faculty degree program module coordinator

1 SHW = Semester Hours per Week

Faculty Optics and Mechatronics

Module Description

Degree Program Photonics (Master)

Module Coordinator

Prof. Dr. T. Hellmuth

Module Name

Fundamental Optics

Module No : 20001

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

6

150

90 h

60 h

Winter Semester Summer Semester

1

1 Semester 2 Semesters

Semesters

Degree Objective

Module Type (PM/WPM/WM)

Division (Upper/Lower)

Incorporated in Degree Programs

Master of Science

PM - Compulsory Module

Study Form

Lecture Tutorial Lab Self-Study Seminar

Assignment Projekt Work Other: Paper, Report

Prerequisites

Supporting Modules / Courses

Course No.

Title of the Module / Course

Lecturer Type SHW1

CP

Sem Module Exam Type/ Length/

Graded

20101

Fundamental Optics

Hellmuth

V P

2

2

1

PLM 20 benotet




PM - Compulsory


Course No.


Lecturer Type SHW1

CP


Graded

20111

Fundamentals of optical design

Hellmuth

V Ü

4

3

1

PLM 20 benotet




PM - Compulsory

Allowed Exam Materials

oral exam

Learning Goals / Competences

Ability to design and analyse simple optical systems; Ability to simulate and optimize optical systems with an optical design program (ZEMAX); Getting an overview of aberration theory. Understanding of the fundamentals of physical optics and optical engineering; realization of acquired knowledge in self-reliant project work; ability to work in small teams. Competence Area Heavy Medium Light

Technical Competence

Methods Competence

Social Competence

Course Contents Introduction to ZEMAX, ray optics, wave optics, image formation, aberrations and their corrections

Language

German English Spanish French

Chinese Portuguese Russian Other:

Literature

Fundamentals of optical design, script; Manual ZEMAX Kingslake "Lens design fundamentals", Smith "Modern lens design" Fundamental of Optics, script Hecht: "Optics" , Addison-Wesley. Pedrotti et. al., "Optik für Ingenieure"

Composition of Final Grade

PLM 100%

Comments / Other

Last Updated

September 2014, TH



Module Description


Module Coordinator


Module Name

Laser photonics

Module No : 20002

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

10

8

300h

120h

180h


1+2


Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded

20102

Lasers and quantum optics

Hellmuth

V L Ü

4

5

1

PLK 60 benotet




PM - Compulsory


Course No.


Lecturer Type SHW1

CP


Graded

20202

Nonlinear optics

Hellmuth

V Ü

4

5

2

PLK 60 benotet




PM - Compulsory


formulary, calculator


Understanding of fundamental properties of lasers and nonlinear optical phenomena. Ability to design and simulate laser systems. Understanding and ability to describe quantum phenomena and quantum optics mathematically. Specification of nonlinear crystals. Tolerance analysis of nonlinear optical components. Understanding and mathematical description of nonlinear phenomena. Ability to describe, explain and measure laser properties quantitatively. Self-reliant literature work. Realization of theoretical knowledge in practical laboratory work. Team work and ability to analyse and explain experimental results. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents

Teaching Contents Rate equations; spectral properties of lasers; simulation of laser resonators and solid state lasers; quantum statistics and quantum optics; coherence; Maxwell and wave equations; nonlinear optics of second and third order; crystal optics, tensors, squeezed states and other nonlinear quantum optical phenomena

Language



Literature

Lasers and quantum optics - Script Nonlinear Optics - Script Literature list in scripts


PLK (100%); laboratory work completed

Comments / Other

Last Updated

September 2014, TH



Module Description


Module Coordinator

Prof. Dr.J. Krapp

Module Name

Optical commuication engineering

Module No : 20003

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

10

5

300

150

150


1+2


Semesters

Degree Objective




Master of Science


HS - Hauptstudium

Photonics

Study Form



Prerequisites

no


Course No.


Lecturer Type SHW1

CP


Graded

20103

Optical fiber systems

Prof. Dr. J. Krapp

V

6

5

1

PLK 90 benotet




PM - Compulsory

HS - Hauptstudium

Photonics


Course No.


