Subject description - A4B34EM

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A4B34EM Electronics and Microelectronics Extent of teaching:2P+2L
Guarantors:Jakovenko J. Roles:PO,V Language of
Teachers:Jakovenko J., Janíček V., Záhlava V. Completion:Z,ZK
Responsible Department:13134 Credits:6 Semester:Z


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.

Course outlines:

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.

Exercises outline:

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.
12. Student project
13. Student project
14. Work presentation, final assessment


P. Gray, P Hurst, S. Lewis, R. Mayer: "Analysis and Design of Analog
Integrated Circuits", John Wiley and Sons, 2000




Electronics, Microelectronics

Subject is included into these academic programs:

Program Branch Role Recommended semester
BPKYR1 Robotics V 3
BPKYR_BO Common courses V 3
BPKYR3 Systems and Control V 3
BPKYR2 Sensors and Instrumentation V 3
BPKME1 Communication Technology V 3
BPKME5 Komunikace a elektronika V 3
BPKME_BO Common courses V 3
BPKME4 Network and Information Technology V 3
BPKME3 Applied Electronics V 3
BPKME2 Multimedia Technology V 3
BPEEM1 Applied Electrical Engineering V 3
BPEEM_BO Common courses V 3
BPEEM2 Electrical Engineering and Management V 3
BPOI1 Computer Systems PO 3
BPOI_BO Common courses PO 3
BMI(ECTS) Manager Informatics V 3
BWM(ECTS) Web and Multimedia V 3
BIS(ECTS) Intelligent Systems V 3
BSI(ECTS) Software Engineering V 3

Page updated 21.2.2020 17:51:44, semester: Z,L/2020-1, Z,L/2019-20, Send comments about the content to the Administrators of the Academic Programs Proposal and Realization: I. Halaška (K336), J. Novák (K336)