1. Introduction to mathematical modeling, principles of mathematical model
2. Analytical solution of Poisson's and Laplace's equation
3. The finite element method, a variation of a functional, properties of basis functions.
4. Patterns of creating finite element mesh (accuracy vs. computation speed).
5. Boundary and initial conditions for modeling of forming processes - an overview.
6. Thermo-mechanical analysis in forming.
7. Tribology and friction during forming.
8. Model of heat transfer to the surroundings and the tools.
9. Mathematical modeling temperature fields of rolled products and forging.
10. Mathematical modeling of forging (upsetting, extension).
11. Mathematical modeling of microstructure evolution during forming.
12. Mathematical modeling of rolling of asymmetrical shapes.
13. Use of mathematical modeling in the evaluation of technological formability.
14. Mathematical modeling of wire drawing
2. Analytical solution of Poisson's and Laplace's equation
3. The finite element method, a variation of a functional, properties of basis functions.
4. Patterns of creating finite element mesh (accuracy vs. computation speed).
5. Boundary and initial conditions for modeling of forming processes - an overview.
6. Thermo-mechanical analysis in forming.
7. Tribology and friction during forming.
8. Model of heat transfer to the surroundings and the tools.
9. Mathematical modeling temperature fields of rolled products and forging.
10. Mathematical modeling of forging (upsetting, extension).
11. Mathematical modeling of microstructure evolution during forming.
12. Mathematical modeling of rolling of asymmetrical shapes.
13. Use of mathematical modeling in the evaluation of technological formability.
14. Mathematical modeling of wire drawing