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2020/2021

Differential equations and modelling I

Code: 100100 ECTS Credits: 9
Degree Type Year Semester
2500149 Mathematics OB 3 1
The proposed teaching and assessment methodology that appear in the guide may be subject to changes as a result of the restrictions to face-to-face class attendance imposed by the health authorities.

Contact

Name:
Magdalena Caubergh
Email:
Magdalena.Caubergh@uab.cat

Use of Languages

Principal working language:
catalan (cat)
Some groups entirely in English:
No
Some groups entirely in Catalan:
Yes
Some groups entirely in Spanish:
No

Teachers

Joan Carles Artés Ferragud

Prerequisites

Linear Algebra

Calculus in Several variables.

Objectives and Contextualisation

The Theory of Differential Equations is distinguished both by the richness of ideas and methods as well as by its applicability. Thus the subject Differential Equations and Modeling I has a theoretical aspect (that will be used in theory and problem lessons)  as well as a very applied aspect (which will be introduced in the theory sessions and will be developed in problems and practical sessions). Practical lessons will be carried out in the computer lab. On the one hand we will emphasize the presentation of the theory and the demonstration of the results and on the other hand the students will learn how to model real situations that allow them to predict the studied behaviors.

We think that this subject is good to show to the students that certain theoretical results that they already know about other subjects (topological properties of normed spaces and Jordan canonical forms, for example) can be applied to develop the theory of differential equations.

Competences

  • Actively demonstrate high concern for quality when defending or presenting the conclusions of one’s work.
  • Identify the essential ideas of the demonstrations of certain basic theorems and know how to adapt them to obtain other results.
  • Recognise the presence of Mathematics in other disciplines.
  • Students must be capable of applying their knowledge to their work or vocation in a professional way and they should have building arguments and problem resolution skills within their area of study.
  • Students must be capable of communicating information, ideas, problems and solutions to both specialised and non-specialised audiences.
  • Use computer applications for statistical analysis, numeric and symbolic calculus, graphic display, optimisation or other purposes to experiment with Mathematics and solve problems.
  • Work in teams.

Learning Outcomes

  1. Actively demonstrate high concern for quality when defending or presenting the conclusions of one’s work.
  2. Apply the main methods for resolving ordinary differential equations and some simple partial derivative equations.
  3. Resolve linear systems of ordinary differential equations.
  4. Students must be capable of applying their knowledge to their work or vocation in a professional way and they should have building arguments and problem resolution skills within their area of study.
  5. Students must be capable of communicating information, ideas, problems and solutions to both specialised and non-specialised audiences.
  6. Translate some real problems into the terms of ordinary differential equations and partial derivative equations.
  7. Work in teams

Content

1. Differential Equations of the first order.

1.1 Introduction to differentia equations. Separable equatiuons. Exact equations.

1.2 Applications to modelling.

2. The linear equation.

2.1  Uniqueness and existence theorems. Algebraic properties of the space of solutions. Liouville's theoreme.

2.2 The autonomous case: Exponencial of a matrix.

2.3 The linear equation of order n.

3. Uniqueness and existence theorems

3.1 The Cauchy's problem. Picard and Peano theorems.

3.2 Prolongation of solutions. Wintner's lemma

3.3 Continuous and differentiable dependence on initial data and parameters.

4. Qualitative theory of autonomous systems.

4.1 Dynamical systems.Critical points and periodic orbits. Stability. Conjugation of dynamical systems.

4.2 Tubular flow theorem. Hartman's theorem.

4.3 Qualitative study of the autonomous linear equation.

Methodology

Fundamental in the learning process of the subject is the work by the student, who can count on the guidance of the teacher at each moment.

There will be three types of guided activities:

Theory Classes: The teacher introduces the basic concepts of the subject matter showing examples, demostrating properties and fundamental results. The student must complement the teacher's explanations with personal study.

Classes of Problems: We work on the understanding and application of the concepts and tools introduced to theory, with the realization of theoretical and/or practical exercises. It is well known that the only way to learn mathematics is by solving lots and lots of problems. For this reason we think that the student must dedicate a minimum of 5 hours a week to solving problems in this subject. The student will have a list of problems for each theme, which he must think about, try to solve and which will be worked on in the problem classes. A delivery of problems is requested for each theme to ensure that this work is done continuously.