Lecturer Type SHW1

CP


Graded

20203

Optical communication networks

Prof. Dr. J. Krapp

V

4

5

2

PLK 90 benotet




PM - Compulsory

HS - Hauptstudium

Photonics


none


The student should - have a detailed knowledge in optical fiber systems, the structure and charateristics of corresponding components, - be able to determine fundamental data concerning signal power and noise by evaluation, - know how to set up basic measurements and their application - should get a fundamental knowledge of actual communication networks including structure functionality, and characteristics of corresponding components - should be capable to realize theoretical knowledge in laboratory work; - should perform experiments in a self-reliant way or within a small team. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents - Optical light sources - Fibers and their characteristics - Fiber coupling - Optical amplifiers (EDFAs) - Receiver concepts - Fundamentals in optical measurements - Fundamental network architectures and technologies, - Digital hierachies, - DWDM, - OMUX and ODMUX, - OADM, - OXC - Coherent Transmission


Language



Literature


examination and/or intermediate examiantions

Comments / Other

Last Updated

12.08.2014; J. Krapp



Module Description

Course of Study Photonics (Master)

Module Coordinator

Prof. Dr. P. Zipfl

Module Name

Analog signal processing

Modul No : 20004

CP

SHW1

Workload

Contact Time

Self-Study

Offering Begin

Sem

Duration

5

4

150

60

90


1


Semesters

Target Degree


Study Division

Use in Courses of Study

Master of Science


Form of Studies



Admission Requirement

Supporting Mini-Modules / Courses

Subjekt No.

Title of the Mini-Module / Course

Lecturer

Type

SHW1

CP

Sem

Modul Exam Type/ Length/

Marked

20104

Analog Signal Processing

Zipfl

V Ü S

3

4

1

PLM benotet

Mini- Module Type (PM/WPM/WM)

Study Division



Subjekt No.


Lecturer

Type

SHW1

CP

Sem

20204

Analog signal Processing (Laboratory)

Zipfl

V S Ü

1

1


Study Division




Allowed Aids Text Books, Calculator, any kind of communication is forbidden


The students are capable of analyzing as well as building electronic circuits or systems with emphasize on photonic applications (i.e. driver circuits for LED and Laser diodes, transimpedance and limiting amplifiers, specialized circuits for processing small signals. Basic integrated circuits can be improved using discrete semiconductors in order to fulfil the special need of phototonic applications. The students are able to perform noise analysis and optimize the noise behaviour. The students learn to realize theoretical knowledge in practical laboratory work, to cooperate within a team and to write laboratory reports. Competence Area Concentration Mini-Concentration In Small Amounts

Professional Competence

Methods Competence

Social Competence

Teaching Contents

Linear Systems in Laplace- and Time-domain. Linear and nonlinear photonic circuits for analog signal processing. Noise sources and transfer functions. Compensation on feedback circuits and electromagnetic interference. Simulation techniques using SPICE

Language



Literature

Zipfl: Script und several application notes (intranet), Graeme: Amplifiers for Photonic Application, Wilmshurst: Signal Recovery, Motchenbacher, Connelly: Low-Noise Electronic System Design.

Composition of the Final Mark

Oral Examination Duration: 20 minutes

Comments / Other

Last Updated

7th October, 2014



Module Description


Module Coordinator

Prof. Dr. R. Börret

Module Name

Optics technology

Modul No : 20005

CP

SHW1

Workload

Contact Time

Self-Study Offering Begin

Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Target Degree


Study Division


Master of Science


Form of Studies




Module 2001 (Fundmental Optics) or equivalent course


Subjekt No.


Lecturer Type SHW1

CP

Sem Modul Exam Type/ Length/

Marked

20205

Optics technology

Börret

V Ü

3

3

2

PLK 60


Study Division


PM - Compulsory

Subjekt No.


