FINITE ELEMENTS
Stampa
Enrollment year
2019/2020
Academic year
2019/2020
Regulations
DM270
Academic discipline
MAT/08 (NUMERICAL ANALYSIS)
Department
DEPARTMENT OF MATHEMATICS "FELICE CASORATI"
Course
MATHEMATICS
Curriculum
PERCORSO COMUNE
Year of study
Period
2nd semester (02/03/2020 - 09/06/2020)
ECTS
9
Lesson hours
72 lesson hours
Language
Italian
Activity type
ORAL TEST
Teacher
SANGALLI GIANCARLO (titolare) - 9 ECTS
Prerequisites
Fundamental notions of Analysis and Numerical Analysis
Learning outcomes
Numerical and theoretical study of the finite element method and its application
Course contents
The aim of the course is to present the theoretical foundation of the finite element course, example of applications to the numerical solution of partial differential equations, and discuss its implementation. We will consider both diffusion (elliptic) problems and mixed problems, analyzing its stability, approximation properties. Then we will focus on mixed problems. In parallel, we will discuss and test its implementation in MATLAB language

Extended summary

Theory lessons will cover the following topics:
- fundamentals of Functional Analysis, with a particular emphasis on the W^{k,p} spaces and on primal variational formulations of elliptic problems
- approximation theory in Sobolev spaces: Deny-Lions Lemma and Brambe-Hilbert lemma
- Lagrange interpolation on n-simplices and corresponding interpolation error for Sobolev norms
-Galerkin method for elliptic problems and error estimates: Cea Lemma and duality techniques
- Finite Element Methods for elliptic problems, with particular emphasis to the bidimensional case
- mixed formulation of elliptic problems and its Galerkin discretization: existence, uniqueness, stability of the solution, and error analysis. Some example of Finite Elements for the diffusion problem in mixed form
- elasticity problem and its FEM discretization: the volumetric locking phenomenon and some possible cures

Computer Lab lessons will address the implementation of the finite element method, in MATLAB language. In particular:
- data structure and algorithm for the triangulation of a planar region
- interpolation and numerical integration of funtions on the triangulation
- local matrices and assembling
- Dirichlet and Neumann boundary condition
- finite element method for the Poisson problem in primal form with P1 elements
- implementation of the RT element
- finite element method for the Poisson problem in mixed form (Darcy problem)

REMARK: This is a tentative program. Significant changes might occur, also depending on the feedback provided by the Student during the lectures.
Teaching methods
Lessons and computer lab practice
Reccomended or required readings
Teacher's notes.

A. Quarteroni, A. Valli: "Numerical Approximation of Partial Differential Equations", Springer-Verlag, 1994.


Daniele Boffi, Franco Brezzi, and Michel Fortin. Mixed finite element methods and applications. Berlin: Springer, 2013.
Assessment methods
Oral examination
Further information
Sustainable development goals - Agenda 2030