Computational Intelligence

Course Information
TitleΥπολογιστική Νοημοσύνη / Computational Intelligence
Code088
FacultyEngineering
SchoolElectrical and Computer Engineering
Cycle / Level1st / Undergraduate
Teaching PeriodSpring
CoordinatorIoannis Theocharis
CommonYes
StatusActive
Course ID600001041

Programme of Study: Merikī Foítīsī - PPS Īlektrológōn Mīchanikṓn kai Mīchanikṓn Ypologistṓn (2016 - sīmera)

Registered students: 0
OrientationAttendance TypeSemesterYearECTS
ĪLEKTRIKĪS ENERGEIASElective Courses845
ĪLEKTRONIKĪS KAI YPOLOGISTŌNElective Courses845
TĪLEPIKOINŌNIŌNElective Courses845

Programme of Study: Electrical and Computer Engineering

Registered students: 175
OrientationAttendance TypeSemesterYearECTS
ELECTRICAL ENERGYElective Courses845
ELECTRONICS AND COMPUTER ENGINEERINGElective Courses845
TELECOMMUNICATIONSElective Courses845

Class Information
Academic Year2020 – 2021
Class PeriodSpring
Faculty Instructors
Class ID
600169952

Class Schedule

Building
FloorUnknown
HallΕξ αποστάσεως (900)
CalendarMonday 12:00 to 15:00
Course Type 2016-2020
  • Scientific Area
Course Type 2011-2015
Specific Foundation / Core
Mode of Delivery
  • Face to face
Digital Course Content
Language of Instruction
  • Greek (Instruction, Examination)
Prerequisites
General Prerequisites
1. Basic principles of classical logic. 2. Basic principles of calculus 3. Principles of classical control designs
Learning Outcomes
1. Comprehending the principles underlying the various processes involved in fuzzy systems: linguistic descriptions, fuzzy IF/THEN rules, rules of inference. 2. For a given problem the student should be able to formulate a suitable fuzzy rule base, select the implication operators, the fuzzification and the de-fuzzification strategies. 3. In regard to control tasks, the student should be able to develop the proper controller structure, formulate its fuzzy rule base and select suitable gain parameters for optimal system’s response. 4. In regard to fuzzy modeling for prediction tasks, design the appropriate fuzzy model and implement the parameters learning algorithm. 5. Comprehending the principles of fuzzy clustering and deal with applications to data classification. 6. Understanding the principle, structures and learning techniques involved in NNs. 7. Examining NNs of various structures, the relevant training techniques, and their applications to control, modeling and classification problems. 8. Integration of fuzzy systems and neural network models.
General Competences
  • Apply knowledge in practice
  • Retrieve, analyse and synthesise data and information, with the use of necessary technologies
  • Adapt to new situations
  • Make decisions
  • Work autonomously
  • Advance free, creative and causative thinking
Course Content (Syllabus)
Fuzzy Systems: Fuzzy sets, properties, fuzzy operators and membership functions. Resolution and extension theorems, a-cuts, fuzzy union, intersection and complement. Fuzzy relations, operations between fuzzy relations, fuzzy relation composition, fuzzy set-relation composition. Fuzzy If/Then rules and implication functions. Fuzzy rule bases, compositional rule of inference, fuzzification and defuzzications structures. Fuzzy controllers, controller structures. Design of fuzzy controllers FZ-PI, FZ-PD and FZ-PID. Comparative gain tuning, experimental results of fuzzy controllers. Fuzzy TSK models and models with crisp outputs. Training algorithms for adaptive neuro-fuzzy networks. Fuzzy clustering algorithms, the Fuzzy C-means method. Neural Networks (NNs): Perceptron model and learning rules. Supervised, unsupervised and reinforcement learning techniques. Single layer and multi-layer networks. The back-propagation algorithm. RBF networks and equivalence to fuzzy systems. Self-organizing networks SOFM. The learning vector quantization (LVQ) algorithm. Applications of NNs to prediction and control tasks. Integration between fuzzy and NN systems, neuron-fuzzy models.
Educational Material Types
  • Notes
  • Slide presentations
  • Book
Use of Information and Communication Technologies
Use of ICT
  • Use of ICT in Communication with Students
Course Organization
ActivitiesWorkloadECTSIndividualTeamworkErasmus
Lectures36
Tutorial36
Project30
Exams48
Total150
Student Assessment
Description
Written Examination (180 min) Assessment of mandatory (5) projects
Student Assessment methods
  • Written Assignment (Summative)
  • Written Exam with Problem Solving (Summative)
  • Report (Summative)
Bibliography
Course Bibliography (Eudoxus)
1. Υπολογιστική Νοημοσύνη και Εφαρμογές, Ι. Μπούταλης, Γ. Συρακούλης, Εκδόσεις: Γ. ΣΥΡΑΚΟΥΛΗΣ, 2010, ISBN: 978-960-93-2008-5 2. Eισαγωγή στην Ασαφή Λογική (Fuzzy Logic)», Γ. Θεοδώρου, Εκδόσεις: ΤΖΙΟΛΑ, 2010, ISBN: 978-960-418-218-3. 3. Neural Fuzzy Systems, C.-T. Lin and C. S. G. Lee, Prentice Hall, Inc., 1996. 4. Neuro-fuzzy and Soft Computing. A computational approach to learning and machine intelligence, J.-S. R. Yang, C.-T. Sun, and E. Mizutani, Prentice Hall, NJ, 1997.
Last Update
02-09-2020