Search result: Catalogue data in Spring Semester 2017
Electrical Engineering and Information Technology Bachelor | ||||||
Bachelor Studies (Programme Regulations 2016) | ||||||
2. Semester | ||||||
First Year Examinations | ||||||
First Year Examination Block A Offered in the autumn semester. | ||||||
First Year Examination Block B | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
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401-0232-10L | Analysis II | O | 8 credits | 4V + 2U | D. A. Salamon | |
Abstract | Introduction to differential calculus and integration in several variables. | |||||
Objective | ||||||
Content | Differentiation in several variables, maxima and minima, the implicit function theorem, integration in several variables, integration over submanifolds, the theorems of Gauss and Stokes. | |||||
Lecture notes | Konrad Koenigsberger, Analysis II. Christian Blatter: Ingenieur-Analysis (Kapitel 4-6). | |||||
252-0836-00L | Computer Science II | O | 4 credits | 2V + 1U | F. Mattern | |
Abstract | Introduction to basic problem solving methods, algorithms, and data structures. Topics: divide and conquer, recursion, sorting algorithms, backtracking, game tree search, data structures (lists, stacks, queues, binary trees), discrete simulation, concurrency. In the assignments and exercises, the programming language Java is used. | |||||
Objective | Introduction to the general methods of computer science for electrical engineers. Also provides basic skills for advanced exercises and projects later in the electrical engineering program. | |||||
Content | Part II of the lecture concentrates on the most common problem solving skills, algorithms, and data structures. It also teaches fundamental concepts and mechanisms of structured programming. Furthermore, working with formal systems, the necessity of abstraction, and the importance of modeling in computer science will be motivated. The emphasis of the lecture is on practical concepts of computer science. Specific topics are: complexity of algorithms, divide and conquer, recursion, algorithms for sorting, backtracking, game tree search, data structures (lists, stacks, queues, binary trees), discrete simulation, and concurrency. For the assignments and exercises, the programming language Java is used. Here, also modularization, abstraction, encapsulation, and object orientation will be considered. Occasionally, short remarks on the historical context of relevant concepts are given. In the practice groups, students program an automatic player for the game "Reversi"; at the end of the semester a tournament will take place. | |||||
Lecture notes | Copies of slides, extended with bonus slides that give hints to advanced concepts and present the historical context of selected concepts. | |||||
Literature | Textbook: Mark Allan Weiss: Data Structures and Problem Solving Using Java, Addison Wesley. | |||||
Prerequisites / Notice | Prerequisite: Part 1 of the course. | |||||
401-0302-10L | Complex Analysis | O | 4 credits | 3V + 1U | T. H. Willwacher | |
Abstract | Basics of complex analysis in theory and applications, in particular the global properties of analytic functions. Introduction to the integral transforms and description of some applications | |||||
Objective | Erwerb von einigen grundlegenden Werkzeuge der komplexen Analysis. | |||||
Content | Examples of analytic functions, Cauchy‘s theorem, Taylor and Laurent series, singularities of analytic functions, residues. Fourier series and Fourier integral, Laplace transform. | |||||
Literature | M. Ablowitz, A. Fokas: "Complex variables: introduction and applications", Cambridge Text in Applied Mathematics, Cambridge University Press 1997 E. Kreyszig: "Advanced Engineering Analysis", Wiley 1999 J. Brown, R. Churchill: "Complex Analysis and Applications", McGraw-Hill 1995 J. Marsden, M. Hoffman: "Basic complex analysis", W. H. Freeman 1999 P. P. G. Dyke: "An Introduction to Laplace Transforms and Fourier Series", Springer 2004 Ch. Blatter: "Komplexe Analysis, Fourier- und Laplace-Transformation", Autographie A. Oppenheim, A. Willsky: "Signals & Systems", Prentice Hall 1997 M. Spiegel: "Laplace Transforms", Schaum's Outlines, Mc Graw Hill | |||||
Prerequisites / Notice | Prerequisites: Analysis I and II | |||||
227-0002-00L | Networks and Circuits II | O | 8 credits | 4V + 2U | J. W. Kolar | |
Abstract | Introduction to AC circuits analysis, Fourier analysis, frequency and time domain, step response of electric circuits, Fourier and Laplace transform, frequency response of electric networks, two-port systems, bipolar and field-effect transistor, basic transistor circuits, push-pull emitter follower and differential amplifier, operational amplifier, basic and advanced operational amplifier circuits | |||||