Lecturer Type SHW1

CP

Sem

20215

Optics technology (laboratory)

Börret

L

1

2

2


Study Division


PM - Compulsory


Allowed Aids manuscript, textbooks, pocket calculator

Learning Goals / Competences The students should - have a profound knowledge of optical technologies; - realize their possibilities and limits; understand typical applications. The students should be able - to apply optical technologies and measuring techniques by themselves; - to select appropriate optical technologies by themselves; - to realize theoretical knowledge in the laboratory; - to work in a self-reliant way as well as within a team.. Competence Area Concentration Mini-Concentration In Small Amounts


Methods Competence

Social Competence

Teaching Contents - specifications: From ISO 10 110 to power spectral density - errorbudget optics - selected processes for fabrication of aspheres and freeforms - new moulding processes for glass and plastics - coting design and coating technology - design, specificationss and fabrication of diffractive optical element - principles of mounting technology

Language



Literature

Manuscript and publications H.H. Kakarow, Fabrication Methods for Precision Optics Braunecker, Hentschel, Tiziani, Advanced Optics with Aspherics J.D. Rancourt, Optical Thin Films P.R. Yoder jr., Mounting Optics in Optical Instruments


30 % PLR,70 % PLK (60 min.)

Comments / Other

Last Updated

03.08.09 13.02.2013 Fritz



Module Description


Module Coordinator

Prof. Dr. Herbert Schneckenburger

Module Name

Biophotonics

Module No : 20006

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded

20206

Biophotonics

Schneckenburger

V V Ü

3

3

2

PLK 60 benotet




PM - Compulsory

Course No.


Lecturer Type SHW1

CP

Sem

20216

Biophotonics (Laboratory)s

Schneckenburger

L

1

2

2




PM - Compulsory



Manuscript, books, calculator

Learning Goals / Competences Getting acquainted with light initiated molecular and cellular mechanisms; learning photonic methods for detection and curing of diseases; getting acquainted with environmental impacts on cells and organisms; responsible handling of living systems and complex photonic instruments; self-reliant literature work; realization of theoretical knowledge in practical laboratory work; self-reliant elaboration and documentation of experimental scientific results; ability to work in a team in laboratory and project work. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents Molecular physics and biophysics, optical spectroscpy and microscopy, light propagation in tissue, interaction of laser radiation with cells and tissues, diagnostic and therapeutic applications.

Language



Literature

relevant publications and exercises


PLK (100%); prerequisite for module 20006: laboratory work completedH. Schneckenburger et al.: “Fluorescence technologies in biomedical diagnostics“, in: Handbook of Optical Biomedical Diagnostics (V.V. Tuchin, ed.), SPIE, Bellingham (USA), 2002, pp. 825-874 P.N. Prasad: Intrudiction to Biophotonics, Wiley, New Jersey, 2003

Comments / Other

Last Updated

Aug. 14, 2009, Schneckenburger



Module Description


Module Coordinator

Prof. Dr. J. Krapp

Module Name

Project

Module No : 20007

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

CP

SHW1

Workload

Contact Time


Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Degree Objective




Master of Science


HS - Hauptstudium

Photonics

Study Form



Prerequisites

no


Course No.


Lecturer Type SHW1

CP


Graded 20207

Project

Prof. Dr. J. Krapp

P

4

5

2

benotet


all


Learning Goals / Competences Conversion of fundamental knowledge to praxis; Sophisticated knowledge of special topics in the optical or/and electrical field; Increasing methodical competence; Self-reliant work within a small team; Self-reliant elaboration of new topics and preparation of a report; Verbalization of a complex context. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents Actual project and accompanying litterature from different fields of photonics.

Language



Literature

relevant publications


practical work, final report, presentation (15 minutes)

Comments / Other

Last Updated

27.01.2010; J. Krapp



Module Description


Module Coordinator Prof. Dr. Andreas Heinrich

Module Name

Photonic Detectors and Devices

Modul No : 20030

CP

SHW1

Workload

Contact Time

Self-Study

Offering Begin

Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Target Degree


Study Division


Master of Science

WPM - Compulsory Elective Module

Form of Studies




Basic knowledge in Optics & Math


Subjekt No.


