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APLICACIONES DE LA ASTROFÍSICA COMPUTACIONAL (AAC)

Créditos Dept.
5.625 (4.5 ECTS) UV

Profesores

Responsable:  (-)
Otros:(-)

Objectivos Generales

In this course, students are expected to apply their knowledge of computational models in astrophysics and supercomputing to solve selected problems. The course is oriented towards the cooperative work of the students.

Objectivos Específicos

Conocimientos

  1. General description of codes in Astrophysical Hydrodynamics.
  2. General description of codes in Relativistic (magneto-)hydrodynamics.
  3. General description of codes in Cosmology.
  4. Numerical experiments.
  5. Computing some simple astrophysical and cosmological models.

Habilidades

  1. To perform numerical experiments using programs provided by the lecturer, or public domain software.
  2. To reproduce some basic tests used for validation of modern Astrophysical numerical codes.
  3. To analyze and represent scientific data.

Competencias

  1. Numerical algorithms in Astrophysical Hydrodynamics.
  2. Numerical algorithms in Cosmology.
  3. Numerical algorithms in Relativistic (magneto-)hydrodynamics.
  4. To solve selected problems in computational astrophysics.

Contenidos

Horas estimadas de:

T P L Alt L Ext. Est O. Ext.
Teoria Problemas Laboratorio Otras actividades Laboratorio externo Estudio Otras horas fuera del horario fijado

1. Introduction.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
1,0 0 0 0 0 0 0 1,0

2. Numerical algorithms in Astrophysical Hydrodynamics.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
2,0 0 0 0 0 2,0 0 4,0

3. Numerical algorithms in Cosmology.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
2,0 0 0 0 0 2,0 0 4,0

4. Numerical algorithms in Relativistic (Magneto-)hydrodynamics.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
4,0 0 0 0 0 2,0 0 6,0

5. General description of codes for Astrophysical applications and Cosmology.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
3,0 0 0 0 0 10,0 0 13,0

6. Numerical experiments.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
2,0 0 18,0 6,0 0 4,0 2,0 32,0
  • Otras actividades:
    Presentation of the results of the computational laboratory.
  • Otras actividades fuera del horario fijado:
    Menthored work.

7. Simple astrophysical and cosmological models.
T      P      L      Alt    L Ext. Est    O. Ext. Total 
2,0 0 14,0 12,0 0 8,0 4,0 40,0
  • Otras actividades:
    Presentation of the results of the computational laboratory.
  • Otras actividades fuera del horario fijado:
    Menthored work.


Total por tipo T      P      L      Alt    L Ext. Est    O. Ext. Total 
16,0 0 32,0 18,0 0 28,0 6,0 100,0
Horas adicionales dedicadas a la evaluación 0
Total horas de trabajo para el estudiante 100,0

Metodología docente

The practical work will consist on computer practices where the student will use programs provided by the lecturer, public domain programs -appropriately documented- or programs that will be developed by the student.

Método de evaluación

The evaluation of the course will be based on the work developed by the students in the practical part (problems).

Bibliografía básica

  • Chorin, A.J., Marsden, J.E. A Mathematical Introduction to Fluid Mechanics, Springer (Chapter 3), 1990.
  • Landau, L. D. & Lifshitz, E. M. Fluid Mechanics, Pergamon, 1987, 2d ed.
  • LeVeque, R. J. Finite Volume Methods for Hyperbolic Problems., Cambridge U. P., 2002.
  • Shore, S.N. An Introduction to Astrophysical Hydrodynamics , Academic Press, 1992.
  • Toro, E. F. Riemann Solvers and Numerical Methods for Fluid Dynamics: A Practical Introduction, Springer, 1999, 2d. ed.

Bibliografía complementaria

  • Martí, J.M., Müller, E. Numerical Hydrodynamics in Special Relativity, Living Reviews in Relativity: http://www.livingreviews.org/Articles/Volume2/1999-3marti/index.html, , 1999.
  • Font, J.A. Numerical Hydrodynamics in General Relativity, Living Reviews in Relativity: http://www.livingreviews.org/Articles/Volume3/2000-2font/index.html, , 2000.
  • Kulsrud, R.M. Physics for Astrophysics, Princeton U. P., 2004.

Enlaces web

  1. http://grape.c.u-tokyo.ac.jp/~hachisu/java.shtml


  2. http://www.strw.leidenuniv.nl/~icke/html/VincentPNO.html


  3. http://jupiter.as.arizona.edu/~burrows/scidac/scidac.html


  4. http://www.phy.ornl.gov/tsi


  5. http://www.livingreviews.org/Articles/Volume2/1999-3marti/index.html (Secc. 7.1)


  6. http://www.astro.washington.edu/balick/WFPC2/index.html


  7. http://www.cv.nrao.edu/~abridle/images.htm


  8. http://www.astro.lsa.umich.edu/~phughes/icon_dir/relproj.html


  9. http://www.livingreviews.org/Articles/Volume2/1999-3marti/index.html (Secc. 7.2)


  10. http://science.nasa.gov/newhome/headlines/ast02nov99_1.htm


  11. http://www.mpa-garching.mpg.de/HIGHLIGHT/2000/highlight0003_e.html


  12. http://www.ifa.hawaii.edu/faculty/barnes/saas-fee/chapter-outline.html


  13. http://www.MPA-Garching.MPG.DE/NumCos/


Capacidades previas

-  Fortran (basic level). Gnuplot. IDL (basic level).


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