| Theme |
Logical control of model motor units (SP1) |
| Supervisor |
Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
ÚTIA, Pod Vodárenskou věží 4, Praha 8
/ 26605 2310 |
| E-Mail / Web |
belda@utia.cas.cz / http://as.utia.cas.cz/asc |
| Key Words |
Logical control, truth table,
distributed mechatronic systems |
| Specification |
Industrial production is more and more realized with increasing number
of productive components generally mechanical, electromechanical,
electrical or electronic ones. The components form usually one technological set.
It can be manipulation, machining, quality checking, packing, etc. operations,
in which the components represent individual or cooperative distributed system.
For mentioned components above, the system is called mechatronic system.
Such system can be controlled on different levels form simple manual and fixed
control, via logical feedback control up to high-level continual feedback
control. The issue is usually managing of several motor units (drives)
to be worked in common time rate.
The aim of the theme is a design and technical documentation of simple logical
control, which provides simple user control of several partially independent
model motor units. |
| Tasks |
|
1.
|
Study and describe available
signals and individual motor units’ respon-ses of distributed mechatronic system.
|
|
2.
|
Realize simple logical control
as Simulink model in programmable environment MATLAB-Simulink.
|
|
| Literature |
|
1.
|
Saleem, A.: Mechatronics
System Design, Controller and control algo-rithm Selection,
Philadelphia University, 2010.
|
|
2.
|
Online Manuals: Using MATLAB,
Simulink; The MathWorks, Inc.
http://www.mathworks.com/.
|
|
3.
|
Other full-text sources:
http://as.utia.cas.cz/asc/ - Link to GPC pages.
|
|
| Note |
Theme for semester project or bachelor project. |
| Theme |
Feedback control of model motor units (BP1) |
| Supervisor |
Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
ÚTIA, Pod Vodárenskou věží 4, Praha 8
/ 26605 2310 |
| E-Mail / Web |
belda@utia.cas.cz / http://as.utia.cas.cz/asc |
| Key Words |
Distributed mechatronic system,
feedback control, real-time control, modeling, mathematical-physical analysis |
| Specification |
Industrial production is more and more realized with increasing number of productive
components generally mechanical, electromechanical, electrical or electronic ones.
The components form usually one technological set. It can be manipulation, machining,
quality checking, packing, etc. operations, in which the components represent individual
or cooperative distributed system. For mentioned components above, the system
is called mechatronic system.
Such system can be controlled on different levels form simple manual and fixed
control, via logical feedback control up to high-level continual feedback control.
The issue is usually managing of several motor units (drives) to be worked
in common time schedule.
The aim of the theme is a design and technical documentation of feedback control,
which provides automatic control of several independent model motor units. |
| Tasks |
|
1.
|
Study and select suitable
feedback control for distributed mechatronic system.
|
|
2.
|
Compose mathematical
description of individual model motor unit.
|
|
3.
|
Apply or implement
selected feedback control in real-time in program-mable environment
MATLAB-Simulink.
|
|
| Literature |
|
1.
|
Saleem, A.: Mechatronics
System Design, Controller and control algo-rithm Selection,
Philadelphia University, 2010.
|
|
2.
|
Maciejowski, J., M.:
Predictive Control with Constrains, Prentice Hall, London 2002.
|
|
3.
|
Online Manuals: Using MATLAB,
Simulink; The MathWorks, Inc.
http://www.mathworks.com/.
|
|
4.
|
Other full-text sources:
http://as.utia.cas.cz/asc/ - Link to GPC pages.
|
|
| Note |
Theme for bachelor project. |
| Theme |
Q. monitoring of ZigBee communication
and contactless position sensing (BP2) |
| Supervisor |
Ing. Pavel Píša, Ph.D. / Proposer: Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
CTU, FEE, Karlovo nám. 13, Prague 2 / 22435 7223
UTIA, Pod Vodárenskou věží 4, Prague 8 / 26605 2310 |
| E-Mail / Web |
pisa@fel.cvut.cz / http://cmp.felk.cvut.cz/~pisa/
belda@utia.cas.cz / http://as.utia.cas.cz/asc |
| Key Words |
ZigBee communication protocol, odometry,
distributed mechatronic system, quality monitoring and analysis |
| Specification |
Wireless communication is spread more and more in industrial automation.
It offers flexible modifications of component connection or component
mobility independent of fixed wires connection. It has advantage e.g.
in production backup to avoid unplanned shut-downs.
The aim of the theme is a monitoring and analysis of the quality of wireless
communi-cation based on ZigBee protocol and contactless position sensing as well.
