Electronics and Telecommunications PROGRAM

Transkrypt

ROZWÓJ POTENCJAŁU I OFERTY DYDAKTYCZNEJ POLITECHNIKI WROCŁAWSKIEJ
Electronics, Photonics and Microsystems
Electronics and Telecommunications
ELECTRONICS, PHOTONICS AND MICROSYSTEMS
II Level – MSc (3 semesters, 90 ECTS)
PROGRAM
3 SEMESTERS
Entry requirements:
MSc
Completed:
Diploma of the I level studies in:
Electronics and Telecommunication
Master Thesis,
Final Exam
Possible extension:
Studies of the III level (PhD)
Graduate:
The graduate will possess multidisciplinary
knowledge
in
electronics
(including
microelectronics), photonics and microsystems.
They will be prepared for solving technical and
technological problems in those fields. They
will have gained experience in technology and
retrieving information from the literature and
other sources. Graduated student will be able
to play the role of the leader of the team and
to organize and run research debates. They
will have acquired the experience necessary
for professional career at research units,
industry and at universities. Students after
graduation will demonstrate well above
standard skills in English communication.
1
Structure of the programme (credits)
Semester 1
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
BC – Basic Courses;
FL (Humanities, Foreign Language)
– Nontechnical courses;
AC – Advanced Courses;
MT – Master Thesis.
FE – Final Exam
2
Semester 2
Semester 3
FL
BC
AC
AC
MT
FE
Structure of the programme (by hours)
27 h
I
32 p
28
27
26
25
ETD8461
ETD8464
2
20000E
Vacuum and Plasma Techniques
ETD8463
4
Optical Fibers
23
2W + 2L
ETD8462
3
10100
ETD8164
3
1W + 2S
12
11
10
4
Ceramic Microsystems
3
ETD9466
10100
ETD8163
10200E
3
ETD9465
20 p
4
20200
2
20000
2W + 2L
Solid State Electronics
ETD8066
11000
3
Optimization Methods 1W + 2C
ETD8065
3
ETD8064
3
11000
Statistics for EPM 1W + 2C
6
ETD 9464
22000E
7
Differential equations
6
3W + 3C
3
10020
Design and Construction of Optoelectronics
11000
Numerical Methods 1W + 2C
MAP
Circuits 1W +2P
ETD9463
3
10100
Operating Systems
ETD9462
1W + 2L
2
10010
Optical-Fiber Networks
ETD9461
5
20120E
ETD9069
3
04000
2
00002
Diploma Seminar
2W + 1L + 2P
5
Advanced Optoelectronics
ETD9068
3
10010
Diagnostics and Reliability 1W + 2P
3
1
MSc Thesis Work
Photovoltaics
8
2
27 p
20010E
Microsystem Modeling
9
4
III
10002
Nanotechnology
13
ETD9468
MOEMS 1W +2L
17
14
20000
ETD9467
18
15
2
7h
Analytical Microsystems 1W + 2L
20
16
31 p
2W + 2P
22
19
II
Autonomous Power Supplying Systems
20200E
24
21
28 h
ETD9066
Foreign Language other than English and native
1
Packaging of EPM
10000
ETD9065
1
10000
Sensors and Actuators
ETD9067
2
00200
Packaging of EPM
3
PLAN OF STUDIES
1st YEAR, SEMESTER 1
Obligatory courses:
Contact hours/week
CHS
TSW
ECTS
Form of
Assessment
30
60
2
E
2
60
120
4
E
1
30
70
3
T
45
100
3
T
30
60
2
T
1
30
60
3
T
1
1
30
60
3
T
Statistics for EPM
1
1
30
60
3
T
Differential
Equations
2
2
60
200
6
E
4
60
200
3
T
405
990
32
No.
