Simulation of Dynamic Systems (FSI-RSD)

Academic year 2020/2021
Supervisor: Ing. Petr Krejčí, Ph.D.  
Supervising institute: ÚMTMB all courses guaranted by this institute
Teaching language: Czech
Aims of the course unit:
Acquaint students basic notions theory dynamic systems and deepen basic piece of knowledge from theory different technical enclosure on such level, to were able to is energetically apply at solving concrete problems technical practice. Explain basic access production computational models subsystems various physical essence and after it complex computational model technical system, crimping with these subsystems with one another different in a way blocked (serial, parallel and combination wiring, etc ..)
Learning outcomes and competences:
Obtaining basic education from theory dynamic systems and cavity basic theoretic piece of knowledge from different technical enclosure in connection with problems computational simulation. Identification basic principles production computational models subsoustav various physical essence and their mergence with the view of creation complex computational model technical system at different type cubic make - up these subsystems
Prerequisites:
The aim of course referring to studding programs of base mechatronics study: Kinematics, Dynamics, Computer Methods in Dynamics, Drive Systems, Stochastic mechanics and Experiments in Mechatronics.
Course contents:
The aim of course is to improve student’s knowledge of the problems in theoretical and applied dynamics. The course is based on interactive conception of engineering mechanics focused on solving of complex engineering problems. The content of curse is oriented on requirements of mechatronics course teaching in master’s and doctoral studding programs.
Teaching methods and criteria:
The course is taught through lectures explaining the basic principles and theory of the discipline. Teaching is suplemented by practical laboratory work.
Assesment methods and criteria linked to learning outcomes:
Requirements on conferment inclusion: active participation in exercising, high - quality elaboration engaged exercise, solving additional exercise at longer forgiven non - participation. Leadership exercising will specify concrete form these conditions in first week semester. Examination combination; written - knowledge basic conceptions, important regularity and their application; mouth – discussion above written part examination and exercise in exercisings.
Controlled participation in lessons:
Attendance is obligatory. Lumpsum tax non - participation can be replaced exercising with other group in same week or elaboration reserve exercise. Longer absence substitutes special setting as directed training.
Type of course unit:
    Lecture  13 × 2 hrs. optionally                  
    Laboratory exercise  13 × 2 hrs. compulsory                  
Course curriculum:
    Lecture 1+2. Fundamental terms theory dynamic systems.
3+4. Fundamental terms and law technical mechanics. Philosophy formation kinetic quadratics mechanical part technical system.
4+5. Fundamental terms and law electricians. Characteristics basic electric elements. Philosophy formation computational models electric system.
6+7+8. Fundamental terms and law hydraulician and termomechaniky. Philosophy formation computational models hydraulic and pneumatic system.
9+10+11. Fundamental terms and law transmission and heat interchange. Philosophy formation computational models heat systems stationary and non - stationary heat tramps.
12. Fundamental terms theory regulation. Philosophy formation computational models basic temporary carrier members and their system, postneuritic different make - up basic temporary carrier members.
13. Exhibits complex access to computational simulation technical system, compound at least from two subsystem about various physical essence.
    Laboratory exercise 1+2. Fundamental terms theory dynamic systems.
3+4. Fundamental terms and law technical mechanics. Philosophy formation kinetic quadratics mechanical part technical system.
4+5. Fundamental terms and law electricians. Characteristics basic electric elements. Philosophy formation computational models electric system.
6+7+8. Fundamental terms and law hydraulician and termomechaniky. Philosophy formation computational models hydraulic and pneumatic system.
9+10+11. Fundamental terms and law transmission and heat interchange. Philosophy formation computational models heat systems stationary and non - stationary heat tramps.
12. Fundamental terms theory regulation. Philosophy formation computational models basic temporary carrier members and their system, postneuritic different make - up basic temporary carrier members.
13. Exhibits complex access to computational simulation technical system, compound at least from two subsystem about various physical essence.
Literature - fundamental:
1. BOLTON, W. Mechatronics: Electronic Control Systems in Mechanical Engineering. Pearson Education Limited, 2015. 664 p. ISBN: 9781292076683.
2. Kilts, S. Advanced FPGA Design : Architecture, Implementation, and Optimization. John Wiley & Sons Inc., 2007. 352 p. ISBN: 9780470054376
Literature - recommended:
1. Essick, J. Hands-on introduction to labview for scientists and engineers. Oxford University Press Inc., 2018. 720 p. ISBN: 9780190853068
The study programmes with the given course:
Programme Study form Branch Spec. Final classification   Course-unit credits     Obligation     Level     Year     Semester  
M2A-P full-time study M-MET Mechatronics -- Cr,Ex 5 Compulsory 2 2 W