Industrial Informatics

Code:

EEC0144

Acronym:

II

Keywords
Classification	Keyword
OFICIAL	Automation, Control & Manufacturing Syst.
OFICIAL	Informatics

Instance: 2014/2015 - 1S

Active?	Yes
Responsible unit:	Department of Electrical and Computer Engineering
Course/CS Responsible:	Master in Electrical and Computers Engineering

Cycles of Study/Courses

Acronym	No. of Students	Study Plan	Curricular Years	Credits UCN	Credits ECTS	Contact hours	Total Time
MIEEC	104	Syllabus	4	-	6	56	162

Teaching language

Portuguese

Objectives

Students should be capable of analysing, structuring, conceiving, implementing and documenting industrial control systems of medium complexity. They should be capable of using modelling tools (UML) and programming languages used in industry (IEC 61131-3 and IEC 61499).

Learning outcomes and competences

Students should be capable of analysing, structuring, conceiving, implementing and documenting industrial control systems of medium complexity. They should be capable of using modelling tools (UML) and programming languages used in industry (IEC 61131-3 and IEC 61499).

Working method

Presencial

Program

Unified Modelling Languages (class models, sequence diagrams, state machines) Object-oriented programming according to IEC 61131-3 Distributed programming according to IEC 61499 Introduction to OPC technology

Mandatory literature

Karl-Heinz John, Michael Tiegelkamp; IEC 61131-3: Programming Industrial Automation Systems, Springer; 1 edition (April 27, 2001), 2001. ISBN: ISBN-13: 978-3540677529
Lewis, Robert W.; Modelling control systems using IEC 61499. ISBN: 0-85296-796-9
Fowler, Martin; UML distilled. ISBN: 0-201-65783-X

Complementary Bibliography

Robert W. Lewis; Programming Industrial Control Systems Using Iec 1131-3, Institution of Electrical Engineers; Revised edition (October 1998), 1998. ISBN: ISBN-13: 978-0852969502
Brandl, Dennis; Design Patterns for Flexible Manufacturing. ISBN: 978-1-55617-998-3

Teaching methods and learning activities

Theoretical classes: presentation of the themes of the course and discussion of practical examples Practical classes: Resolution of exercises and supervision of the assignments (control of a flexible manufacturing cell)

Software

Isagraf

Evaluation Type

Distributed evaluation with final exam

Assessment Components

Designation	Weight (%)
Exame	50,00
Trabalho laboratorial	50,00
Total:	100,00

Eligibility for exams

According to General Evaluation Rules of FEUP Students have to reach a minimum mark of 50% in the practical component of the course

Calculation formula of final grade

Final Exam: 9 values Practical Assignment: 9 values Professors’ opinion: 2 values Students have to reach a minimum mark of 40% in each of the assessment components. If it happens to exist a difference of more than 4 values between the two components (from 0 to 20), the best mark will be adjusted, so that there is only a difference of 4 values.

Examinations or Special Assignments

To be decided with the professors

Special assessment (TE, DA, ...)

To be decided with the professors