Code
Subject/Module
1
ETD 8464
Vacuum and
Plasma Techniques
2
2
ETD 8463
Optical Fibers
2
3
ETD 8462
MEOMS
1
4
ETD 8164
Nanotechnology
1
5
ETD 8163
Solid State
Electronics
2
6
ETD 8066
Optimization
Methods
1
7
ETD 8065
Numerical
Methods
8
ETD 8064
9
MAP
10
Foreign language
TOTAL
4
L
13
T
lab
p
s
2
9
3
2
1st YEAR, SEMESTER 2
Obligatory courses:
Contact hours/week
CHS
TSW
ECTS
Form of
Assessment
60
120
2
T
45
110
4
E
1
30
80
3
T
1
2
45
120
3
E
Photovoltaics
2
2
60
140
4
T
ETD 9464
Design and
Construction of
Optoelectronic
Circuits
1
45
100
3
T
7
ETD 9463
Operating Systems
1
30
60
3
T
8
ETD 9462
Optical-Fiber
Networks
1
1
30
60
2
T
9
ETD 9461
Advanced
Optoelectronics
2
1
75
180
5
E
10
ETD 9066
Packaging of EPM
1
15
30
1
T
11
ETD 9065
Sensors and
Actuators
1
15
30
1
T
450
1030
31
No.
Code
Subject/Module
1
ETD 8461
Autonomous
Power Supplying
Systems
2
2
ETD 9468
Ceramic
Microsystems
2
3
ETD 9467
Analytical
Microsystems
1
4
ETD 9466
Microsystem
Modeling
5
ETD 9465
6
TOTAL
L
15
T
lab
p
1
2
1
2
8
5
s
5
2nd YEAR, SEMESTER 3
Obligatory courses:
No.
Code
Subject/Module
1
ETD 9065
MSc Thesis
3
ETD 9069
Diploma Seminar
2
ETD 9068
Diagnostics and
Reliability
4
ETD 9067
Packaging of EPM
TOTAL
L
T
lab
p
Contact hours/week
L
T
lab
p
s
20
2
1
1
2
1
20
2
1
2
CHS
TSW
ECTS
Form of
Assessment
240
550
20
CW
30
60
2
T
30
80
3
T
30
60
2
T
330
750
27
s
L – Lecture T – Tutorials, l – laboratory, p – project, s – seminar,
CHS
TSW
CHS – Contact Hours (organized), TSW – Total Student Workload (h), E – Exam, T – Test, CW – Course Work
6
Description of the courses
1st Semester
CODE ETD 8464
VACUUM AND PLASMA TECHNIQUES
Language: English
Course: Basic/Advanced
Year (I), semester (1)
Level: II
Obligatory/Optional
Prerequisites: none
Teaching:Traditional/Distance L.
Lecturer: Witold Posadowski, DSc., Prof. Zbigniew Kowalski
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
Exam / Course work/T:
E
ECTS
2
Workload (h)
60
Outcome: Getting the knowledge about the thin film technology used at microelectronics basing on the
phenomena proceeded at vacuum atmosphere.
Content: The course covers the kinetic theory of gases, gas flow, out gassing, pressure measurement and
vacuum devices (rough and high vacuum pumps). It is also devoted to introducing the students of
electronics to the problems and application of the vacuum technique. During the subsequent lectures the
physical properties of rarefied gas environment as well as the methods of generation of high and ultrahigh vacuum are described. The movement of electrons and ions in gas and plasma classification of
discharges in gas is presented. Different methods used in the thin films microelectronics (ion sputtering,
ion plating, ion implantation) are presented.
Literature:
1. Lecture’s content
2. Nigel Harris, “Modern Vacuum Practice” , self-published, (third edition), 2005.
3. J.O’Hanlon, “A user’s Guide to Vacuum Technology”, Wiley-Interscience, (third edition), 2003.
4. M. Wutz, H. Adam, W. Walcher „Theory and Practice of Vacuum Technology”, Friedr. Vieweg &
Sohn, Braunschweig, 1989
CODE ETD 8463
OPTICAL FIBERS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Sergiusz Patela, DSc; Anna Sankowska, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
30
E
ECTS
4
Workload (h)
60
60
Outcome: Ability to select and evaluate waveguide and optoelectronic elements used for the design of
photonic systems and optical networks.
