13E044SRV - Real-Time Systems

Course specification
Course title		Real-Time Systems
Acronym		13E044SRV
Study programme		Electrical Engineering and Computing
Module		Electronics
Type of study		bachelor academic studies
Lecturer (for classes)		professor PhD Ivan Popović
Lecturer/Associate (for practice)		asst. MA Haris Turkmanović, electrical and computer engineer
Lecturer/Associate (for OTC)		asst. MA Haris Turkmanović, electrical and computer engineer
ESPB		6.0	Status	elective
Condition		none
The goal		Introduce students to the fundamentals of real-time systems, real-time operating systems architecture, scheduling theory, multitasking concepts and the principles of development and design of real-time embedded systems.Provide students with the ability to analyze, design and realize microcontroler based real-time system.
The outcome		Students will be able to develop microcontroller firmware architecture for real-time embedded system based on system requirement specification. Students will be able to develop embedded firmware of the microcontroller based real-time system with real-time operating system objects and services.
Contents
URL to the subject page		http://tnt.etf.bg.ac.rs/~oe4srv/
URL to lectures		http://tnt.etf.bg.ac.rs/~oe4srv/index_files/Page323.html
Contents of lectures		Introduction to real-time systems, real-time operating systems architecture, standard objects and services, scheduling theory, inter-task synchronization and communication concepts, specific solution design patterns. Developing embedded applications in multitasking environment.
Contents of exercises		Introduction to selected real-time operating system API, user and reference guide. Multitasking code examples, code debugging in selected integrated development environment.
Literature
Teaching notes available at web site of department/course Qing Li and Carolyn Yao, Real-Time Concepts for Embedded Systems, CMP Books, 2003 Phillip A. Laplante, Real-Time Systems Design And Analysis, A John Wiley & Sons, Inc., Publication, 2004
Number of hours per week during the semester/trimester/year
Lectures	Exercises	OTC	Study and Research	Other classes
3	1	1
Methods of teaching		45 hours of lectures, 15 hours of supervised problem classes and consultations and 30 hours of lab exercises and project related work and midterm test. Approximately 75 hours of personal study and project related work (3 hours per week during semester, and approximately 30 hours of midterm and final test preparation)
Knowledge score (maximum points 100)
Pre obligations		Points	Final exam	Points
Activites during lectures		0	Test paper	0
Practical lessons		10	Oral examination	40
Projects
Colloquia		30
Seminars		20