Optical Metrology R1a
Courses
Content
- Repetition of light wave and ray optical principles
- Repetition of diffraction phenomena and Fourier optics
- Microscopic imaging and image processing techniques
- Confocal microscopy, Interferometry, white-light interferometer, integrated interferometers, interference microscopes
- Fiber-Bragg-Grating sensors, repetition of optical fibers
- Optical sensors and applied devices in optical sensors (including: microoptics, adaptive optics, diffractive optical elements)
- Principles and application of optical in-process measurement
- Thin-film preparation and measurement techniques (ellipsometry, RHEED)
- Absorption, transmission, spectroscopy, gas-sensors
- Intra-Cavity-Absorption-Spectroscopy, mode competition
- Photoluminescence, Scanning Electron Microscope, Tunneling Electron Microscope
- Atomic Force Microscope (AFM), cantilever based sensors
- Scanning near-field optical sensors, Magneto Resistive Effects.
Learning outcomes
- Overview on measurement techniques and operating principles
- Principals of optical sensors, scope of applications
- Learning about modern concepts of precision metrology
- Getting practical experience in optical measurement set-ups
- Establishing synergies between engineering disciplines and natural sciences
- Finding access to theses in the innovative field of optical technologies
- Introduction to the 21st century as the “century of photonics and nano technology”
Details
- Lecturer: Peter Lehmann and team
- Teaching method: seminar
- SWS: 2
- Credit points: 3
- Examination: seminar attendance and presentation
- Course identifier: FB16-4204
Content
- Repetition of light wave and ray optical principles
- Repetition of diffraction phenomena and Fourier optics
- Microscopic imaging and image processing techniques
- Confocal microscopy, Interferometry, white-light interferometer, integrated interferometers, interference microscopes
- Fiber-Bragg-Grating sensors, repetition of optical fibers
- Optical sensors and applied devices in optical sensors (including: microoptics, adaptive optics, diffractive optical elements)
- Principles and application of optical in-process measurement
- Thin-film preparation and measurement techniques (ellipsometry, RHEED)
- Absorption, transmission, spectroscopy, gas-sensors
- Intra-Cavity-Absorption-Spectroscopy, mode competition
- Photoluminescence, Scanning Electron Microscope, Tunneling Electron Microscope
- Atomic Force Microscope (AFM), cantilever based sensors
- Scanning near-field optical sensors, Magneto Resistive Effects
Learning outcomes
- Overview on measurement techniques and operating principles
- Principals of optical sensors, scope of applications
- Learning about modern concepts of precision metrology
- Getting practical experience in optical measurement set-ups
- Establishing synergies between engineering disciplines and natural sciences
- Finding access to theses in the innovative field of optical technologies
- Introduction to the 21st century as the “century of photonics and nano technology”
Details
- Lecturer: Peter Lehmann and team
- Teaching method: lab training
- SWS: 2
- Credit points: 3
- Examination: lab training attendance and conductance of experiments
- Course identifier: FB16-4203