Course syllabus for Partial differential equations, first course

The course syllabus contains changes
See changes

Course syllabus adopted 2022-02-09 by Head of Programme (or corresponding).

Overview

  • Swedish namePartiella differentialekvationer, grundkurs
  • CodeTMA373
  • Credits7.5 Credits
  • OwnerMPENM
  • Education cycleSecond-cycle
  • Main field of studyMathematics
  • DepartmentMATHEMATICAL SCIENCES
  • GradingTH - Pass with distinction (5), Pass with credit (4), Pass (3), Fail

Course round 1

  • Teaching language English
  • Application code 20154
  • Open for exchange studentsYes

Credit distribution

0122 Laboratory, part A 1.5 c
Grading: UG
1.5 c
0222 Examination, part B 6 c
Grading: TH
6 c
  • 13 Mar 2023 am J
  • 08 Jun 2023 pm J
  • 24 Aug 2023 am J

In programmes

Examiner

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Eligibility

General entry requirements for Master's level (second cycle)
Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling the requirements above.

Specific entry requirements

English 6 (or by other approved means with the equivalent proficiency level)
Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling the requirements above.

Course specific prerequisites

Linear algebra and calculus in one and several variables

Aim

The course gives an introduction to the modern theory of partial differential equations (PDE) with applications in science and engineering. It also presents an introduction to the finite element method (FEM) as a general tool for numerical solution of PDE. The students will obtain a basic understanding of qualitative properties, such as existence, regularity, uniqueness, and stability of solutions of PDE and their approximations by means of FEM. The understanding should be sufficient to allow them, in a future professional or research situation, to model scientific problems as PDE and to construct and analyze numerical approximation methods.   

Learning outcomes (after completion of the course the student should be able to)

  • derive weak formulations of the basic initial-boundary value problems for PDEs.
  • derive stability estimates for the continuous problems and predict the influence of data.
  • formulate Galerkin finite element methods for PDEs and dynamical systems.
  • derive error estimates using exact solution (a priori) and numerical solution (a posteriori).
  • explain how the finite element method is implemented in computer code.
  • improve the error estimates modifying the method or employing adaptive procedure.
  • draw relevant conclusions about stability, reliability and efficiency of the methods.

Content

Weak solutions to elliptic, parabolic, and hyperbolic partial differential equations (PDE). Computation of approximate solutions to various PDE by the finite element method (as well as dynamical systems). Interpolation, quadrature and linear systems. A brief introduction to representation theorems and abstract theory to justify the weak (variational) approach. A priori and a posteriori error estimates. Applications to e.g. diffusion, heat conduction, and wave propagation. More precisely the course covers following topics: Basic interpolation theory: Interpolation with polynomials Interpolations error analys quadrature rules and quadrature error. Numerical linear algebra: Solving linear system of equation with Jacobi's method Gauss- Seidel and Overrelaxation methods. Dynamical system: Structures in approximation with polynomials Ill-conditioned system. Finite element method for boundary-value problem in 1D: Stability Error estimates and algorithms Finite element method för initial-value problem i 1D: Fundamental solution Stability Error estimates and algorithms The dual problem. Lax-Milgram theorem: Abstract formulation Riesz representation theorem Studies and Analysis of problems in higher space dimensions: Finite element in higher space dimensions. Finite element method for Poisson equation in higher space dimensions. Finite element method for heat equation in higher space dimensions. Stability Error estimates and numerical algorithms Finite element method for wave equation in higher space dimensions. Fundamental solution Stability Error estimates and numerical algorithms Finite element method for convection-diffusion equations: Stability Error estimates and numerical algorithms

Organisation

Lectures (about 35 hours), exercises (about 21 hours) and home assignments consisting of both theoretical and computer assingments.

Literature

M. Asadzadeh : An Introduction to Finite Element Methods (FEM) for Differential Equations. (Available in Cremona)

M. Asadzadeh, Lecture Notes in PDE (electronic)

Examination including compulsory elements

Written exam, and pass on computer exercises

The course examiner may assess individual students in other ways than what is stated above if there are special reasons for doing so, for example if a student has a decision from Chalmers on educational support due to disability.

The course syllabus contains changes

  • Changes to examination:
    • 2023-03-20: Exam date Exam date 2023-08-24 added by Elisabeth Eriksson
      [36847, 59195, 3], New exam for academic_year 2022/2023, ordinal 3 (not discontinued course)
    • 2023-01-10: Exam date Exam date 2023-06-08 added by Elisabeth Eriksson
      [36847, 59195, 2], New exam for academic_year 2022/2023, ordinal 2 (not discontinued course)