# Computational Fluid Dynamics Video Lectures

Computational Fluid Dynamics
'Computational Fluid Dynamics' Video Lectures by Dr. K. M. Singh from IIT Roorkee
 "Computational Fluid Dynamics" - Video Lectures 1. General Introduction: Historical Background and Spectrum of Applications 2. CFD: Simulation Process and Course Outline 3. Conservation Laws and Mathematical Preliminaries 4. Mass Conservation: Continuity Equation 5. Momentum Equation: Newtons 2nd Law 6. Momentum Equation: Navier-Stokes Equations 7. Navier-Stokes Equation and its Simplified Forms 8. Energy and Scalar Transport Equations 9. Scalar Transport, Mathematical Classification and Boundary Conditions 10. Finite Difference Method: Methodology and Grid Notation 11. Finite Difference Approximation of First Order Derivatives 12. Finite Difference Approximation of Second Order Derivatives 13. Finite Difference Approximation of Second Order Derivatives-2 14. Approximation of Mixed Derivatives and Multi-Dimensional F.D. Formulae 15. Implementation of Boundary Conditions and Finite Difference Algebraic System 16. Applications of FDM to Scalar Transport Problems-1 17. Applications of FDM to Scalar Transport Problems-2 18. Application of FDM to Advection-Diffusion and Computer Implementation Aspects 19. Computer Implementation of FDM for Steady State Heat Diffusion Problems 20. Computer Implementation of FDM for Steady State Heat Diffusion Problems -2 21. Computer Implementation of FDM for Steady State Heat Diffusion Problems -3 22. Solution of Discrete Algebraic Systems 23. Direct and Basic Iterative Methods for Linear Systems 24. Accelerated Iterative Methods for Linear Systems 25. Two Level and Multi-Level Methods for First Order IVPs 26. Two Level and Multi-Level Methods for First Order IVPs-2 27. Application to Unsteady Transport Problems 28. Introduction to Finite Volume Method 29. Finite Volume Interpolation Schemes 30. Application of FVM to Scalar Transport 31. Introduction to Finite Element Method 32. Finite Element Shape Functions and Numerical Integration 33. Finite Element Shape Functions and Numerical Integration-2 34. Application of FEM to Scalar Transport 35. Special Features of Navier-Stokes Equations 36. Time Integration Techniques for Navier-Stokes Equations 37. Implicit Pressure Correction Methods 38. SIMPLEC, SIMPLER and Fractional Step Methods 39. Turbulent Flows: Features and Simulation Strategies 40. Reynolds Averaging and RANS Simulation Models 41. RANS Turbulence Models and Large Eddy Simulation 42. Introduction to Grid Generation 43. Aspects of Practical CFD Analysis
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