Program description

Content

Microelectronics, or better named nanoelectronics, because the minimum structure size of state-of-the-art integrated electronic circuits are in the range of 20 nm and below, is the base of the products that significantly influence the daily life of people almost anywhere on earth. Examples are personal computers and smartphones. Both of them open up new possibilities of communication and give access to almost unlimited sources of information, especially when those devices are connected to the world wide web. Another example are medical diagnostic tools for computer tomography or nuclear resonance tomography or intelligent medical implants as all these systems are based on the high computational performance and high data communication efficiency provided by advanced nanoelectronics.

The fundament for microelectronics and microsystems is semiconductor physics and technology. Thus, the objective of the International Master Program “Microelectronics and Microsystems” is to give the students a profound knowledge on physical level about electronic effects in semiconductor materials, especially silicon, and on the functionality of electronic devices. Furthermore, the students are taught about process technology for fabrication of integrated circuits and microsystems. This will enable the students to understand in depth the function of advanced  electronic devices and fabrication processes. They will be able to comprehend in a critical way the problems accompanied with the transition to smaller minimum structure sizes. Thus, the students can conceive which possible solutions may exist or could be developed to overcome the problems of scaling-down the device minimum feature size. This will enable the students to understand the ongoing scaling-down of MOS transistors with its potential but also with its limitations. 

Besides the essential role of physical basics the precise knowledge of process dependent manufacturing procedures are of key importance for training of the students in the field of nanoelectronics and microsystems. This will help them to develop during their professional life the ability to generate innovative concepts and bring them to practical applications.

The International Master Program “Microelectronics and Microsystems” qualifies the students for scientific professional work in the fields of electrical engineering and information technology. This professional work may extend from the development, production and application to the quality control of complex systems with highly integrated circuits and microsystems components. Both fields are coming closer and closer together, as a fast rising number of complex applications requires the integration of nanoelectronics and microsystems to one combined system.

In particular, this program enables the students not only to design new complex systems for innovative applications, but also to make them usable for practical applications. This can be realized by teaching the students engineering methods both on a physical and theoretical level and on an application oriented level.

In addition to the foundational curriculum taught at TUHH, seminars on developing personal skills are integrated into the dual study programme, in the context of transfer between theory and practice. These seminars correspond to the modern professional requirements expected of an engineer, as well as promoting the link between the two places of learning.

The intensive dual courses at TUHH integrating practical experience consist of an academic-oriented and a practice-oriented element, which are completed at two places of learning. The academic-oriented element comprises study at TUHH. The practice-oriented element is coordinated with the study programme in terms of content and time, and consists of practical modules and phases spent in an affiliate company during periods when there are no lectures.


Career prospects

The graduates of the International Master Program “Microelectronics and Microsystems” can find a wide variety of professional options as they have well founded knowledge about technology, design and application of highly integrated systems based on nanoelectronics and microsystems.

Thus, one group of possible employers are large companies with international sites for the production of integrated circuits, but also small or medium-sized companies for microsystems. Many job opportunities also exist in the field of development and design of integrated circuits and of microsystems. Because of the fast decline in prices of high-performance computer system, even small companies can conduct tasks that require many computational efforts such as the design of integrated circuits that, then, are fabricated by specialized companies, so-called silicon foundries. This allows many small companies to participate in the market for integrated circuits, so that they can contribute to a good job market for engineers in nanoelectronics and microsystems.

In addition, students acquire basic professional and personal skills as part of the dual study programme that enable them to enter professional practice at an early stage and to go on to further study. Students also gain practical work experience through the integrated practical modules. Graduates of the dual course have broad foundational knowledge, fundamental skills for academic work and relevant personal competences.


Learning target

Knowledge

W1        The graduates understand the basic physical principles of microelectronic devices and functional block of microsystems. Furthermore, they have solid knowledge regarding fabrication technologies, so that they can explain them in detail.

W2        The graduates have gained solid knowledge in selected fields based on a broad theoretical and methodical fundament.

W3        The graduates possess in-depth knowledge of interdisciplinary relationships.

W4        The graduates have the required background knowledge in order to position their professional subjects by appropriate means in the scientific and social environment.

Skills

F1    The graduates are able to apply computational methods for quantitative analysis of design parameters and for development of innovative systems for microelectronics and microsystems.

F2    The graduates are able to solve complex problems and  tasks in a self-dependent manner by basic methodical approaches that may be, if necessary, beyond the standard patterns 

F3    The graduates are able to consider technological progress and scientific advancements by taking into account the technical, financial and ecological boundary conditions.

Social Skills

S1     The graduates are capable of working in interdisciplinary teams and organizing their tasks in a process oriented manner to become prepared for conducting research based professional work and for taking management responsibilities.

S2     The graduates are able to present their results in a written or oral form effectively targeting the audience, on international stage also.

Autonomy

A1     The graduates can pervade in an effectively and self-dependently organized way special areas of their professional fields using scientific methods.

A2     The graduates are able to present their knowledge by appropriate media techniques or to describe it by documents with reasonable lengths.

A3     The students are able to identify the need for additional information and to develop a strategy for self-dependent enhancement of their knowledge.


By continually switching places of learnings throughout the dual study programme, it is possible for theory and practice to be interlinked. Students reflect theoretically on their individual professional practical experience, and apply the results of their reflection to new forms of practice. They also test theoretical elements of the course in a practical setting, and use their findings as a stimulus for theoretical debate.


Program structure

The curriculum of the International Master Program „Microelectronics and Microsystems“ is structured as follows:

  • Core Qualification: 
  • Main subject: The students choose one main subject out of the following two options:

The students have to take for their main subjects moduls totaling 18 CPs (1. - 3. semester).

  • Master thesis with 30 CP (4. semester)

The sum of required credit points of this Master program is 150 CP.

The structural model of the dual study programme follows a module-differentiating approach. Given the practice-oriented element, the curriculum of the dual study programme is different compared to a standard Bachelor’s course. Five practical modules are completed at the dual students’ partner company as part of corresponding practical terms during lecture-free periods.

Core Qualification

Module M0523: Business & Management

Module Responsible Prof. Matthias Meyer
Admission Requirements None
Recommended Previous Knowledge None
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students are able to find their way around selected special areas of management within the scope of business management.
  • Students are able to explain basic theories, categories, and models in selected special areas of business management.
  • Students are able to interrelate technical and management knowledge.


Skills
  • Students are able to apply basic methods in selected areas of business management.
  • Students are able to explain and give reasons for decision proposals on practical issues in areas of business management.


Personal Competence
Social Competence
  • Students are able to communicate in small interdisciplinary groups and to jointly develop solutions for complex problems

Autonomy
  • Students are capable of acquiring necessary knowledge independently by means of research and preparation of material.


Workload in Hours Depends on choice of courses
Credit points 6
Courses
Information regarding lectures and courses can be found in the corresponding module handbook published separately.

Module M0676: Digital Communications

Courses
Title Typ Hrs/wk CP
Digital Communications (L0444) Lecture 2 3
Digital Communications (L0445) Recitation Section (large) 2 2
Laboratory Digital Communications (L0646) Practical Course 1 1
Module Responsible Prof. Gerhard Bauch
Admission Requirements None
Recommended Previous Knowledge
  • Mathematics 1-3
  • Signals and Systems
  • Fundamentals of Communications and Random Processes
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students are able to understand, compare and design modern digital information transmission schemes. They are familiar with the properties of linear and non-linear digital modulation methods. They can describe distortions caused by transmission channels and design and evaluate detectors including channel estimation and equalization. They know the principles of single carrier transmission and multi-carrier transmission as well as the fundamentals of basic multiple access schemes.

The students are familiar with the contents of lecture and tutorials. They can explain and apply them to new problems.

Skills The students are able to design and analyse a digital information transmission scheme including multiple access. They are able to choose a digital modulation scheme taking into account transmission rate, required bandwidth, error probability, and further signal properties. They can design an appropriate detector including channel estimation and equalization taking into account performance and complexity properties of suboptimum solutions. They are able to set parameters of a single carrier or multi carrier transmission scheme and trade the properties of both approaches against each other.
Personal Competence
Social Competence

The students can jointly solve specific problems.

Autonomy

The students are able to acquire relevant information from appropriate literature sources. They can control their level of knowledge during the lecture period by solving tutorial problems, software tools, clicker system.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Written elaboration
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Data Science: Specialisation II. Computer Science: Elective Compulsory
Data Science: Specialisation IV. Special Focus Area: Elective Compulsory
Electrical Engineering: Core Qualification: Compulsory
Computer Science in Engineering: Specialisation II. Engineering Science: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems: Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems, Focus Networks: Elective Compulsory
International Management and Engineering: Specialisation II. Information Technology: Elective Compulsory
International Management and Engineering: Specialisation II. Electrical Engineering: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Course L0444: Digital Communications
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Gerhard Bauch
Language EN
Cycle WiSe
Content
  • Repetition: Baseband Transmission
    • Pulse shaping: Non-return to zero (NRZ) rectangular pulses, raised-cosine pulses, square-root raised-cosine pulses
    • Power spectral density (psd) of baseband signals
    • Intersymbol interference (ISI)
    • First and second Nyquist criterion
    • AWGN channel
    • Matched filter
    • Matched-filter receiver and correlation receiver
    • Noise whitening matched filter
    • Discrete-time AWGN channel model
  • Representation of bandpass signals and systems in the equivalent baseband
    • Quadrature amplitude modulation (QAM)
    • Equivalent baseband signal and system
    • Analytical signal
    • Equivalent baseband random process, equivalent baseband white Gaussian noise process
    • Equivalent baseband AWGN channel
    • Equivalent baseband channel model with frequency-offset and phase noise
    • Equivalent baseband Rayleigh fading and Rice fading channel models
    • Equivalent baseband frequency-selective channel model
    • Discrete memoryless channels (DMC)
  • Bandpass transmission via carrier modulation
    • Amplitude modulation, frequency modulation, phase modulation
    • Linear digital modulation methods
      • On-off keying, M-ary amplitude shift keying (M-ASK), M-ary phase shift keying (M-PSK), M-ary quadrature amplitude modulation (M-QAM), offset-QPSK
      • Signal space representation of transmit signal constellations and signals
      • Energy of linear digital modulated signals, average energy per symbol
      • Power spectral density of linear digital modulated signals
      • Bandwidth efficiency
      • Correlation coefficient of elementary signals
      • Error probabilities of linear digital modulation methods
        • Error functions
        • Gray mapping and natural mapping
        • Bit error probabilities, symbol error probabilities, pairwise symbol error probabilities
        • Euclidean distance and Hamming distance
        • Exact and approximate computation of error probabilities
        • Performance comparison of modulation schemes in terms of per bit SNR vs. per symbol SNR
      • Hierarchical modulation, multilevel modulation
      • Effects of carrier phase offset and carrier frequency offset
      • Differential modulation
        • M-ary differential phase shift keying (M-PSK)
        • Coherent and non-coherent detection of DPSK
        • p/M-differential phase shift keying (p/M-DPSK)
        • Differential amplitude and phase shift keying (DAPSK)
    • Non-linear digital modulation methods
      • Frequency shift keying (FSK)
      • Modulation index
      • Minimum shift keying (MSK)
        • Offset-QPSK representation of MSK
        • MSK with differential precoding and rotation
        • Bit error probabilities of MSK
        • Gaussian minimum shift keying (GMSK)
        • Power spectral density of MSK and GMSK
      • Continuous phase modulation (CPM)
        • General description of CPM signals
        • Frequency pulses and phase pulses
      • Coherent and non-coherent detection of FSK
    • Performance comparison of linear and non-linear digital modulation methods
  • Frequency-selective channels, ISI channels
    • Intersymbol interference and frequency-selectivity
    • RMS delay spread
    • Narrowband and broadband channels
    • Equivalent baseband transmission model for frequency-selective channels
    • Receive filter design
  • Equalization
    • Symbol-spaced and fractionally-spaced equalizers
    • Inverse system
    • Non-recursive linear equalizers
      • Linear zero-forcing (ZF) equalizer
      • Linear minimum mean squared error (MMSE) equalizer
    • Non-linear equalization:
      • Decision feedback equalizer (DFE)
      • Tomlinson-Harashima precoding
    • Maximum a posteriori probability (MAP) and maximum likelihood equalizer, Viterbi algorithm
  • Single-carrier vs. multi-carrier transmission
  • Multi-carrier transmission
    • General multicarrier transmission
    • Orthogonal frequency division multiplex (OFDM)
      • OFDM implementation using the Fast Fourier Transform (FFT)
      • Cyclic guard interval
      • Power spectral density of OFDM
      • Peak-to-average power ratio (PAPR)
  • Multiple access
    • Principles of time division multiple access (TDMA), frequency division multiple access (FDMA), code division multiple access (CDMA), non-orthogonal multiple access (NOMA), hybrid multiple access
  • Spread spectrum communications
    • Direct sequence spread spectrum communications
    • Frequency hopping
    • Protection against eavesdropping
    • Protection against narrowband jammers
    • Short vs. long spreading codes
    • Direct sequence spread spectrum communications in frequency-selective channels
      • Rake receiver
    • Code division multiple access (CDMA)
      • Design criteria of spreading sequences, autocorrelation function and crosscorrelation function of spreading sequences
      • Intersymbol interference (ISI) and multiple access interference (MAI)
      • Pseudo noise (PN) sequences, maximum length sequences (m-sequences), Gold codes, Walsh-Hadamard codes, orthogonal variable spreading factor (OVSF) codes
      • Multicode transmission   
      • CDMA in uplink and downlink of a wireless communications system
      • Single-user detection vs. multi-user detection


Literature

K. Kammeyer: Nachrichtenübertragung, Teubner

P.A. Höher: Grundlagen der digitalen Informationsübertragung, Teubner.

J.G. Proakis, M. Salehi: Digital Communications. McGraw-Hill.

S. Haykin: Communication Systems. Wiley

R.G. Gallager: Principles of Digital Communication. Cambridge

A. Goldsmith: Wireless Communication. Cambridge.

D. Tse, P. Viswanath: Fundamentals of Wireless Communication. Cambridge.

Course L0445: Digital Communications
Typ Recitation Section (large)
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Gerhard Bauch
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course
Course L0646: Laboratory Digital Communications
Typ Practical Course
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Gerhard Bauch
Language DE/EN
Cycle WiSe
Content

- DSL transmission

- Random processes

- Digital data transmission

Literature

K. Kammeyer: Nachrichtenübertragung, Teubner

P.A. Höher: Grundlagen der digitalen Informationsübertragung, Teubner.

J.G. Proakis, M. Salehi: Digital Communications. McGraw-Hill.

S. Haykin: Communication Systems. Wiley

R.G. Gallager: Principles of Digital Communication. Cambridge

A. Goldsmith: Wireless Communication. Cambridge.

D. Tse, P. Viswanath: Fundamentals of Wireless Communication. Cambridge.

Module M1048: Integrated Circuit Design

Courses
Title Typ Hrs/wk CP
Integrated Circuit Design (L0691) Lecture 3 4
Integrated Circuit Design (L0998) Recitation Section (small) 1 2
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge

Basic knowledge of (solid-state) physics and mathematics.

Knowledge in fundamentals of electrical engineering and electrical networks.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students can explain basic concepts of electron transport in semiconductor devices (energy bands, generation/recombination, carrier concentrations, drift and diffusion current densities, semiconductor device equations).  
  • Students are able to explain functional principles of pn-diodes, MOS capacitors, and MOSFETs using energy band diagrams.
  • Students can present and discuss current-voltage relationships and small-signal equivalent circuits of these devices.
  • Students can explain the physics and current-voltage behavior transistors based on charged carrier flow.
  • Students are able to explain the basic concepts for static and dynamic logic gates for integrated circuits
  • Students can exemplify approaches for low power consumption on the device and circuit level
  • Students can describe the potential and limitations of analytical expression for device and circuit analysis.
  • Students can explain characterization techniques for MOS devices.


Skills
  • Students can qualitatively construct energy band diagrams of the devices for varying applied voltages.
  • Students are able to qualitatively determine electric field, carrier concentrations, and charge flow from energy band diagrams.
  • Students can understand scientific publications from the field of semiconductor devices.
  • Students can calculate the dimensions of MOS devices in dependence of the circuits properties
  • Students can design complex electronic circuits and anticipate possible problems.
  • Students know procedure for optimization regarding high performance and low power consumption


Personal Competence
Social Competence
  • Students can team up with other experts in the field to work out innovative solutions.
  • Students are able to work by their own or in small groups for solving problems and answer scientific questions.
  • Students have the ability to critically question the value of their contributions to working groups.


Autonomy
  • Students are able to assess their knowledge in a realistic manner.
  • Students are able to define their personal approaches to solve challenging problems


Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
International Management and Engineering: Specialisation II. Electrical Engineering: Elective Compulsory
Mechanical Engineering and Management: Specialisation Mechatronics: Elective Compulsory
Mechatronics: Specialisation System Design: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Course L0691: Integrated Circuit Design
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Prof. Matthias Kuhl
Language EN
Cycle WiSe
Content
  • Electron transport in semiconductors
  • Electronic operating principles of diodes, MOS capacitors, and MOS field-effect transistors
  • MOS transistor as four terminal device
  • Performace degradation due to short channel effects
  • Scaling-down of MOS technology
  • Digital logic circuits
  • Basic analog circuits
  • Operational amplifiers
  • Bipolar and BiCMOS circuits


Literature


  • Yuan Taur, Tak H. Ning:  Fundamentals of Modern VLSI Devices, Cambridge University Press 1998
  • R. Jacob Baker: CMOS, Circuit Design, Layout and Simulation,  IEEE Press, Wiley Interscience, 3rd Edition, 2010
  • Neil H.E. Weste and David Money Harris, Integrated Circuit Design, Pearson, 4th International Edition, 2013
  • John E. Ayers, Digital Integrated Circuits: Analysis and Design, CRC Press, 2009
  • Richard C. Jaeger and Travis N. Blalock: Microelectronic Circuit Design, Mc Graw-Hill, 4rd. Edition, 2010


Course L0998: Integrated Circuit Design
Typ Recitation Section (small)
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Prof. Matthias Kuhl
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M0746: Microsystem Engineering

Courses
Title Typ Hrs/wk CP
Microsystem Engineering (L0680) Lecture 2 4
Microsystem Engineering (L0682) Project-/problem-based Learning 2 2
Module Responsible Dr. Timo Lipka
Admission Requirements None
Recommended Previous Knowledge Basic courses in physics, mathematics and electric engineering
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students know about the most important technologies and materials of MEMS as well as their applications in sensors and actuators.

Skills

Students are able to analyze and describe the functional behaviour of MEMS components and to evaluate the potential of microsystems.

Personal Competence
Social Competence

Students are able to solve specific problems alone or in a group and to present the results accordingly.

Autonomy

Students are able to acquire particular knowledge using specialized literature and to integrate and associate this knowledge with other fields.

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement
Compulsory Bonus Form Description
No 10 % Presentation
Examination Written exam
Examination duration and scale 2h
Assignment for the Following Curricula Electrical Engineering: Core Qualification: Compulsory
International Management and Engineering: Specialisation II. Electrical Engineering: Elective Compulsory
International Management and Engineering: Specialisation II. Mechatronics: Elective Compulsory
Mechanical Engineering and Management: Specialisation Mechatronics: Elective Compulsory
Mechatronics: Specialisation System Design: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Bio- and Medical Technology: Elective Compulsory
Course L0680: Microsystem Engineering
Typ Lecture
Hrs/wk 2
CP 4
Workload in Hours Independent Study Time 92, Study Time in Lecture 28
Lecturer Dr. Timo Lipka
Language EN
Cycle WiSe
Content

Object and goal of MEMS

Scaling Rules

Lithography

Film deposition

Structuring and etching

Energy conversion and force generation

Electromagnetic Actuators

Reluctance motors

Piezoelectric actuators, bi-metal-actuator

Transducer principles

Signal detection and signal processing

Mechanical and physical sensors

Acceleration sensor, pressure sensor

Sensor arrays

System integration

Yield, test and reliability

Literature

M. Kasper: Mikrosystementwurf, Springer (2000)

M. Madou: Fundamentals of Microfabrication, CRC Press (1997)

Course L0682: Microsystem Engineering
Typ Project-/problem-based Learning
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Dr. Timo Lipka
Language EN
Cycle WiSe
Content

Examples of MEMS components

Layout consideration

Electric, thermal and mechanical behaviour

Design aspects

Literature

Wird in der Veranstaltung bekannt gegeben

Module M1137: Technical Elective Complementary Course for IMPMM - field ET (according to Subject Specific Regulations)

Courses
Title Typ Hrs/wk CP
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge Basic knowledge in electrical enginnering, physics, semiconductor devices and mathematics at Bachelor of Science level
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge As this modul can be chosen from the modul catalogue of the department E, the competence to be acquired is acccording to the chosen subject.
Skills

As this modul can be chosen from the modul catalogue of the department E, the skills to be acquired is acccording to the chosen subject.