Lecturer

Type

SHW1

CP

Sem


Marked

20130

photonic detectors and devices

Prof. Dr. Andreas Heinrich

V

4

5

1

PLK 90


Study Division



Subjekt No.


Lecturer

Type

SHW1

CP

Sem


Study Division



Allowed Aids none

Learning Goals / Competences students will learn functionallity and physics behind componets for optics and electrooptical components for optical Systems. Additionally they will be able to use this components / devices in practial life. Competence Area Concentration Mini-Concentration In Small Amounts


Methods Competence

Social Competence

Teaching Contents - optical components basic components (plane-prallel plates, Prisms, lenses, mirrors, beam-splitters) special copmponents (gradient-index lenses, diffusers, dynamic light modulators, Fresnel lenses, light pitpes, Axicons, beam displacer optics) optical filters (absorption filters, Fabry Perot filters, Interference filters, electrical tuneable filters, gratings) polarizing elements (polarisator, retarder, compensator, depolarizer, optical isolators) - electro-optical components light sources and illumination (LED, SMD, OLED, structured illumination, requirements for an adequat illumination) projectors (SLMs, LCOS, LCDs, GLVs, DMDs, DLPs) detectors (CCD, CMOS, polarization camera, neuronal network camera, plenoptical camera) displays (3D Displays and imaging: stereoscopic, autoscopic, holographic) MEMS/MOEMS

Language



Literature

Hand-out, detailed manuscript with exercises


written exam (100%)

Comments / Other

Last Updated

Sep, 30, 2014 Oct, 09, 2012



Module Description


Module Coordinator Prof. Dr. Rainer Börret

Module Name

Quality and project management

Module No : 20031

CP

SHW1

Workload

Contact Time

Self-Study

Begin

Sem

Duration

5

2

150h

60 h

90 h


1+2


Semesters

Degree Objective




Master of Science


HS - Hauptstudium

Photonics(Master)

Study Form



Prerequisites

none


Course No.


Lecturer

Type

SHW1

CP

Sem

Module Exam Type/ Length/

Graded

20131

Project management

Börret

S

2

3

1

PLP benotet





HS - Hauptstudium

Photonics (Master)

Course No.


Lecturer

Type

SHW1

CP

Sem

Module Exam Type/ Length/

Graded

20132

Quality management

Fiedler

V

2

2

2

PLP 60





HS - Hauptstudium

Photonics (Master)



Project management: script, literature, pocket calculator Quality management, additional PC


The students should get the competence, to apply the the methods of quality and project management in industry, to manage succesfully a project and to to lead a project team. For quality management, they should be able, to apply and to document the six sigma method according the product or process of interest.

Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents

Methods and application of quality and project management, e.g. - definition of quality; - conditions and basics for a functioning QM system - conditions and procedure for introducing QM systems - structure and content of advanced excellence approaches (Six Sigma, EFQM, TRIZ) - instruments and methods of quality; appropriate procedure and fields of application

Language



Literature

PMP project management, A study guide Handbuch Projektmanagement, J.Kuster, E.Huber, R.Lippmann, A.Schmid, E.Schneider, U.Witschi, R.Wüst; Springer ISBN-10 3-540-25040-9 Manuscript and exercises John Morgan: “Lean Six Sigma For Dummies”, ISBN-10: 1119953707 Juri Salamatov: “TRIZ: The right solution at the right time”,ISNB 90-804680-1-0


related to CPs, 40% Quality Management and 60% Project Management

Comments / Other

Last Updated

29.09.14; Fiedler, Börret



Module Description


Module Coordinator

N.N.

Module Name

Photonic intruments and systems

Module No : 20032

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

4

150h

60 h

90 h


1


Semesters

Degree Objective




Master of Science

WPM - Compulsory Elect

HS - Hauptstudium

Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded 20132

Photonics instruments and systems

N.N.

V

4

5

1

PLK 60 benotet


none


Learning Goals / Competences The students should - become acquainted with functional principles of essential optical instruments and photonic systems; - understand the criteria for technical realizations upon application - learn to acquire complex expertise in a self-reliant way.. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents Diffraction gratings; spectrometers; interferometers; scanners and scanning systems; confocal microscopy; optical coherence tomography; Speckle interferometry; laser Doppler velocimetry; colour and colour measurement; optical storage technology; optical networks; optical gyroscope; wavefront measurement.

