Computer based Design of Microelectronic Circuits

• sketch out the process and targets of the physical design,
• explain predetermined, well-known algorithms,
• combine partial algorithm sections in a way that they form a complete process, compare implementations of given algorithms,
• create implementations of algorithms,
• assess in qualitative terms the results of placement and wiring,
• classify and explain simulation procedures

• Gaining deeper insight into the mathematical and natural science areas
• Gaining a deeper knowledge about the specific electrical fundamentals
• Acquiring enhanced and applied subject-specific basics
• Identifying and classifying complex electro-technical and interdisciplinary tasks
• Being confident in the ability to apply and evaluate analytical methods
• Being able to create and evaluate solving methods independently
• Familiarising oneself with new areas of knowledge, running searches and assessing the results
• Gaining important and profound experience in the area of practical technical skills and engineering activities
• Working and researching in national and international contexts

Based on the theoretical foundations, methods and algorithms, which provide the basis for current industrial CAD systems for the integrated circuit design (chip design), are discussed in a way following the corresponding design process.

This serves to promote a deeper understanding of their functionality and thus enables an efficient and targeted use of these tools. Among other things, this course deals with optimisation methods, algorithms of the physical design (partitioning, placement and wiring) as well as simulation algorithms.

• Sabih H. Gerez: Algorithms for VLSI Design Automation, John Wiley & Sons, 1st edition, 1998
• Naveed A. Sherwani: Algorithms for VLSI Physical Design Automation, Springer Verlag; 3rd edition. 1999
• Michael J. S. Smith: Application-Specific Integrated Circuits, Addison-Wesley Longman, 1997
• Jens Lienig: Layout Synthesis of Electronic Circuits, Springer Verlag, 1st edition, 2006
• Reinhard Diestel: Graph Theory, Springer, Berlin; 3rd edition, 2006
• More reference literature is going to be recommended in the course or on the homepage of the department.
• Goble, W. M., Control systems safety evaluation and reliability, 3rd ed. ISA resources for measurement and control series. Research Triangle Park, N.C: International Society of Automation, 2010.
• Goble, W. M. and Goble, W. M. E. c. s. r., Control systems safety evaluation and reliability, 2nd ed. Resources for measurement and control series. Research Triangle Park, N.C. ISA, 1998.
• Birolini, A., Reliability of devices and systems . Springer eBook Collection Computer Science and Engineering. Berlin, Heidelberg: Springer Berlin Heidelberg, 1997.
• Schnieder, L. and Hosse, R. S., Guide Safety of the Intended Functionality: refining the safety of the intended function on the way to autonomous driving /  Lars Schnieder, René S. Hosse , Second edition. essentials. Wiesbaden: Springer Vieweg, 2020.
• Gregorius, C., ed, Functional safety of machinery: practical application of DIN EN ISO 13849-1, 1st edition. Beuth Praxis Maschinenbau. Berlin: Beuth Verlag, 2016. ebookcentral.proquest.com/lib/kxp/detail.action.
• Montenegro, S., Safe and fault-tolerant control systems: Development of safety-related systems. Munich, Vienna: Carl Hanser Verlag, 1999.
• Kumamoto, H. and Henley, E. J., Probabilistic risk assessment and management for engineers and scientists, 2nd ed. New York: IEEE Press, 1996.