Optimization Methods and Artificial Intelligence
BASIC DATA
course listing
A - main register
course code
EMT1135
course title in Estonian
Optimeerimismeetodid ja tehisintellekt
course title in English
Optimization Methods and Artificial Intelligence
course volume CP
-
ECTS credits
6.00
to be declared
yes
fully online course
not
assessment form
Examination
teaching semester
autumn
language of instruction
Estonian
English
Study programmes that contain the course
Structural units teaching the course
EM - Department of Mechanical and Industrial Engineering
Timetable link
Version:
VERSION SPECIFIC DATA
course aims in Estonian
Õppeaine eesmärk on anda üliõpilasele ülevaade traditsioonilistest ja kaasaegsetest optimeerimise meetoditest, selgitada nende tööpõhimõtet ning tutvustada olemasoleva rakendustarkvara kasutamist. Põhitähelepanu on pööratud praktiliste optimiseerimisprobleemide lahendamise oskuse omandamisele, kasutades ja kohandades rakendustarkvara ning tehisintellekti vahendeid.
course aims in English
The aim of the course is to give an overview on traditional and modern optimization methods, to explain working principles of these methods. Main attention is paid to aquiring practical problem solving skills utilizing and adpting optimization software and artificial intelligence tools.
learning outcomes in the course in Est.
Õppeaine läbnud üliõpilane:
- rakendab traditsiooniliste optimeerimise meetodeid inseneerias;
- kohandab ja rakendab globaalse optimeerimise ja täisarvilise planeerimise meetodeid;
- kohandab ja rakendab hübriid- ja lokaalseid otsingu algoritme inseneerias;
- rakendab multikriteriaalse optimeerimise meetodeid;
- kohandab ja rakendab tehisintellekti algoritme optimeerimisel;
- kasutab optimeerimise rakendustarkvara;
- rakendab tundlikkuse analüüsi inseneriülesannete lahendamisel.
- rakendab traditsiooniliste optimeerimise meetodeid inseneerias;
- kohandab ja rakendab globaalse optimeerimise ja täisarvilise planeerimise meetodeid;
- kohandab ja rakendab hübriid- ja lokaalseid otsingu algoritme inseneerias;
- rakendab multikriteriaalse optimeerimise meetodeid;
- kohandab ja rakendab tehisintellekti algoritme optimeerimisel;
- kasutab optimeerimise rakendustarkvara;
- rakendab tundlikkuse analüüsi inseneriülesannete lahendamisel.
learning outcomes in the course in Eng.
After completing this course, the student:
- applies traditional optimization methods in engineering;
- adjusts and applies global optimization methods and integer programming tools;
- adjusts and applies hybrid and local search algorithms in engineering;
- applies multicriteria optimization methods;
- adjusts and applies artificial intelligence algorithms in optimization;
- applies optimization software tools;
- applies sensitivity analysis for solving engineering problems.
- applies traditional optimization methods in engineering;
- adjusts and applies global optimization methods and integer programming tools;
- adjusts and applies hybrid and local search algorithms in engineering;
- applies multicriteria optimization methods;
- adjusts and applies artificial intelligence algorithms in optimization;
- applies optimization software tools;
- applies sensitivity analysis for solving engineering problems.
brief description of the course in Estonian
1. Sissejuhatus
1.1 Optimeerimisülesande püstitus. Lineaarse-, ruut- ja mittelineaarse programmeerimise ülesanded.
1.2. Lisakitsendused võrduste ja võrratuste kujul.
2.Lineaarne planeerimine
2.1.Lineaarse planeerimise ülesande lahendamine. Simpleksmeetod.
2.2.Duaalülesanne. Optimaalsuse tingimused.
2.3.Transpordiülesanne.
2.4.Täisarvuline planeerimine. Lõiketasandite meetodid.
3.Gradiendi meetodid
3.1.Kiirema languse meetod.
3.2.Newtoni meetod.
3.3.Kvaasi-Newtoni ja Gauss-Newtoni meetodid.
3.4.Karush-Kuhn-Tuckeri optimaalsuse tingimused.
3.5.Lagrange kordajate meetod.
4.Tehisintellekti vahendid optimeerimisel
5. Globaalne optimeerimine. Evolutsioonilised algoritmid.
5.1.Geneetiline algoritm,
5.2.Osakeste parve algoritmid
5.3.Sipelgameetod.
5.4.Lokaalne otsing.
5.4.1.Mägironimine (Hill Climbing)
5.4.2.Simuleeritud lõõmutamine
5.4.3.Tabu otsing.
6.Hübriidalgoritmid.
6.1.GA+Gradient
6.2.GA+Lokaalse otsingu algoritmid.
7.Funktsioonide lähendamine, vastavuse pind.
7.1.Tehisnärvivõrgud,
7.2.vähimruutude meetod.
8.Multikriteriaalne optimeerimine.
8.1.Pareto printsiip.
8.2.Kriteeriumide kombineerimisel põhinevad meetodid.
9.Tundlikkuse (sensitivity) analüüs.
1.1 Optimeerimisülesande püstitus. Lineaarse-, ruut- ja mittelineaarse programmeerimise ülesanded.
1.2. Lisakitsendused võrduste ja võrratuste kujul.
2.Lineaarne planeerimine
2.1.Lineaarse planeerimise ülesande lahendamine. Simpleksmeetod.
2.2.Duaalülesanne. Optimaalsuse tingimused.
2.3.Transpordiülesanne.
2.4.Täisarvuline planeerimine. Lõiketasandite meetodid.
