTATIONAL FOURIER OPTICS: A MATLAB tutorial, David Voeltz, 1ª Ed. SPIE Press, 2011
2. A LABORATORY MANUAL IN BIOPHOTONICS, Vadim Backman et al, CRC Press, 2018
3. TISSUE OPTICS, Valery Tuchin, 3rd Ed., SPIE Press, 2015
4. DIGITAL HOLOGRAPHIC MICROSCOPY: Principles, Techniques, and Applications, Myung K. Kim, Springer, 2011
5. Óptica e Fotónica, Mário Ferreira, Lidel edições técnicas Lda. (2003)
6. Introduction to Fourier optics. Goodman, J. W.. Roberts and Company publishers (2005).
Scientific articles related to the subject published in specialized scientific journals.
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Teaching Methodologies and Assessment Criteria |
The teaching/learning activities of this discipline comprise theoretical-practical classes with lectures interspersed with laboratory and computational practices. Students also learn the content related to the skills to be acquired through programmed online activities in the form of quizzes, using distance learning platforms such as Moodle. There will be a set of laboratory activities where the student will become familiar with some experimental techniques of Computational Optics with emphasis on the acquisition of holographic images and reconstruction of three-dimensional images.
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Language |
Portuguese. Tutorial support is available in English.
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