Göran Andersson: Catalogue data in Autumn Semester 2012 |
| Name | Prof. em. Dr. Göran Andersson |
| Field | Elektrische Energiesysteme und -prozesse |
| Address | Inst. f. El. Energieübertragung ETH Zürich, ETL G 15.2 Physikstrasse 3 8092 Zürich SWITZERLAND |
| andersson@eeh.ee.ethz.ch | |
| Department | Information Technology and Electrical Engineering |
| Relationship | Professor emeritus |
| Number | Title | ECTS | Hours | Lecturers | |
|---|---|---|---|---|---|
| 115-0373-00L | Week 17: Technical Infrastructure  | 2 credits | 1G | G. Andersson, F. Günther, H. Leibundgut, M. Maurer, to be announced | |
| Abstract | History of spatial planning; current issues in spatial development | ||||
| Learning objective | Knowledge of the history of spatial planning; Knowledge of current issues of spatial development | ||||
| Content | Knowledge of and discussion of the history of spatial planning, knowledge of and discusion of current issues of spatial development | ||||
| 151-0906-00L | Frontiers in Energy Research | 2 credits | 2S | M. Mazzotti, R. S. Abhari, G. Andersson, J. Carmeliet, M. Filippini | |
| Abstract | PhD students at ETH Zurich working in the broad area of energy present their research to their colleagues, to their advisors and to the scientific community. | ||||
| Learning objective | Knowledge of advanced research in the area of energy. | ||||
| Content | PhD students at ETH Zurich working in the broad area of energy present their research to their colleagues, to their advisors and to the scientific community. Every week there are two presentations, each structured as follows: 15 min introduction to the research topic, 15 min presentation of the results, 15 min discussion with the audience. | ||||
| Lecture notes | Slides will be distributed. | ||||
| 227-0076-00L | Electrical Engineering II | 4 credits | 2V + 1U + 1K | G. Andersson | |
| Abstract | Signals and systems in the time and frequency domain, principle of operation and design of basic analog and digital circuits, analog-digital conversion. Basic power electronic circuits, design of magnetic components and concept of force and torque generation, electromechanical energy conversion, principle of operation and characteristics of stationary and selected rotating electrical machines. | ||||
| Learning objective | see above | ||||
| Content | Beschreibung von Signalen und Systemen im Zeit- und Frequenzbereich, Funktion grundlegender analoger und digitaler Schaltungen, Analog-Digital-Wandler. Grundlagen leistungselektronischer Konverter, Berechnung magnetischer Kreise, Grundprinzip der Kraft- und Drehmomentbildung, elektromechanische Energiewandlung, Funktionsprinzip ruhender und ausgewählter rotierender elektrischer Maschinen. | ||||
| 227-0122-00L | Electric Power Systems | 6 credits | 4G | G. Andersson, C. Franck | |
| Abstract | Introduction to theory and technology of electric power systems. | ||||
| Learning objective | At the end of this lesson, the student will be able to: describe the structure of electric power systems, name the most important components and describe what they are needed for, apply models for transformers and lines, explain the technology of power lines and switchgear, calculate stationary power flows and other basic parameters in simple power systems. | ||||
| Content | Structure of electric power systems, transformer and power line models, analysis of and power flow calculation in basic systems, symmetrical and unsymmetrical three-phase systems, transient current and voltage processes, technology and principle of electric power systems. | ||||
| Lecture notes | Lecture script in English, exercises and sample solutions, translation of important vocabulary: english-german. | ||||
| 227-0526-00L | Power System Analysis | 6 credits | 4G | G. Andersson | |
| Abstract | The goal of this course is understanding the stationary and dynamic problems in electrical power systems. The course includes the development of stationary models of the electrical network, their mathematical representation and special characteristics and solution methods of large linear and non-linear systems of equations related to electrical power networks. | ||||
| Learning objective | The goal of this course is understanding the stationary and dynamic problems in electrical power systems. The course includes the development of stationary models of the electrical network, their mathematical representation and special characteristics and solution methods of large linear and non-linear systems of equations related to electrical power networks. | ||||
| Content | The electrical power transmission system, the energy management system, requirements of the electrical power transmission (demand oriented, operationally, economically), network planning and network operation, models of N-port network components (line, cables, shunts, transformers), the p.u. computation, computer oriented network models, linear networks (solution methods - direct, iterative), algorithms for the solution of non-linear sets of equations, derived from the electrical power system (Newton-Raphson), power flow computation (problem definition, solution methods), three phase short-circuit computation, application of power flow algorithms. Introduction to power system stability. | ||||
| Lecture notes | Lecture notes. Course is supported by WWW-teaching system. | ||||
| 227-0940-00L | Current Problems of Power Engineering | 0 credits | 1K | G. Andersson, C. Franck | |
| Abstract | Current topics in current problems in Power Engineering presented mostly by external speakers from academia and industry. | ||||
| Learning objective | see above | ||||