Checking date: 05/09/2022

Course: 2022/2023

Real time systems
Study: Bachelor in Industrial Electronics and Automation Engineering (223)

Coordinating teacher: ARMINGOL MORENO, JOSE MARIA

Department assigned to the subject: Systems Engineering and Automation Department

Type: Electives
ECTS Credits: 3.0 ECTS


Requirements (Subjects that are assumed to be known)
Computing Systems
By the end of this content area, students will be able to have: 1. coherent knowledge of their branch of engineering including some at the forefront of the branch in real time systems; 2. the ability to apply their knowledge and understanding of computing systems to identify, formulate and solve engineering problems using established methods for deterministic systems; 3. the ability to apply their knowledge and understanding to develop and realise designs to meet defined and specified time requirements; 4. an understanding of design methodologies, and an ability to use them. 5. workshop and programming skills. 6. the ability to select and use appropriate equipment, tools and methods; 7. the ability to combine theory and practice to solve problems of computing systems; 8. an understanding of applicable techniques and methods in computing systems, and of their limitations
Skills and learning outcomes
Description of contents: programme
1- Introduction to real-time systems. 1.1 - Applications of Real-Time Systems 2- Concurrent Programming. 2.1 - Concurrent components 2.2 - Interaction and communication 3- Real-time operating systems. 3.1 - Characteristics of Real-Time Systems 4- Methods-time measurement. 4.1 - Time Services 4.2 - Posix 5- Fault-Tolerant Real-Time Systems. 5.1 - Components 5.2 - Redundancy 5.3 - Standards 6- Planning and task analysis. 6.1 - Types of Real-Time Tasks 6.2 - Task Scheduling 7- Response time. 7.1 - Algorithms
Learning activities and methodology
- Skillful classes, classes of resolution of doubts in reduced groups, individual presentations of the students, individual tutorials and personal work of the student; oriented to the theoretical knowledge acquisition (3 credits ECTS). - Practices of laboratory and individual classes of problems in reduced groups, individual tutorials and personal work of the student; oriented to the acquisition of practical abilities related to the program of the subject (3 credits ECTS).
Assessment System
  • % end-of-term-examination 0
  • % of continuous assessment (assigments, laboratory, practicals...) 100
Calendar of Continuous assessment
Basic Bibliography
  • Burns, A.; Wellings, A.. Real-time systems and programming languages. Addison-Wesley. 2003
  • Klein, M.. A Practitioner¿s Handbook for Real Time Analysis. Kluwer . 1996
  • Kopetz, Hermann. Real-time systems : design principles for distributed embedded applications. Springer. 2011
  • Phillip A. Laplante. Real-Time Systems Design and Analysis, 3rd Edition. Wiley-IEEE Press. 2004
  • Rajib Mall. Real-Time Systems. Pearson India. On-line
  • Sanjoy BaruahMarko BertognaGiorgio Buttazzo. Multiprocessor Scheduling for Real-Time Systems. Springer. 2015
Recursos electrónicosElectronic Resources *
Additional Bibliography
  • David Vallejo, Carlos González, Javier A. Albusac. Programación Concurrente y Tiempo Real. 2015
  • Liu, Jane W.S.. Real time systems . Prentice-Hall. 2000
  • Mathai, J.. Real Time Systems: Specification. Verification and Analysis. Prentice Hall . 1996
  • Rajkumar, R. . Synchronization in Real-Time Systems: a priority inheritance approach. Kluwer. 1991
  • Stallings, W.. Sistemas operativos. Prentice-Hall. 1997
  • Williams, Rob. Real-time systems development. Butterworth Heinemann. 2006
Recursos electrónicosElectronic Resources *
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The course syllabus may change due academic events or other reasons.