On the basis of the obtained results, the possible improvements of the sensing
and communication have to be determined and possibly realized. |
| Tasks |
|
1.
|
Study ZigBee communication protocol.
|
|
2.
|
Study technical solutions
of contactless position sensing.
|
|
3.
|
Monitor and analyze quality
of ZigBee communication protocol and contactless position sensing.
|
|
4.
|
Propose possible ways
of improvement for contactless position sensing (sensors, scan surfaces etc.)
and select a way with the most expected improvement effect to be realized.
|
|
| Literature |
|
| Note |
Theme for bachelor project or master’s thesis. |
| Theme |
Wireless software upgrade of control
module of ZigBee communication (BP3) |
| Supervisor |
Ing. Pavel Píša, Ph.D. / Proposer: Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
CTU, FEE, Karlovo nám. 13, Prague 2 / 22435 7223
UTIA, Pod Vodárenskou věží 4, Prague 8 / 26605 2310 |
| E-Mail / Web |
pisa@fel.cvut.cz / http://cmp.felk.cvut.cz/~pisa/
belda@utia.cas.cz / http://as.utia.cas.cz/asc |
| Key Words |
ZigBee communication protocol, open components TinyOS |
| Specification |
Wireless communication is spread more and more in industrial automation.
It offers flexible modifications of component connection or component
mobility independent of fixed wires connection. It has advantage e.g.
in production backup to avoid unplanned shut-downs.
The aim of the theme is realization of wireless upgrade of utility
software for control module of ZigBee communication. |
| Tasks |
|
1.
|
Study ZigBee communication protocol.
|
|
2.
|
Design and modify utility
software for control module.
|
|
3.
|
Realize and verify designed
utility software module for wireless software upgrade of control module
of ZigBee communication
|
|
| Literature |
|
| Note |
Theme for bachelor project or master’s thesis. |
| Theme |
Model based control of robots (MT1) |
| Supervisor |
Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
UTIA, Pod Vodárenskou věží 4, Prague 8
/ 26605 2310 |
| E-Mail / Web |
belda@utia.cas.cz / http://as.utia.cas.cz/asc |
| Key Words |
Industrial robots, predictive control,
real-time control, modeling, mathematical-physical analysis |
| Specification |
Robots and manipulators are fundamental parts in industrial production.
They are especially characterized by their flexibility in the use and certain
degree of autonomous intelligence. This character enables them to change their
environment contrary to other production machines.
With development of new robot structures, the requirements on their control grow too.
Perspective direction is the use of the controllers constructed on model-based control
strategies. These strategies enable to spread the energy to individual robot drives
and by this their full utilization.
The aim of the theme is a development of algorithms of predictive control, which
belongs to model-based control strategies. |
| Tasks |
|
1.
|
On the basis of mathematical-physical
analysis compose mathematical model of given robot.
|
|
2.
|
Study the basis of the predictive
control design and derive suitable selected its algorithm.
|
|
3.
|
Prove this algorithm by simulation
and in case of availability of laboratory model of considered robot,
prove the algorithm even on this model.
|
|
| Literature |
|
1.
|
Maciejowski, J., M.:
Predictive Control with Constrains, Prentice Hall, London 2002.
|
|
2.
|
Rossiter, J., A.:
Model-Based Predictive Control – A Practical Approach, CRC Press, London 2003.
|
|
3.
|
Other full-text sources:
http://as.utia.cas.cz/asc/ - Link to GPC pages.
|
|
| Note |
Theme for thesis. |
| Theme |
Model-based control for distributed
mechatronic systems (MT2) |
| Supervisor |
Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
UTIA, Pod Vodárenskou věží 4, Prague 8
/ 26605 2310 |
| E-Mail / Web |
belda@utia.cas.cz /
http://as.utia.cas.cz/asc |
| Key Words |
Distributed mechatronic system,
predictive control, modeling, mathematical-physical analysis |
| Specification |
Industrial production is more and more realized with increasing number
of productive components generally mechanical, electromechanical,
electrical or electronic ones. The components form usually one technological set.
It can be manipulation, machining, quality checking, packing, etc. operations,
in which the components represent individual or cooperative distributed system.
For mentioned components above, the system is called mechatronic system.
Such system can be controlled on different levels form simple manual and fixed
control, via logical feedback control up to high-level continual feedback control.
The issue is usually managing of several motor units (drives) to be worked
in common time schedule.