7
Content: Telecommunications fiber optic systems. Optical and mechanical properties of optical fibers.
Coupling of passive and active photonics elements with optical fibers. Installation and measurements of
local and long-reach fiber optic networks. Measuring procedures of fiber optic connectors. Generation of
optical fiber systems and properties of their transmitting and receiving modules. Fundamentals of
nonlinear optics. New trends in photonics. Laboratory part of the course deals with present-day problems
of optical fiber techniques such us: methods of the fiber joints using an electrical fusion splicer, the
termination procedure for ST connector, the loss measurement of the fiber connector, measurement
methods of optical fiber systems: the two-point measurement, the optical time-domain reflectometer
(OTDR), measurement of spectral loss and refractive index profile in optical fiber, directional couplers;
parameters and application in the proximity sensors
Literature:
Lecture materials
CODE ETD 8462
MEOMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Jan A. Dziuban; Rafał Walczak, PhD; Paweł Knapkiewicz, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
3
Workload (h)
30
70
Outcome: Knowledge of optical microsystems, mechanically passive and active MEOMS’s, own
laboratorial experiments.
Content: MEMS and MEOMS technological compatibility, classification of MEOMS, application fields,
market, manufacturers, history and future development.
Static microoptical components: couplers,
microlenses, diffraction grids 1-D and 2-D, microoptical benches, other constructions. Movable
microoptical components: mirrors, switchers, adaptive optics, DMD projectors, confocal and SNOM
microscopes on-chip, opto-mechanical memory.
Light-beam modulators, optical filters,
microspectrometers LIGA. Physical and chemical MOEMS microsensors, microsensors for analytical
applications, VIS/NIR spetrophotometric sensors in chemistry, bio and med science. Spectrofluorometric
sensors: scale factor, chromofores, excitation light sources, detectors, application in ELISA/DNA-chip and
portable instruments. CPT effect and its application in integrated cesium clocks, magnetometers and
interferometric devices.
Literature:
1. P. Rai-Choudhury (ed), “MEMS and MOEMS Technology and Applications”, SPIE Press, Washington,
2000
2. Journal: Pure and Applied Optics J., Spectrum, J. of Optics, J. Micromechanics and Microengineering, J. of
MEMS, Sensors and Actuators
8
CODE ETD 8164
NANOTECHNOLOGY
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Damian Pucicki, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
30
T
ECTS
3
Workload (h)
45
100
Outcome: One of the main aims of the course is presentation of nanotechnology as a technical science
which couples many fields of activities like: material science, chemistry, physics and biology.
Additionally, the knowledge referring to semiconductor nanodevices and semiconductor nanotechnology
will be expanded.
Content: Nanotechnology – definition, development direction and application fields. Molecular electronic
devices – operation rules of molecular wires, molecular resistor, molecular diode and molecular switches.
Drexler’s and Feynman’s worlds – simulations of molecules which perform, for example, a mechanical
function. Quantum size effects and their influence on properties of objects/devices. Properties of
semiconductor devices with QD/Qdash/MQW (Quantum Dot/Quantum Dash/Multi Quantum Well)
active regions. Influence of intermolecular interaction on properties of semiconductor heterostructures.
Modification of band diagram of semiconductors by presence of defects, stresses and reciprocal positions
of atoms in crystal lattice. Modification of properties of semiconductor heterostructures during selective
oxidation and rapid thermal annealing – technological processes, rearrangement of crystal structures. Self
assembled structures – properties and technology. Two- and one- dimensional electron gas (2DEG and
1DEG) – properties, carrier transport, ballistic carrier transport. Hall effect and quantum Hall effect.
Quantum wire transistor and single electron transistor– construction, operation rules.
1.
2.
3.
4.
5.
6.
