Welcome,
Guest
.
Login
.
Türkçe
NİNOVA
COURSES
HELP
ABOUT
Where Am I:
Ninova
/
Courses
/
Institute of Science and Technology
/
UUM 510E
/
Course Informations
Return to Faculty
Home Page
Course Information
Course Weekly Lecture Plan
Course Evaluation Criteria
Course Information
Course Name
Turkish
Hesaplamalı Akışkankar Mekaniği_2018
English
Computational Fluid Dynamics
Course Code
UUM 510E
Credit
Lecture
(hour/week)
Recitation
(hour/week)
Laboratory
(hour/week)
Semester
1
3
3


Course Language
English
Course Coordinator
Mehmet Şahin
Course Objectives
Due to the recent advances in computer technology, the goal is to teach students the basic computational techniques becoming increasingly common and their implementation to the basic problems of fluid mechanics, to improve their ability to use these techniques and to improve student skills for evaluating new techniques.
Course Description
Analytic aspects of partial differential equations; Introduction to finite difference, finite volume and finite element methods; Analysis of numerical methods; Steady convectiondiffusion equation; Unsteady convectiondiffusion equation; Iterative and direct solution techniques; Governing equations of fluid dynamics; Scalar conservation laws; The Euler equations in one space dimension; Numerical solution of the Euler equaitons in general domains; Unified methods for incompressible and compressible flow computations; Numerical methods for incompressible fluid flows.
Course Outcomes
M.Sc./Ph.D. students who successfully pass this course gain knowledge, skill and competency in the following subjects;
1. Understand the type of a PDE and be able to define a well posed problem
2. Learn basic discretization techniques such as FDM, FVM and FEM
3. Be able to use von Neuman stability analysis
4. Understand stability, convergence, accuracy and consistency
5. Understand CFL and cellReynolds numbers and their effects to the convectiondiffusion equation
6. Learn Newton’s methods
7. Learn how to solve a linear system of equations
8. Learn how to solve the Euler equations in multidimension
9. Learn how to solve the incompressible NavierStokes equations
Prerequisite(s)
Required Facilities
Other
Textbook
• Fletcher, C.A.J., Computational Techniques for Fluid dynamics I  Fundamental and General Techniques, SpringerVerlag, 1991.
• Fletcher, C.A.J., Computational Techniques for Fluid Dynamics II – Specific Techniques for Different Flow Categories, SpringerVerlag, 1991.
• Ferziger J.H., Peric, M., Computational Methods for Fluid Dynamics, Springer, 1999.
• Anderson, J.D., Computational Fluid Dynamics The Basics with Applications, McGrawHill, 1995.
• Wesseling, P., Principles of Computational Fluid Dynamics, Springer, 2000.
Other References
Computational Fluid Dynamics Vol.I  Hoffmann
Courses
.
Help
.
About
Ninova is an ITU Office of Information Technologies Product. © 2020