Course

Applied Mathematical Modelling and Analysis (PET933)

The course introduces methods for deriving and analyzing mathematical models of systems and processes within science and engineering, focusing on how such models can be used to motivate, design and interpret experiments. Fundamental conservation principles will be used to derive mathematical models followed by dimensional analyses and scaling for solving the model analytically by perturbation methods or numerically. The course concludes with certain topics from statistics, including linear and nonlinear regression methods.

Throughout the course, example problems from classical mechanics and/or fluid mechanics will be used to illustrate the application of both analytical and numerical methods. Examples may include mechanical vibrations of slender structures, advection and diffusion processes, or general viscous flows in two-dimensional geometries.


Course description for study year 2021-2022. Please note that changes may occur.

See course description and exam/assesment information for this semester (2024-2025)

Semesters

Facts

Course code

PET933

Credits (ECTS)

10

Semester tution start

Autumn

Language of instruction

English

Number of semesters

1

Exam semester

Autumn

Time table

View course schedule

Literature

The syllabus can be found in Leganto

Content

The course introduces methods for deriving and analyzing mathematical models of systems and processes within science and engineering, focusing on how such models can be used to motivate, design and interpret experiments. Fundamental conservation principles will be used to derive mathematical models followed by dimensional analyses and scaling for solving the model analytically by perturbation methods or numerically. The course concludes with certain topics from statistics, including linear and nonlinear regression methods.

Throughout the course, example problems from classical mechanics and/or fluid mechanics will be used to illustrate the application of both analytical and numerical methods. Examples may include mechanical vibrations of slender structures, advection and diffusion processes, or general viscous flows in two-dimensional geometries.

Learning outcome

Upon successful completion of the course, the student will be able to:
  • Apply conservation principles to derive mathematical models of a wide range of physical systems and processes,
  • Use dimensional analysis and scaling to analyze and simplify models,
  • Solve mathematical models using regular and singular perturbation techniques, as well as numerical methods,
  • Actively use mathematical models to design experiments and analyze measurements.

Required prerequisite knowledge

None

Recommended prerequisites

Mathematical Methods 1 (MAT100), Mathematical Methods 2 (MAT200), Probability and Statistics 1 (STA100)
Basic knowledge of physics and mathematics, including statistics. Basic knowledge of numerical methods is recommended.

Exam

Form of assessment Weight Duration Marks Aid Exam system Withdrawal deadline Exam date
Oral exam 2/5 Passed / Not Passed
Project assignment 3/5 Passed / Not Passed None permitted


Course teacher(s)

Head of Department:

Øystein Arild

Course coordinator:

Hans Joakim Skadsem

Method of work

Lectures, voluntary exercises and a mandatory project assignment.

Open for

Single Course Admission to PhD-courses Technology and Natural Science - PhD programme

Course assessment

Standard UiS procedure.

Contact

Head of Department:

Øystein Arild

Course coordinator:

Hans Joakim Skadsem

Offered by

Faculty of Science and Technology

Department of Energy and Petroleum Engineering

The course description is retrieved from FS (Felles studentsystem). Version 1