Language



Literature

Monographien und Originalartikel B. E.A. Saleh, M.V. Teich: Fundamentals of Photonics


PLK (100%)

Comments / Other

Last Updated

23.04.2012, H. Schneckenburger



Module Description


Module Coordinator

Prof. Dr. J. Schneider

Module Name

image Processing

Modul No : 20033

CP

SHW1

Workload

Contact Time


Sem

Duration

5

4

150h

60 h

90 h


1


Semesters

Target Degree


Study Division


Form of Studies





Subjekt No.


Lecturer Type SHW1

CP


Marked

20133

Image Processing

Schneider

V Ü

3

3

1

PLK 60 benotet


Study Division


WPM - Compulso

Subjekt No.


Lecturer Type SHW1

CP

Sem

20233

Image processing (laboratory)

Schneider

L

1

2


Study Division


WPM - Compulso


Allowed Aids Calculator

Learning Goals / Competences Hardware structure of image processing systems, Image processing software for gradient operators, image enhancement, sharpening and smoothing, Image restoration and image transformations, Image segmentation and representation, Statistical image description, Application of theoretical knowledge in laboratory work, ability to work within a team. Competence Area Concentration Mini-Concentration In Small Amounts


Methods Competence

Social Competence

Teaching Contents Detailed knowledge of the hardware components of image processing systems, Evaluate and applicate various algorithms for image smoothing, image sharpening and for extracting the border of image objects, Segmentation of images and measuring objects, Evaluate image statistics.

Language



Literature

Gonzalez R./Woods R., Digital Image Processing, 2002, Prentice Hall, New Jersey. Lecture documents


PLK

Comments / Other

Last Updated

27. July 2009, J. Schneider



Module Description


Module Coordinator

Prof. Dr. A. Kettler

Module Name

Digital signal processing

Module No : 20034

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

4

150h

60 h

90 h


1


Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded

20134

Digital signal processing

Kettler

V

1

2

1

PLK 60 benotet




WPM - Compulso

Photonics

Subjekt No.


Lecturer Type SHW1

CP

Sem

20234

Digital signal processing (practical applications)

Kettler

L

3

3

1




WPM - Compulso

Photonics



Pocket calculator

Learning Goals / Competences The students should understand basic concepts, components and tools of digital signal processing (DSP). They should be able to apply this knowledge to analyze and process typical signals of photonic systems. Students should be able to - understand basic concepts of DSP - know typical DSP applications - select appropriate hardware components for DSP applications - select, modify and develop DSP algorithms - apply modern tools for design and simulation of DSP systems - acquire new solutions by themselves as well as within a team. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents Lecture - continuous and discrete systems - efects of quantisation and discretisation - convolution and correlation - DFT, FFT z-transformation - design methods for FIR and IIR filters Lab/ Seminar: - DSP applications - Matlab /Simulink for design and simulation

Language



Literature

Web-book The Scientists and Engineers Guide to Digital Signal Processing (Steven W. Smith), Script (PPT), Homework Exercises, Computer Exercises and Examples (Intranet)


PLK 60, written exam. (60 %) PLL, Lab (20 %) PLR, presentation (20%)

Comments / Other

Prerequisites: complex numbers, vectors and matrices basics of transformations (Fourier-, Laplace- z-transform) programming experience

Last Updated

July 30 2009; A. Kettler 13.02.2013 Fritz



Module Description


Module Coordinator

Dr. Bernd Dörband

Module Name

Interferometry and testing

Modul No : 20035

CP

SHW1

Workload

Contact Time


Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Target Degree


Study Division


Master of Science


Form of Studies




20001 Fundamental Optics


Subjekt No.


Lecturer Type SHW1

CP


Marked

20135

Interferometry

Dr. Bernd Dörband

V

4

5

2

PLK 60


Study Division


WPM - Compulso

Subjekt No.


