Cyber-phisical systems modelling and implementation - opis przedmiotu

Informacje ogólne

Nazwa przedmiotu	Cyber-phisical systems modelling and implementation
Kod przedmiotu	11.3-WE-INFD-C-PSMabdI-Er
Wydział	Wydział Informatyki, Elektrotechniki i Automatyki
Kierunek	Informatyka
Profil	ogólnoakademicki
Rodzaj studiów	Program Erasmus drugiego stopnia
Semestr rozpoczęcia	semestr zimowy 2022/2023

Informacje o przedmiocie

Semestr	2
Liczba punktów ECTS do zdobycia	4
Typ przedmiotu	obowiązkowy
Język nauczania	angielski
Sylabus opracował	dr inż. Grzegorz Bazydło

Formy zajęć

Forma zajęć	Liczba godzin w semestrze (stacjonarne)	Liczba godzin w tygodniu (stacjonarne)	Liczba godzin w semestrze (niestacjonarne)	Liczba godzin w tygodniu (niestacjonarne)	Forma zaliczenia
Wykład	15	1	-	-	Zaliczenie na ocenę
Laboratorium	30	2	-	-	Zaliczenie na ocenę
Projekt	15	1	-	-	Zaliczenie na ocenę

Cel przedmiotu

Familiarize students with the designing methods of a control part of a cyber-physical system.
Shaping basic skills for specification, analysis, and implementation of a control part of cyber-physical systems (especially distributed).

Wymagania wstępne

Fundamentals of digital system design.

Zakres tematyczny

Introduction: cyber-physical system (CPS), control part of the CPS, smart systems, Internet of Things (IoT), embedded and distributed CPSs.
The general designing flow of a control part of the CPS: modelling, analysis (including validation and verification), implementation and hardware verification.
Graphical specification methods of a control part of the CPS: FSM, Petri net (including interpreted Petri nets), UML diagrams.
Methods of the analysis of a control part of the CPS: validation, formal verification, concurrency (state space analysis), and sequentiality analysis. The computational complexity of the algorithms for the CPS control part analysis.
Modelling and decomposition of the CPS control algorithm: decomposition into state machine components, decomposition methods.
Implementation of the CPS control algorithm: logic synthesis and implementation, system description in the hardware description languages (e.g., VHDL, Verilog) and programming languages (e.g., C/.C++), physical implementation in the FPGA device and microcontrollers (e.g., Arduino).
Static and dynamic partial reconfiguration of the already implemented CPS control algorithm (with and without system stop), design framework of the CPS control part for future static and dynamic partial reconfiguration of the control module of the CPS.

Metody kształcenia

Lecture: conventional lecture, discussion.

Laboratory: laboratory exercises, work in groups.

Project: project method.

Efekty uczenia się i metody weryfikacji osiągania efektów uczenia się

Opis efektu	Symbole efektów	Metody weryfikacji	Forma zajęć

Warunki zaliczenia

Lecture – the passing condition is to obtain a positive mark from the final test (written or oral).

Laboratory – the passing condition is to obtain positive marks from all laboratory exercises to be planned during the semester.

Project – the passing condition is to obtain a positive mark from all projects conducted during the semester.

Final mark components: lecture 30% + laboratory 40% + project 30%.

Literatura podstawowa

E. A. Lee, S. A. Seshia, Introduction to Embedded Systems: A Cyber-Physical Systems Approach, Cambridge, MA, USA:MIT Press, 2017.
W. Reisig, Petri Nets: An Introduction, Berlin, Germany:Springer-Verlag, 2012.
R. Wiśniewski, Prototyping of Concurrent Control Systems Implemented in FPGA Devices, Cham, Switzerland:Springer, 2017.
I. Grobelna, R. Wiśniewski, M. Grobelny, M. Wiśniewska, "Design and verification of real-life processes with application of Petri nets", IEEE Trans. Syst. Man Cybern. Syst., vol. 47, no. 11, pp. 2856-2869, Nov. 2017.
R. Wiśniewski, G. Bazydło, L. Gomes, A. Costa, "Dynamic partial reconfiguration of concurrent control systems implemented in FPGA devices", IEEE Trans. Ind. Informat., vol. 13, no. 4, pp. 1734-1741, Aug. 2017.

Literatura uzupełniająca

E. Best, R. Devillers, M. Koutny, Petri Net Algebra, Berlin, Germany:Springer-Verlag, 2013.
L. Gomes, F. Moutinho, F. Pereira, "IOPT-tools - A Web based tool framework for embedded systems controller development using Petri nets", Proc. 23rd Int. Conf. Field Program. Logic Appl., pp. 1, Sep. 2013.
Z. Li, N. Q. Wu, M. C. Zhou, "Deadlock control of automated manufacturing systems based on Petri nets - A literature review", IEEE Trans. Syst. Man Cybern. C Appl. Rev., vol. 42, no. 4, pp. 437-462, Jul. 2012.
M. Zhou, N. Q. Wu, System Modeling and Control With Resource-Oriented Petri Nets, Boca Raton, FL, USA:CRC Press, 2009.
I. Grobelna, "Model checking of reconfigurable FPGA modules specified by Petri nets", J. Syst. Archit., vol. 89, pp. 1-9, Sep. 2018.
R. Wiśniewski, "Dynamic partial reconfiguration of concurrent control systems specified by Petri nets and implemented in Xilinx FPGA devices", IEEE Access, vol. 6, pp. 32376-32391, 2018.
V. Hahanov et al., "Cyber social computing" in Social Business and Industrial Applications, Cham, Switzerland:Springer, pp. 489-515, 2019.
R. Wiśniewski, A. Karatkevich, M. Adamski, A. Costa, L. Gomes, "Prototyping of concurrent control systems with application of Petri nets and comparability graphs", IEEE Trans. Control Syst. Technol., vol. 26, no. 2, pp. 575-586, Mar. 2018.
M.C. Golumbic, Algorithmic Graph Theory and Perfect Graphs, Academic Press, 1980.
R. Wiśniewski, G. Bazydło, P. Szcześniak, I. Grobelna, M. Wojnakowski, „Design and Verification of Cyber-Physical Systems Specified by Petri Nets - A Case Study of a Direct Matrix Converter”, Mathematics, vol. 7, pp. 1-24, 2019.

Uwagi

Zmodyfikowane przez dr inż. Grzegorz Bazydło (ostatnia modyfikacja: 21-04-2022 10:08)