Identifying Data

2021/22

Subject (*)

Boundary element methods

Code

614855230

Study programme

Mestrado Universitario en Matemática Industrial (2013)

Descriptors

Cycle

Period

Year

Type

Credits

Official Master's Degree

2nd four-month period

First

Optional

Language

Spanish

Teaching method

Hybrid

Prerequisites

Department

Matemáticas

Coordinador

Gonzalez Taboada, Maria

E-mail

maria.gonzalez.taboada@udc.es

Lecturers

Gonzalez Taboada, Maria

E-mail

maria.gonzalez.taboada@udc.es

Web

http://http://www.m2i.es

General description

Neste curso preséntase unha introdución ao método dos elementos de contorno. Usando como modelo un problema de potencial, estudianse o método directo e os métodos indirectos baseados nas formulacións de capa simple e capa dobre para resolver problemas en dúas e tres dimensións. Seguidamente descríbese a aplicación do método a problemas de dispersión (scattering) e de radiación acústica, mecánica de fluidos e elastostática linear. Finalmente, amósanse técnicas básicas de acoplamiento de métodos de elementos de contorno con métodos de elementos finitos que permiten ampliar á apricabilidade das técnicas estudiadas.

Contingency plan

1. Modificacións nos contidos
Non se realizarán cambios.

2. Metodoloxías
*Metodoloxías docentes que se mantienen
Se mantienen todalas metodoloxías.

*Metodoloxías docentes que se modifican

3. Mecanismos de atención personalizada ao alumnado

Correo electrónico: La profesora lo consultará diariamente con el obxectivo de resolver consultas rápidas, concertar reunións virtuals para resolver dudas dos estudiantes e para o seguimento dos traballos tutelados.

Teams: Se realizarán duas sesións semanais para avanzar nos contidos e nos traballos tutelados. Estas sesións se celebrarán na franxa horaria que teña asignada a materia no calendario académico. Poderanse realizar titorías empregando Teams.

4. Modificacións na avaliación

Non hai cambios.

*Observacións da avaliación:

5. Modificacións da bibliografía o webgrafía

Non hai cambios. Os materiais de traballo dixitalizados se facilitarán aos estudiantes bien por correo electrónico o bien a través de Teams.

Study programme competencies

Code	Study programme competences
A4	Ser capaz de seleccionar un conjunto de técnicas numéricas, lenguajes y herramientas informáticas, adecuadas para resolver un modelo matemático.
A8	Saber adaptar, modificar e implementar herramientas de software de simulación numérica.
B3	Ser capaz de integrar conocimientos para enfrentarse a la formulación de juicios a partir de información que, aun siendo incompleta o limitada, incluya reflexiones sobre las responsabilidades sociales y éticas vinculadas a la aplicación de sus conocimientos.
B5	Poseer las habilidades de aprendizaje que les permitan continuar estudiando de un modo que habrá de ser en gran medida autodirigido o autónomo, y poder emprender con éxito estudios de doctorado.

Learning aims

Learning outcomes	Study programme competences
To know the advantages and limitations of the boundary element method	AC4	BC2 BR1
To know the steps to solve a boundary value problem using the boundary element method		BC2 BR1
To know the fundamental solutions, the integral representation formula and the boundary integral equations related to the problems considered in this subject	AC4	BC2 BR1
Be able to construct Matlab programs that solve an elliptic problem using the boundary element method.	AC8	BC2 BR1
To know and be able to apply the direct and indirect methods	AC4	BC2 BR1
Given a boundary integral equation, be able to discretize it using the boundary element method and to derive the associated linear system	AC8	BC2 BR1

Contents

Topic	Sub-topic
Introduction and some preliminaries	1. Introduction 2. Integral equations 3. Singular integrals 4. Fractional index Sobolev spaces
Potential problems	1. The model problem 2. Fundamental solution for the Laplace operator 3. The transmission property 4. Jump relations 5. Boundary integral equations 6. The boundary element method 7. Indirect formulations 8. Implementation in MATLAB
Other applications of the boundary element methods	1. Acoustics: the Helmholtz equation 2. The Stokes problem 3. Linear elastostatics
Introduction to the coupling of boundary elements and finite elements	1. Introduction 2. The one integral equation method 3. The two integral equations methods 4. The uncoupling method

Planning

Methodologies / tests	Competencies	Ordinary class hours	Student’s personal work hours	Total hours
Guest lecture / keynote speech	A4 B5 B3	14	35	49
Laboratory practice	A8 B5 B3	7	7	14
Supervised projects	A4 A8 B5 B3	1	9	10

Personalized attention		2	0	2

(*)The information in the planning table is for guidance only and does not take into account the heterogeneity of the students.

Methodologies

Methodologies	Description
Guest lecture / keynote speech	The theoretical contents will be presented through lectures.
Laboratory practice	The implementation in Matlab of the boundary element method to solve the problems considered in the subject will be shown.
Supervised projects	At the end of the course, a project will be proposed to each student.

Personalized attention

Methodologies

Supervised projects

Description

Students can ask to the teacher any questions that arise during the performance of the project that has been proposed to them.

Assessment

Methodologies	Competencies	Description	Qualification
Supervised projects	A4 A8 B5 B3	The evaluation of the knowledge acquired in this subject will take into account the completion of the exercises presented in the lectures (50% of the final grade) and the supervised work that will be proposed at the end of the subject (50% remaining).	100

Assessment comments
The evaluation criteria are the same in June and July.

Sources of information

Basic	S.A. Sauter y C. Schwab (2011). Boundary Element Methods. Springer G. Chen y J. Zhou (1992). Boundary Element Methods. Academic Press G.C: Hsiao y W.L. Wendland (2021). Boundary Integral Equations. Springer K.-C. Ang (2007). Introducing the boundary element method with MATLAB. Int. J. Math. Education in Sci. and Technology

Complementary	W. Hackbusch (1995). Integral Equations. Birkhauser G. Beer (2001). Programming the Boundary Element Method. John Wiley & Sons R. Adams (1979). Sobolev spaces. Academic Press W. McLean (2000). Strongly elliptic systems and boundary integral equations. Cambridge University Press

Recommendations

Subjects that it is recommended to have taken before

Numerical methods and programming/614855201

Numerical methods for partial differential equations/614855204

Subjects that are recommended to be taken simultaneously

Subjects that continue the syllabus

Other comments
It is recommended that students take the subject up to date and use the tutorial hours to solve their doubts.

(*)The teaching guide is the document in which the URV publishes the information about all its courses. It is a public document and cannot be modified. Only in exceptional cases can it be revised by the competent agent or duly revised so that it is in line with current legislation.