Personal Competence
Social Competence
  • Students can team up with one or several partners who may have different professional backgrounds
  • Students are able to work by their own or in small groups for solving problems and answer scientific questions.
Autonomy


  • Students are able to assess their knowledge in a realistic manner.
  • The students are able to draw scenarios for estimation of the impact of advanced mobile electronics on the future lifestyle of the society.
Workload in Hours Depends on choice of courses
Credit points 6
Assignment for the Following Curricula Microelectronics and Microsystems: Core Qualification: Elective Compulsory

Module M0768: Microsystems Technology in Theory and Practice

Courses
Title Typ Hrs/wk CP
Microsystems Technology (L0724) Lecture 2 4
Microsystems Technology (L0725) Project-/problem-based Learning 2 2
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge

Basics in physics, chemistry, mechanics and semiconductor technology

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students are able

     to present and to explain current fabrication techniques for microstructures and especially methods for the fabrication of microsensors and microactuators, as well as the integration thereof in more complex systems

     to explain in details operation principles of microsensors and microactuators and

     to discuss the potential and limitation of microsystems in application.


Skills

Students are capable

     to analyze the feasibility of microsystems,

     to develop process flows for the fabrication of microstructures and

     to apply them.




Personal Competence
Social Competence


Students are able to plan and carry out experiments in groups, as well as present and represent the results in front of others. These social skills are practiced both during the preparation phase, in which the groups work out and present the theory, and during the follow-up phase, in which the groups prepare, document and present their practical experiences.


Autonomy

The independence of the students is demanded and promoted in that they have to transfer and apply what they have learned to ever new boundary conditions. This requirement is communicated at the beginning of the semester and consistently practiced until the exam. Students are encouraged to work independently by not being given a solution, but by learning to work out the solution step by step by asking specific questions. Students learn to ask questions independently when they are faced with a problem. They learn to independently break down problems into manageable sub-problems. 

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Subject theoretical and practical work Studierenden führen in Kleingruppen ein Laborpraktikum durch. Jede Gruppe präsentiert und diskutiert die Theorie sowie die Ergebniise ihrer Labortätigkeit. vor dem gesamten Kurs.
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Electrical Engineering: Specialisation Medical Technology: Elective Compulsory
International Management and Engineering: Specialisation II. Mechatronics: Elective Compulsory
Biomedical Engineering: Specialisation Implants and Endoprostheses: Elective Compulsory
Biomedical Engineering: Specialisation Management and Business Administration: Elective Compulsory
Biomedical Engineering: Specialisation Artificial Organs and Regenerative Medicine: Elective Compulsory
Biomedical Engineering: Specialisation Medical Technology and Control Theory: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Course L0724: Microsystems Technology
Typ Lecture
Hrs/wk 2
CP 4
Workload in Hours Independent Study Time 92, Study Time in Lecture 28
Lecturer Prof. Hoc Khiem Trieu
Language EN
Cycle WiSe
Content
  • Introduction (historical view, scientific and economic relevance, scaling laws)
  • Semiconductor Technology Basics, Lithography (wafer fabrication, photolithography, improving resolution, next-generation lithography, nano-imprinting, molecular imprinting)
  • Deposition Techniques (thermal oxidation, epitaxy, electroplating, PVD techniques: evaporation and sputtering; CVD techniques: APCVD, LPCVD, PECVD and LECVD; screen printing)
  • Etching and Bulk Micromachining (definitions, wet chemical etching, isotropic etch with HNA, electrochemical etching, anisotropic etching with KOH/TMAH: theory, corner undercutting, measures for compensation and etch-stop techniques; plasma processes, dry etching: back sputtering, plasma etching, RIE, Bosch process, cryo process, XeF2 etching)
  • Surface Micromachining and alternative Techniques (sacrificial etching, film stress, stiction: theory and counter measures; Origami microstructures, Epi-Poly, porous silicon, SOI, SCREAM process, LIGA, SU8, rapid prototyping)
  • Thermal and Radiation Sensors (temperature measurement, self-generating sensors: Seebeck effect and thermopile; modulating sensors: thermo resistor, Pt-100, spreading resistance sensor, pn junction, NTC and PTC; thermal anemometer, mass flow sensor, photometry, radiometry, IR sensor: thermopile and bolometer)
  • Mechanical Sensors (strain based and stress based principle, capacitive readout, piezoresistivity,  pressure sensor: piezoresistive, capacitive and fabrication process; accelerometer: piezoresistive, piezoelectric and capacitive; angular rate sensor: operating principle and fabrication process)
  • Magnetic Sensors (galvanomagnetic sensors: spinning current Hall sensor and magneto-transistor; magnetoresistive sensors: magneto resistance, AMR and GMR, fluxgate magnetometer)
  • Chemical and Bio Sensors (thermal gas sensors: pellistor and thermal conductivity sensor; metal oxide semiconductor gas sensor, organic semiconductor gas sensor, Lambda probe, MOSFET gas sensor, pH-FET, SAW sensor, principle of biosensor, Clark electrode, enzyme electrode, DNA chip)
  • Micro Actuators, Microfluidics and TAS (drives: thermal, electrostatic, piezo electric and electromagnetic; light modulators, DMD, adaptive optics, microscanner, microvalves: passive and active, micropumps, valveless micropump, electrokinetic micropumps, micromixer, filter, inkjet printhead, microdispenser, microfluidic switching elements, microreactor, lab-on-a-chip, microanalytics)
  • MEMS in medical Engineering (wireless energy and data transmission, smart pill, implantable drug delivery system, stimulators: microelectrodes, cochlear and retinal implant; implantable pressure sensors, intelligent osteosynthesis, implant for spinal cord regeneration)
  • Design, Simulation, Test (development and design flows, bottom-up approach, top-down approach, testability, modelling: multiphysics, FEM and equivalent circuit simulation; reliability test, physics-of-failure, Arrhenius equation, bath-tub relationship)
  • System Integration (monolithic and hybrid integration, assembly and packaging, dicing, electrical contact: wire bonding, TAB and flip chip bonding; packages, chip-on-board, wafer-level-package, 3D integration, wafer bonding: anodic bonding and silicon fusion bonding; micro electroplating, 3D-MID)


Literature

M. Madou: Fundamentals of Microfabrication, CRC Press, 2002

N. Schwesinger: Lehrbuch Mikrosystemtechnik, Oldenbourg Verlag, 2009

T. M. Adams, R. A. Layton:Introductory MEMS, Springer, 2010

G. Gerlach; W. Dötzel: Introduction to microsystem technology, Wiley, 2008

Course L0725: Microsystems Technology
Typ Project-/problem-based Learning
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Hoc Khiem Trieu
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M1759: Linking theory and practice (dual study program, Master's degree)

Module Responsible Dr. Henning Haschke
Admission Requirements None
Recommended Previous Knowledge
  • Successful completion of practical modules as part of the dual Bachelor’s course
  • Module "interlinking theory and practice as part of the dual Master’s course"
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Dual students …

… can describe and classify selected classic and current theories, concepts and methods 

  • related to project management and
  • change and transformation management

... and apply them to specific situations, processes and plans in a personal, professional context.


Skills

Dual students …

  • ... anticipate typical difficulties, positive and negative effects, as well as success and failure factors in the engineering sector, evaluate them and consider promising strategies and courses of action.
  • … develop specialised technical and conceptual skills to solve complex tasks and problems in their professional field of activity/work.
Personal Competence
Social Competence

Dual students …

  • … can responsibly lead interdisciplinary teams within the framework of complex tasks and problems.
  • … engage in sector-specific and cross-sectoral discussions with experts, stakeholders and staff, representing their approaches, points of view and work results.
Autonomy

Dual students …

  • … define, reflect and evaluate goals and measures for complex application-oriented projects and change processes.
  • … shape their professional area of responsibility independently and sustainably.
  • … take responsibility for their actions and for the results of their work.
Workload in Hours Independent Study Time 96, Study Time in Lecture 84
Credit points 6
Course achievement None
Examination Written elaboration
Examination duration and scale Studienbegleitende und semesterübergreifende Dokumentation: Die Leistungspunkte für das Modul werden durch die Anfertigung eines digitalen Lern- und Entwicklungsberichtes (E-Portfolio) erworben. Dabei handelt es sich um eine fortlaufende Dokumentation und Reflexion der Lernerfahrungen und der Kompetenzentwicklung im Bereich der Personalen Kompetenz.
Course L2890: Responsible Project Management in Engineering (for Dual Study Program)
Typ Seminar
Hrs/wk 3
CP 3
Workload in Hours Independent Study Time 48, Study Time in Lecture 42
Lecturer Dr. Henning Haschke, Heiko Sieben
Language DE
Cycle WiSe/SoSe
Content
  • Theories and methods of project management
  • Innovation management
  • Agile project management
  • Fundamentals of classic and agile methods
  • Hybrid use of classic and agile methods  
  • Roles, perspectives and stakeholders throughout the project
  • Initiating and coordinating complex engineering projects
  • Principles of moderation, team management, team leadership, conflict management
  • Communication structures: in-house, cross-company
  • Public information policy
  • Promoting commitment and empowerment
  • Sharing experience with specialists and managers from the engineering sector
  • Documenting and reflecting on learning experiences
Literature

Seminarapparat

Course L2891: Responsible Change and Transformation Management in Engineering (for Dual Study Program)
Typ Seminar
Hrs/wk 3
CP 3
Workload in Hours Independent Study Time 48, Study Time in Lecture 42
Lecturer Dr. Henning Haschke, Heiko Sieben
Language DE
Cycle WiSe/SoSe
Content
  • Basic concepts, opportunities and limits of organisational change 
  • Models and methods of organisational design and development
  • Strategic orientation and change, and their short-, medium- and long-term consequences for individuals, organisations and society as a whole
  • Roles, perspectives and stakeholders in change processes
  • Initiating and coordinating change measures in engineering
  • Phase models of organisational change (Lewin, Kotter, etc.) 
  • Change-oriented information policy and dealing with resistance and uncertainty 
  • Promoting commitment and empowerment
  • Successfully handling change and transformation: personally, as an employee, as a manager (personal, professional, organisational)
  • Company-level and globally (systemic)
  • Sharing experience with specialists and managers from the engineering sector
  • Documenting and reflecting on learning experiences
Literature Seminarapparat

Module M1756: Practical module 1 (dual study program, Master's degree)

Courses
Title Typ Hrs/wk CP
Practical term 1 (dual study program, Master's degree) (L2887) 0 10
Module Responsible Dr. Henning Haschke
Admission Requirements None
Recommended Previous Knowledge
  • Successful completion of a compatible dual B.Sc. at TU Hamburg or comparable practical work experience and competences in the area of interlinking theory and practice
  • Course D from the module on interlinking theory and practice as part of the dual Master’s course
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Dual students …

  • … combine their knowledge of facts, principles, theories and methods gained from previous study content with acquired practical knowledge - in particular their knowledge of practical professional procedures and approaches, in the current field of activity in engineering. 
  • … have a critical understanding of the practical applications of their engineering subject.
Skills

Dual students …

  • … apply technical theoretical knowledge to complex, interdisciplinary problems within the company, and evaluate the associated work processes and results, taking into account different possible courses of action.
  • … implement the university’s application recommendations with regard to their current tasks. 
  • … develop solutions as well as procedures and approaches in their field of activity and area of responsibility.
Personal Competence
Social Competence

Dual students …

  • … work responsibly in project teams within their working area and proactively deal with problems within their team. 
  • … represent complex engineering viewpoints, facts, problems and solution approaches in discussions with internal and external stakeholders.
Autonomy

Dual students …

  • … define goals for their own learning and working processes as engineers.
  • … reflect on learning and work processes in their area of responsibility.
  • … reflect on the relevance of subject modules specialisations and specialisation for work as an engineer, and also implement the university’s application recommendations and the associated challenges to positively transfer knowledge between theory and practice.
Workload in Hours Independent Study Time 300, Study Time in Lecture 0
Credit points 10
Course achievement None
Examination Written elaboration
Examination duration and scale Documentation accompanying studies and across semesters: Module credit points are earned by completing a digital learning and development report (e-portfolio). This documents and reflects individual learning experiences and skills development relating to interlinking theory and practice, as well as professional practice. In addition, the partner company provides proof to the dual@TUHH Coordination Office that the dual student has completed the practical phase.
Assignment for the Following Curricula Civil Engineering: Core Qualification: Compulsory
Bioprocess Engineering: Core Qualification: Compulsory
Chemical and Bioprocess Engineering: Core Qualification: Compulsory
Computer Science: Core Qualification: Compulsory
Electrical Engineering: Core Qualification: Compulsory
Energy Systems: Core Qualification: Compulsory
Environmental Engineering: Core Qualification: Compulsory
Aircraft Systems Engineering: Core Qualification: Compulsory
Computer Science in Engineering: Core Qualification: Compulsory
Information and Communication Systems: Core Qualification: Compulsory
International Management and Engineering: Core Qualification: Compulsory
Logistics, Infrastructure and Mobility: Core Qualification: Compulsory
Aeronautics: Core Qualification: Compulsory
Materials Science and Engineering: Core Qualification: Compulsory
Materials Science: Core Qualification: Compulsory
Mechanical Engineering and Management: Core Qualification: Compulsory
Mechatronics: Core Qualification: Compulsory
Biomedical Engineering: Core Qualification: Compulsory
Microelectronics and Microsystems: Core Qualification: Compulsory
Product Development, Materials and Production: Core Qualification: Compulsory
Renewable Energies: Core Qualification: Compulsory
Naval Architecture and Ocean Engineering: Core Qualification: Compulsory
Theoretical Mechanical Engineering: Core Qualification: Compulsory
Process Engineering: Core Qualification: Compulsory
Water and Environmental Engineering: Core Qualification: Compulsory
Course L2887: Practical term 1 (dual study program, Master's degree)
Typ
Hrs/wk 0
CP 10
Workload in Hours Independent Study Time 300, Study Time in Lecture 0
Lecturer Dr. Henning Haschke
Language DE
Cycle WiSe/SoSe
Content

Company onboarding process

  • Assigning a professional field of activity as an engineer (B.Sc.) and associated fields of work
  • Establishing responsibilities and authorisation of the dual student within the company as an engineer (B.Sc.)
  • Working independently in a team and on selected projects - across departments and, if applicable, across companies
  • Scheduling the current practical module with a clear correlation to work structures 
  • Scheduling the examination phase/subsequent study semester

Operational knowledge and skills

  • Company-specific: Responsibility as an engineer (B.Sc.) in their own area of work, coordinating team and project work, dealing with complex contexts and unsolved problems, developing and implementing innovative solutions
  • Subject specialisation (corresponding to the chosen course [M.Sc.]) in the field of activity
  • Systemic skills
  • Implementing the university’s application recommendations (theory-practice transfer) in corresponding work and task areas across the company 

Sharing/reflecting on learning

  • Creating an e-portfolio
  • Importance of course contents (M.Sc.) when working as an engineer
  • Importance of development and innovation when working as an engineer
Literature
  • Studierendenhandbuch
  • Betriebliche Dokumente
  • Hochschulseitige Handlungsempfehlungen zum Theorie-Praxis-Transfer

Module M0747: Microsystem Design

Courses
Title Typ Hrs/wk CP
Microsystem Design (L0683) Lecture 2 3
Microsystem Design (L0684) Practical Course 3 3
Module Responsible Dr. Timo Lipka
Admission Requirements None
Recommended Previous Knowledge

Mathematical Calculus, Linear Algebra, Microsystem Engineering

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students know about the most important and most common simulation and design methods used in microsystem design. The scientific background of finite element methods and the basic theory of these methods are known.

Skills

Students are able to apply simulation methods and commercial simulators in a goal oriented approach to complex design tasks. Students know to apply the theory in order achieve estimates of expected accuracy and can judge and verify the correctness of results. Students are able to develop a design approach even if only incomplete information about material data or constraints are available. Student can make use of approximate and reduced order models in a preliminary design stage or a system simulation.

Personal Competence
Social Competence

Students are able to solve specific problems alone or in a group and to present the results accordingly. Students can develop and explain their solution approach and subdivide the design task to subproblems which are solved separately by group members.

Autonomy

Students are able to acquire particular knowledge using specialized literature and to integrate and associate this knowledge with other fields.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Written elaboration
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Course L0683: Microsystem Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Dr. Timo Lipka
Language EN
Cycle SoSe
Content

Finite difference methods

Approximation error

Finite element method

Order of convergence

Error estimation, mesh refinement

Makromodeling

Reduced order modeling

Black-box models

System identification

Multi-physics systems

System simulation

Levels of simulation, network simulation

Transient problems

Non-linear problems

Introduction to Comsol

Application to thermal, electric, electromagnetic, mechanical and fluidic problems

Literature

M. Kasper: Mikrosystementwurf, Springer (2000)

S. Senturia: Microsystem Design, Kluwer (2001)

Course L0684: Microsystem Design
Typ Practical Course
Hrs/wk 3
CP 3
Workload in Hours Independent Study Time 48, Study Time in Lecture 42
Lecturer Dr. Timo Lipka
Language EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M0918: Advanced IC Design

Courses
Title Typ Hrs/wk CP
Advanced IC Design (L0766) Lecture 2 3
Advanced IC Design (L1057) Project-/problem-based Learning 2 3
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge Fundamentals of electrical engineering, electronic devices and circuits
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students can explain the basic structure of the circuit simulator SPICE.
  • Students are able to describe the differences between the MOS transistor models of the circuit simulator SPICE.
  • Students can discuss the different concept for realization the hardware of electronic circuits.
  • Students can exemplify the approaches for “Design for Testability”.
  • Students can specify models for calculation of the reliability of electronic circuits.


Skills
  • Students can determine the input parameters for the circuit simulation program SPICE.
  • Students can select the most appropriate MOS modelling approaches for circuit simulations.
  • Students can quantify the trade-off of different design styles.
  • Students can determine the lot sizes and costs for reliability analysis.


Personal Competence
Social Competence
  • Students can compile design studies by themselves or together with partners.
  • Students are able to select the most efficient design methodology for a given task.
  • Students are able to define the work packages for design teams.


Autonomy
  • Students are able to assess the strengths and weaknesses of their design work in a self-contained manner.
  • Students can name and bring together all the tools required for total design flow.


Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Course L0766: Advanced IC Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Matthias Kuhl
Language EN
Cycle SoSe
Content
  • Circuit-Simulator SPICE 
  • SPICE-Models for MOS transistors
  • IC design
  • Technology of MOS circuits
  • Standard cell design
  • Design of gate arrays
  • CMOS transconductance and transimpedance amplifiers
  • frequency behavior of CMOS circuits
  • Techniques for improved circuit behaviour (e.g. cascodes, gain boosting, folding, ...)
  • Examples for realization of ASICs in the institute of nanoelectronics
  • Reliability of integrated circuits
  • Testing of integrated circuits
Literature

R. J. Baker, „CMOS-Circuit Design, Layout, and Simulation“, Wiley & Sons, IEEE Press, 2010 

B. Razavi,"Design of Analog CMOS Integrated Circuits", McGraw-Hill Education Ltd, 2000


X. Liu, VLSI-Design Methodology Demystified; IEEE, 2009


Course L1057: Advanced IC Design
Typ Project-/problem-based Learning
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Matthias Kuhl, Weitere Mitarbeiter
Language EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M1131: Technical Elective Complementary Course for IMPMM - field TUHH (according to Subject Specific Regulations)

Courses
Title Typ Hrs/wk CP
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge

Basic knowledge in electrical enginnering, physics, semiconductor devices, software and mathematics at Bachelor of Science level.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

As this module can be chosen from the module catalogue of the TUHH, the competence to be acquired is according to the chosen subject.

Skills


As this module can be chosen from the module catalogue of the TUHH, the skills to be acquired is according to the chosen subject.

Personal Competence
Social Competence
  • Students can team up with one or several partners who may have different professional backgrounds
  • Students are able to work by their own or in small groups for solving problems and answer scientific questions.
Autonomy
Workload in Hours Depends on choice of courses
Credit points 6
Assignment for the Following Curricula Microelectronics and Microsystems: Core Qualification: Elective Compulsory

Module M0761: Semiconductor Technology

Courses
Title Typ Hrs/wk CP
Semiconductor Technology (L0722) Lecture 4 4
Semiconductor Technology (L0723) Practical Course 2 2
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge

Basics in physics, chemistry, material science and semiconductor devices

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge


Students are able

     to describe and to explain current fabrication techniques for Si and GaAs substrates,

     to discuss in details the relevant fabrication processes, process flows and the impact thereof on the fabrication of semiconductor devices and integrated circuits and

     to present integrated process flows.


Skills


Students are capable

     to analyze the impact of process parameters on the processing results,

     to select and to evaluate processes and

     to develop process flows for the fabrication of semiconductor devices.


Personal Competence
Social Competence


Students are able to plan and carry out experiments in groups, as well as present and represent the results in front of others. These social skills are practiced both during the preparation phase, in which the groups work out and present the theory, and during the follow-up phase, in which the groups prepare, document and present their practical experiences.


Autonomy The independence of the students is demanded and promoted in that they have to transfer and apply what they have learned to ever new boundary conditions. This requirement is communicated at the beginning of the semester and consistently practiced until the exam. Students are encouraged to work independently by not being given a solution, but by learning to work out the solution step by step by asking specific questions. Students learn to ask questions independently when they are faced with a problem. They learn to independently break down problems into manageable sub-problems. 
Workload in Hours Independent Study Time 96, Study Time in Lecture 84
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Biomedical Engineering: Specialisation Artificial Organs and Regenerative Medicine: Elective Compulsory
Biomedical Engineering: Specialisation Implants and Endoprostheses: Elective Compulsory
Biomedical Engineering: Specialisation Medical Technology and Control Theory: Elective Compulsory
Biomedical Engineering: Specialisation Management and Business Administration: Elective Compulsory
Microelectronics and Microsystems: Core Qualification: Elective Compulsory
Course L0722: Semiconductor Technology
Typ Lecture
Hrs/wk 4
CP 4
Workload in Hours Independent Study Time 64, Study Time in Lecture 56
Lecturer Prof. Hoc Khiem Trieu
Language DE/EN
Cycle SoSe
Content
  • Introduction (historical view and trends in microelectronics)
  • Basics in material science (semiconductor, crystal, Miller indices, crystallographic defects)
  • Crystal fabrication (crystal pulling for Si and GaAs: impurities, purification, Czochralski , Bridgeman and float zone process)
  • Wafer fabrication (process flow, specification, SOI)
  • Fabrication processes
  • Doping (energy band diagram, doping, doping by alloying, doping by diffusion: transport processes, doping profile, higher order effects and process technology, ion implantation: theory, implantation profile, channeling, implantation damage, annealing and equipment)

  • Oxidation (silicon dioxide: structure, electrical properties and oxide charges, thermal oxidation: reactions, kinetics, influences on growth rate, process technology and equipment, anodic oxidation, plasma oxidation, thermal oxidation of GaAs)

  • Deposition techniques (theory: nucleation, film growth and structure zone model, film growth process, reaction kinetics, temperature dependence and equipment; epitaxy: gas phase, liquid phase, molecular beam epitaxy; CVD techniques: APCVD, LPCVD, deposition of metal silicide, PECVD and LECVD; basics of plasma, equipment, PVD techniques: high vacuum evaporation, sputtering)

  • Structuring techniques (subtractive methods, photolithography: resist properties, printing techniques: contact, proximity and projection printing, resolution limit, practical issues and equipment, additive methods: liftoff technique and electroplating, improving resolution: excimer laser light source, immersion lithography and phase shift lithography, electron beam lithography, X-ray lithography, EUV lithography, ion beam lithography, wet chemical etching: isotropic and anisotropic, corner undercutting, compensation masks and etch stop techniques; dry etching: plasma enhanced etching, backsputtering, ion milling, chemical dry etching, RIE, sidewall passivation)

  • Process integration (CMOS process, bipolar process)

  • Assembly and packaging technology (hierarchy of integration, packages, chip-on-board, chip assembly, electrical contact: wire bonding, TAB and flip chip, wafer level package, 3D stacking)

     

Literature

S.K. Ghandi: VLSI Fabrication principles - Silicon and Gallium Arsenide, John Wiley & Sons

S.M. Sze: Semiconductor Devices - Physics and Technology, John Wiley & Sons

U. Hilleringmann: Silizium-Halbleitertechnologie, Teubner Verlag

H. Beneking: Halbleitertechnologie - Eine Einführung in die Prozeßtechnik von Silizium und III-V-Verbindungen, Teubner Verlag

K. Schade: Mikroelektroniktechnologie, Verlag Technik Berlin

S. Campbell: The Science and Engineering of Microelectronic Fabrication, Oxford University Press

P. van Zant: Microchip Fabrication - A Practical Guide to Semiconductor Processing, McGraw-Hill

Course L0723: Semiconductor Technology
Typ Practical Course
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Hoc Khiem Trieu
Language DE/EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M1757: Practical module 2 (dual study program, Master's degree)

Courses
Title Typ Hrs/wk CP
Practical term 2 (dual study program, Master's degree) (L2888) 0 10
Module Responsible Dr. Henning Haschke
Admission Requirements None
Recommended Previous Knowledge
  • Successful completion of practical module 1 as part of the dual Master’s course
  • course D from the module on interlinking theory and practice as part of the dual Master’s course
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Dual students …

  • … combine their knowledge of facts, principles, theories and methods gained from previous study content with acquired practical knowledge - in particular their knowledge of practical professional procedures and approaches, in the current field of activity in engineering. 
  • … have a critical understanding of the practical applications of their engineering subject.
Skills

Dual students …

  • … apply technical theoretical knowledge to complex, interdisciplinary problems within the company, and evaluate the associated work processes and results, taking into account different possible courses of action.
  • … implement the university’s application recommendations with regard to their current tasks. 
  • … develop (new) solutions as well as procedures and approaches in their field of activity and area of responsibility - including in the case of frequently changing requirements (systemic skills).
Personal Competence
Social Competence

Dual students …

  • … work responsibly in cross-departmental and interdisciplinary project teams and proactively deal with problems within their team. 
  • … represent complex engineering viewpoints, facts, problems and solution approaches in discussions with internal and external stakeholders and develop these further together.
Autonomy

Dual students …

  • … define goals for their own learning and working processes as engineers.
  • … reflect on learning and work processes in their area of responsibility.
  • … reflect on the relevance of subject modules specialisations and specialisation for work as an engineer, and also implement the university’s application recommendations and the associated challenges to positively transfer knowledge between theory and practice.
Workload in Hours Independent Study Time 300, Study Time in Lecture 0
Credit points 10
Course achievement None
Examination Written elaboration
Examination duration and scale Documentation accompanying studies and across semesters: Module credit points are earned by completing a digital learning and development report (e-portfolio). This documents and reflects individual learning experiences and skills development relating to interlinking theory and practice, as well as professional practice. In addition, the partner company provides proof to the dual@TUHH Coordination Office that the dual student has completed the practical phase.
Assignment for the Following Curricula Civil Engineering: Core Qualification: Compulsory
Bioprocess Engineering: Core Qualification: Compulsory
Chemical and Bioprocess Engineering: Core Qualification: Compulsory
Computer Science: Core Qualification: Compulsory
Electrical Engineering: Core Qualification: Compulsory
Energy Systems: Core Qualification: Compulsory
Environmental Engineering: Core Qualification: Compulsory
Aircraft Systems Engineering: Core Qualification: Compulsory
Computer Science in Engineering: Core Qualification: Compulsory
Information and Communication Systems: Core Qualification: Compulsory
International Management and Engineering: Core Qualification: Compulsory
Logistics, Infrastructure and Mobility: Core Qualification: Compulsory
Aeronautics: Core Qualification: Compulsory
Materials Science and Engineering: Core Qualification: Compulsory
Materials Science: Core Qualification: Compulsory
Mechanical Engineering and Management: Core Qualification: Compulsory
Mechatronics: Core Qualification: Compulsory
Biomedical Engineering: Core Qualification: Compulsory
Microelectronics and Microsystems: Core Qualification: Compulsory
Product Development, Materials and Production: Core Qualification: Compulsory
Renewable Energies: Core Qualification: Compulsory
Naval Architecture and Ocean Engineering: Core Qualification: Compulsory
Theoretical Mechanical Engineering: Core Qualification: Compulsory
Process Engineering: Core Qualification: Compulsory
Water and Environmental Engineering: Core Qualification: Compulsory
Course L2888: Practical term 2 (dual study program, Master's degree)
Typ
Hrs/wk 0
CP 10
Workload in Hours Independent Study Time 300, Study Time in Lecture 0
Lecturer Dr. Henning Haschke
Language DE
Cycle WiSe/SoSe
Content

Company onboarding process

  • Assigning a professional field of activity as an engineer (B.Sc.) and associated fields of work
  • Establishing responsibilities and authorisation of the dual student within the company as an engineer (B.Sc.)
  • Taking personal responsibility within a team and on selected projects - across departments and, if applicable, across companies
  • Scheduling the current practical module with a clear correlation to work structures 
  • Scheduling the examination phase/subsequent study semester

Operational knowledge and skills

  • Company-specific: Responsibility as an engineer (B.Sc.) in their own area of work, coordinating team and project work, dealing with complex contexts and unsolved problems, developing and implementing innovative solutions
  • Subject specialisation (corresponding to the chosen course [M.Sc.]) in the field of activity
  • Systemic skills
  • Implementing the university’s application recommendations (theory-practice transfer) in corresponding work and task areas across the company 

Sharing/reflecting on learning

  • Updating their e-portfolio
  • Importance of course contents (M.Sc.) when working as an engineer
  • Importance of development and innovation when working as an engineer 
Literature
  • Studierendenhandbuch
  • Betriebliche Dokumente
  • Hochschulseitige Anwendungsempfehlungen zum Theorie-Praxis-Transfer

Module M1130: Project Work IMPMM

Courses
Title Typ Hrs/wk CP
Module Responsible Dozenten des SD E
Admission Requirements None
Recommended Previous Knowledge Good knowledge in the design of electronic circuits, microprocessor systems, systems for signal processing and the handling of software packages for simulation of electrical and physical processes.
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge The student is able to achieve in a specific scientific field special knowledge and she or he can independently acquire in this field the skills necessary for solving these scientific problems.
Skills The student is able to formulate the scientific problems to be solved and to work out solutions in an independent manner and to realize them.
Personal Competence
Social Competence The student can integrate herself or himself into small teams of researchers and she or he can discuss proposals for solutions of scientific problems within the team. She or he is able to present the results in a clear and well structured manner.
Autonomy The student can perform scientific work in a timely manner and document the results in a detailed and well readable form. She or he is able to anticipate possible problems well in advance and to prepare proposals for their solutions.
Workload in Hours Independent Study Time 450, Study Time in Lecture 0
Credit points 15
Course achievement None
Examination Study work
Examination duration and scale see FSPO
Assignment for the Following Curricula Microelectronics and Microsystems: Core Qualification: Compulsory

Module M1591: Seminar for IMPMM

Courses
Title Typ Hrs/wk CP
Seminar for IMPMM (L2428) Seminar 2 3
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge Basics from the field of the seminar
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge Students can explain the most important facts and relationships of a specific topic from the field of the seminar.
Skills Students are able to compile a specified topic from the field of the seminar and to give a clear, structured and comprehensible presentation of the subject. They can comply with a given duration of the presentation. They can write in English a summary including illustrations that contains the most important results, relationships and explanations of the subject.
Personal Competence
Social Competence Students are able to adapt their presentation with respect to content, detailedness, and presentation style to the composition and previous knowledge of the audience. They can answer questions from the audience in a curt and precise manner.
Autonomy Students are able to autonomously carry out a literature research concerning a given topic. They can independently evaluate the material. They can self-reliantly decide which parts of the material should be included in the presentation.
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Credit points 3
Course achievement None
Examination Presentation
Examination duration and scale 15 minutes presentation + 5-10 minutes discussion + 2 pages written abstract
Assignment for the Following Curricula Microelectronics and Microsystems: Core Qualification: Compulsory
Course L2428: Seminar for IMPMM
Typ Seminar
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Hoc Khiem Trieu
Language EN
Cycle WiSe/SoSe
Content

Prepare, present, and discuss talks about recent topics from the field of semiconductors. The presentations must be given in English.

Evaluation Criteria:

  • understanding of subject, discussion, response to questions
  • structure and logic of presentation (clarity, precision)
  • coverage of the topic, selection of subjects presented
  • linguistic presentation (clarity, comprehensibility)
  • visual presentation (clarity, comprehensibility)
  • handout (see below)
  • compliance with timing requirement.

Handout:
A printed handout (short abstract) of your presentation in English language is mandatory. This should not be longer than two pages A4, and include the most important results,
conclusions, explanations and diagrams.

Literature

Aktuelle Veröffentlichungen zu dem gewählten Thema.

Recent publications of the selected topics.

Module M1758: Practical module 3 (dual study program, Master's degree)

Courses
Title Typ Hrs/wk CP
Practical term 3 (dual study program, Master's degree) (L2889) 0 10
Module Responsible Dr. Henning Haschke
Admission Requirements None
Recommended Previous Knowledge
  • Successful completion of practical module 2 as part of the dual Master’s course
  • course E from the module on interlinking theory and practice as part of the dual Master’s course
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Dual students …

  • … combine their comprehensive and specialised engineering knowledge acquired from previous study contents with the strategy-oriented practical knowledge gained from their current field of work and area of responsibility. 
  • … have a critical understanding of the practical applications of their engineering subject, as well as related fields when implementing innovations.


Skills

Dual students …

  • … apply specialised and conceptual skills to solve complex, sometimes interdisciplinary problems within the company, and evaluate the associated work processes and results, taking into account different possible courses of action.
  • … implement the university’s application recommendations with regard to their current tasks. 
  • … develop new solutions as well as procedures and approaches to implement operational projects and assignments - even when facing frequently changing requirements and unpredictable changes (systemic skills).
  • … can use academic methods to develop new ideas and procedures for operational problems and issues, and to assess these with regard to their usability.
Personal Competence
Social Competence

Dual students …

  • … work responsibly in cross-departmental and interdisciplinary project teams and proactively deal with problems within their team. 
  • … can promote the professional development of others in a targeted manner.
  • … represent complex and interdisciplinary engineering viewpoints, facts, problems and solution approaches in discussions with internal and external stakeholders and develop these further together.
Autonomy

Dual students …

  • … reflect on learning and work processes in their area of responsibility.
  • … define goals for new application-oriented tasks, projects and innovation plans while reflecting on potential effects on the company and the public. 
  • … reflect on the relevance of areas of specialisation and research for work as an engineer, and also implement the university’s application recommendations and the associated challenges to positively transfer knowledge between theory and practice.
Workload in Hours Independent Study Time 300, Study Time in Lecture 0
Credit points 10
Course achievement None
Examination Written elaboration
Examination duration and scale Documentation accompanying studies and across semesters: Module credit points are earned by completing a digital learning and development report (e-portfolio). This documents and reflects individual learning experiences and skills development relating to interlinking theory and practice, as well as professional practice. In addition, the partner company provides proof to the dual@TUHH Coordination Office that the dual student has completed the practical phase.
Assignment for the Following Curricula Civil Engineering: Core Qualification: Compulsory
Bioprocess Engineering: Core Qualification: Compulsory
Chemical and Bioprocess Engineering: Core Qualification: Compulsory
Computer Science: Core Qualification: Compulsory
Electrical Engineering: Core Qualification: Compulsory
Energy Systems: Core Qualification: Compulsory
Environmental Engineering: Core Qualification: Compulsory
Aircraft Systems Engineering: Core Qualification: Compulsory
Computer Science in Engineering: Core Qualification: Compulsory
Information and Communication Systems: Core Qualification: Compulsory
International Management and Engineering: Core Qualification: Compulsory
Logistics, Infrastructure and Mobility: Core Qualification: Compulsory
Aeronautics: Core Qualification: Compulsory
Materials Science and Engineering: Core Qualification: Compulsory
Materials Science: Core Qualification: Compulsory
Mechanical Engineering and Management: Core Qualification: Compulsory
Mechatronics: Core Qualification: Compulsory
Biomedical Engineering: Core Qualification: Compulsory
Microelectronics and Microsystems: Core Qualification: Compulsory
Product Development, Materials and Production: Core Qualification: Compulsory
Renewable Energies: Core Qualification: Compulsory
Naval Architecture and Ocean Engineering: Core Qualification: Compulsory
Theoretical Mechanical Engineering: Core Qualification: Compulsory
Process Engineering: Core Qualification: Compulsory
Water and Environmental Engineering: Core Qualification: Compulsory
Course L2889: Practical term 3 (dual study program, Master's degree)
Typ
Hrs/wk 0
CP 10
Workload in Hours Independent Study Time 300, Study Time in Lecture 0
Lecturer Dr. Henning Haschke
Language DE
Cycle WiSe/SoSe
Content

Company onboarding process

  • Assigning a future professional field of activity as an engineer (M.Sc.) and associated fields of work
  • Extending responsibilities and authorisation of the dual student within the company up to the intended first assignment after completing their studies 
  • Working responsibly in a team; project responsibility within own area - as well as across divisions and companies if necessary
  • Scheduling the final practical module with a clear correlation to work structures 
  • Internal agreement on a potential topic or innovation project for the Master’s dissertation
  • Planning the Master’s dissertation within the company in cooperation with TU Hamburg  
  • Scheduling the examination phase/subsequent study semester

Operational knowledge and skills

  • Company-specific: dealing with change, project and team development, responsibility as an engineer in their future field of work (M.Sc.), dealing with complex contexts, frequent and unpredictable changes, developing and implementing innovative solutions
  • Specialising in one field of work (final dissertation)
  • Systemic skills
  • Implementing the university’s application recommendations (theory-practice transfer) in corresponding work and task areas across the company 

Sharing/reflecting on learning

  • E-portfolio
  • Relevance of study content and personal specialisation when working as an engineer
  • Relevance of research and innovation when working as an engineer
Literature
  • Studierendenhandbuch
  • betriebliche Dokumente
  • Hochschulseitige Anwendungsempfehlungen zum Theorie-Praxis-Transfer

Specialization Communication and Signal Processing

Students of the specialization Communication and Signal Processing learn both physical and technical basics of state-of-the-art wired and wireless communication systems and the hardware realization of those systems. They can deepen their knowledge towards core areas such as systems for audio or video signal processing. The students understand the fundamental concepts of those systems and can identify their limitations. Based on this knowledge they are able to determine possible improvements and to implement them.

Students have to choose lectures with a total of 18 credit points from the catalog of this specialization.

