FY505: Physical mathematics (5 ECTS)
STADS: 07000501Level
Bachelor course
Teaching period
The course is offered in the autumn semester.
2nd quarter.
Teacher responsible
Email: paolo.sibani@ifk.sdu.dkAdditional teachers
svensson@imada.sdu.dk steen@ifk.sdu.dkTimetable
| Group | Type | Day | Time | Classroom | Weeks | Comment |
|---|---|---|---|---|---|---|
| Common | I | Monday | 14-16 | U17 | 45-48 | |
| Common | I | Wednesday | 10-12 | U17 | 45-48 | |
| S1 | TL | Monday | 14-17 | IFK | 49-51 | |
| S1 | TL | Wednesday | 14-17 | IFK | 49-51 | |
| S1 | TE | Thursday | 10-12 | U17 | 45-48 | |
| S1 | TE | Friday | 08-10 | U17 | 45-48 |
Show personal time table for this course.
Prerequisites:
None
Academic preconditions:
FY501, FY502, MM501 and MM502 must be known.
Course introduction
To introduce the students to fundamental concepts of linear algebra and to show how to use them in modelling selected physical systems.
Qualifications
General qualifications: ability to use fundamental techniques and principles in linear algebra and numeric software for solving dynamic problems, e.g. coupled linear differential equations and boundary value problems in simple geometries. Personal qualifications: the ability of collaborate with others, to use abstract ideas in a specific connection, and to present the results in a well-planned and convincing way.
Expected learning outcome
Subject overview
The course consists of two parts of 5 ECTS points each. It is offered jointly by IFK and IMADA.
1. week: Introduction and problem formulation by IFK
2.-4. week: Mathematics - IMADA
5.-7. week: Numeric project work – IFK
Physics subject:
1. Linearisation as a physical modelling tool.
2. Coupled ordinary differential equations and normal modes.
3. Partial differential equations (diffusion equation, Schrödinger’s equation) in simple geometries.
4. Fourier transformation as a tool for data analysis and as a solving technique.
Mathemical subject:
1. Basic theory of linear vector spaces: vectors, linear independence, basis, dimension, the Euclidean vector spaces Rn and Cn. E.g. vector spaces of functions: Fourier series.
2. Linear mappings between vector spaces: rank and kernel, matrix representation, eigenvalues and eigenvectors, diagonalisation of symmetric (or hermitic) n x n matrix, solution of boundary value problems by expansion in eigenfunctions.
Projects:
The project is based on physical models and is solved by using software packages e.g. Maple or Matlab. The results must be presented in a report written using LaTeX.
Literature
- Erwin Kreyszig: Advanced Engineering Mathematics, Wiley.
Syllabus
See syllabus.
Website
This course uses e-learn (blackboard).
Prerequisites for participating in the exam
None
Assessment and marking:
1 project report. Internal examination by lecturer. Marks according to the 7-scale.
Reexamination after 4th quarter.
Expected working hours
The teaching method is based on three phase model.
Ved Institut for Matematik og Datalogi:
Forelæsninger 12 timer
Eksaminatorier 12 timer
Ved Institut for Fysik og kemi:
Forelæsninger 4 timer
Lab.øvelser 24 timer
Educational activities
Language
This course is taught in English, if international students participate. Otherwise the course is taught in Danish.
Course enrollment
See deadline of enrolment.
Tuition fees for single courses
See fees for single courses.