3.Gradiendi meetodid
3.1.Kiirema languse meetod.
3.2.Newtoni meetod.
3.3.Kvaasi-Newtoni ja Gauss-Newtoni meetodid.
3.4.Karush-Kuhn-Tuckeri optimaalsuse tingimused.
3.5.Lagrange kordajate meetod.
4.Tehisintellekti vahendid optimeerimisel
5. Globaalne optimeerimine. Evolutsioonilised algoritmid.
5.1.Geneetiline algoritm,
5.2.Osakeste parve algoritmid
5.3.Sipelgameetod.
5.4.Lokaalne otsing.
5.4.1.Mägironimine (Hill Climbing)
5.4.2.Simuleeritud lõõmutamine
5.4.3.Tabu otsing.
6.Hübriidalgoritmid.
6.1.GA+Gradient
6.2.GA+Lokaalse otsingu algoritmid.
7.Funktsioonide lähendamine, vastavuse pind.
7.1.Tehisnärvivõrgud,
7.2.vähimruutude meetod.
8.Multikriteriaalne optimeerimine.
8.1.Pareto printsiip.
8.2.Kriteeriumide kombineerimisel põhinevad meetodid.
9.Tundlikkuse (sensitivity) analüüs.
brief description of the course in English
1. Introduction
1.1. Formulation of the optimization problem. Linear-, quadratic- and non-linear programming.
1.2 Constraints in equality and inequality form.
2. Linear planning
2.1. Solution of linear plenning problem. The simplex method.
2.2. Dual problem, optimality conditions.
2.3. Transportation problem.
2.4. Integer programming. Methods of cutting planes.
3. Gradient methods.
3.1.Steepest descent method.
3.2. Newton method
3.3 Quasi Newton and Gauss-Newton methods.
3.4. The Kuhn-Tucker condtions
3.5. The Langrange multipliers method
4. Utilizing artificial intelligence in optimization
5. Global optimization techniques. Population methods.
5.1. Genetic algorithm.
5.2. Particle swarm optimization.
5.3. Ant colony optimization.
5.4. Local search
5.4.1. Hill Climbing
5.4.2. Simulated annealing
5.4.3 Tabu search
6. Hybrid algorithms
6.1. GA+Gradient
6.2. GA+local search
7. Function approximation, responce surface.
7.1. Artificial neural networks
7.2. Least square method
8. Multicriteria optimization
8.1. Pareto concept
8.2.Combining optimality criteria
9. Sensitivity analysis.
1.1. Formulation of the optimization problem. Linear-, quadratic- and non-linear programming.
1.2 Constraints in equality and inequality form.
2. Linear planning
2.1. Solution of linear plenning problem. The simplex method.
2.2. Dual problem, optimality conditions.
2.3. Transportation problem.
2.4. Integer programming. Methods of cutting planes.
3. Gradient methods.
3.1.Steepest descent method.
3.2. Newton method
3.3 Quasi Newton and Gauss-Newton methods.
3.4. The Kuhn-Tucker condtions
3.5. The Langrange multipliers method
4. Utilizing artificial intelligence in optimization
5. Global optimization techniques. Population methods.
5.1. Genetic algorithm.
5.2. Particle swarm optimization.
5.3. Ant colony optimization.
5.4. Local search
5.4.1. Hill Climbing
5.4.2. Simulated annealing
5.4.3 Tabu search
6. Hybrid algorithms
6.1. GA+Gradient
6.2. GA+local search
7. Function approximation, responce surface.
7.1. Artificial neural networks
7.2. Least square method
8. Multicriteria optimization
8.1. Pareto concept
8.2.Combining optimality criteria
9. Sensitivity analysis.
type of assessment in Estonian
-
type of assessment in English
-
independent study in Estonian
MATLAB rakendused gradiendi meetodite ja evolutsiooniliste meetodite realiseerimiseks nii ühe- kui ka multikriteriaalsete optimeerimisülesannete lahendamiseks.
independent study in English
MATLAB application for utilizing gardient and evolutionary methods for solution of both one and multicriteria optimization problems.
study literature
1. Singiresu S Rao, Engineering Optimization Theory and Practice, Fifth Edition
2020 John Wiley & Sons, Inc, DOI:10.1002/9781119454816
2. Joaquim R. R. A. Martins Andrew Ning,Engineering Design Optimization, 2022
3. Amir H. Gandomi and Laith Abualigah , Eds., Evolutionary Process for Engineering Optimization,
2022, 286p, https://doi.org/10.3390/books978-3-0365-4772-5
2020 John Wiley & Sons, Inc, DOI:10.1002/9781119454816
2. Joaquim R. R. A. Martins Andrew Ning,Engineering Design Optimization, 2022
3. Amir H. Gandomi and Laith Abualigah , Eds., Evolutionary Process for Engineering Optimization,
2022, 286p, https://doi.org/10.3390/books978-3-0365-4772-5
study forms and load
daytime study: weekly hours
4.0
session-based study work load (in a semester):
lectures
2.0
lectures
16.0
practices
2.0
practices
16.0
exercises
0.0
exercises
-
lecturer in charge
Jüri Majak, täisprofessor tenuuris (EM - mehaanika ja tööstustehnika instituut)
LECTURER SYLLABUS INFO
semester of studies
teaching lecturer / unit
language of instruction
Extended syllabus or link to Moodle or to home page
2024/2025 autumn
Jüri Majak, EM - Department of Mechanical and Industrial Engineering
English