Module M0836: Communication Networks

Courses
Title Typ Hrs/wk CP
Selected Topics of Communication Networks (L0899) Project-/problem-based Learning 2 2
Communication Networks (L0897) Lecture 2 2
Communication Networks Excercise (L0898) Project-/problem-based Learning 1 2
Module Responsible Prof. Andreas Timm-Giel
Admission Requirements None
Recommended Previous Knowledge
  • Fundamental stochastics
  • Basic understanding of computer networks and/or communication technologies is beneficial
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students are able to describe the principles and structures of communication networks in detail. They can explain the formal description methods of communication networks and their protocols. They are able to explain how current and complex communication networks work and describe the current research in these examples.

Skills

Students are able to evaluate the performance of communication networks using the learned methods. They are able to work out problems themselves and apply the learned methods. They can apply what they have learned autonomously on further and new communication networks.

Personal Competence
Social Competence

Students are able to define tasks themselves in small teams and solve these problems together using the learned methods. They can present the obtained results. They are able to discuss and critically analyse the solutions.

Autonomy

Students are able to obtain the necessary expert knowledge for understanding the functionality and performance capabilities of new communication networks independently.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement None
Examination Presentation
Examination duration and scale 1.5 hours colloquium with three students, therefore about 30 min per student. Topics of the colloquium are the posters from the previous poster session and the topics of the module.
Assignment for the Following Curricula Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Electrical Engineering: Specialisation Control and Power Systems Engineering: Elective Compulsory
Aircraft Systems Engineering: Core Qualification: Elective Compulsory
Computer Science in Engineering: Specialisation I. Computer Science: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems: Elective Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems, Focus Networks: Elective Compulsory
International Management and Engineering: Specialisation II. Information Technology: Elective Compulsory
Aeronautics: Core Qualification: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Robotics and Computer Science: Elective Compulsory
Course L0899: Selected Topics of Communication Networks
Typ Project-/problem-based Learning
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Dr.-Ing. Koojana Kuladinithi
Language EN
Cycle WiSe
Content Example networks selected by the students will be researched on in a PBL course by the students in groups and will be presented in a poster session at the end of the term.
Literature
  • see lecture
Course L0897: Communication Networks
Typ Lecture
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Dr.-Ing. Koojana Kuladinithi
Language EN
Cycle WiSe
Content
Literature
  • Skript des Instituts für Kommunikationsnetze
  • Tannenbaum, Computernetzwerke, Pearson-Studium


Further literature is announced at the beginning of the lecture.

Course L0898: Communication Networks Excercise
Typ Project-/problem-based Learning
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Dr.-Ing. Koojana Kuladinithi
Language EN
Cycle WiSe
Content Part of the content of the lecture Communication Networks are reflected in computing tasks in groups, others are motivated and addressed in the form of a PBL exercise.
Literature
  • announced during lecture

Module M0710: Microwave Engineering

Courses
Title Typ Hrs/wk CP
Microwave Engineering (L0573) Lecture 2 3
Microwave Engineering (L0574) Recitation Section (large) 2 2
Microwave Engineering (L0575) Practical Course 1 1
Module Responsible Prof. Alexander Kölpin
Admission Requirements None
Recommended Previous Knowledge

Fundamentals of communication engineering, semiconductor devices and circuits. Basics of Wave propagation from transmission line theory and theoretical electrical engineering.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students can explain the propagation of electromagnetic waves and related phenomena. They can describe transmission systems and components. They can name different types of antennas and describe the main characteristics of antennas. They can explain noise in linear circuits, compare different circuits using characteristic numbers and select the best one for specific scenarios.


Skills

Students are able to calculate the propagation of electromagnetic waves. They can analyze complete transmission systems und configure simple receiver circuits. They can calculate the characteristic of simple antennas and arrays based on the geometry. They can calculate the noise of receivers and the signal-to-noise-ratio of transmission systems. They can apply their theoretical knowledge to the practical courses.


Personal Competence
Social Competence

Students work together in small groups during the practical courses. Together they document, evaluate and discuss their results.


Autonomy

Students are able to relate the knowledge gained in the course to contents of previous lectures. With given instructions they can extract data needed to solve specific problems from external sources. They are able to apply their knowledge to the laboratory courses using the given instructions.


Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Subject theoretical and practical work
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Electrical Engineering: Core Qualification: Compulsory
Information and Communication Systems: Specialisation Communication Systems: Elective Compulsory
International Management and Engineering: Specialisation II. Electrical Engineering: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Course L0573: Microwave Engineering
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Alexander Kölpin
Language DE/EN
Cycle WiSe
Content

- Antennas: Analysis - Characteristics - Realizations

- Radio Wave Propagation

- Transmitter: Power Generation with Vacuum Tubes and Transistors

- Receiver: Preamplifier - Heterodyning - Noise

- Selected System Applications


Literature

H.-G. Unger, „Elektromagnetische Theorie für die Hochfrequenztechnik, Teil I“, Hüthig, Heidelberg, 1988

H.-G. Unger, „Hochfrequenztechnik in Funk und Radar“, Teubner, Stuttgart, 1994

E. Voges, „Hochfrequenztechnik - Teil II: Leistungsröhren, Antennen und Funkübertragung, Funk- und Radartechnik“, Hüthig, Heidelberg, 1991

E. Voges, „Hochfrequenztechnik“, Hüthig, Bonn, 2004


C.A. Balanis, “Antenna Theory”, John Wiley and Sons, 1982

R. E. Collin, “Foundations for Microwave Engineering”, McGraw-Hill, 1992

D. M. Pozar, “Microwave and RF Design of Wireless Systems”, John Wiley and Sons, 2001

D. M. Pozar, “Microwave Engineerin”, John Wiley and Sons, 2005


Course L0574: Microwave Engineering
Typ Recitation Section (large)
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Alexander Kölpin
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course
Course L0575: Microwave Engineering
Typ Practical Course
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Alexander Kölpin
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M0637: Advanced Concepts of Wireless Communications

Courses
Title Typ Hrs/wk CP
Advanced Concepts of Wireless Communications (L0297) Lecture 3 4
Advanced Concepts of Wireless Communications (L0298) Recitation Section (large) 2 2
Module Responsible Dr. Rainer Grünheid
Admission Requirements None
Recommended Previous Knowledge
  • Lecture "Signals and Systems"
  • Lecture "Fundamentals of Telecommunications and Stochastic Processes"
  • Lecture "Digital Communications"
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students are able to explain the general as well as advanced principles and techniques that are applied to wireless communications. They understand the properties of wireless channels and the corresponding mathematical description. Furthermore, students are able to explain the physical layer of wireless transmission systems. In this context, they are proficient in the concepts of multicarrier transmission (OFDM), modulation, error control coding, channel estimation and multi-antenna techniques (MIMO). Students can also explain methods of multiple access. On the example of contemporary communication systems (LTE, 5G) they can put the learnt content into a larger context.

The students are familiar with the contents of lecture and tutorials. They can explain and apply them to new problems.

Skills

Using the acquired knowledge, students are able to understand the design of current and future wireless systems. Moreover, given certain constraints, they can choose appropriate parameter settings of communication systems. Students are also able to assess the suitability of technical concepts for a given application.

Personal Competence
Social Competence Students can jointly elaborate tasks in small groups and present their results in an adequate fashion.
Autonomy Students are able to extract necessary information from given literature sources and put it into the perspective of the lecture. They can continuously check their level of expertise with the help of accompanying measures (such as online tests, clicker questions, exercise tasks) and, based on that, to steer their learning process accordingly. They can relate their acquired knowledge to topics of other lectures, e.g., "Fundamentals of Communications and Stochastic Processes" and "Digital Communications".
Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 minutes; scope: content of lecture and exercise
Assignment for the Following Curricula Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Electrical Engineering: Specialisation Wireless and Sensor Technologies: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Course L0297: Advanced Concepts of Wireless Communications
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Dr. Rainer Grünheid
Language EN
Cycle SoSe
Content

The lecture deals with technical principles and related concepts of mobile communications. In this context, the main focus is put on the physical and data link layer of the ISO-OSI stack.

In the lecture, the transmission medium, i.e., the mobile radio channel, serves as the starting point of all considerations. The characteristics and the mathematical descriptions of the radio channel are discussed in detail. Subsequently, various physical layer aspects of wireless transmission are covered, such as channel coding, modulation/demodulation, channel estimation, synchronization, and equalization. Moreover, the different uses of multiple antennas at the transmitter and receiver, known as MIMO techniques, are described. Besides these physical layer topics, concepts of multiple access schemes in a cellular network are outlined.

In order to illustrate the above-mentioned technical solutions, the lecture will also provide a system view, highlighting the basics of some contemporary wireless systems, including LTE, LTE Advanced, and 5G New Radio.


Literature

John G. Proakis, Masoud Salehi: Digital Communications. 5th Edition, Irwin/McGraw Hill, 2007

David Tse, Pramod Viswanath: Fundamentals of Wireless Communication. Cambridge, 2005

Bernard Sklar: Digital Communications: Fundamentals and Applications. Second Edition, Pearson, 2013

Stefani Sesia, Issam Toufik, Matthew Baker: LTE - The UMTS Long Term Evolution. Second Edition, Wiley, 2011

Erik Dahlman, Stefan Parkvall, Johan Sköld: 5G NR - The Next Generation Wireless Access Technology. Second Edition, Academic Press, 2021

Course L0298: Advanced Concepts of Wireless Communications
Typ Recitation Section (large)
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Dr. Rainer Grünheid
Language EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M1700: Satellite Communications and Navigation

Courses
Title Typ Hrs/wk CP
Radio-Based Positioning and Navigation (L2711) Lecture 2 3
Satellite Communications (L2710) Lecture 3 3
Module Responsible Prof. Gerhard Bauch
Admission Requirements None
Recommended Previous Knowledge

The module is designed for a diverse audience, i.e. students with different background. Basic knowledge of communications engineering and signal processing are of advantage but not required. The course intends to provide the chapters on communications techniques such that on the one hand students with a communications engineering background learn additional concepts and examples (e.g. modulation and coding schemes or signal processing concepts) which have not or in a different way been treated in our other bachelor and master courses. On the other hand, students with other background shall be able to grasp the ideas but may not be able to understand in the same depth. The individual background of the students will be taken into consideration in the oral exam.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students are able to understand, compare and analyse digital satellite communications system as well as navigation techniques. They are familiar with principal ideas of the respective communications, signal processing and positioning methods. They can describe distortions and resulting limitations caused by transmission channels and hardware components. They can describe how fundamental communications and navigation techniques are applied in selected practical systems. 

The students are familiar with the contents of lecture and tutorials. They can explain and apply them to new problems.



Skills

The students are able to describe and analyse digital satellite communications systems and navigation systems. They are able to analyse transmission chains including link budget calculations. They are able to choose appropriate transmission technologies and system parameters for given scenarios. 

Personal Competence
Social Competence

The students can jointly solve specific problems.

Autonomy

The students are able to acquire relevant information from appropriate literature sources. 

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems, Focus Networks: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems, Focus Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Course L2711: Radio-Based Positioning and Navigation
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Gerhard Bauch, Dr. Ing. Rico Mendrzik
Language EN
Cycle SoSe
Content
  • Information extraction from communication signals
    • Time-of-arrival principle
      • Ranging in additive white Gaussian noise (AWGN) channel
      • Correlation-based range estimation
      • Effect of multipath propagation on time-of-arrival principle
      • Zero-forcing range estimation in the presence of multipath
      • Optimum range estimation in the presence of multipath
      • Zero-forcing in presence of noise
    • Angle-of-arrival principle
      • Angle-of-arrival estimation in AWGN channel
      • Delay-and-sum estimator
      • Multiple Signal Classifier (MUSIC)
      • MUSIC-based angle-of-arrival estimation
      • Case study: Comparison of estimators in AWGN channels
      • Effect of multipath propagation on angle-of-arrival principle
      • Case study: Comparison of estimators in multipath channels
  • Information fusion of extracted signals 
    • Distance-based positioning
      • Principle of time-of-arrival positioning
      • Geometric interpretation
      • Positioning in the absence of noise
      • Linearization of the positioning problem
      • Positioning in the presence of noise
      • Optimality criteria
      • Least squares time-of-arrival positioning
      • Maximum likelihood time-of-arrival positioning
      • Interactive Matlab demo
      • Excursion: gradient descent solvers for nonlinear programs
      • Real-life positioning with embedded development board (Arduino)
      • Linearized least squares time-of-arrival positioning
      • Effect of clock offsets on distance-based positioning
      • Time-difference-of-arrival principle
      • Least squares time-difference-of-arrival positioning
      • Clock offset mitigation via two-way ranging
    • Performance limits of distance-based positioning
      • Fisher information and the Cramér-Rao lower bound
      • Fisher information in the AWGN case
      • Multi-variate Fisher information
      • Cramér-Rao lower bound for synchronized time-of-arrival positioning
      • Case study: Synchronized time-of-arrival positioning
      • Cramér-Rao lower bound for unsynchronized time-of-arrival positioning
      • Case study: Unsynchronized time-of-arrival positioning
    • Angle-based Positioning
      • Angle-of-arrival positioning principle
      • Geometric interpretation angle-of-arrival positioning principle
      • Noise-free angle-of-arrival positioning with known orientation
      • Effect of noise on angle-of-arrival positioning
      • Least squares angle-of-arrival positioning with known orientation
      • Linear least squares angle-of-arrival positioning
      • Effect of orientation uncertainty
      • Angle-difference-of-arrival positioning
      • Geometric interpretation angle difference of arrival positioning
      • Proof of angle-difference-of-arrival locus
      • Inscribed angle lemma
      • Case study: Angle-difference-of-arrival-positioning
    • Performance limits of angle-based positioning
      • Cramér-Rao lower bound for angle-of-arrival positioning with known orientation
      • Case study: Angle-of-arrival positioning with known orientation
  • Information Filtering
    • Bayesian filtering
      • Principle of Bayesian filtering
      • General Problem Formulation
      • Solution to the linear Gaussian case
      • State transition in the linear Gaussian case
      • Proof of predicted posterior distribution of the Kalman filter
      • State update in the linear Gaussian case
      • Proof of marginal posterior distribution of the Kalman filter
      • Working with Gaussian random variables
        • Proof: Affine transformation
        • Proof: Marginalization
        • Proof: Conditioning
      • Kalman filter: Optimum Inference in the linear Gaussian case
      • Modeling of process noise
      • Modeling of measurement noise
      • Case study: Kalman filtering in the linear Gaussian case
      • Interactive Kalman filtering in Matlab
      • Dealing with nonlinearities in Bayesian filtering
      • Nonlinear Gaussian case
      • Extended Kalman filter
      • Proof of predicted posterior distribution of the extended Kalman filter
      • Proof of marginal posterior distribution of the extended Kalman filter
      • Example: Nonlinear state transition
      • Case study: Extended Kalman filtering
      • Practical considerations for filter design
  • Satellite Navigation
    • Overview from positioning perspective
      • Earth-centered earth-fixed (ECEF) coordinate system
      • World geodetic system (WGS)
      • Satellite navigation systems
      • System-receiver clock offsets and pseudo-ranges
      • Unsynchronized time-of-arrival positioning revisited
    • GPS legacy signals and ranging
      • Signal overview
      • Time-of-arrival principle revisited
      • Direct sequence spread spectrum principle
      • Short and long codes
      • Satellite signal generation
      • Carriers and codes
      • Correlation properties of codes
      • Code division multiple access in flat fading channels
      • Navigation message
    • Velocity estimation
    • Hands-on case study: Design of an extended Kalman filter for satellite navigation based on recorded data
  • Robust navigation
    • Multipath-assisted positioning in millimeter wave multiple antenna systems
    • Multi-sensor fusion 
Literature
Course L2710: Satellite Communications
Typ Lecture
Hrs/wk 3
CP 3
Workload in Hours Independent Study Time 48, Study Time in Lecture 42
Lecturer Prof. Gerhard Bauch
Language EN
Cycle SoSe
Content
  • Introduction to satellite communications
    • What is a satellite
    • Overview orbits, Van Allen Belt, components of a satellite
    • Satellite services
    • Frequency bands for satellite services
    • International Telecommunications Union (ITU)
    • Influence of atmospheric impairments
    • Milestones in satellite communications
  • Components of a satellite communications system
    • Ground segment
    • Space segment
    • Control segment
  • Communication links
    • Uplink, downlink
    • Forward link, reverse link
    • Intersatellite links
    • Multiple access
    • Performance measures
      • Effective isotropic radiated power (EIRP), antenna gain, figure of merit, G/T, carrier to noise ratio
      • Signal to noise power ratio vs. carrier to noise ratio
  • Single beam and multibeam satellites
    • Beam coverage
    • Examples for beam coverage of LEO and GEO satellites (Iridium, Viasat)
  • Transparent vs. regenerative payload
  • Orbits
    • Low earth orbot (LEO), medium earth orbit (MEO), geosynchroneous and geostationary orbits (GEO), highly elliptical orbits (HEO
    • Favourable orbits:
      • HEO orbits with 63-64o inclination, Molnya and Tundra orbits
      • Circular LEO orbits
      • Circular MEO Orbits (Intermediate Circular Orbits (ICO))
      • Equatorial orbits, geostationary orbit (GEO)
    • Important aspects of LEO, MEO and GEO satellites
  • Kepler’s laws of planetary motion
  • Gravitational force
  • Parameters of ellipses and elliptical orbits
    • Major and minor half axis
    • Foci
    • Eccentricity
    • Eccentric anomaly, mean anomaly, true anomaly
    • Area
    • Orbit period
    • Perigee, apogee
    • Distance of satellite from center of earth
    • Construction of ellipses according to de La Hire
    • Orbital plane in space, inclination, right ascension (longitude) of ascending node, Vernal equinox
  • Newton’s laws of motion
  • Newton’s universal law of gravitation
  • Energy of satellites: Potential energy, kinetic energy, total energy
  • Instantaneous speed of a satellite
  • Kepler’s equation
  • Satellite visibility, elevation
  • Required number of LEO, MEO or GEO satellites for continuous earth coverage
  • Satellite altitude and distance from a point on earth
  • Choice of orbits
    • LEO, HEO, GEO
    • Elliptical orbits with non-zero inclination, Molnya orbits, Tundra orbits
    • Geosynchronous orbits
      • Parameters of geosynchronous orbits
      • Circular geosynchronous orbits
      • Inclined geosynchronous orbits
      • Quasi-zenith satellite systems (QZSS)
      • Syb-synchronous circular equatorial orbits
      • Geostationary orbit
        • Parameters of the geostationary orbit
        • Visibility
        • Propagation delay
        • Applications and system examples
  • Perturbations of orbits
    • Station keeping
      • Station keeping box
      • Estimation of orbit parameters
  • Fundamentals of digital communications techniques
    • Components of a digital communications system
    • Principles of encryption
    • Scrambling
    • Scrambling vs. interleaving for randomization of data sequences
    • Interleaving: Block interleaver, convolutional interleaver, random interleaver
    • Digital modulation methods
      • Linear and non-linear digital modulation methods
      • Linear digital modulation methods
        • QAM modulator and demodulator
        • Pulse shaping, square-root raised-cosine pulses
        • Average power spectral density
        • Signal space constellation
        • Examples: M-ary phase shift keying (M-PSK), M-ary quadrature amplitude shift keying (M-QAM)
        • M-PSK in noisy channels
        • Bit error probabilities of M-PSK and M-QAM
        • M-PSK vs. M-QAM
        • M-ary amplitude and phase shift keying (M-APSK)
        • M-APSK vs. M-QAM
        • Differential phase shift keying (DPSK)

Error control coding (channel coding)

  • Error detecting and forward error correcting (FEC) codes
  • Principle of channel coding
  • Data rate, code rate, Baud rate, spectral efficiency of modulation and coding schemes
  • Bandwidth-power trade-off, bandwidth-limited vs. power-limited transmission
  • Coding and modulation for transparent vs. regenerative payload
  • Block codes and convolutional codes
  • Concatenated codes
  • Bit-interleaved coded modulation
  • Convolutional codes
  • Low density parity check (LDPC) codes, principle of message passing decoding, bit error rate performance
  • Cyclic block codes
    • Examples for cyclic block codes
    • Single errors vs. block errors, cyclic block codes for burst errors
    • Generator matrix, generator polynomials
    • Systematic encoding and syndrome determination with shift registers
    • Cyclic redundancy check (CRC) codes