Lecturer Type SHW1

CP

Sem


Study Division



Allowed Aids None

Learning Goals / Competences Students should understand - the basic concepts in interferometry and optical metrology - the application fields of optical measurement techniques - future developments and “state of the art” Students should be able to - choose and specify suitable interferometric setups for different applications - choose and specify suitable light sources, sensors and components for interferometric setups and applications - design an interferometric setup for different applications - choose and specify fringe analysis software and evaluation techniques - choose a suitable calibration technique to qualify an interferometer - Specify the range, resolution and accuracy of an interferometric setup Competence Area Concentration Mini-Concentration In Small Amounts


Methods Competence

Social Competence

Teaching Contents Lecture: - Basic principles of interference - Interferometers - Detection techniques and algorithms - Calibration techniques - Dynamic range of CCD sensors in interferometry - Accuracy and error sources - Testing the quality of optical materials - Testing the geometry of optical components

Language



Literature

- Hand-out, detailed manuscript with exercises - Dörband, Müller, Gross: "Handbook of Optical Systems, Vol. 5" - Hecht „Optics“ (Fundamentals) - Malacara „Optical Shop Testing“


written exam (100%)

Comments / Other

Last Updated

June 7, 2012 Dörband Oct, 09, 2012



Module Description


Module Coordinator


Module Name

Advanced optical design

Module No : 20036

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded

20136

Advanced design methods

Pretorius

V

2

2

2

2 PLK 90 benotet




WPM - Compulso

Course No.


Lecturer Type SHW1

CP

Sem

20236

Simulation of optical systems

Frasch

V

2

3

2




WPM - Compulso



Pocket calculator

Learning Goals / Competences Students shall learn - to develop optical systems under consideration of basic technological conditions from the beginnings up to data specification in a self-reliant way; - to calculate and realize optical systems with modern computer programs.. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents

Language



Literature

Manuscript and data sheets


PLK (100%)

Comments / Other

Last Updated

12.1.2012 TH



Module Description


Module Coordinator

N. N.

Module Name

Infrared systems

Module No : 20037

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded 20137

Infrared systems

N. N.

V

4

5

2

PLK 60 benotet


Manuscript, textbooks, pocket calculator


Learning Goals / Competences The students shall - learn the basics of radiometry; - understand the principles of radiation of black bodies (Stefan-Boltzmann, Wien, Planck); - realize the properties of atmospheric transmission; - become acquainted with the properties of infrared optical materials and systems; - understand examples of existing infrared optical systems Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents - Radiometric calculations and measurements; - Infrared physics and infrared optics; - Specific infrared optical systems

Language



Literature

Extensive list of references


PLK (100%)

Comments / Other

Last Updated

14.04.2014 Fz



Module Description


Module Coordinator

Prof. Dr. H. Riegel

Module Name

Laser Application Technology

Module No : 20038

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

5

4

150h

60h

90h


1+2


Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

none


Course No.


Lecturer Type SHW1

CP


Graded

20138

Laser-Application-Technology

Riegel

V L Ü

4

5

1

PLK 60 benotet




WM - Elective Mo


Course No.


Lecturer Type SHW1

CP


Graded





given formulary collection, calculator


The goal of the course is an understanding of "Laser Applications". The course is split into two parts. Part 1: Fundamentals of laser materials processing with the relevant physical phenomena. Part 2 gives an overview of the most common applications (cutting, welding, drilling) including the most important laser beam sources and the most important manufacturing and production technology. The relevant pyhsical properties of beam to material interactions are taught. Further laser applications like hardening, cleaning and generating are introduced. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents

Teaching Contents Beam propagation, Focus diameter, Beam propagation product, reflectivity of metalls, volume efficiency, process efficiency. Thermodynamics: thermal conductivity, thermal diffusivity, phase transformations, melting and vaporization. Joining, cutting and corresponding system technology. Surface treatment, drilling, forming and ablation.

