Electronics and Microelectronics
- Safety in Electrical Engineering for a bachelor´s degree (BEEZB)
Basic health and occupational safety regulations (BEEZZ)
- Department of Microelectronics
Semiconductors fundamentals, PN junction. Bipolar transistor, MOSFET structure. Fundamentals of Integrated systems processing technologies. CMOS technology, layout design, design rules. Analogue CMOS integrated circuits blocks, AD and DA convertors. Memory structures. Micro-electro-mechanical systems. Optoelectronics devices.
- Syllabus of lectures:
1.Microelectronics and integrated circuit design history, roadmaps, Moor?s laws, IO design methodologies, current trends
2.Semiconductors fundamentals - types and properties, PN junction, metal-semiconductor junction, diode.
3.Bipolar transistor, MOSFET - architecture, working principle, substitutive models.
4.Fabrication process of semiconductor devices and integrated circuits.
5.CMOS fabrication process, layout, topological masks, isolation methods, CMOS process variances, interconnection technology.
6.Advanced IC technologies, advanced sub-micron technologies, SOI, RF IC.
7.Software tools for IC design, analogue, digital and mix-signal integrated systems design methodologies, design abstraction levels, application specific integrated systems, design economical aspects.
8.Layout design, design rules, parasitics, parasitics extraction. Interconnection design methods, delay calculation, time analysis, crosstalk and interference problems.
9.CMOS logic gate parameters, gate power dissipation, delay, bus drivers.
10.Fundamental blocks of analogue CMOS ICs, operational amplifier.
11.Integrated AD and DA converters - types, speed and power dissipation.
12.Integrated memories structures - DRAM, SRAM, EEPROM, Flash.
13.Design of Micro-electro-mechanical systems (MEMS), technologies, application.
14.Optoelectronics fundamentals, photodiode, phototransistor, laser, LED - parameters, applications.
- Syllabus of tutorials:
1.Introduction to CADENCE design tools.
2.CMOS design kits and libraries, simulator Spectre - analysis types. Models for active and passive devices.
3.Design, simulation and testing of amplifier stage.
4.Logic gates static and dynamic parameters and characteristics of CMOS transmition gate.
5.Analog design, tests and testbenches .
6.Influence of processing variances, Corner analysis, Monte Carlo analysis.
7.Layout of analogue IC.
8.Layout of analogue IC.
9.Design rule check, parasitic extraction.
10.Digital IC design flow, simulations.
11.Digital design synthesis and verification.
14.Work presentation, final assessment
- Study Objective:
- Study materials:
P. Gray, P Hurst, S. Lewis, R. Mayer: "Analysis and Design of Analog
Integrated Circuits", John Wiley and Sons, 2000
- Further information:
- No time-table has been prepared for this course
- The course is a part of the following study plans:
- Cybernetics and Robotics - Robotics (elective course)
- Cybernetics and Robotics - Senzors and Instrumention (elective course)
- Cybernetics and Robotics - Systems and Control (elective course)
- Electrical Engineering, Power Engineering and Management - Applied Electrical Engineering (elective course)
- Electrical Engineering, Power Engineering and Management - Electrical Engineering and Management (elective course)
- Communications, Multimedia and Electronics - Communication Technology (elective course)
- Communications, Multimedia and Electronics - Multimedia Technology (elective course)
- Communications, Multimedia and Electronics - Applied Electronics (elective course)
- Communications, Multimedia and Electronics - Network and Information Technology (elective course)
- Open Informatics - Computer Systems (compulsory course of the specialization)
- Electrical Engineering, Power Engineering and Management (elective course)
- Communications, Multimedia and Electronics (elective course)
- Cybernetics and Robotics (elective course)
- Communications, Multimedia and Electronics - Communications and Electronics (elective course)