  • Automatic repeat request (ARQ)
    • Principle of ARQ
    • Stop-and-wait ARQ
    • Go-back-N ARQ
    • Selective-repeat ARQ
  • Transmission gains and losses
    • Antenna gain
      • Antenna radiation pattern
      • Maximum antenna gain, 3dB beamwidth
      • Maximum antenna gain of circular aperture
      • Maximum antenna gain of a geostationary satellite with global coverage
    • Effective isotropic radiated power (EIRP)
    • Power flux density
    • Path loss
      • Free space loss, free space loss for geostationary satellites
      • Atmospheric loss
      • Received power
    • Losses in transmit and receive equipment
      • Feeder loss
      • Depointing loss
      • Polarization mismatch loss
    • Combined effect of losses
  • Noise
    • Origins of noise
    • White noise
    • Noise power spectral density and noise power
    • Additive white Gaussian noise (AWGN) channel model
    • Antenna noise temperature
    • Earth brightness temperature
    • Signal to noise ratios
  • Atmospheric distortions
    • Atmosphere of the earth: Troposphere, stratosphere, mesosphere, thermosphere, exosphere
    •  Attenuation and depolarization due to rain, fog, rain and ice clouds, sandstorms
    • Scintillation
    • Faraday effect
    • Multipath contributions
  • Link budget calculations
    • GEO clear sky uplink and downlink
    • GEO uplink and downlink under rain conditions
    • Transparent vs. regenerative payload
  • Link availability improvement through site diversity and adaptive transmission
    • Transparent vs. regenerative payload
      • Non-linear amplifiers
        • Saleh model, Rapp model
        • Input and output back-off factor
      • Single carrier and multicarrier operation
      • Dimensioning of transmission parameters
      • Sources of noise: Thermal noise, interference, intermodulation products
      • Signal to noise ratio and bit error probability
      • Robustness against interference and non-linear channels
  • Satellite networks
    • Satellite network reference architectures
    • Network topologies
    • Network connectivity
      • Types of network connectivity
      • On-board connectivity
      • Inter-satellite links
    • Broadcast networks
    • Satellite-based internet
  • Satellite communications systems and standards examples
    • The role of standards in satellite communications
    • The Digital Video Broadcast Satellite Standard: DVB-S, DVB-S2, DVB-S2X
    • Satellites in 3GPP mobile communications networks
    • LEO megaconstellations: SpaceX Starlink, Kuiper, OneWeb
    • Space debris
    • The German Heinrich Hertz mission


Literature

Module M1743: COSIMA (Competition in Microsystem Application)

Courses
Title Typ Hrs/wk CP
COSIMA (L3111) Project-/problem-based Learning 4 6
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge

Knowledge of microsystems operation and application.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Consolidation of knowledge in the application of microsystems with practical relevance. Learning how an idea could turn into a product.

Skills

Realization of a concrete system by integrating hardware components and, under certain circumstances, software into a demonstrator. Development of a business plan for the innovative product. Convincing companies to sponsor the project. Presentation of the project in the form of an exposé.

Personal Competence
Social Competence

Students work in groups of 3 to 4 participants each to implement their project idea. The division of tasks takes place within the group, taking into account the complementary skills of the members.

Autonomy

The groups work on the project independently from the idea to the implementation. Supervision is provided through joint analysis of the problems and advice to the students.

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Subject theoretical and practical work
Examination duration and scale 60 minutes
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L3111: COSIMA
Typ Project-/problem-based Learning
Hrs/wk 4
CP 6
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Lecturer Prof. Hoc Khiem Trieu
Language EN
Cycle WiSe/SoSe
Content

Students learn the entire development process for a microsystem and its application, starting with the generation of ideas, through cost planning and implementation, to the acquisition of sponsorships and the creation of an exposé.

 
Literature

Module M0738: Digital Audio Signal Processing

Courses
Title Typ Hrs/wk CP
Digital Audio Signal Processing (L0650) Lecture 3 4
Digital Audio Signal Processing (L0651) Recitation Section (large) 1 2
Module Responsible Prof. Udo Zölzer
Admission Requirements None
Recommended Previous Knowledge

Signals and Systems

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Die Studierenden können die grundlegenden Verfahren und Methoden der digitalen Audiosignalverarbeitung erklären. Sie können die wesentlichen physikalischen Effekte bei der Sprach- und Audiosignalverarbeitung erläutern und in Kategorien einordnen. Sie können einen Überblick der numerischen Methoden und messtechnischen Charakterisierung von Algorithmen zur Audiosignalverarbeitung geben. Sie können die erarbeiteten Algorithmen auf weitere Anwendungen im Bereich der Informationstechnik und Informatik abstrahieren.

Skills

The students will be able to apply methods and techniques from audio signal processing in the fields of mobile and internet communication. They can rely on elementary algorithms of audio signal processing in form of Matlab code and interactive JAVA applets. They can study parameter modifications and evaluate the influence on human perception and technical applications in a variety of applications beyond audio signal processing. Students can perform measurements in time and frequency domain in order to give objective and subjective quality measures with respect to the methods and applications.

Personal Competence
Social Competence

The students can work in small groups to study special tasks and problems and will be enforced to present their results with adequate methods during the exercise.

Autonomy

The students will be able to retrieve information out of the relevant literature in the field and putt hem into the context of the lecture. They can relate their gathered knowledge and relate them to other lectures (signals and systems, digital communication systems, image and video processing, and pattern recognition). They will be prepared to understand and communicate problems and effects in the field audio signal processing.

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 60 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems, Focus Signal Processing: Elective Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems, Focus Software and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Course L0650: Digital Audio Signal Processing
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Prof. Udo Zölzer
Language EN
Cycle WiSe
Content
  • Introduction (Studio Technology,  Digital Transmission Systems, Storage Media, Audio Components at Home)

  • Quantization (Signal Quantization, Dither, Noise Shaping, Number Representation)

  • AD/DA Conversion (Methods, AD Converters, DA Converters, Audio Processing Systems, Digital Signal Processors, Digital Audio Interfaces, Single-Processor Systems, Multiprocessor Systems)

  • Equalizers (Recursive Audio Filters, Nonrecursive Audio Filters, Multi-Complementary Filter Bank)

  • Room Simulation (Early Reflections, Subsequent Reverberation, Approximation of Room Impulse Responses)

  • Dynamic Range Control (Static Curve, Dynamic Behavior, Implementation, Realization Aspects)

  • Sampling Rate Conversion (Synchronous Conversion, Asynchronous Conversion, Interpolation Methods)

  • Data Compression (Lossless Data Compression, Lossy Data Compression, Psychoacoustics, ISO-MPEG1 Audio Coding)

Literature

- U. Zölzer, Digitale Audiosignalverarbeitung, 3. Aufl., B.G. Teubner, 2005.

- U. Zölzer, Digitale Audio Signal Processing, 2nd Edition, J. Wiley & Sons, 2005.


- U. Zölzer (Ed), Digital Audio Effects, 2nd Edition, J. Wiley & Sons, 2011.


 






Course L0651: Digital Audio Signal Processing
Typ Recitation Section (large)
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Prof. Udo Zölzer
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M1686: Selected Aspects of Communication and Signal Processing

Courses
Title Typ Hrs/wk CP
Selected Aspects of Communication and Signal Processing (L2674) Lecture 3 4
Selected Aspects of Communication and Signal Processing (L2675) Recitation Section (small) 1 2
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Course L2674: Selected Aspects of Communication and Signal Processing
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Dozenten des SD E
Language EN
Cycle WiSe/SoSe
Content
Literature
Course L2675: Selected Aspects of Communication and Signal Processing
Typ Recitation Section (small)
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Dozenten des SD E
Language EN
Cycle WiSe/SoSe
Content See interlocking course
Literature See interlocking course

Module M1598: Image Processing

Courses
Title Typ Hrs/wk CP
Image Processing (L2443) Lecture 2 4
Image Processing (L2444) Recitation Section (small) 2 2
Module Responsible Prof. Tobias Knopp
Admission Requirements None
Recommended Previous Knowledge Signal and Systems
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students know about

  • visual perception
  • multidimensional signal processing
  • sampling and sampling theorem
  • filtering
  • image enhancement
  • edge detection
  • multi-resolution procedures: Gauss and Laplace pyramid, wavelets
  • image compression
  • image segmentation
  • morphological image processing
Skills

The students can

  • analyze, process, and improve multidimensional image data
  • implement simple compression algorithms
  • design custom filters for specific applications
Personal Competence
Social Competence

Students can work on complex problems both independently and in teams. They can exchange ideas with each other and use their individual strengths to solve the problem.

Autonomy

Students are able to independently investigate a complex problem and assess which competencies are required to solve it. 

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Data Science: Core Qualification: Elective Compulsory
Data Science: Specialisation I. Mathematics/Computer Science: Elective Compulsory
Data Science: Specialisation II. Computer Science: Elective Compulsory
Data Science: Specialisation IV. Special Focus Area: Elective Compulsory
Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Electrical Engineering: Specialisation Medical Technology: Elective Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems, Focus Software and Signal Processing: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems, Focus Signal Processing: Elective Compulsory
International Management and Engineering: Specialisation II. Information Technology: Elective Compulsory
Mechatronics: Specialisation Intelligent Systems and Robotics: Elective Compulsory
Mechatronics: Specialisation System Design: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Robotics and Computer Science: Elective Compulsory
Course L2443: Image Processing
Typ Lecture
Hrs/wk 2
CP 4
Workload in Hours Independent Study Time 92, Study Time in Lecture 28
Lecturer Prof. Tobias Knopp
Language DE/EN
Cycle WiSe
Content
  • Visual perception
  • Multidimensional signal processing
  • Sampling and sampling theorem
  • Filtering
  • Image enhancement
  • Edge detection
  • Multi-resolution procedures: Gauss and Laplace pyramid, wavelets
  • Image Compression
  • Segmentation
  • Morphological image processing
Literature

Bredies/Lorenz, Mathematische Bildverarbeitung, Vieweg, 2011
Pratt, Digital Image Processing, Wiley, 2001
Bernd Jähne: Digitale Bildverarbeitung - Springer, Berlin 2005

Course L2444: Image Processing
Typ Recitation Section (small)
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Tobias Knopp
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M0677: Digital Signal Processing and Digital Filters

Courses
Title Typ Hrs/wk CP
Digital Signal Processing and Digital Filters (L0446) Lecture 3 4
Digital Signal Processing and Digital Filters (L0447) Recitation Section (large) 2 2
Module Responsible Prof. Gerhard Bauch
Admission Requirements None
Recommended Previous Knowledge
  • Mathematics 1-3
  • Signals and Systems
  • Fundamentals of signal and system theory as well as random processes.
  • Fundamentals of spectral transforms (Fourier series, Fourier transform, Laplace transform)
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students know and understand basic algorithms of digital signal processing. They are familiar with the spectral transforms of discrete-time signals and are able to describe and analyse signals and systems in time and image domain. They know basic structures of digital filters and can identify and assess important properties including stability. They are aware of the effects caused by quantization of filter coefficients and signals. They are familiar with the basics of adaptive filters. They can perform traditional and parametric methods of spectrum estimation, also taking a limited observation window into account.

The students are familiar with the contents of lecture and tutorials. They can explain and apply them to new problems.

Skills The students are able to apply methods of digital signal processing to new problems. They can choose and parameterize suitable filter striuctures. In particular, the can design adaptive filters according to the minimum mean squared error (MMSE) criterion and develop an efficient implementation, e.g. based on the LMS or RLS algorithm.  Furthermore, the students are able to apply methods of spectrum estimation and to take the effects of a limited observation window into account.
Personal Competence
Social Competence

The students can jointly solve specific problems.

Autonomy

The students are able to acquire relevant information from appropriate literature sources. They can control their level of knowledge during the lecture period by solving tutorial problems, software tools, clicker system.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Control and Power Systems Engineering: Elective Compulsory
Computer Science in Engineering: Specialisation II. Engineering Science: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems, Focus Signal Processing: Elective Compulsory
Mechanical Engineering and Management: Specialisation Mechatronics: Elective Compulsory
Mechatronics: Specialisation Intelligent Systems and Robotics: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Robotics and Computer Science: Elective Compulsory
Course L0446: Digital Signal Processing and Digital Filters
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Prof. Gerhard Bauch
Language EN
Cycle WiSe
Content
  • Transforms of discrete-time signals:

    • Discrete-time Fourier Transform (DTFT)

    • Discrete Fourier-Transform (DFT), Fast Fourier Transform (FFT)

    • Z-Transform

  • Correspondence of continuous-time and discrete-time signals, sampling, sampling theorem

  • Fast convolution, Overlap-Add-Method, Overlap-Save-Method

  • Fundamental structures and basic types of digital filters

  • Characterization of digital filters using pole-zero plots, important properties of digital filters

  • Quantization effects

  • Design of linear-phase filters

  • Fundamentals of stochastic signal processing and adaptive filters

    • MMSE criterion

    • Wiener Filter

    • LMS- and RLS-algorithm

  • Traditional and parametric methods of spectrum estimation

Literature

K.-D. Kammeyer, K. Kroschel: Digitale Signalverarbeitung. Vieweg Teubner.

V. Oppenheim, R. W. Schafer, J. R. Buck: Zeitdiskrete Signalverarbeitung. Pearson StudiumA. V.

W. Hess: Digitale Filter. Teubner.

Oppenheim, R. W. Schafer: Digital signal processing. Prentice Hall.

S. Haykin:  Adaptive flter theory.

L. B. Jackson: Digital filters and signal processing. Kluwer.

T.W. Parks, C.S. Burrus: Digital filter design. Wiley.

Course L0447: Digital Signal Processing and Digital Filters
Typ Recitation Section (large)
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Gerhard Bauch
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M1249: Medical Imaging

Courses
Title Typ Hrs/wk CP
Medical Imaging (L1694) Lecture 2 3
Medical Imaging (L1695) Recitation Section (small) 2 3
Module Responsible Prof. Tobias Knopp
Admission Requirements None
Recommended Previous Knowledge Basic knowledge in linear algebra, numerics, and signal processing
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

After successful completion of the module, students are able to describe reconstruction methods for different tomographic imaging modalities such as computed tomography and magnetic resonance imaging. They know the necessary basics from the fields of signal processing and inverse problems and are familiar with both analytical and iterative image reconstruction methods. The students have a deepened knowledge of the imaging operators of computed tomography and magnetic resonance imaging.

Skills

The students are able to implement reconstruction methods and test them using tomographic measurement data. They can visualize the reconstructed images and evaluate the quality of their data and results. In addition, students can estimate the temporal complexity of imaging algorithms.

Personal Competence
Social Competence

Students can work on complex problems both independently and in teams. They can exchange ideas with each other and use their individual strengths to solve the problem.

Autonomy

Students are able to independently investigate a complex problem and assess which competencies are required to solve it. 

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Computer Science: Specialisation II: Intelligence Engineering: Elective Compulsory
Data Science: Specialisation III. Applications: Elective Compulsory
Data Science: Specialisation IV. Special Focus Area: Elective Compulsory
Electrical Engineering: Specialisation Medical Technology: Elective Compulsory
Computer Science in Engineering: Specialisation I. Computer Science: Elective Compulsory
Interdisciplinary Mathematics: Specialisation Computational Methods in Biomedical Imaging: Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Technomathematics: Specialisation II. Informatics: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Bio- and Medical Technology: Elective Compulsory
Course L1694: Medical Imaging
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Tobias Knopp
Language DE/EN
Cycle WiSe
Content
  • Overview about different imaging methods
  • Signal processing
  • Inverse problems
  • Computed tomography
  • Magnetic resonance imaging
  • Compressed Sensing
  • Magnetic particle imaging

Literature

Bildgebende Verfahren in der Medizin; O. Dössel; Springer, Berlin, 2000

Bildgebende Systeme für die medizinische Diagnostik; H. Morneburg (Hrsg.); Publicis MCD, München, 1995

Introduction to the Mathematics of Medical Imaging; C. L.Epstein; Siam, Philadelphia, 2008

Medical Image Processing, Reconstruction and Restoration; J. Jan; Taylor and Francis, Boca Raton, 2006

Principles of Magnetic Resonance Imaging; Z.-P. Liang and P. C. Lauterbur; IEEE Press, New York, 1999

Course L1695: Medical Imaging
Typ Recitation Section (small)
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Tobias Knopp
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Specialization Embedded Systems

Module M0791: Computer Architecture

Courses
Title Typ Hrs/wk CP
Computer Architecture (L0793) Lecture 2 3
Computer Architecture (L0794) Project-/problem-based Learning 2 2
Computer Architecture (L1864) Recitation Section (small) 1 1
Module Responsible Prof. Heiko Falk
Admission Requirements None
Recommended Previous Knowledge

Module "Computer Engineering"

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

This module presents advanced concepts from the discipline of computer architecture. In the beginning, a broad overview over various programming models is given, both for general-purpose computers and for special-purpose machines (e.g., signal processors). Next, foundational aspects of the micro-architecture of processors are covered. Here, the focus particularly lies on the so-called pipelining and the methods used for the acceleration of instruction execution used in this context. The students get to know concepts for dynamic scheduling, branch prediction, superscalar execution of machine instructions and for memory hierarchies.

Skills

The students are able to describe the organization of processors. They know the different architectural principles and programming models. The students examine various structures of pipelined processor architectures and are able to explain their concepts and to analyze them w.r.t. criteria like, e.g., performance or energy efficiency. They evaluate different structures of memory hierarchies, know parallel computer architectures and are able to distinguish between instruction- and data-level parallelism.

Personal Competence
Social Competence

Students are able to solve similar problems alone or in a group and to present the results accordingly.

Autonomy

Students are able to acquire new knowledge from specific literature and to associate this knowledge with other classes.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
No 15 % Subject theoretical and practical work
Examination Written exam
Examination duration and scale 90 minutes, contents of course and 4 attestations from the PBL "Computer architecture"
Assignment for the Following Curricula General Engineering Science (German program, 7 semester): Specialisation Computer Science: Elective Compulsory
Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Aircraft Systems Engineering: Core Qualification: Elective Compulsory
Computer Science in Engineering: Specialisation I. Computer Science: Elective Compulsory
Aeronautics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L0793: Computer Architecture
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Heiko Falk
Language DE/EN
Cycle WiSe
Content
  • Introduction
  • VHDL Basics
  • Programming Models
  • Realization of Elementary Data Types
  • Dynamic Scheduling
  • Branch Prediction
  • Superscalar Machines
  • Memory Hierarchies

The theoretical tutorials amplify the lecture's content by solving and discussing exercise sheets and thus serve as exam preparation. Practical aspects of computer architecture are taught in the FPGA-based PBL on computer architecture whose attendance is mandatory.

Literature
  • D. Patterson, J. Hennessy. Rechnerorganisation und -entwurf. Elsevier, 2005.
  • A. Tanenbaum, J. Goodman. Computerarchitektur. Pearson, 2001.
Course L0794: Computer Architecture
Typ Project-/problem-based Learning
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Heiko Falk
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course
Course L1864: Computer Architecture
Typ Recitation Section (small)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Heiko Falk
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M1749: Energy Efficiency in Embedded Systems

Courses
Title Typ Hrs/wk CP
Energy Efficiency in Embedded Systems (L2870) Lecture 2 3
Energy Efficiency in Embedded Systems (L2872) Project-/problem-based Learning 2 2
Energy Efficiency in Embedded Systems (L2871) Recitation Section (large) 1 1
Module Responsible Prof. Ulf Kulau
Admission Requirements None
Recommended Previous Knowledge
  • Computer Engineering (mandatory)
  • Programming Skills in C (mandatory)
  • Computer Architecture (recommended)
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge Motivation:

In the field of computer science we have only limited possibilities to influence the efficiency of the hardware directly, respectively we are dependent on the manufacturers (e.g. of microcontrollers). However, in order to exploit the full potential of the hardware we are given at the system level, we need a deeper understanding of the background, processes and mechanisms of power dissipation in embedded systems. Where does the power dissipation come from, what happens at the hardware level, what mechanisms can I use directly/indirectly, what is the tradeoff between flexibility and efficiency,.... are only a few questions, which will be elaborated and discussed in this event.