Literature:
“Springer Handbook of Nanotechnology”, Bharat Bhushan Editor, Springer-Verlang Berlin Heidelberg
2004
Pallab Bhattacharya, “Semicondudtor Optoelectronic Devices, Second Edition”, Prentice Hall New
Jersey 1997
J. H. Davies, A. R. Long, Physics of Nanostructures, Proceedings of the Thirty-Eighth Scottish
Universitates Summer School in Physics St Andrews, 1991
Nanoscale Materials in Chemistry, Wiley, 2001
C. Joachim, J. K. Gimzewski, A. Aviram, “Electronics using hybrid-molecular and mono-molecular
devices”, Nature, vol 408, 30 November 2000
D. Goldhaber-Gordon, Michael S. Montemerlo, J. Christopher Love, Gregory J. Opiteck, James C.
Ellenbogen, “Overview of nanoelectronic devices”, The Procedings of the IEEE, April 1997
9
CODE ETD 8163 SOLID STATE ELECTRONICS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Danuta Kaczmarek
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
T
ECTS
2
Workload (h)
60
Outcome: Completion of theoretical and experimental principles for particular courses within the range
of electronics and photonics; applying the knowledge of electronics and physics for technical purposes.
Content: The course presents advanced energy band structure of semiconductors, Si and GaAs structures,
local states, statistical physics of equilibrium and non-equilibrium states (transportation and diffusion of
carriers), superconductivity.
Literature:
1. Ch. Kittel, “Introduction to solid state physics”, PWN, Warszawa, 1999
2. Sukiennicki, „Zagórski, Solid state physics”, WNT, Warszawa, 1984
3. Hennel, “Elements of semiconductor electronics”, WNT, Warszawa, 1986
CODE ETD 8066
OPTIMIZATION METHODS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Tadeusz Berlicki
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
2
Workload (h)
30
60
Outcome: Introduce students to optimization methods - linear and nonlinear programming.
Content: Optimization methods: simplex method, duality, revised simplex method, convex
programming, gradient methods, cutting plane methods.
Literature:
Lecture materials
10
CODE ETD 8065
NUMERICAL METHODS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Artur Wymysłowski, DSc
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
3
Workload (h)
30
60
Outcome: To present theoretical and practical knowledge concerning application of numerical methods in
typical engineering applications.
Content: The goal of the course is to improve students’ theoretical and practical knowledge on solving
typical engineering problems with numerical methods. One of the benefits of application numerical
methods in engineering applications is ability to perform advanced prototyping quicker and cheaper. The
course frame would consist of the following scheme: understanding, modeling and/or experimentation,
solving and finally interpreting the results. Thus course covers such aspects as physical and mathematical
background and description of basic software packages, which will be the most suitable in selected
engineering applications. In case of physical and mathematical background it is meant to help
understanding physical phenomena with corresponding physical fields and field coupling while in case
of mathematical background the corresponding mathematical theories including basic assumptions,
equations and formulas. Additionally in case of prototyping aspects there would be briefly described
problems of optimization, sensitivity and tolerance analysis, design and analysis of experiments. The
above theoretical knowledge would be presented along with appropriate numerical tools either freeware
as Virtual Prototyping Tool or commercially available packages as MATLAB, ANSYS, ABAQUS,
MATERIAL STUDIO, etc. The whole course would be filled with examples of typical engineering
problems concerning micro- and nano-scale simulations up to molecular modeling.
1.
2.
3.
4.
5.
6.
Literature:
Kreyszig E., „Advanced Engineering Mathematics”, John Wiley and Sons, 2006
Montgomery D., “Design and Analysis of Experiments”, John Wiley and Sons, 2005
William D., Callister Jr., “Materials Science and Engineering an Introduction”, John Wiley and Sons, 2007
Pang T., “An Introduction to Computational Physics”, Cambridge University Press, 2006
Incropera F., Dewitt D., Bergman T., Lavine A., ”Fundamentals of Heat and Mass Transfer”, John Wiley
and Sons, 2007
Manuals to software packages as Ansys, Abaqus, Material Studio, etc.