The aim of the theme is a design and technical documentation of model-based control
of several independent model motor units. |
| Tasks |
|
1.
|
Study and select suitable
feedback control for distributed mechatronic system.
|
|
2.
|
Compose mathematical
description of individual model motor unit.
|
|
3.
|
Apply or implement
selected model-based control in programmable envi-ronment MATLAB-Simulink.
|
|
| Literature |
|
1.
|
Saleem, A.: Mechatronics System Design,
Controller and control algo-rithm Selection, Philadelphia University, 2010.
|
|
2.
|
Maciejowski, J., M.:
Predictive Control with Constrains, Prentice Hall, London 2002.
|
|
3.
|
Online Manuals: Using MATLAB,
Simulink; The MathWorks, Inc.
http://www.mathworks.com/.
|
|
4.
|
Další plnotextové zdroje:
http://as.utia.cas.cz/asc/ - Link to GPC pages.
|
|
| Note |
Theme for master’s thesis. |
| Theme |
Model-based control of electric motors
with permanent magnets (MT3) |
| Supervisor |
Ing. Pavel Píša, Ph.D. / Consultant: Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
CTU, FEE, Karlovo nám. 13, Prague 2 / 22435 7223
UTIA, Pod Vodárenskou věží 4, Prague 8 / 26605 2310 |
| E-Mail / Web |
pisa@fel.cvut.cz / http://cmp.felk.cvut.cz/~pisa/
belda@utia.cas.cz / http://as.utia.cas.cz/asc |
| Key Words |
Synchronous electric motors
with permanent magnets, speed control, force control, predictive control,
modeling, mathematical-physical analysis |
| Specification |
Latest development stage in the domain of electric motors is represented
by brushless alternate current electric motor, also known as a permanent
magnet synchronous motor (PMSM). These motors are employed in many applications
connected with industrial robotics and machine tools and driving of transport means.
The aim of the theme is a composition of suitable mathematical description
of PMSM electric motors for model-based control and algorithmic implementation
of the control. |
| Tasks |
|
1.
|
Study basic types of structural
configuration of synchronous electric motors with permanent magnets.
|
|
2.
|
On the basis
of mathematical-physical analysis compose suitable mathematical model
of synchronous motor with permanent magnets.
|
|
3.
|
Study the basis of model-based
control design and select suitable algorithm for motor control. Consider
separately position control, speed control and torque (force) control.
|
|
4.
|
Prove selected algorithm
by simulation and in case of availability of real electric motor,
prove it experimentally as well.
|
|
| Literature |
|
1.
|
Freescale Semiconductor:
3-Phase PM Synchronous Motor Vector Con-trol Using a 56F80x, 56F8100,
or 56F8300 Device, Application Note Rev. 3, 1/2005,
http://cache.freescale.com/files/product/doc/AN1931.pdf.
|
|
2.
|
Rossiter, J., A.: Model-Based
Predictive Control – A Practical Approach, CRC Press, London 2003.
|
|
3.
|
Další plnotextové zdroje:
http://as.utia.cas.cz/asc - Link to GPC pages,
http://cmp.felk.cvut.cz/~pisa/.
|
|
| Note |
Theme for master’s thesis. |
| Theme |
Predictive control for industrial machines and robots (Dis1) |
| Supervisor |
Ing. Květoslav Belda, Ph.D. |
| Affiliation
/ Phone |
ÚTIA, odd. adaptivních systémů, Pod Vodárenskou věží 4, Praha 8 / 26605 2310 |
| E-Mail / Web |
belda@utia.cas.cz /
http://as.utia.cas.cz/asc |
| Key Words |
Industrial robots, predictive control,
CNC control, real time control, modeling, mathematical-physical analysis
|
| Specification |
Aim of the work is design, software optimization and implementation of predictive
control algorithms form mechatronic structures forming the basis
of the industrial machines and robots. Implementation of algorithms
is assumed in the form of autonomous functions, for independent tests
and experiments on different types of mechatronic configurations.
|
| Tasks |
|
1.
|
Study control algorithms
of predictive control.
|
|
2.
|
Make model (mathematical-physical)
analysis and compose mathematical model of the real mechatronic structure.
|
|
3.
|
Analyze dimensions
of functional parameters, inputs and outputs.
|
|
4.
|
Design suitable optimization
procedure of on-line processing of CNC programs for control algorithms.
|
|
5.
|
Implement designed control
algorithms by M functions and S functions for MATLAB & Simulink.
|
|
| Literature |
|
1.
|
Belda, K., Böhm, J., Píša, P.:
Concepts of Model-Based Control and Trajectory Planning for Parallel Robots.
Proc. of 13th IASTED Int. Conf. on Robotics and Applications 2007, Würzburg,
Germany. pp. 15-20.
|
|
2.
|
Bobál, V., Böhm, J., Fessl, J.,
Macháček, J.: Digital Self-tuning Controllers Algorithms, Implementation
and Applications, Springer 2005.
|
|
3.
|
J. A. Rossiter: Model-Based
Predictive Control, A Practical Approach, London, CRC Press, 2003.
|
|
4.
|
Other full-text sources:
http://as.utia.cas.cz/asc
- Link to GPC pages.
|
|
| Note |
Theme for dissertation. |
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