Contents of teaching:
  • Motivation and power dissipation on semiconductor level
  • Power dissipation of digital circuits, inparticular CMOS
  • Power Management in Hard- and Software (Sleep Modes, DVS, FS, Undervolting)
  • Energy efficient system design (applications)
  • Energy Harvesting and Transiently Powered Computing (TPC)
Skills

Upon completion of this module, students will have a deeper understanding of hardware and software mechanisms for evaluating and developing energy-efficient embedded systems

  • They have a deeper understanding of the electrotechnical basics of power dissipation in digital systems
  • They can analyze the power dissipation of systems at any level and apply appropriate methods to increase efficiency
  • They can use a variety of standard techniques to achieve "Energy Efficiency by Design"
  • They can model, evaluate as well as implement energy-autonomous systems
Personal Competence
Social Competence

As part of the module, concepts learned in the lecture will be implemented on a hardware platform within small groups. Students learn to work in a team and to develop solutions together. Specific tasks are worked on within the group, whereby cross-group collaboration (exchange) also takes place. The second part is a challenge-based project in which the groups find the most energy-efficient solutions possible in healthy competition with each other. This strengthens the cohesion in the groups and reinforces mutual motivation, support and creativity.


Autonomy

After completing this module, students will be able to independently develop, optimize and evaluate solutions for embedded systems based on the knowledge they have acquired and further technical literature. 

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement None
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Electrical Engineering: Specialisation Wireless and Sensor Technologies: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L2870: Energy Efficiency in Embedded Systems
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Ulf Kulau
Language DE/EN
Cycle WiSe
Content Motivation:

In the field of computer science we have only limited possibilities to influence the efficiency of the hardware directly, respectively we are dependent on the manufacturers (e.g. of microcontrollers). However, in order to exploit the full potential of the hardware we are given at the system level, we need a deeper understanding of the background, processes and mechanisms of power dissipation in embedded systems. Where does the power dissipation come from, what happens at the hardware level, what mechanisms can I use directly/indirectly, what is the tradeoff between flexibility and efficiency,.... are only a few questions, which will be elaborated and discussed in this event.

Contents of teaching:
  • Motivation and power dissipation on semiconductor level
  • Power dissipation of digital circuits, inparticular CMOS
  • Power Management in Hard- and Software (Sleep Modes, DVS, FS, Undervolting)
  • Energy efficient system design (applications)
  • Energy Harvesting and Transiently Powered Computing (TPC)
Literature

DE: Die Vorlesung basiert af einer Vielzahl von Quellen, welche in [1.] angegeben sind.

ENG: The lecture is based on multiple sources which are listed in [1.].

  1. Kulau, Ulf: Course: Energy Efficiency in Embedded Systems-A System-Level Perspective for Computer Scientists, EWME, 2018.
  2. Harris, David, and N. Weste: CMOS VLSI Design ed., Pearson Education, 2010
  3. Rabaey, Jan: Low Power Design Essentials (Integrated Circuits and Systems), Springer, 2009
Course L2872: Energy Efficiency in Embedded Systems
Typ Project-/problem-based Learning
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Ulf Kulau
Language DE/EN
Cycle WiSe
Content

In this project-based exercise, the learned aspects for achieving energy-efficient embedded systems are implemented and consolidated in practical environments in a small project. First, a tool set for the implementation of energy efficiency mechanisms is implemented in common exercises by means of defined tasks. In the second part, a challenge-based exercise is carried out in which a system that is as efficient as possible is to be implemented independently. A system based on an AVR micro-controller is used, which can be operated autonomously by a Solar-Energy Harvester.

  1. Task phase: 6 "hands-on" tasks to gain experience and to create a SW library.
  2. Project phase: Implementation of an energy autonomous system with the goal of highest possible energy efficiency (Challenge)   

Literature
Course L2871: Energy Efficiency in Embedded Systems
Typ Recitation Section (large)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Ulf Kulau
Language DE/EN
Cycle WiSe
Content

In the lecture hall exercise, the theoertical basics taught in the lecture are deepened. This is done through in-depth discussion of relevant aspects, but also through calculation examples, in which a deeper understanding of the topic of energy efficiency in embedded systems is gained. Exercises will be distributed in advance and solutions will be presented in the lecture hall exercise. Contents of the exercise are as follows:

  • Basics and calculation of power dissipation on semiconductor
  • Power dissipation of CMOS using the example of an inverter
  • Influence of the activity factor and external components
  • DVS and scheduling
  • Evaluation to show the benefit of undervolting
  • Aspects of energy harvesting (MPPT)


Literature

Module M0924: Software for Embedded Systems

Courses
Title Typ Hrs/wk CP
Software for Embdedded Systems (L1069) Lecture 2 3
Software for Embdedded Systems (L1070) Recitation Section (small) 3 3
Module Responsible Prof. Bernd-Christian Renner
Admission Requirements None
Recommended Previous Knowledge
  • Very Good knowledge and practical experience in programming in the C language and its compilation process
  • Basic knowledge in software engineering
  • Basic understanding of assembly language
  • Basic knowledge of electrical engineering
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students know the basic principles and procedures of software engineering for embedded systems.
  • They are able to describe the usage and advantages of event-based programming using interrupts.
  • They know the components and functions of a concrete microcontroller.
  • The participants explain requirements of real time systems.
  • They know at least three scheduling algorithms for real time operating systems including their pros and cons.
Skills
  • Students design and write hardware-oriented software modules for an embedded system based on a specific microcontroller.
  • They learn to interact with peripherals (timer, ADC, EEPROM), including interrupt-based processing and program flow.
  • They build and use a (preemptive) scheduler for an embedded system.
  • They learn to write independent, reusable software components.
Personal Competence
Social Competence
  • Students are able to work goal-oriented in small mixed groups.
  • They learn and broaden their teamwork abilities.
  • They learn to define and split tasks within the team.
Autonomy

Students are able

  • to solve assignments related to this lecture independently with instructional direction.
  • to design, implement, and test software components for an embedded system independently based on a textual description.
  • to read and understand data sheets and manuals of electronic components (such as micro-controllers and sensors)
Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
No 10 % Attestation
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Data Science: Specialisation II. Computer Science: Elective Compulsory
Data Science: Specialisation IV. Special Focus Area: Elective Compulsory
Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems, Focus Software: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Robotics and Computer Science: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Robotics and Computer Science: Elective Compulsory
Course L1069: Software for Embdedded Systems
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Bernd-Christian Renner
Language DE/EN
Cycle SoSe
Content
  • General-Purpose Processors
  • Programming the Atmel AVR
  • Interrupts
  • C for Embedded Systems
  • Standard Single Purpose Processors: Peripherals
  • Finite-State Machines
  • Memory
  • Operating Systems for Embedded Systems
  • Real-Time Embedded Systems
  • Boot loader and Power Management
Literature
  1. Embedded System Design,  F. Vahid and T. Givargis,  John Wiley
  2. Programming Embedded Systems: With C and Gnu Development Tools, M. Barr and A. Massa, O'Reilly

  3. C und C++ für Embedded Systems,  F. Bollow, M. Homann, K. Köhn,  MITP
  4. The Art of Designing  Embedded Systems, J. Ganssle, Newnses

  5. Mikrocomputertechnik mit Controllern der Atmel AVR-RISC-Familie,  G. Schmitt, Oldenbourg
  6. Making Embedded Systems: Design Patterns for Great Software, E. White, O'Reilly

Course L1070: Software for Embdedded Systems
Typ Recitation Section (small)
Hrs/wk 3
CP 3
Workload in Hours Independent Study Time 48, Study Time in Lecture 42
Lecturer Prof. Bernd-Christian Renner
Language DE/EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M1400: Design of Dependable Systems

Courses
Title Typ Hrs/wk CP
Designing Dependable Systems (L2000) Lecture 2 3
Designing Dependable Systems (L2001) Recitation Section (small) 2 3
Module Responsible Prof. Görschwin Fey
Admission Requirements None
Recommended Previous Knowledge Basic knowledge about data structures and algorithms
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

In the following "dependable" summarizes the concepts Reliability, Availability, Maintainability, Safety and Security.

Knowledge about approaches for designing dependable systems, e.g.,

  • Structural solutions like modular redundancy
  • Algorithmic solutions like handling byzantine faults or checkpointing

Knowledge about methods for the analysis of dependable systems


Skills

Ability to implement dependable systems using the above approaches.

Ability to analyzs the dependability of systems using the above methods for analysis.

Personal Competence
Social Competence

Students

  • discuss relevant topics in class and
  • present their solutions orally.
Autonomy Using accompanying material students independently learn in-depth relations between concepts explained in the lecture and additional solution strategies.
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Subject theoretical and practical work Die Lösung einer Aufgabe ist Zuslassungsvoraussetzung für die Prüfung. Die Aufgabe wird in Vorlesung und Übung definiert.
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Computer Science in Engineering: Specialisation I. Computer Science: Elective Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Theoretical Mechanical Engineering: Specialisation Robotics and Computer Science: Elective Compulsory
Course L2000: Designing Dependable Systems
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Görschwin Fey
Language DE/EN
Cycle SoSe
Content

Description

The term dependability comprises various aspects of a system. These are typically:
  • Reliability
  • Availability
  • Maintainability
  • Safety
  • Security
This makes dependability a core aspect that has to be considered early in system design, no matter whether software, embedded systems or full scale cyber-physical systems are considered.

Contents

The module introduces the basic concepts for the design and the analysis of dependable systems. Design examples for getting practical hands-on-experience in dependable design techniques. The module focuses towards embedded systems. The following topics are covered:
  • Modelling
  • Fault Tolerance
  • Design Concepts
  • Analysis Techniques
Literature
Course L2001: Designing Dependable Systems
Typ Recitation Section (small)
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Görschwin Fey
Language DE/EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M1772: Smart Sensors

Courses
Title Typ Hrs/wk CP
Smart Sensors (L2904) Lecture 2 2
Smart Sensors Lab (L2905) Project-/problem-based Learning 3 4
Module Responsible Prof. Ulf Kulau
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 25 min
Assignment for the Following Curricula Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Electrical Engineering: Specialisation Information and Communication Systems: Elective Compulsory
Electrical Engineering: Specialisation Wireless and Sensor Technologies: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L2904: Smart Sensors
Typ Lecture
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Prof. Ulf Kulau
Language DE/EN
Cycle SoSe
Content
Literature
Course L2905: Smart Sensors Lab
Typ Project-/problem-based Learning
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Prof. Ulf Kulau
Language DE/EN
Cycle SoSe
Content
Literature

Module M1743: COSIMA (Competition in Microsystem Application)

Courses
Title Typ Hrs/wk CP
COSIMA (L3111) Project-/problem-based Learning 4 6
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge

Knowledge of microsystems operation and application.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Consolidation of knowledge in the application of microsystems with practical relevance. Learning how an idea could turn into a product.

Skills

Realization of a concrete system by integrating hardware components and, under certain circumstances, software into a demonstrator. Development of a business plan for the innovative product. Convincing companies to sponsor the project. Presentation of the project in the form of an exposé.

Personal Competence
Social Competence

Students work in groups of 3 to 4 participants each to implement their project idea. The division of tasks takes place within the group, taking into account the complementary skills of the members.

Autonomy

The groups work on the project independently from the idea to the implementation. Supervision is provided through joint analysis of the problems and advice to the students.

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Subject theoretical and practical work
Examination duration and scale 60 minutes
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L3111: COSIMA
Typ Project-/problem-based Learning
Hrs/wk 4
CP 6
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Lecturer Prof. Hoc Khiem Trieu
Language EN
Cycle WiSe/SoSe
Content

Students learn the entire development process for a microsystem and its application, starting with the generation of ideas, through cost planning and implementation, to the acquisition of sponsorships and the creation of an exposé.

 
Literature

Module M0803: Embedded Systems

Courses
Title Typ Hrs/wk CP
Embedded Systems (L0805) Lecture 3 3
Embedded Systems (L2938) Project-/problem-based Learning 1 1
Embedded Systems (L0806) Recitation Section (small) 1 2
Module Responsible Prof. Heiko Falk
Admission Requirements None
Recommended Previous Knowledge Computer Engineering
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Embedded systems can be defined as information processing systems embedded into enclosing products. This course teaches the foundations of such systems. In particular, it deals with an introduction into these systems (notions, common characteristics) and their specification languages (models of computation, hierarchical automata, specification of distributed systems, task graphs, specification of real-time applications, translations between different models).

Another part covers the hardware of embedded systems: Sonsors, A/D and D/A converters, real-time capable communication hardware, embedded processors, memories, energy dissipation, reconfigurable logic and actuators. The course also features an introduction into real-time operating systems, middleware and real-time scheduling. Finally, the implementation of embedded systems using hardware/software co-design (hardware/software partitioning, high-level transformations of specifications, energy-efficient realizations, compilers for embedded processors) is covered.

Skills After having attended the course, students shall be able to realize simple embedded systems. The students shall realize which relevant parts of technological competences to use in order to obtain a functional embedded systems. In particular, they shall be able to compare different models of computations and feasible techniques for system-level design. They shall be able to judge in which areas of embedded system design specific risks exist.
Personal Competence
Social Competence

Students are able to solve similar problems alone or in a group and to present the results accordingly.

Autonomy

Students are able to acquire new knowledge from specific literature and to associate this knowledge with other classes.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes 10 % Subject theoretical and practical work
Examination Written exam
Examination duration and scale 90 minutes, contents of course and labs
Assignment for the Following Curricula General Engineering Science (German program, 7 semester): Specialisation Computer Science: Compulsory
Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Electrical Engineering: Core Qualification: Elective Compulsory
Engineering Science: Specialisation Mechatronics: Elective Compulsory
Engineering Science: Specialisation Electrical Engineering: Elective Compulsory
Aircraft Systems Engineering: Core Qualification: Elective Compulsory
General Engineering Science (English program, 7 semester): Specialisation Mechatronics: Elective Compulsory
Computer Science in Engineering: Core Qualification: Compulsory
Aeronautics: Core Qualification: Elective Compulsory
Mechatronics: Core Qualification: Elective Compulsory
Mechatronics: Specialisation Naval Engineering: Compulsory
Mechatronics: Specialisation Electrical Systems: Compulsory
Mechatronics: Specialisation Dynamic Systems and AI: Compulsory
Mechatronics: Specialisation Robot- and Machine-Systems: Compulsory
Mechatronics: Specialisation Medical Engineering: Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L0805: Embedded Systems
Typ Lecture
Hrs/wk 3
CP 3
Workload in Hours Independent Study Time 48, Study Time in Lecture 42
Lecturer Prof. Heiko Falk
Language EN
Cycle SoSe
Content
  • Introduction
  • Specifications and Modeling
  • Embedded/Cyber-Physical Systems Hardware
  • System Software
  • Evaluation and Validation
  • Mapping of Applications to Execution Platforms
  • Optimization
Literature
  • Peter Marwedel. Embedded System Design - Embedded Systems Foundations of Cyber-Physical Systems. 2nd Edition, Springer, 2012., Springer, 2012.
Course L2938: Embedded Systems
Typ Project-/problem-based Learning
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Heiko Falk
Language EN
Cycle SoSe
Content
  • Introduction
  • Specifications and Modeling
  • Embedded/Cyber-Physical Systems Hardware
  • System Software
  • Evaluation and Validation
  • Mapping of Applications to Execution Platforms
  • Optimization
Literature
  • Peter Marwedel. Embedded System Design - Embedded Systems Foundations of Cyber-Physical Systems. 2nd Edition, Springer, 2012., Springer, 2012.
Course L0806: Embedded Systems
Typ Recitation Section (small)
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Prof. Heiko Falk
Language EN
Cycle SoSe
Content See interlocking course
Literature See interlocking course

Module M1771: Research Based Learning - Smart Sensing Applications

Courses
Title Typ Hrs/wk CP
Research Based Learning - Smart Sensing Applications (L2903) Project-/problem-based Learning 4 6
Module Responsible Prof. Ulf Kulau
Admission Requirements None
Recommended Previous Knowledge
  • Embedded Systems
  • Smart Sensors
  • Technische Informatik
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  •  Involvement of students in real research topic.
  •  Topics may change depending on timeliness. BCG offers itself as a topic: It is relevant, current and interdisciplinary.
  •  Create interdisciplinary connection points / colloquium with project-related, but also with institutes/universities from other disciplines
  •  Generate or provide data sets
  •  Find methods derive develop for integrated signal processing for the respective project reference
  •  Soft skills in the area of communication & interdisciplinarity (learning to understand each other's language)
Skills

After completing the module, students are able to better understand and actively accompany scientific processes. Thereby, the involvement in a real research project (topic depending on topicality) is a high motivation and is given. Students receive a general understanding of the respective research project, iundem basics and backgrounds are conveyed. In order to be able to provide own research contributions within the set framework, methods for scientific practice are taught.

  • Teaching of fundamentals (interdisciplinary, smart sensors / other disciplines)
  • Design of experiments / hypotheses (framework is given -> methodology should be taught)
  • Execution of experiments (execution of experiments / generation of measurement data)
  • Scientific evaluation of the data
  • Presentation of results Discussion of further utilization (publication if necessary) 
Personal Competence
Social Competence

The work is done in groups and close cooperation and coordination within the individual teams is required. Through the interface "sensors" it is possible to select topics with a strong interdisciplinary share. Mutual understanding (finding a common language) is learned through this. Since real scientific problems are to be investigated, students acquire the ability to implement good scientific practice in a disciplined, objective and critical manner. 

Autonomy

After completing the module, students will be able to independently plan and carry out scientific processes. In group work, organization, idea generation, derivation of hypotheses and thought processes are to be independently moderated and carried out.

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Written elaboration
Examination duration and scale Paper including the achieved results
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L2903: Research Based Learning - Smart Sensing Applications
Typ Project-/problem-based Learning
Hrs/wk 4
CP 6
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Lecturer Prof. Ulf Kulau
Language DE/EN
Cycle SoSe
Content
Literature

Module M0925: Digital Circuit Design

Courses
Title Typ Hrs/wk CP
Digital Circuit Design (L0698) Lecture 2 3
Advanced Digital Circuit Design (L0699) Lecture 2 3
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 40 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
International Management and Engineering: Specialisation II. Electrical Engineering: Elective Compulsory
Mechanical Engineering and Management: Specialisation Mechatronics: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L0698: Digital Circuit Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Volkhard Klinger
Language EN
Cycle WiSe
Content
Literature
Course L0699: Advanced Digital Circuit Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Volkhard Klinger
Language EN
Cycle SoSe
Content
Literature

Module M1687: Selected Aspects of Embedded Systems

Courses
Title Typ Hrs/wk CP
Selected Aspects of Embedded Systems (L2676) Lecture 3 4
Selected Aspects of Embedded Systems (L2677) Recitation Section (small) 1 2
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L2676: Selected Aspects of Embedded Systems
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Dozenten des SD E
Language EN
Cycle WiSe/SoSe
Content
Literature
Course L2677: Selected Aspects of Embedded Systems
Typ Recitation Section (small)
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Dozenten des SD E
Language EN
Cycle WiSe/SoSe
Content See interlocking course
Literature See interlocking course

Module M1780: Massively Parallel Systems: Architecture and Programming

Courses
Title Typ Hrs/wk CP
Massively Parallel Systems: Architecture and Programming (L2936) Lecture 2 3
Massively Parallel Systems: Architecture and Programming (L2937) Project-/problem-based Learning 2 3
Module Responsible Prof. Sohan Lal
Admission Requirements None
Recommended Previous Knowledge

An introductory module on computer Engineering or computer architecture, good programming skills in C/C++.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The course starts with parallel computers classification, multithreading, and covers the architecture of centralized and distributed shared-memory parallel systems, multiprocessor cache coherence, snooping / directory-based cache coherence protocols, implementation, and limitations. Next, students study interconnection networks and routing in parallel systems. To ensure the correctness of shared-memory multithreaded programs, independent of the speed of execution of their individual threads, the important topics of memory consistency and synchronization will be covered in detail. As a case study, the architecture of a few accelerators such as GPUs will also be discussed in detail. Besides understanding the architecture and organization of parallel systems, programming them is also very challenging. The course will also cover how to program massively parallel systems using API/libraries such as CUDA/OpenCL/MPI/OpenMP.

