Personal tools

Lab Course Scientific-Computing: Computational Fluid Dynamics - Summer 12

From Sccswiki

Jump to: navigation, search
Term
Summer 12
Lecturer
Philipp Neumann, Atanas Atanasov, Christoph Kowitz
Time and Place
Friday, 14:00-17:00, MI 02.07.023
Audience
Students of Computer Science (Master/Diplom, voluntary course, Module IN2106,IN8904,IN2182)
Students of Mathematics (Master, voluntary course)
Students of Computational Science and Engineering (Master, voluntary course, Module IN2186,IN2182)
Tutorials
-
Exam
no final exam
Semesterwochenstunden / ECTS Credits
6 SWS (6P) / 10 credits
TUMonline
Praktikum - Scientific Computing: CFD


Contents

Moodle

All further announcements, worksheets and information can be found on the Moodle - Page of this course.

Requirements

Module IN1503 Introduction to Programming (Module IN1503), Introduction to Scientific Computing (Module IN 2005) or equivalent knowledge.

The language used in the Lab-Course for programming is C. There will not be a particular introduction to the language C! For beginners in C-programming, the following tutorials are considered to be a good starting point to get familiar with C:

Depending on the level, further introduction books or tutorials may be required.

Timeline

The timeline for the Lab Course will be given below. Please check the timeline regularly as minor changes might still occur!

Date Room Session Contents Material
Jan 12, 16:30 02.07.023 Preliminary session Introduction to the Lab Course
Apr 20, 14:00 02.07.023 Lecture 1 The Navier-Stokes equations, Pt. 1
Apr 27, 14:00 02.07.023 Lecture 2 The Navier-Stokes equations, Pt. 2
May 4, 14:00 02.07.023 Lecture 3 The Lattice Boltzmann method
May 9, t.b.a. 02.05.033 Review session Worksheet 1 (Navier-Stokes)
May 18, 14:00 IAS Auditorium 0.001 map Lecture 4 Complex geometries
May 23, t.b.a. 02.05.033 Review session Worksheet 2 (Lattice Boltzmann method)
May 25, 14:00 02.07.023 Lecture 5 Parallelisation of the simulation codes
May 30, t.b.a. 02.05.033 Review session Worksheet 3 (Complex geometries)
June 1, 14:00 02.07.023 Lecture 6 Topics for individual student projects
June 13, t.b.a. 02.05.033 Review session Worksheet 4 (Parallelisation)
June 15, 14:00 02.07.023 Meeting Groups decide on their individual project topic
June 29, 14:00 02.07.023 Meeting/ Lecture 7 Intermediate presentation of group projects
July 18, t.b.a. 02.05.033 Review session Project work
July 20, 14:00 02.07.023 Meeting/ Lecture 8 Final presentation of group projects; have a drink at C2


Contents

The lab course gives an application oriented introduction to the following topics in computational fluid dynamics (lecturers may select certain deepening aspects):

  • Modelling of macroscopic fluid flow via the Navier-Stokes equations
    • Finite-Difference methods for spatial discretisation of the partial differential equations
    • Semi-implicit time-stepping methods for incompressible flow
  • Lattice Boltzmann Methods (LBM)

In the first half of the Lab (approx. the first 6-7 weeks of the lecture period), the theory behind the different methods (Navier-Stokes, LBM) is introduced and test scenarios for each of these methods are simulated. Group work of at most three students is highly recommended! The programming language used for these exercises will be C.

In the second half (approx. the last 6-7 weeks of the lecture period), each student group focuses on an individual project evolving from a specialisation or extension of one of the presented methods. Possible topics comprise:

  • Domain decomposition and parallelisation of the existing solver using MPI
  • Algorithmic and code optimisations
  • Free surface flows
  • Multicomponent flows
  • Integration of transport equations for heat or chemical species in the flow
  • Three-dimensional flow scenarios

During the project phase, the groups work independently on their project. However, in the midterm of the project phase, the students of each group present their results to their colleagues and the lecturers.

The lectures accompanying this lab course will be conducted in English. The assignments will also be given in English. Completed assignments in the first part of the term as well as the final project results will be presented by the students in English or German during a review session that is to be announced approx. one-two weeks in advance. Each review session is compulsory for all students!


VelMP step0001 2.jpg VelCyliChannel step14000 3.gif


General Literature

  • J.H. Ferzinger, M. Peric: Computational Methods for Fluid Dynamics. Springer, 2nd edition, 1999.
  • M. Griebel, T. Dornseifer und T. Neunhoeffer: Numerical Simulation in Fluid Dynamics: A Practical Introduction. Siam Monographs on Mathematical Modeling and Computation. SIAM, Philadelphia, 1997.
  • M. Griebel, T. Dornseifer und T. Neunhoeffer: Numerische Simulation in der Strömungsmechanik. Vieweg, Braunschweig/Wiesbaden, 1995.
  • ParaView User’s Guide (Version 1.6). http://www.paraview.org/files/v1.6/ParaViewUsersGuide.PDF
  • ParaView Online Documentation. http://paraview.org/OnlineHelpCurrent/
  • S. Succi: The Lattice Boltzmann Equation for Fluid Dynamics and Beyond. Oxford University Press, 2001.
  • M. Sukop, D.T. Thorne: Lattice Boltzmann modeling: An introduction for geoscientists and engineers.Springer, 2010.
  • Dieter A. Wolf-Gladrow: Lattice-Gas Cellular Automata and Lattice Boltzmann Models - An Introduction. Springer, 2005.



The author is not responsible for any contents linked or referred to from his pages - unless he has full knowlegde of illegal contents and would be able to prevent the visitors of his site from viewing those pages. If any damage occurs by the use of information presented there, only the author of the respective pages might be liable, not the one who has linked to these pages. Furthermore the author is not liable for any postings or messages published by users of discussion boards, guestbooks or mailinglists provided on his page.