The course provides a comprehensive theoretical and practical understanding and engineering applications of computational methods such as advanced topics in finite element methods, computational fluid dynamics and linear/nonlinear engineering optimization techniques..
Course description for study year 2021-2022. Please note that changes may occur.
Semester tution start
Number of semesters
Language of instruction
Faculty of Science and Technology, Department of Mechanical and Structural Engineering and Materials Science
Upon finishing the course, the candidate is expected to be able to:
Understand finite element formulations and/or finite volume methods
Formulate and solve nonlinear problems in continuum mechanics/fluid dynamics
Use numerical modeling techniques to model material/fluid behavior,
Use finite element programming tools to formulate and solve engineering optimization problems, plasticity problems and dynamics systems.
The course content covers some or all of the following topics, based on the potential candidate(s) direction of study:
FEM: Finite elements in continuum and solid mechanics, Eulerian and Lagrangian finite element formulations, Numerical modeling of material behavior, Material and geometric nonlinearity analysis, Plasticity models, Computational methods in dynamic problems, Finite elements in engineering optimization
CFD: Finite volume techniques in fluid dynamics, discretization and solution methods, selected topics in multiphase flows including Euler-Euler, Euler-Lagrange as well as Volume of fluid (VOF) methods.
Engineering optimization, linear and nonlinear optimization, advanced and nature-inspired optimization tools and approaches.
Required prerequisite knowledge
Basic background in finite element (FEM) methods and/or computational fluid dynamics (CFD).
Form of assessment
Project assignment and oral exam
Pass - Fail
The oral exam can be conducted in a form of presentation.
Hirpa Gelgele Lemu
Knut Erik Teigen Giljarhus
Head of Department:
Tor Henning Hemmingsen
Method of work
The course is conducted as self-study with student presentations, colloquia, seminars, project works and computer-based modeling and simulation exercises. Project report is submitted in a scientific article format and graded. This project report will have a quality of at least an international conference level and commonly presented in conferences and published.
Open for students admitted to PhD study in Offshore Technology or similar.
Forms/and or discussion according to given guidelines/regulations.