Skills

After completing this course, students will be able to understand the architecture and organization of parallel systems. They will be able to evaluate different design choices and make decisions while designing a parallel system. In addition, they will be able to program parallel systems (ranging from an embedded system to a supercomputer) using CUDA/OpenCL/MPI/OpenMP. 

Personal Competence
Social Competence The course will encourage students to work in small groups to solve complex problems, thus, inculcating the importance of teamwork. 
Autonomy

Today, parallel computers are present everywhere. Students will be able to not only program parallel computers independently, but also understand their underlying organization and architecture. This will further help to understand the performance issues of parallel applications and provide insights to improve them. 

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes 20 % Subject theoretical and practical work
Examination Oral exam
Examination duration and scale 25 min
Assignment for the Following Curricula Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Data Science: Specialisation II. Computer Science: Elective Compulsory
Data Science: Specialisation IV. Special Focus Area: Elective Compulsory
Computer Science in Engineering: Specialisation I. Computer Science: Elective Compulsory
Information and Communication Systems: Specialisation Communication Systems, Focus Software: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L2936: Massively Parallel Systems: Architecture and Programming
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Sohan Lal
Language EN
Cycle WiSe
Content

Brief outline:

  • Parallel computers and their classification
  • Centralized and distributed shared-memory architectures: snooping vs directory-based cache coherence protocols, implementation, and limitations
  • Chip multiprocessors: software-based, block (coarse-grain), interleaved (fine-grain), simultaneous multithreading
  • Synchronization: high-level primitives and implementation, memory consistency models: sequential and weaker memory consistency models
  • Interconnection networks: topologies (direct and indirect networks) and routing techniques
  • Graphics Processing Units (GPUs) architecture and programming using CUDA/OpenCL
  • Parallel programming with message passing interface (MPI), OpenMP


Literature
  • Michel Dubois, Murali Annavaram, and Per Stenström, Parallel Computer Organization and Design (Book)
  • David A Patterson and John L. Hennessy, Computer Architecture: A Quantitative Approach, Elsevier (Book)
  • David B. Kirk, Wen-mei W. Hwu, Programming Massivley Parallel Processors, Elsevier (Book)


Course L2937: Massively Parallel Systems: Architecture and Programming
Typ Project-/problem-based Learning
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Sohan Lal
Language EN
Cycle WiSe
Content

There will be 3-4 assignments for project-based learning consisting of the following: 

  • Implement and compare different cache coherence protocols using a simulator or a high-level, event-driven simulation interface such as SystemC
  • Programming massively parallel systems to solve computationally intensive problems such as password cracking using CUDA/OpenCL/MPI/OpenMP


Literature

The following literature will be useful for project-based learning. The further required resources will be discussed during the course.

  • David B. Kirk, Wen-mei W. Hwu, Programming Massivley Parallel Processors, Elsevier (Book)
  • MPI Forum, https://www.mpi-forum.org/ 
  • SystemC, https://www.accellera.org/community/systemc

Module M1842: GPU Architectures and Programming

Courses
Title Typ Hrs/wk CP
GPU Architectures and Programming (L3039) Lecture 2 3
GPU Architectures and Programming (L3040) Project-/problem-based Learning 4 3
Module Responsible Prof. Sohan Lal
Admission Requirements None
Recommended Previous Knowledge

An introductory module on computer engineering or computer architecture, and good programming skills in C/C++.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 96, Study Time in Lecture 84
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Computer Science: Specialisation I. Computer and Software Engineering: Elective Compulsory
Data Science: Specialisation II. Computer Science: Elective Compulsory
Data Science: Specialisation IV. Special Focus Area: Elective Compulsory
Information and Communication Systems: Specialisation Secure and Dependable IT Systems, Focus Software and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L3039: GPU Architectures and Programming
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Sohan Lal
Language EN
Cycle SoSe
Content

- Review of computer architecture basics - measuring performance, benchmarks, five-stage RISC pipeline, caches
- GPU basics - evolution of GPU computing, a high-level overview of a GPU architecture
- GPU programming with CUDA - program structure, CUDA threads organization, warp/thread-block scheduling
- GPU (micro) architecture - streaming multiprocessors, single instruction multiple threads (SIMT) core design, tensor/RT cores, mixed-precision support
- GPU memory hierarchy - banked register file and operand collectors, shared memory, GPU caches (differences w.r.t. CPU caches), global memory
- Branch and memory divergence - branch handling, stack-based reconvergence, memory coalescing, coalescer design
- Barriers and synchronization
- Temporal and spatial locality exploitation challenges in GPU caches
- Global memory- high throughput requirements, GDDR/HBM, memory bandwidth optimization techniques
- GPU research issues - performance bottlenecks, GPU power modeling, high-power consumption/energy efficiency, GPU security
- Application case study - deep learning
- Cycle-accurate simulators for GPUs

The learning in the lectures will be augmented by a semester-long problem-based project.

Literature
  • David B. Kirk, Wen-mei W. Hwu, Programming Massively Parallel Processors - A Hands-on Approach, Second Edition (Book)
  • David A. Patterson and John L. Hennessy, Computer Architecture: A Quantitative Approach, 5th Edition (Book)
Course L3040: GPU Architectures and Programming
Typ Project-/problem-based Learning
Hrs/wk 4
CP 3
Workload in Hours Independent Study Time 34, Study Time in Lecture 56
Lecturer Prof. Sohan Lal
Language EN
Cycle SoSe
Content

A semester-long problem-based project will augment the learning in the lectures. Several topics related to GPUs will be proposed. You are required to choose a topic and work on it. It is possible to work in groups. There will be (bi-) weekly meetings to discuss progress and problems. 

In addition to the semester-long project, there will be assignments to teach CUDA programming. 

Literature
  • David B. Kirk, Wen-mei W. Hwu, Programming Massively Parallel Processors - A Hands-on Approach, Second Edition (Book)
  • David A. Patterson and John L. Hennessy, Computer Architecture: A Quantitative Approach, 5th Edition (Book)

Specialization Microelectronics Complements

Students of the specialization Microelectronics Complements expand their knowledge towards the application of microelectronics and microsystems for medical use, the processing of digital signals, the development and design of highly complex integrated systems and networks for optical communication. Thus, they strengthen their knowledge by analyzing practical applications and link it up with the requirements of technical realizations.

Students have to choose lectures with a total of 18 credit points from the catalog of this specialization.

Module M0925: Digital Circuit Design

Courses
Title Typ Hrs/wk CP
Digital Circuit Design (L0698) Lecture 2 3
Advanced Digital Circuit Design (L0699) Lecture 2 3
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 40 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
International Management and Engineering: Specialisation II. Electrical Engineering: Elective Compulsory
Mechanical Engineering and Management: Specialisation Mechatronics: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Course L0698: Digital Circuit Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Volkhard Klinger
Language EN
Cycle WiSe
Content
Literature
Course L0699: Advanced Digital Circuit Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Volkhard Klinger
Language EN
Cycle SoSe
Content
Literature

Module M1611: Silicon Photonics

Courses
Title Typ Hrs/wk CP
Silicon Photonics (L2408) Lecture 2 4
Silicon Photonics (L2418) Project-/problem-based Learning 2 2
Module Responsible Dr. Timo Lipka
Admission Requirements None
Recommended Previous Knowledge

Basics in physics, optics, microsystem and semiconductor technology

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

The students know the fundamentals of silicon photonics and about the most important and commonly used materials and fabrication techniques. 

Students are able

  • to explain the basic principles of silicon photonics technology and to discuss theoretical and practical aspects
  • to describe photonic circuit devices and their working principle
  • to describe the manufacturing of silicon photonic devices and to discuss in details the relevant fabrication processes, process flows and the impact thereof on the fabrication of photonic integrated circuit components
Skills

Students are capable to

  • analyze the feasibility of integrated photonic circuit components
  • choose appropriate tools and methods to design them
  • develop process flows for the fabrication
Personal Competence
Social Competence

Students are able to prepare and perform their lab experiments in team work as well as to present and discuss the results in front of audience.

Autonomy

none

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L2408: Silicon Photonics
Typ Lecture
Hrs/wk 2
CP 4
Workload in Hours Independent Study Time 92, Study Time in Lecture 28
Lecturer Dr. Timo Lipka
Language EN
Cycle WiSe
Content
  • Introduction (historical view and trends in der Silicon Photonics)
  • Fabrication Technology (SOI-Wafer, Deposition, Sputtering and Evaporation, Epitaxy, MOCVD, Lithography)
  • Planar Waveguide Fundamentals
  • Optical Materials in silicon Photonics
  • Waveguide Types (Loss Mechanisms, Dispersion and Polarisation in Waveguides)
  • Coupling of Silicon Photonic Devices and Systems
  • Silicon Photonic Circuit Devices and Building Blocks (Passive Devices: Resonators, Interferometers, Mode Converters, Power Splitters,  Gratings, Polarizers and Rotators)
  • Material fundamentals and components for tuning and switching
  • Integration of active Devices (Laser, Detector, Modulators)
  • Photonics and Electronics Integration
  • Photonic Interconnects
  • Optical Multiplexing
  • Switch Fabrics and Routers
  • Silicon Photonics for Sensing
Literature
  • Graham T. Reed, Andrew Knights, Silicon Photonics - An Introduction, John Wiley & Sons Ltd (2004)
  • Clifford R. Pollocka and Michal Lipson, Integrated Photonics, Springer-Verlag (2003)
  • Sami Franssila, Introduction to microfabrication,  Chichester, West Sussex Wiley (2010)
  • Dominik G. Rabus, Integrated Ring Resonators: The Compendium,  in Springer Series in Optical Sciences (2007)  
Course L2418: Silicon Photonics
Typ Project-/problem-based Learning
Hrs/wk 2
CP 2
Workload in Hours Independent Study Time 32, Study Time in Lecture 28
Lecturer Dr. Timo Lipka
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M0769: EMC I: Coupling Mechanisms, Countermeasures and Test Procedures

Courses
Title Typ Hrs/wk CP
EMC I: Coupling Mechanisms, Countermeasures, and Test Procedures (L0743) Lecture 3 4
EMC I: Coupling Mechanisms, Countermeasures, and Test Procedures (L0744) Recitation Section (small) 1 1
EMC I: Coupling Mechanisms, Countermeasures, and Test Procedures (L0745) Practical Course 1 1
Module Responsible Prof. Christian Schuster
Admission Requirements None
Recommended Previous Knowledge

Fundamentals of Electrical Engineering

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students are able to explain the fundamental principles, inter-dependencies, and methods of Electromagnetic Compatibility of electric and electronic systems and to ensure Electromagnetic Compatibility of such systems. They are able to classify and explain the common interference sources and coupling mechanisms. They are capable of explaining the basic principles of shielding and filtering.  They are able of giving an overview over measurement and simulation methods for the characterization of Electromagnetic Compatibility in electrical engineering practice.

Skills

Students are able to apply a series of modeling methods for the Electromagnetic Compatibility of typical electric and electronic systems. They are able to determine the most important effects that these models are predicting in terms of Electromagnetic Compatibility. They can classify these effects and they can quantitatively analyze them. They are capable of deriving problem solving strategies from these predictions and they can adapt them to applications in electrical engineering practice. They can evaluate their problem solving strategies against each other.

Personal Competence
Social Competence

Students are able to work together on subject related tasks in small groups. They are able to present their results effectively in English, during laboratory work and exercises, e.g..

Autonomy

Students are capable to gather necessary information from the references provided and relate that information to the context of the lecture. They are able to make a connection between their knowledge obtained in this lecture with the content of other lectures (e.g. Theoretical Electrical Engineering and Communication Theory). They can communicate problems and solutions in the field of Electromagnetic Compatibility in english language.

Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Presentation
Examination Oral exam
Examination duration and scale 45 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Microwave Engineering, Optics, and Electromagnetic Compatibility: Elective Compulsory
Electrical Engineering: Specialisation Wireless and Sensor Technologies: Elective Compulsory
Mechatronics: Technical Complementary Course: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0743: EMC I: Coupling Mechanisms, Countermeasures, and Test Procedures
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Prof. Christian Schuster
Language DE/EN
Cycle SoSe
Content
  • Introduction to Electromagnetic Compatibility (EMC)
  • Interference sources in time an frequency domain
  • Coupling mechanisms
  • Transmission lines and coupling to electromagnetic fields
  • Shielding
  • Filters
  • EMC test procedures
Literature
  • C.R. Paul: "Introduction to Electromagnetic Compatibility", 2nd ed., (Wiley, New Jersey, 2006).
  • A.J. Schwab und W. Kürner: "Elektromagnetische Verträglichkeit", 6. Auflage, (Springer, Berlin 2010).
  • F.M. Tesche, M.V. Ianoz, and T. Karlsson: "EMC Analysis Methods and Computational Models", (Wiley, New York, 1997).
Course L0744: EMC I: Coupling Mechanisms, Countermeasures, and Test Procedures
Typ Recitation Section (small)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Christian Schuster
Language DE/EN
Cycle SoSe
Content

The exercise sessions serve to deepen the understanding of the concepts of the lecture.

Literature
  • C.R. Paul: "Introduction to Electromagnetic Compatibility", 2nd ed., (Wiley, New Jersey, 2006).
  • A.J. Schwab und W. Kürner: "Elektromagnetische Verträglichkeit", 6. Auflage, (Springer, Berlin 2010).
  • F.M. Tesche, M.V. Ianoz, and T. Karlsson: "EMC Analysis Methods and Computational Models", (Wiley, New York, 1997).
  • Scientific articles and papers
Course L0745: EMC I: Coupling Mechanisms, Countermeasures, and Test Procedures
Typ Practical Course
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Christian Schuster
Language DE/EN
Cycle SoSe
Content

Laboratory experiments serve to practically investigate the following EMC topics:

  • Shielding
  • Conducted EMC test procedures
  • The GTEM-cell as an environment for radiated EMC test
Literature Versuchsbeschreibungen und zugehörige Literatur werden innerhalb der Veranstaltung bereit gestellt.

Module M0919: Laboratory: Digital Circuit Design

Courses
Title Typ Hrs/wk CP
Laboratory: Digital Circuit Design (L0694) Project-/problem-based Learning 2 6
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge Basic knowledge of semiconductor devices and circuit design
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students can explain the structure and philosophy of the software framework for circuit design.
  • Students can determine all necessary input parameters for circuit simulation.
  • Students are able to explain the functions of the logic gates of their digital design.
  • Students can explain the algorithms of checking routines.
  • Students are able to select the appropriate transistor models for fast and accurate simulations.


Skills
  • Students can activate and execute all necessary checking routines for verification of proper circuit functionality.
  • Students are able to run the input desks for definition of their electronic circuits.
  • Students can define the building blocks of digital systems.


Personal Competence
Social Competence
  • Students are trained to work through complex circuits in teams.
  • Students are able to share their knowledge for efficient design work.
  • Students can help each other to understand all the details and options of the design software.
  • Students are aware of their limitations regarding circuit design, so they do not go ahead, but they involve experts when required.
  • Students can present their design approaches for easy checking by more experienced experts.


Autonomy
  • Students are able to realistically judge the status of their knowledge and to define actions for improvements when necessary.
  • Students can break down their design work in sub-tasks and can schedule the design work in a realistic way.
  • Students can handle the complex data structures of their design task and document it in consice but understandable way.
  • Students are able to judge the amount of work for a major design project.


Workload in Hours Independent Study Time 152, Study Time in Lecture 28
Credit points 6
Course achievement None
Examination Subject theoretical and practical work
Examination duration and scale 30 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0694: Laboratory: Digital Circuit Design
Typ Project-/problem-based Learning
Hrs/wk 2
CP 6
Workload in Hours Independent Study Time 152, Study Time in Lecture 28
Lecturer Prof. Matthias Kuhl
Language EN
Cycle SoSe
Content
  • Definition of specifications
  • Architecture studies
  • Digital simulation flow
  • Philosophy of standard cells
  • Placement and routing of standard cells
  • Layout generation
  • Design checking routines


Literature Handouts will be distributed

Module M0645: Fibre and Integrated Optics

Courses
Title Typ Hrs/wk CP
Fibre and Integrated Optics (L0363) Lecture 2 3
Fibre and Integrated Optics (Problem Solving Course) (L0365) Recitation Section (small) 1 1
Module Responsible Prof. Manfred Eich
Admission Requirements None
Recommended Previous Knowledge

Basic principles of electrodynamics and optics

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students can explain the fundamental mathematical and physical relations and technological basics of guided optical waves. They can describe integrated optical as well as fibre optical structures. They can give an overview on the applications of integrated optical components in optical signal processing.

Skills

Students can generate models and derive mathematical descriptions in relation to fibre optical and integrated optical wave propagation. They can derive approximative solutions and judge factors influential on the components' performance.


Personal Competence
Social Competence Students can jointly solve subject related problems in groups. They can present their results effectively within the framework of the problem solving course.
Autonomy

Students are capable to extract relevant information from the provided references and to relate this information to the content of the lecture. They can reflect their acquired level of expertise with the help of lecture accompanying measures such as exam typical exam questions. Students are able to connect their knowledge with that acquired from other lectures.

Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Credit points 4
Course achievement None
Examination Written exam
Examination duration and scale 60 minutes
Assignment for the Following Curricula Electrical Engineering: Specialisation Microwave Engineering, Optics, and Electromagnetic Compatibility: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0363: Fibre and Integrated Optics
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Dr. Hagen Renner
Language EN
Cycle SoSe
Content
  • Theory of optical waveguides
  • Coupling to and from waveguides
  • Losses
  • Linear and nonlinear dspersion
  • Components and technical applications
Literature

Bahaa E. A. Saleh, Malvin Carl Teich, Fundamentals of Photonics, Wiley 2007
Hunsperger, R.G., Integrated Optics: Theory and Technology, Springer, 2002
Agrawal, G.P.,Fiber-Optic Communication Systems, Wiley, 2002, ISBN 0471215716
Marcuse, D., Theory of Dielectric Optical Waveguides, Academic Press,1991, ISBN 0124709516
Tamir, T. (ed), Guided-Wave Optoelectronics, Springer, 1990

Course L0365: Fibre and Integrated Optics (Problem Solving Course)
Typ Recitation Section (small)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Dr. Hagen Renner
Language EN
Cycle SoSe
Content

See lecture Fibre and Integrated Optics

Literature

See lecture Fibre and Integrated Optics

Module M0643: Optoelectronics I - Wave Optics

Courses
Title Typ Hrs/wk CP
Optoelectronics I: Wave Optics (L0359) Lecture 2 3
Optoelectronics I: Wave Optics (Problem Solving Course) (L0361) Recitation Section (small) 1 1
Module Responsible Dr. Alexander Petrov
Admission Requirements None
Recommended Previous Knowledge

Basics in electrodynamics, calculus


Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students can explain the fundamental mathematical and physical relations of freely propagating optical waves.
They can give an overview on wave optical phenomena such as diffraction, reflection and refraction, etc. 
Students can describe waveoptics based components such as electrooptical modulators in an application oriented way.



Skills

Students can generate models and derive mathematical descriptions in relation to free optical wave propagation.
They can derive approximative solutions and judge factors influential on the components' performance.


