Course
PBO - Project-based optics
PDF Course Catalog Deutsche Version: PBO
Version: 2 | Last Change: 13.10.2019 18:19 | Draft: 0 | Status: vom verantwortlichen Dozent freigegeben
| Long name | Project-based optics |
|---|---|
| Approving CModule | PBO_BaET |
| Responsible |
Prof. Dr. Michael Gartz
Professor Fakultät IME |
| Level | Bachelor |
| Semester in the year | summer semester |
| Duration | Semester |
| Hours in self-study | 78 |
| ECTS | 5 |
| Professors |
Prof. Dr. Michael Gartz
Professor Fakultät IME |
| Requirements | Geometric optics Optical metrology wave optics Mathematics 1/2 Physics 1/2 elementary geometry |
| Language | German |
| Separate final exam | Yes |
Literature
Pedrotti, Pedrotti, Bausch, Schmidt: Optik für Ingenieure. Grundlagen (Springer)
Hecht: Optik (Oldenbourg)
Bergmann, Schaefer, Bd.3, Optik, de Gruyter
Daniel Malacara, Optical Shop Testing, John Wiley and Sons
Max Born und Emil Wolf, Principles of Optics, Cambridge University Press
Hecht: Optik (Oldenbourg)
Bergmann, Schaefer, Bd.3, Optik, de Gruyter
Daniel Malacara, Optical Shop Testing, John Wiley and Sons
Max Born und Emil Wolf, Principles of Optics, Cambridge University Press
Final exam
Details
Oral examination in which the taxonomy levels of understanding, applying, analysing, synthesising and evaluating are tested by students presenting and explaining their projects carried out during the semester and showing that they can understand and apply the technical terms, theories and procedures developed in the lecture, have analysed the requirements of their project task and have synthesised a solution to their project task and can evaluate it in the examination interview.Minimum standard
50 % of the questions and tasks out of all parts of the examination correctly answeredExam Type
Oral examination in which the taxonomy levels of understanding, applying, analysing, synthesising and evaluating are tested by students presenting and explaining their projects carried out during the semester and showing that they can understand and apply the technical terms, theories and procedures developed in the lecture, have analysed the requirements of their project task and have synthesised a solution to their project task and can evaluate it in the examination interview.Learning goals
Knowledge
Matrix Sensors
CCD sensors
superstructure
mode of action
sensitivity
noise sources
CMOS sensors
superstructure
mode of action
sensitivity
noise sources
Image error corrections
dark current correction
flat field correction
interfaces
Analog / BAS
Firewire 1394
USB
Ethernet / GigE
Holographic interferometry
double exposure holography
basics
superstructure
evaluation
applications
time-average holography
basics
superstructure
evaluation
applications
laser light sectioning
basics
superstructure
evaluation
applications
Chromatic longitudinal aberrations
basics
superstructure
evaluation
applications
Chapters of students' choice
Laser Material Processing
basics
cold ablation
thermal processing
laser types
applications
Optical Shop Testing
Twyman Green Interferometer
Fizeau Interfermometer
Laser Doppler Anemometry
Interferometric speed measurement
heterodyne principle
applications
... (Students' suggestions)
CCD sensors
superstructure
mode of action
sensitivity
noise sources
CMOS sensors
superstructure
mode of action
sensitivity
noise sources
Image error corrections
dark current correction
flat field correction
interfaces
Analog / BAS
Firewire 1394
USB
Ethernet / GigE
Holographic interferometry
double exposure holography
basics
superstructure
evaluation
applications
time-average holography
basics
superstructure
evaluation
applications
laser light sectioning
basics
superstructure
evaluation
applications
Chromatic longitudinal aberrations
basics
superstructure
evaluation
applications
Chapters of students' choice
Laser Material Processing
basics
cold ablation
thermal processing
laser types
applications
Optical Shop Testing
Twyman Green Interferometer
Fizeau Interfermometer
Laser Doppler Anemometry
Interferometric speed measurement
heterodyne principle
applications
... (Students' suggestions)
Skills
calculate
the dynamics of a CCD sensor
of deformations in holographic interferometry
of oscillation amplitudes in holographic interferometry
the working range of the chromatic longitudinal aberration
sensor
the resolution of the light section sensor
define
the resolution of matrix sensors
the working range depending on a measuring task
determine
of the wavefront aberrations
of the sensitivity of a CDD sensor