11
CODE ETD 8064
STATISTICS FOR EPM
Language: English
Level: II
Prerequisites: none
Lecturer: Dr eng. Domaradzki Jaroslaw, PhD
Lecture
Tutorials
Hours / sem. (h)
15
15
T
ECTS
3
Workload (h)
30
60
Obligatory/Optional
Laboratory
Project
Seminar
Outcome:
The course is specially addressed to students of technical science, major electronics and related domains.
At the and of the course students will be able to apply simply statistical methods in engineering practice
for: data analysis, presentation and data interpretation.
Content:
During the course, statistical methods and examples of their application in solving of practical problems
in different areas of engineering are presented. Specially matters connected with data acquisition, data
description, graphical presentation, data analysis and data approximation are discussed. Gauss, Poisson,
F and other distribution and regression models and their properties are presented. Application of
statistics in simulation of different physical phenomena is discussed, as well.
Literature:
In English: R.J. Barlow, Statistics. A guide to the use of statistical methods in the physical sciences, Wiley,
1989.
CODE MAP
DIFFERENTIAL EQUATIONS
Language: English
Level: II
Obligatory/Optional
Prerequisites: Mathematics I
Lecturer: lecturers of the Institute of Mathematics and Computer Science
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
30
E
ECTS
8
Workload (h)
80
120
Outcome: Solving main mathematical problems which occur in technical sciences.
Content: Ordinary differential equations of first and second order. Linear differential equations. Partial
differential equations of first order. Applications of differential equations in physics and techniques.
Integral equations. Basic notions of theory of stochastic processes: Markov processes, renewal processes,
Gaussian processes. Linear space and Hilbert space.
Literature:
Lecture materials
12
CODE MAP
FOREIGN LANGUAGE OTHER THAN ENGLISH AND NATIVE
Language: English
Level: II
Obligatory/Optional
Prerequisites: Mathematics I
Lecturer: lecturers of the
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
60
T
ECTS
3
Workload (h)
120
2nd Semester
CODE ETD 8461
AUTONOMOUS POWER SUPPLY SYSTEMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Jan A. Dziuban; Prof. Andrzej Dziedzic, Rafał Walczak, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
T
ECTS
2
Workload (h)
60
Outcome: Knowledge of modern power supplying methods intended for autonomous devices and
proper selection of the supply to the energy requirements of autonomous devices. Overview of main
constructions and their basics, parameters and examples of application.
Content: Balance of energy in microsystems. Power supplying rules of microsystems. Photovoltaic effect,
solar cells. Technological and constructional solutions and exploitation parameters of solar microcells and
micromodules. Thermoelectric phenomena. Technological and constructional solutions and exploitation
parameters of thermoelectric microgenerators. Simple and reciprocal piezoelectric effect. Technological
and constructional solutions and exploitation parameters of piezoelectrc microgenerators. Fuel cells –
principle of work. Technological and constructional solutions and exploitation parameters of fuel
microcells. Mechanical microgenerators of energy. Energy storage rules. Batteries for microsystems technological and constructional solutions and exploitation parameters. Energy sources – global
problems.
Literature:
1. W. Ehrefeld et al., “Microreactors – new technology for modern chemistry”, Wiley-Vch Verlag 2000
2. D.M. Rove ” Handbook of Thermoelectrics”, London, CRC Press 1996
3. Articles in “Sensors and Actuators” and other related journals
13
CODE ETD 9468
CERAMIC MICROSYSTEMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Leszek Golonka
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
15
E
ECTS
4
Workload (h)
45
110
Outcome: Knowledge of sensor, actuator and microsystem thick film and LTCC (Low Temperature
Cofired Ceramics) technologies, device construction and principle of work
Content: This course acquaints students with the basic thick film and LTCC microfabrication processes of
physical and chemical sensors, microsystems and actuators. The device construction, principle of work,
properties and applications are described. Moreover, various applications (analytical chemistry,
medicine, automotive) and future trends of ceramic LTCC microsystems are presented.