Objective | The lecture is aiming to make students familiar with basis methods of AC circuits analysis, the Fourier analysis of non-sinusoidal periodic signals, i.e. the relations of frequency and time domain, the calculation of the step response and transfer function of linear networks using Fourier- and Laplace transform and the analysis and design of transistor and operational amplifier circuits. | |||||
Content | Introduction to AC circuits analysis, Fourier analysis, frequency and time domain, step response of electric circuits, Fourier and Laplace transform, frequency response of electric networks, two-port systems, bipolar and field-effect transistor, basic transistor circuits, push-pull emitter follower and differential amplifier, operational amplifier, basic and advanced operational amplifier circuits | |||||
Lecture notes | Specified literature and lectures slides | |||||
Literature | Grundlagen der Elektrotechnik Bd. 2 - Periodische und nicht periodische Signalformen M. Albach Pearson Studium Ausgabe 2005 (ISBN 9783827371089) oder Ausgabe 2011 (ISBN 9783868940800) Bd. 3 - Netzwerke L.-P. Schmidt et al. Pearson Studium Ausgabe 2006 (ISBN 9783827371072) Microelectronic Circuits Adel S. Sedra, Kenneth C. Smith 5th or 6th Edition (Vorlesung entsprechend 5th Edition) ISBN 0-19-514252-7 Oxford University Press, 2004 | |||||
402-0052-00L | Physics I: Waves and Thermodynamics | O | 4 credits | 2V + 2U | A. Imamoglu | |
Abstract | Physics I is an introduction to continuum mechanics, wave phenomena, and fundamental concepts of thermodynamics. | |||||
Objective | After completing this course, students should be able to construct and apply simple models of dynamics in non-rigid materials. Students should also be able to identify and relate basic thermodynamic quantities in equilibrium systems given realistic constraints. | |||||
Content | The lecture will discuss the following concepts: Waves - One dimensional wave equation - Plane waves, spherical waves in 2 and 3 dimensions - Elastic waves, sound velocity - Stationary waves, resonances - Propagation: interference and diffraction - Doppler effect Thermodynamics - Kinetic theory of gases, perfect gases - Conservation of energy, first principle - Second principle, thermal cycles - Entropy, thermodynamical and statistical interpretation - Thermal radiation and heat transfer. | |||||
Lecture notes | The lecture notes will be distributed via the Moodle platform. | |||||
Literature | P. A. Tipler and G. Mosca, "Physics for Scientists and Engineers" (6th edition) Chapters 14-20. | |||||
Prerequisites / Notice | Technical Mechanics, Analysis | |||||
First Year Compulsory Laboratory Courses | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
227-0004-10L | Networks and Circuits Laboratory Only for Electrical Engineering and Information Technology BSc. | O | 1 credit | 1P | J. W. Kolar | |
Abstract | Concepts from the lectures "Networks and Circuits I and II" explored through experiments, with inductive energy transmission systems (equivalent circuit parameters, transmission characteristics, resonance compensation, high-voltage generation) and photovoltaics (solar module characteristics, power flow adjustment with DC-DC converters, electro-mechanical energy conversion) used as examples. | |||||
Objective | The core topics of the course "Networks and Circuits I and II" are reviewed in practice, through experiments, in a modern laboratory environment. Furthermore, through the illustrative experiments in the fields of inductive power transfer and photovoltaics, a methodical experimental approach, the use of modern measurement equipment, and proper documentation skills are all learned. | |||||
Content | The "Networks and Circuits Laboratory" covers core topics presented in the lectures and exercises of the courses "Networks and Circuits I and II" through experiments. These topics are demonstrated in practice within the context of selected real-world industrial applications: - Inductive power transfer (topics: parameters of equivalent circuits, transmission characteristics, resonance compensation, and high-voltage generation); and - Photovoltaics (topics: characteristics and power performance of a solar module, power flow and/or operating point adjustment with power electronic converters, electro-mechanical energy conversion). In each experiment, after measuring and observing components and subsystems of the above, the structuring and overall function of the system is discussed, in order to promote higher-level abstract reasoning and synthesis skills in addition to analysis skills. Further important goals of this Laboratory Course are familiarisation with modern measuring equipment, and highlighting the importance of planning, executing, and documenting experiments and measurements in a thorough and methodical fashion. | |||||
Lecture notes | Instruction manual | |||||
Literature | Lectures documents Networks and Circuits I and II | |||||
Prerequisites / Notice | Networks and Circuits I and II |
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