Personal Competence
Social Competence

Students can jointly solve subject related problems in groups. They can present their results effectively within the framework of the problem solving course.


Autonomy

Students are capable to extract relevant information from the provided references and to relate this information to the content of the lecture. They can reflect their acquired level of expertise with the help of lecture accompanying measures such as exam typical exam questions. Students are able to connect their knowledge with that acquired from other lectures.


Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Credit points 4
Course achievement None
Examination Written exam
Examination duration and scale 60 minutes
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Electrical Engineering: Specialisation Microwave Engineering, Optics, and Electromagnetic Compatibility: Elective Compulsory
Materials Science: Specialisation Nano and Hybrid Materials: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Renewable Energies: Specialisation Solar Energy Systems: Elective Compulsory
Course L0359: Optoelectronics I: Wave Optics
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Dr. Alexander Petrov
Language EN
Cycle SoSe
Content
  • Introduction to optics
  • Electromagnetic theory of light
  • Interference
  • Coherence
  • Diffraction
  • Fourier optics
  • Polarisation and Crystal optics
  • Matrix formalism
  • Reflection and transmission
  • Complex refractive index
  • Dispersion
  • Modulation and switching of light
Literature

Bahaa E. A. Saleh, Malvin Carl Teich, Fundamentals of Photonics, Wiley 2007 
Hecht, E., Optics, Benjamin Cummings, 2001
Goodman, J.W. Statistical Optics, Wiley, 2000
Lauterborn, W., Kurz, T., Coherent Optics: Fundamentals and Applications, Springer, 2002

Course L0361: Optoelectronics I: Wave Optics (Problem Solving Course)
Typ Recitation Section (small)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Dr. Alexander Petrov
Language EN
Cycle SoSe
Content see lecture Optoelectronics 1 - Wave Optics
Literature

see lecture Optoelectronics 1 - Wave Optics

Module M1743: COSIMA (Competition in Microsystem Application)

Courses
Title Typ Hrs/wk CP
COSIMA (L3111) Project-/problem-based Learning 4 6
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge

Knowledge of microsystems operation and application.

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Consolidation of knowledge in the application of microsystems with practical relevance. Learning how an idea could turn into a product.

Skills

Realization of a concrete system by integrating hardware components and, under certain circumstances, software into a demonstrator. Development of a business plan for the innovative product. Convincing companies to sponsor the project. Presentation of the project in the form of an exposé.

Personal Competence
Social Competence

Students work in groups of 3 to 4 participants each to implement their project idea. The division of tasks takes place within the group, taking into account the complementary skills of the members.

Autonomy

The groups work on the project independently from the idea to the implementation. Supervision is provided through joint analysis of the problems and advice to the students.

Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Subject theoretical and practical work
Examination duration and scale 60 minutes
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Communication and Signal Processing: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Embedded Systems: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L3111: COSIMA
Typ Project-/problem-based Learning
Hrs/wk 4
CP 6
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Lecturer Prof. Hoc Khiem Trieu
Language EN
Cycle WiSe/SoSe
Content

Students learn the entire development process for a microsystem and its application, starting with the generation of ideas, through cost planning and implementation, to the acquisition of sponsorships and the creation of an exposé.

 
Literature

Module M0781: EMC II: Signal Integrity and Power Supply of Electronic Systems

Courses
Title Typ Hrs/wk CP
EMC II: Signal Integrity and Power Supply of Electronic Systems (L0770) Lecture 3 4
EMC II: Signal Integrity and Power Supply of Electronic Systems (L0771) Recitation Section (small) 1 1
EMC II: Signal Integrity and Power Supply of Electronic Systems (L0774) Practical Course 1 1
Module Responsible Prof. Christian Schuster
Admission Requirements None
Recommended Previous Knowledge

Fundamentals of electrical engineering


Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students are able to explain the fundamental principles, inter-dependencies, and methods of signal and power integrity of electronic systems. They are able to relate signal and power integrity to the context of interference-free design of such systems, i.e. their electromagnetic compatibility. They are capable of explaining the basic behavior of signals and power supply in typical packages and interconnects. They are able to propose and describe problem solving strategies for signal and power integrity issues. They are capable of giving an overview over measurement and simulation methods for characterization of signal and power integrity in electrical engineering practice.


Skills

Students are able to apply a series of modeling methods for characterization of electromagnetic field behavior in packages and interconnect structure of electronic systems. They are able to determine the most important effects that these models are predicting in terms of signal and power integrity. They can classify these effects and they can quantitatively analyze them. They are capable of deriving problem solving strategies from these predictions and they can adapt them to applications in electrical engineering practice. The can evaluate their problem solving strategies against each other.


Personal Competence
Social Competence

Students are able to work together on subject related tasks in small groups. They are able to present their results effectively in English (e.g. during CAD exercises).


Autonomy

Students are capable to gather necessary information from the references provided and relate that information to the context of the lecture. They are able to make a connection between their knowledge obtained in this lecture with the content of other lectures (e.g. theory of electromagnetic fields, communications, and semiconductor circuit design). They can communicate problems and solutions in the field of signal integrity and power supply of interconnect and packages in English.


Workload in Hours Independent Study Time 110, Study Time in Lecture 70
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes None Presentation
Examination Oral exam
Examination duration and scale 45 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Microwave Engineering, Optics, and Electromagnetic Compatibility: Elective Compulsory
Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Electrical Engineering: Specialisation Wireless and Sensor Technologies: Elective Compulsory
Mechatronics: Technical Complementary Course: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0770: EMC II: Signal Integrity and Power Supply of Electronic Systems
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Prof. Christian Schuster
Language DE/EN
Cycle WiSe
Content

- The role of packages and interconnects in electronic systems

- Components of packages and interconnects in electronic systems

- Main goals and concepts of signal and power integrity of electronic systems

- Repeat of relevant concepts from the theory electromagnetic fields

- Properties of digital signals and systems

- Design and characterization of signal integrity

- Design and characterization of power supply

- Techniques and devices for measurements in time- and frequency-domain

- CAD tools for electrical analysis and design of packages and interconnects

- Connection to overall electromagnetic compatibility of electronic systems


Literature

- J. Franz, "EMV: Störungssicherer Aufbau elektronischer Schaltungen", Springer (2012)

- R. Tummala, "Fundamentals of Microsystems Packaging", McGraw-Hill (2001)

- S. Ramo, J. Whinnery, T. Van Duzer, "Fields and Waves in Communication Electronics", Wiley (1994)

- S. Thierauf, "Understanding Signal Integrity", Artech House (2010)

- M. Swaminathan, A. Engin, "Power Integrity Modeling and Design for Semiconductors and Systems", Prentice-Hall (2007)


Course L0771: EMC II: Signal Integrity and Power Supply of Electronic Systems
Typ Recitation Section (small)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Christian Schuster
Language DE/EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course
Course L0774: EMC II: Signal Integrity and Power Supply of Electronic Systems
Typ Practical Course
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Prof. Christian Schuster
Language DE/EN
Cycle WiSe
Content

- The role of packages and interconnects in electronic systems

- Components of packages and interconnects in electronic systems

- Main goals and concepts of signal and power integrity of electronic systems

- Repeat of relevant concepts from the theory electromagnetic fields

- Properties of digital signals and systems

- Design and characterization of signal integrity

- Design and characterization of power supply

- Techniques and devices for measurements in time- and frequency-domain

- CAD tools for electrical analysis and design of packages and interconnects

- Connection to overall electromagnetic compatibility of electronic systems


Literature

- J. Franz, "EMV: Störungssicherer Aufbau elektronischer Schaltungen", Springer (2012)

- R. Tummala, "Fundamentals of Microsystems Packaging", McGraw-Hill (2001)

- S. Ramo, J. Whinnery, T. Van Duzer, "Fields and Waves in Communication Electronics", Wiley (1994)

- S. Thierauf, "Understanding Signal Integrity", Artech House (2010)

- M. Swaminathan, A. Engin, "Power Integrity Modeling and Design for Semiconductors and Systems", Prentice-Hall (2007)


Module M0913: Mixed-signal Circuit Design

Courses
Title Typ Hrs/wk CP
Mixed-signal Circuit Design (L0764) Lecture 2 3
Mixed-signal Circuit Design (L1063) Project-/problem-based Learning 2 3
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge Advanced knowledge of analog or digital MOS devices and circuits
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students can explain the descriptive parameters of mixed-signal systems
  • Students can explain various architectures of analog-to-digital and digital-to-analog converters
  • Students are able to explain the fundamental limitations of different analog-to-digital and digital-to-analog converters
Skills
  • Students can derive the fundamental limitations of different analog-to-digital and digital-to-analog converters
  • Students can select the most suitable architecture for a specific mixed-signal task
  • Students can describe complex mixed-signal systems by their functional blocks.
  • Students can calculate the specifications of mixed-signal circuits
Personal Competence
Social Competence
  • Students can team up with one or several partners who may have different professional backgrounds
  • Students are able to work by their own or in small groups for solving problems and answer scientific questions.


Autonomy
  • Students are able to assess their knowledge in a realistic manner.
  • Students are able to draw scenarios for estimation of the impact of an increase of data vs. an increase of energy on the future lifestyle of the society.


Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement
Compulsory Bonus Form Description
Yes 5 % Subject theoretical and practical work
Examination Written exam
Examination duration and scale 90 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0764: Mixed-signal Circuit Design
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Matthias Kuhl
Language EN
Cycle WiSe
Content
  • Differences between analog and digital filtering of electrical signals
  • Quantization error and its consideration in electrical circuits
  • Architectures of state-of-the-art digital-to-analog converters
  • Architectures of state-of-the-art analog-to-digital converters
  • Differentiation between Nyquist and oversampling converters
  • noise in ADCs and DACs 
Literature
  • R. J. Baker, „CMOS-Circuit Design, Layout, and Simulation“, Wiley & Sons, IEEE Press, 2010 
  • B. Razavi,"Design of Analog CMOS Integrated Circuits", McGraw-Hill Education Ltd, 2000
Course L1063: Mixed-signal Circuit Design
Typ Project-/problem-based Learning
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Prof. Matthias Kuhl
Language EN
Cycle WiSe
Content See interlocking course
Literature See interlocking course

Module M1688: Selected Aspects of Microelectronics and Microsystems

Courses
Title Typ Hrs/wk CP
Selected Aspects of Microelectronics and Microsystems (L2678) Lecture 3 4
Selected Aspects of Microelectronics and Microsystems (L2679) Recitation Section (small) 1 2
Module Responsible Prof. Hoc Khiem Trieu
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
Skills
Personal Competence
Social Competence
Autonomy
Workload in Hours Independent Study Time 124, Study Time in Lecture 56
Credit points 6
Course achievement None
Examination Oral exam
Examination duration and scale 30 min
Assignment for the Following Curricula Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L2678: Selected Aspects of Microelectronics and Microsystems
Typ Lecture
Hrs/wk 3
CP 4
Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Lecturer Dozenten des SD E
Language EN
Cycle WiSe/SoSe
Content
Literature
Course L2679: Selected Aspects of Microelectronics and Microsystems
Typ Recitation Section (small)
Hrs/wk 1
CP 2
Workload in Hours Independent Study Time 46, Study Time in Lecture 14
Lecturer Dozenten des SD E
Language EN
Cycle WiSe/SoSe
Content See interlocking course
Literature See interlocking course

Module M1589: Laboratory: Analog Circuit Design

Courses
Title Typ Hrs/wk CP
Laboratory: Analog Circuit Design (L0692) Project-/problem-based Learning 2 6
Module Responsible NN
Admission Requirements None
Recommended Previous Knowledge

Basic knowledge of semiconductor devices and circuit design

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge
  • Students can explain the structure and philosophy of the software framework for circuit design.
  • Students can determine all necessary input parameters for circuit simulation.
  • Students know the basics physics of the analog behavior.
  • Students can explain the algorithms of circuit verification.
  • Students are able to select the appropriate transistor models for fast and accurate simulations.

Skills
  • Students can activate and execute all necessary checking routines for verification of proper circuit functionality.
  • Students can define the specifications of the electronic circuits to be designed.
  • Students can optimize the electronic circuits for low-noise and low-power.
  • Students can develop analog circuits for specific applications. 



Personal Competence
Social Competence
  • Students are trained to work through complex circuits in teams.
  • Students are able to share their knowledge for efficient design work.
  • Students can help each other to understand all the details and options of the design software.
  • Students are aware of their limitations regarding circuit design, so they do not go ahead, but they involve experts when required.
  • Students can present their design approaches for easy checking by more experienced experts.



Autonomy
  • Students are able to realistically judge the status of their knowledge and to define actions for improvements when necessary.
  • Students can break down their design work in sub-tasks and can schedule the design work in a realistic way.
  • Students can handle the complex data structures of their design task and document it in consice but understandable way.
  • Students are able to judge the amount of work for a major design project.



Workload in Hours Independent Study Time 152, Study Time in Lecture 28
Credit points 6
Course achievement None
Examination Subject theoretical and practical work
Examination duration and scale 30 min
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0692: Laboratory: Analog Circuit Design
Typ Project-/problem-based Learning
Hrs/wk 2
CP 6
Workload in Hours Independent Study Time 152, Study Time in Lecture 28
Lecturer Prof. Matthias Kuhl, Weitere Mitarbeiter
Language EN
Cycle WiSe
Content
  • Input desk for circuits
  • Algorithms for simulation
  • MOS transistor model
  • Simulation of analog circuits
  • Placement and routing     
  • Generation of layouts
  • Design checking routines
  • Postlayout simulations



Literature Handouts to be distributed

Module M0644: Optoelectronics II - Quantum Optics

Courses
Title Typ Hrs/wk CP
Optoelectronics II: Quantum Optics (L0360) Lecture 2 3
Optoelectronics II: Quantum Optics (Problem Solving Course) (L0362) Recitation Section (small) 1 1
Module Responsible Dr. Alexander Petrov
Admission Requirements None
Recommended Previous Knowledge

Basic principles of electrodynamics, optics and quantum mechanics

Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Students can explain the fundamental mathematical and physical relations of quantum optical phenomena such as absorption, stimulated and spontanous emission. They can describe material properties as well as technical solutions. They can give an overview on quantum optical components in technical applications.

Skills

Students can generate models and derive mathematical descriptions in relation to quantum optical phenomena and processes. They can derive approximative solutions and judge factors influential on the components' performance.


Personal Competence
Social Competence

Students can jointly solve subject related problems in groups. They can present their results effectively within the framework of the problem solving course.


Autonomy

Students are capable to extract relevant information from the provided references and to relate this information to the content of the lecture. They can reflect their acquired level of expertise with the help of lecture accompanying measures such as exam typical exam questions. Students are able to connect their knowledge with that acquired from other lectures.


Workload in Hours Independent Study Time 78, Study Time in Lecture 42
Credit points 4
Course achievement None
Examination Written exam
Examination duration and scale 60 minutes
Assignment for the Following Curricula Electrical Engineering: Specialisation Nanoelectronics and Microsystems Technology: Elective Compulsory
Electrical Engineering: Specialisation Microwave Engineering, Optics, and Electromagnetic Compatibility: Elective Compulsory
Materials Science: Specialisation Nano and Hybrid Materials: Elective Compulsory
Microelectronics and Microsystems: Specialisation Microelectronics Complements: Elective Compulsory
Course L0360: Optoelectronics II: Quantum Optics
Typ Lecture
Hrs/wk 2
CP 3
Workload in Hours Independent Study Time 62, Study Time in Lecture 28
Lecturer Dr. Alexander Petrov
Language EN
Cycle WiSe
Content
  • Generation of light
  • Photons
  • Thermal and nonthermal light
  • Laser amplifier
  • Noise
  • Optical resonators
  • Spectral properties of laser light
  • CW-lasers (gas, solid state, semiconductor)
  • Pulsed lasers
Literature

Bahaa E. A. Saleh, Malvin Carl Teich, Fundamentals of Photonics, Wiley 2007
Demtröder, W., Laser Spectroscopy: Basic Concepts and Instrumentation, Springer, 2002
Kasap, S.O., Optoelectronics and Photonics: Principles and Practices, Prentice Hall, 2001
Yariv, A., Quantum Electronics, Wiley, 1988
Wilson, J., Hawkes, J., Optoelectronics: An Introduction, Prentice Hall, 1997, ISBN: 013103961X
Siegman, A.E., Lasers, University Science Books, 1986

Course L0362: Optoelectronics II: Quantum Optics (Problem Solving Course)
Typ Recitation Section (small)
Hrs/wk 1
CP 1
Workload in Hours Independent Study Time 16, Study Time in Lecture 14
Lecturer Dr. Alexander Petrov
Language EN
Cycle WiSe
Content see lecture Optoelectronics 1 - Wave Optics
Literature

see lecture Optoelectronics 1 - Wave Optics

Thesis

Module M1801: Master thesis (dual study program)

Courses
Title Typ Hrs/wk CP
Module Responsible Professoren der TUHH
Admission Requirements None
Recommended Previous Knowledge
Educational Objectives After taking part successfully, students have reached the following learning results
Professional Competence
Knowledge

Dual students ...

  • ... use the specialised knowledge (facts, theories and methods) from their field of study and the acquired professional knowledge confidently to deal with technical and practical professional issues.
  • ... can explain the relevant approaches and terminologies in depth in one or more of their subject’s specialist areas, describe current developments and take a critical stance. 
  • ... formulate their own research assignment to tackle a professional problem and contextualise it within their subject area. They ascertain the current state of research and critically assess it.
Skills

Dual students ...

  • ... can select suitable methods for the respective subject-related professional problem, apply them and develop them further as required. 
  • ... assess knowledge and methods acquired during their studies (including practical phases) and apply their expertise to complex and/or incompletely defined problems in a solution- and application-oriented manner.
  • ... acquire new academic knowledge in their subject area and critically evaluate it.
Personal Competence
Social Competence

Dual students ...

  • ... can present a professional problem in the form of an academic question in a structured, comprehensible and factually correct manner, both in writing and orally, for a specialist audience and for professional stakeholders. 
  • ... answer questions as part of a professional discussion in an expert, appropriate manner. They represent their own points of view and assessments convincingly.
Autonomy

Dual students ...

  • ... can structure their own project into work packages, work through them at an academic level and reflect on them with regard to feasible courses of action for professional practice.  
  • ... work in-depth in a partially unknown area within the discipline and acquire the information required to do so.
  • ... apply the techniques of academic work comprehensively in their own research work when dealing with an operational problem and question.
Workload in Hours Independent Study Time 900, Study Time in Lecture 0
Credit points 30
Course achievement None
Examination Thesis
Examination duration and scale According to General Regulations
Assignment for the Following Curricula Civil Engineering: Thesis: Compulsory
Bioprocess Engineering: Thesis: Compulsory
Chemical and Bioprocess Engineering: Thesis: Compulsory
Computer Science: Thesis: Compulsory
Data Science: Thesis: Compulsory
Electrical Engineering: Thesis: Compulsory
Energy Systems: Thesis: Compulsory
Environmental Engineering: Thesis: Compulsory
Aircraft Systems Engineering: Thesis: Compulsory
Computer Science in Engineering: Thesis: Compulsory
Information and Communication Systems: Thesis: Compulsory
International Management and Engineering: Thesis: Compulsory
Logistics, Infrastructure and Mobility: Thesis: Compulsory
Aeronautics: Thesis: Compulsory
Materials Science and Engineering: Thesis: Compulsory
Materials Science: Thesis: Compulsory
Mechanical Engineering and Management: Thesis: Compulsory
Mechatronics: Thesis: Compulsory
Biomedical Engineering: Thesis: Compulsory
Microelectronics and Microsystems: Thesis: Compulsory
Product Development, Materials and Production: Thesis: Compulsory
Renewable Energies: Thesis: Compulsory
Naval Architecture and Ocean Engineering: Thesis: Compulsory
Theoretical Mechanical Engineering: Thesis: Compulsory
Process Engineering: Thesis: Compulsory
Water and Environmental Engineering: Thesis: Compulsory