Literature:
1. J.W. Gardner, “Microsensors”, Wiley, 1994
2. M. Prudenziati, “Thick film sensors”, Elsevier, 1994
4. Conference Proceedings of IMAPS/ACerS International Conference and Exhibition
on Ceramic Interconnect and Ceramic Microsystems Technologies (CICMT)
CODE ETD 9467
ANALYTICAL MICROSYSTEMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Jan A. Dziuban, PhD, DSc, ; Anna Górecka-Drzazga, DSc; Rafał Walczak, PhD, Paweł
Knapkiewicz, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
3
Workload (h)
30
80
Outcome: Physical, chemical and technological principles, basic constructions, fabrication work and using
of analytical microsystems, microreactors, bio-microsystems and lab-on-a-chips.
Content: Design, fabrication, work and application of microsystems for chemistry, microchemistry and
life-sciences. Key components for fluids and gas maintaining in micro, pico and nano volume, filters,
mixers, valves, capillaries. Detection in microscale. Microreactors, heat exchange units, apparatus
integration. Electronic and optoelectronic detectors. Integrated gas and fluid analysing devices and
instruments. Bio-chips, lab-on –a-chips, DNA chips, PCR reactors. Microtas’s economy and development.
Literature:
14
1. J. Saliterman, “Fundamentals of Bio-MEMS and Medical Microdevices”,
2. Nam-Trung Nguyen, Steven T. Wereley, “Fundamentals and applications of Microfluidics”, Artech
House, 2002
3. J. A. Dziuban,”Bonding in microsystem technology”, Springer 2006
4. M. P. Hughes, K. F. Hoettges, Microengineering in biotechnology, Humana Press 2009
CODE ETD 9466
MICROSYSTEM MODELLING
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Artur Wymysłowski, DSc
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
30
T
ECTS
3
Workload (h)
45
120
Outcome: To present theoretical and practical knowledge concerning the application of numerical
methods in the field of modelling and prototyping of microsystems.
Content: The goal of the course is to provide the students with the advanced theoretical and practical
knowledge concerning application of numerical methods and tools in the field of microsystems’
numerical prototyping. The basic modeling knowledge would be presented together with the practical
examples covering the typical microsystems’ solutions and applications. The course frame would consist
of the following scheme: understanding, modeling, solving and finally interpreting the results. As the
problem of microsystem modeling is complex it requires interdisciplinary knowledge on material
engineering, coupled field analysis including description of different physical phenomena, numerical
modeling techniques specific for micro- and nano-scale. Additionally, there will be a special attention
paid to the practical aspects of complex numerical prototyping including optimization and quality
design. Numerical modeling would cover such methods as finite element (FEM), finite volume (FVM)
and additionally quantum mechanics and molecular dynamics. The laboratory will be organized on the
basis of such numerical packages as: VPT, ANSYS, ABAQUS, MATERIAL STUDIO and will be focused
on advanced modeling aspects including mainly coupled field microsystem models. The final stage of the
laboratory will organized so as to prepare student for realization of their own individual projects.
1.
2.
3.
4.
5.
6.
Literature:
Thompson E., "Introduction to the Finite Element Method", John Wiley and Sons, 2005
William D., Callister Jr., "Materials Science and Engineering an Introduction", John Wiley and Sons, 2007
Incropera F., Dewitt D., Berg/nan T., Lavine A., "Fundamentals of Heat and Mass Transfer", John Wiley
and Sons, 2007
Zienkiewicz O.C., Taylor R.L., "The Finite Element Method: Volumes 1-3", Butterworth-Heinemann,
London, 2000
Tabata O., Tsuchiya T., “Reliability of MEMS”, Willey-VCH, 2007
Manuals to software packages as VPT, Ansys, Abaqus, Material Studio, etc
15
CODE ETD 9465
PHOTOVOLTAICS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Tadeusz Żdanowicz, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
30
T
ECTS
4
Workload (h)
60
140
Outcome: Knowledge of the basics, main parameters and applications of solar photovoltaic cells.