Language



Literature

Laser Application Technology (Script) Tailored Light 2, Springer Verlag


PLK (100%)

Comments / Other

Last Updated

March 2013, HR



Module Description


Module Coordinator

Prof. Dr. H. Schneckenburger

Module Name

Master Thesis

Module No : 20040

CP

SHW1

Workload

Contact Time

Self-Study Begin

Sem

Duration

29

870h


1


3 Semesters

Degree Objective




Master of Science


Study Form



Prerequisites

50 credit points achieved; module 20007 (project) passed


Course No.


Lecturer Type SHW1

CP


Graded

9998

Introduction to Master Thesis

All Photonics Professors

P

9

PLR benotet




PM - Compulsory


Course No.


Lecturer Type SHW1

CP


Graded

9999

Master Thesis

All Photonics Professors

P

3

PLA benotet




PM - Compulsory


all


Self-reliant scientific work; orientation in a new scientific field; comprehension of complex technical literature; learning of special (advanced) experimental methods; ability to work in a research team; oral and written presentation of complex scientific projects and results. Competence Area Heavy Medium Light


Methods Competence

Social Competence

Course Contents Actual work from different fields of photonics

Language



Literature

Subject-specific books and publications


oral report (9998): 20%; Master thesis (9999): 80%

Comments / Other

Last Updated

31.07.2009; Schneckenburger



Module Description



Module Name

Optical Metrology Systems

Modul No : 20043

CP

SHW1

Workload

Contact Time


Sem

Duration

5

4

150h

60 h

90 h


1


Semesters

Target Degree


Study Division


Master of Science


Form of Studies






Subjekt No.


Lecturer Type SHW1

CP


Marked

20143

Optical Metrology Systems


V

4

5

1

PLK 90


Study Division


WPM - Compulso

Subjekt No.


Lecturer Type SHW1

CP

Sem


Study Division



Allowed Aids 2 personal A4 paper, non programmable calculator

Learning Goals / Competences students will learn to deal with optical systems, especially how to tolerate such systems and how system testing is performed. Additionally students will enrich their knowledge on optical metrology. Competence Area Concentration Mini-Concentration In Small Amounts


Methods Competence

Social Competence

Teaching Contents - basic in optical systems (rays in optical systems, pupils, Delano Diagram,…) - tolerancing of optical systems (decenter and tilt tolerances, tolerance costs, compensators and adjustments, tolerance distributions, practical tolerancing) - metrology systems using imaging (principle of image analysis, star and slit tests, test targets, visual inspection, distortion metrology) - System testing (basic parameters of optical systems, measurement of image quality (PSF, ESF, LSF), Measurement of the transfere function (MTF) - Model based metrology for optical metrology systems - Ways to overcome resolution problem in optical metrology systems

Language



Literature



written exam (100%)

Comments / Other

passing pre-test(s) is mandatory for admission to written exam

Last Updated

Jan, 22, 2014 Oct, 09, 2012



Module Description



Module Name

Introduction into Matlab/Simulink

Modul No : 20044

CP

SHW1

Workload

Contact Time

Self-Study

Offering Begin

Sem

Duration

5

4

150h

60 h

90 h


2


Semesters

Target Degree


Study Division


Master of Science


Form of Studies






Subjekt No.


Lecturer

Type

SHW1

CP

Sem


Marked

20144

introduction into matlab/simulink


V Ü

4

5

1

PLK 90


Study Division



Subjekt No.


Lecturer

Type

SHW1

CP

Sem


Study Division



Allowed Aids none

Learning Goals / Competences students will leanr how to use matlab for mathematical operations and simulations using Simulink Competence Area Concentration Mini-Concentration In Small Amounts


Methods Competence

Social Competence

Teaching Contents - variables in matlab - arthmetic operations - mathematical functions - grafic functions - I/O Operations - matrix multiplications - complex data structure - Matlab desktop - programming in Matlab - Matlab editor and debugger - Symbolic Math Toolbox - functionality of Simulink - solving mathematical functions using Simulink - Simulink and Matlab

Language



Literature



written exam (100%)

Comments / Other

Last Updated

Sep, 30, 2014 Oct, 09, 2012

faculty degree program module coordinator

Documents