Courses persons responsible
Juhani Koski

Lecturers
Juhani Koski

Implementations

	Period 1	Period 2	Period 3	Period 4	Period 5	Summer
Lecture	-	-	4 h/week	4 h/week	2 h/week	-
Exercise	-	-	2 h/week	2 h/week	2 h/week	-
Exam

(Timetable for academic year 2007-2008)

Content

Content	Core content	Complementary knowledge	Specialist knowledge
1.	Different formulations of structural optimization problems. Linear programming in plasticity. Unconstrained nonlinear programming problem. Basic algorithms for the numerical solution of the optimization problem. Kuhn-Tucker conditions and general sensitivity analysis. Approximations. Discrete and global optimization. Sensitivity computations based on FEM. Shape optimization. Dual theory. Optimality criteria methods. Decomposition of large problems. Multicriterion optimization. Computer packages for FEM-based structural optimization.

Requirements for completing the course
Exercises, team work and a written examination.

Evaluation criteria for the course

Study material

Type	Name	Auhor	ISBN	URL	Edition, availability...	Exam material	Language
Book	Elements of Structural Optimization	R., T., Haftka and Z., Gurdal			Kluwer, 1992	Yes	English
Book	Optimum Structural Design	U., Kirsch			Springer-Verlag, 1993	No	English

Prerequisites

Code	Course	Credits	M/R
TME-1300	TME-1300 Strength of Materials	5	Recommendable
TME-2300	TME-2300 Finite Element Method	6	Recommendable

Prequisite relations (Sign up to TUT Intranet required)

Remarks

Distance learning

- In information distribution via homepage, newsgroups or mailing lists, e.g. current issues, timetables
- In distributing and/or returning exercise work, material etc

- Contact teaching: 47 %
- Distance learning: 0 %
- Proportion of a student's independent study: 53 %

Scaling

Methods of instruction	Hours
Lectures	90
Exercises	30
Assignments	39
Total sum	159

Correspondence of content
TME-3400 Structural Optimization

Course homepage

Last modified	31.01.2007
Modified by	Tapio Salmi