Computer practices: in each session a different type of differential equation will be dealt with to model a real situation and predict future behaviors depending on circumstancial parameters.

The exercises that appear in the lists of Problems or Computer Practices and that have not finished in the corresponding session will have to solve them the student like part of his autonomous work.

The notes on the Theory, the lists of Problems and Computer Practices will be posted on the subject's Moodle Aules website; a summary of the Theory and Problem classes is also posted weekly.

Activities

Title Hours ECTS Learning Outcomes
Type: Directed      
Practical modelization problems 12 0.48
Theory classes 30 1.2
Type: Supervised      
Problem classes 30 1.2
Type: Autonomous      
Study of the theory and resolution of problems 114 4.56

Assessment

50% of the course will be evaluated in a continuous way.

Continuous evaluation:

  • Control at the end of 2-3 practical sessions (9%) and 1 final exam of practical sessions (9%).
  • 5 handouts of Problems (1 for each theme)
  • 1 partial exam that counts for 27%.

Evaluation that can be repeated to get a new oportunity:

  • 1 final exam that counts for 50%.
  • In case the final exam is repeated, the new opportunity counts for 50%.

To pass the course it is necessary to have obtained a note of at least 40% at the final exam.

Assessment Activities

Title Weighting Hours ECTS Learning Outcomes
Exam of practical sessions 9% 3 0.12 5, 4, 3, 6
Final exam 50% 4 0.16 2, 1, 4, 3, 6
Handout of practical work 9% 12 0.48 5, 4, 3, 6, 7
Handout of problemes 5% 12 0.48 2, 1, 4, 3, 6, 7
Partial exam 27% 4 0.16 2, 1, 4, 3, 6
Repeated final exam 50% 4 0.16 2, 1, 4, 3, 6

Bibliography

P. Blanchard, and R.L. Devaney. Differential Equations. G.R. Hall, 2002. Traduït al castellà: "Ecuaciones Diferenciales". International Thomson Editores, México, 1999.

E. Boyce, y R.C. Di Prima. Ecuaciones Diferenciales y Problemas con Valores en la Frontera. Ed. Limusa, México, 1967.

R.L. Borrelli and C.S. Coleman. Differential equations: a modeling perspective. Prentice-Hall, 1987.

M. Braun. Ecuaciones diferenciales y sus aplicaciones. Grupo Editorial Iberoamérica. México, 2000. 

R. Cubarsí. Equacions diferencials i la transformada de Laplace. Iniciativa Digital Politècnica, 2012. (http://hdl.handle.net/2099.3/36610)

C. Fernandez y J.M. Vegas. Ecuaciones diferenciales. Pirámide, Madrid, 1996.

G. Fulford, P. Forrester, A. Jones. Modelling with differential and difference equations. Cambridge University Press, New York, 1997.

M. Guzmán. Ecuaciones diferenciales ordinarias. Ed. Alhambra, Madrid, 1978.

M. W. Hirsch , S. Smale, R. Devaney. Differential Equations, Dynamical Systems: An Introduction to Chaos. Elsevier, 2003.

V. Jimenez. Ecuaciones diferenciales. Serie: enseñanza. Universidad de Murcia, 2000.

M.C. Leseduarte, M. D. Llongueras, A. Magaña, R. Quintanilla de Latorre. Equacions Diferencials: Problemes resolts. Iniciativa Digital Politècnica, 2012. (http://hdl.handle.net/2099.3/36607)

F. Mañosas. Apunts d'Equacions diferencials. Campus virtual.

R. Martínez. Models amb Equacions Diferencials. Materials de la UAB, Servei de Publicacions de la UAB, no. 149. Bellaterra, 2004.

R.K. Nagle, E.B. Saff and A.D. Snyder. Fundamentos de Ecuaciones diferenciales. Addison Wesley, 1992.

C.Perelló.Càlcul infinitesimal amb mètodes numèrics i aplicacions. Enciclopèdia Catalana, 1994.

G.F. Simmons. Ecuaciones diferenciales con aplicaciones y notas históricas. Mc Graw-Hill, 1977.

H. Ricardo. Ecuaciones diferenciales: una introducción moderna. Editorial Reverté, Barcelona, 2008.

D.G. Zill. Ecuaciones diferenciales con aplicaciones de modelado. International Thomson Editores, México, 2001.