assess
of the measuring signal of a light section sensor
of the usability of a matrix sensor for a specific measurement
task
the dynamics of a CCD sensor
of deformations in holographic interferometry
of oscillation amplitudes in holographic interferometry
the working range of the chromatic longitudinal aberration
sensor
the resolution of the light section sensor
define
the resolution of matrix sensors
the working range depending on a measuring task
determine
of the wavefront aberrations
of the sensitivity of a CDD sensor
assess
of the measuring signal of a light section sensor
of the usability of a matrix sensor for a specific measurement
task
Expenditure classroom teaching
| Type | Attendance (h/Wk.) |
|---|---|
| Lecture | 2 |
| Tutorial (voluntary) | 0 |
Special literature
keine/none
Special requirements
none
Accompanying material
Presentation slides for the lecture as pdf-files
Separate exam
none
Learning goals
Skills
Adjusting optical superstructures
Recording and documenting of measurement series
Create diagrams
Ergebnisse auf Plausibilität überprüfen
Recognizing and understanding of interrelationships
error calculation
analyse an optical measuring task
Independently recognized measuring task can be analyzed
Analyzing a given measuring task
design a solution approach for the analyzed optical measuring task
Consideration of laboratory resources
Consideration of the available time quota
Presentation of a project outline
Describe the task
outline the approach
Present results in a clearly structured way
Discuss results in technical and scientific manner
Milestone presentation to check the progress of the project
Describe the task
outline the approach
Present results in a clearly structured way
Discuss results in technical and scientific manner
Final presentation with presentation of the realized solution approach
Describe the task
outline the approach
Present results in a clearly structured way
Discuss results in technical and scientific manner
realize basic optical structures yourself
build
adjust
Carry out function test
investigate scientific/technical principles with an optical structure
Plan measurement series
Estimate error influences
Check the suitability of the superstructure
Evaluate self-acquired measurement series
Graphic display of measured values
Calculate implicit quantities from measured values math.
correctly
discover and name logical errors
Simulate measured values using predefined formulas
Work on complex technical tasks in a team
Organize into subtasks
Discuss measurement results
complement each other meaningfully
Recording and documenting of measurement series
Create diagrams
Ergebnisse auf Plausibilität überprüfen
Recognizing and understanding of interrelationships
error calculation
analyse an optical measuring task
Independently recognized measuring task can be analyzed
Analyzing a given measuring task
design a solution approach for the analyzed optical measuring task
Consideration of laboratory resources
Consideration of the available time quota
Presentation of a project outline
Describe the task
outline the approach
Present results in a clearly structured way
Discuss results in technical and scientific manner
Milestone presentation to check the progress of the project
Describe the task
outline the approach
Present results in a clearly structured way
Discuss results in technical and scientific manner
Final presentation with presentation of the realized solution approach
Describe the task
outline the approach
Present results in a clearly structured way
Discuss results in technical and scientific manner
realize basic optical structures yourself
build
adjust
Carry out function test
investigate scientific/technical principles with an optical structure
Plan measurement series
Estimate error influences
Check the suitability of the superstructure
Evaluate self-acquired measurement series
Graphic display of measured values
Calculate implicit quantities from measured values math.
correctly
discover and name logical errors
Simulate measured values using predefined formulas
Work on complex technical tasks in a team
Organize into subtasks
Discuss measurement results
complement each other meaningfully
Expenditure classroom teaching
| Type | Attendance (h/Wk.) |
|---|---|
| Project | 2 |
| Tutorial (voluntary) | 0 |
Special literature
keine/none
Special requirements
none
Accompanying material
oral discussions with project supervisor with individual given references
Separate exam
none
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