Content: The course describes the basics of operation and common constructions of solar photovoltaic
cells. The most important processes limiting conversion efficiency of the solar cells - as light absorption
and recombination of minority charge carriers - are discussed. Presented are both most common cells
based on crystalline silicon as well as thin-film devices manufactured using various semiconductor
materials. Special constructions and perspective solutions are discussed, including so called third
generation of photovoltaic devices. In the last part of the course, the basics of design and installation of
complete PV systems are discussed with the emphasis on such system components as energy storage
elements, charge controllers or inverters. The practical training course includes such tasks as
measurements of current-voltage (I-V) curves of illuminated solar cells with determining their
parameters as a function of temperature and irradiance level, measurement of non-illuminated (dark) I-V
curves, measurements of PV modules in various interconnection options and investigation of partial
shadowing effects. The last point of the course is a design of the complete PV system with the help of
professional PC software.
Literature:
1. M. A. Green "Solar Cells - Operating principles, Technology and System Applications",
Ed. Univ. of New South Wales, Australia, 1992;
2. A. Luque, S. Hegedus. ed., “Handbook of Photovoltaic Science and Engineering” (John Wiley & Sons Ltd.,
Chichester, England, 2003).
3. M. A. Green, “Third Generation Photovoltaics. Advanced Solar Energy Conversion”, Springer Series in
Photonics (Springer-Verlag, Berlin Heidelberg New York, 2003).
16
CODE ETD 9464
DESIGN AND CONCSTRUCTION OF OPTOELECTRONICS CIRCUITS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Jacek Radojewski, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
30
T
ECTS
3
Workload (h)
45
100
Outcome: Knowledge about basics of optoelectronic circuits design.
Content: During the lecture students will learn the basics of electronic circuits construction and design,
including specific optoelectronic components. Basic passive and active optoelectronic components are
described together with the integrated circuits classes of specific optoelectronic applications. Computer
programs for printed boards design and electronic circuits simulation will be described, especially for the
optoelectronic circuits applications. The project requires students to prepare basic design work and
construction work on electronic circuits with the optoelectronic parts applied. The whole project
realization includes the phase of a brief fordesign determination, optoelectronic and electronic circuit
design, PCB design and housing design. During the project realization students are learning how to use
catalogues of electronic and optoelectronic parts in book format, CD-ROM and internet format.
Literature:
Lecture materials and journals
CODE ETD 9463
OPERATING SYSTEMS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Krzysztof Urbański, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
3
Workload (h)
30
60
Outcome: Getting the knowledge about internal structure and the principles of operation of
contemporary operating systems. Ability to use low-level system functions. Programming and
configuring embedded operating systems designed for microcontrollers.
Content: The course is devoted to presenting to the students of electronics the principles of operation,
usage and programming operating systems.Windows, Linux and embedded systems will be presented.
1.
2.
3.
Literature:
R. Love, “Linux Kernel Development, Developer's Library”
http://www.msdn.com
A. Silberschatz, P. B. Galvin, G, Gagne, „Operating System Concepts”
17
CODE ETD 9462
OPTICAL-FIBER NETWORKS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Sergiusz Patela, DSc
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
2
Workload (h)
30
60
Outcome: Ability to build and analyze fiber-optic data-transmission systems and networks.
Content: The course presents topics of design and structure of optical networks, starting with simple
local computer networks, through communications WDM network, up to advanced all optical fiber
networks with packet switching. Network components (both active and passive) and measurement
procedures are also described. Elements of network design and modeling are introduced within the
project of the course.
Literature:
Lecture materials
CODE ETD 9461
ADVANCED OPTOELECTRONICS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Sergiusz Patela,DSc Prof. Marek Tłaczła, PhD, DSc,
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
30
15
E
ECTS
5
Workload (h)
60
60
60
Outcome: Ability to fabricate, design and evaluate optoelectronic elements for telecommunication and
non-telecommunication applications.
