55 | Imagerie optique | Physical engineering and embedded systems | S9 | ||||||
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Lessons : 14 h | TD : 0 h | TP : 0 h | Project : 0 h | Total : 14 h | |||||
Co-ordinator : Mathieu Laroche |
Prerequisite | |
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Geometric Optics, Coherent Optics, Optoelectronics | |
Course Objectives | |
Understand the fundamental principles of optical imaging systems and their limitations. Learn the operating principle of some conventional and advanced imaging systems. |
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Syllabus | |
Modeling of a scene: lighting, luminance, diffusion, disturbances. Image formation: approximate stigmatism, geometric and chromatic aberrations, matrix optics, resolution, modulation transfer function, depth of field. Conventional imaging techniques: microscope, imaging sensors, colorimetry. Advanced imaging techniques: adaptive optics, laser scanning microscopy. |
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Practical work (TD or TP) | |
Approximate stigmatism applied to spherical systems. Matrix optics applied to centered spherical systems. Color systems : RGB, XYZ, HSL. |
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Acquired skills | |
Understanding of an imaging system: from scene to digital image. Techniques for characterizing and correcting geometric and chromatic aberrations. Principles and operation of modern imaging systems. |
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Bibliography | |
Optique : Fondements et applications, J.P. Pérez, Masson. Modern optics, R. Guenther John, Wiley & Sons. |
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