Content: Physical principles of integrated optical circuits operation. Fabrication methods of optical layers
and planar waveguides. Waveguides switches and modulators and other devices of integrated optics.
Fundamentals of nonlinear optoelectronics. Optical bistability. Photonic crystals. Measurements of light
sources spectral characteristics. Measurements and analysis of propagation parameters of planar
waveguides. Modal structure of gas and semiconductor lasers. Semiconductor lasers characterization.
Optical properties of semiconductor hetrostructures and superlattices. Optical and electrical
characteristics of photodetectors and light sources. Laboratory work of the course will include also
measurements of shear-force mechanism characteristics. Interferometric distance measurements, IR
microscopy, LCD displays characterization, light and picture transducers and multipliers.
Literature:
Lecture materials
18
CODE ETD 9066
PACKAGING OF EPM
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Jan Felba; Tomasz Fałat PhD; Przemysław Matkowski PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
T
ECTS
1
Workload (h)
30
Outcome: The aim of the course is to inform about the fundamentals of electronics and microsystems
packaging. Such knowledge can be useful for engineers involved in electronics, microsystems and
photonics research and production, as all electronic devices need to be packaged until they are electronic
systems or electronic devices.
Content: The role and levels of packaging in electronics and microsystems, printed circuits boards and
other substrates, elements for through hole and surface mount technologies, basic packaging processes
(wire bonding, flip chip, soldering, gluing), materials for packaging (lead-free solders, electrically and
thermally adhesives, underfill materials), packaging reliability, thermal management
Literature:
Lecture materials
CODE ETD 9065
SENSORS AND ACTUATORS
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Rafał Walczak, PhD, Paweł Knapkiewicz, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
T
ECTS
1
Workload (h)
30
Outcome: Knowledge of basics, construction, main parameters and applications of different sensors and
actuators fabricated by microtechniques.
Content: In this course description of various methods of actuation and sensing in micromechanical
structures of microsystems is given. Examples of microsystems utilizing described actuation/sensing
methods are presented. Special attention is paid to piezorezistive pressure sensors – its construction,
technology and parameters. Detailed construction and principle of work of accelerometers and
gyroscopes are presented
Literature:
1.
S. Lyshevski, MEMS and NEMS Systems, Devices and Structure, CRD PRESS, ISBN 0-8493-1262-0
2.
M. Bao, Analysis and Design Principles of MEMS Devices, Elsevier 2005
19
3rd Semester
CODE ETD 9065
MSC THESIS
Language: English
Year (II), semester (3)
Level: II
Prerequisites: none
Lecturer: supervisors
Lecture
Tutorials
Hours / sem. (h)
240
CW
ECTS
20
Workload (h)
550
Obligatory/Optional
Laboratory
Project
Seminar
CODE ETD 9069
DIPLOMA SEMINAR
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer:
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
T
ECTS
2
Workload (h)
60
Outcome: Skill of short and condensed preparation and presentation of the results of student’s work .
Literature:
Supervisor’s materials
CODE ETD 9063
DIAGNOSTICS AND RELIABILITY
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Tadeusz Berlicki; Jarosław Domaradzki, PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
15
15
T
ECTS
3
Workload (h)
30
80
Outcome: Introduce students to the reliability theory, methods or reliability testing, diagnostics methods.
20
CODE ETD 9062
PACKAGING OF EPM
Language: English
Level: II
Obligatory/Optional
Prerequisites: none
Lecturer: Prof. Jan Felba; Tomasz Fałat PhD; Przemysław Matkowski PhD
Lecture
Tutorials
Project
Seminar
Laboratory
Hours / sem. (h)
30
T
ECTS
2
Workload (h)
60
Outcome: The aim of the course is to inform about the fundamentals of electronics and microsystems
packaging. Such knowledge can be useful for engineers involved in electronics, microsystems and
photonics research and production, as all electronic devices need to be packaged until they are electronic
systems or electronic devices.
Content: Laboratory will be practical illustration of the issues discussed during lectures on previous
semester.
Literature:
Lecture materials
21

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