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Mod-01 Lec-01 General Introduction: Historical Background and Spectrum of Applications

Mod-01 Lec-02 CFD: Simulation Process and Course Outline

Mod-02 Lec-01 Conservation Laws and Mathematical Preliminaries

Mod-02 Lec-02 Mass Conservation: Continuity Equation

Mod-02 Lec-03 Momentum Equation: Newton's 2nd Law

Mod-02 Lec-04 Momentum Equation: Navier-Stokes Equations

Mod-02 Lec-05 Navier-Stokes Equation and its Simplified Forms

Mod-02 Lec-06 Energy and Scalar Transport Equations

Mod-02 Lec-07 Scalar Transport, Mathematical Classification and Boundary Conditions

Mod-03 Lec-01 Finite Difference Method: Methodology and Grid Notation

Mod-03 Lec-02 Finite Difference Approximation of First Order Derivatives

Mod-03 Lec-03 Finite Difference Approximation of Second Order Derivatives

Mod-03 Lec-04 Finite Difference Approximation of Second Order Derivatives-2

Mod-03 Lec-05 Approximation of Mixed Derivatives and Multi-Dimensional F.D. Formulae

Mod-03 Lec-06 Implementation of Boundary Conditions and Finite Difference Algebraic System

Mod-03 Lec-07 Applications of FDM to Scalar Transport Problems-1

Mod-03 Lec-08 Applications of FDM to Scalar Transport Problems-2

Mod-03 Lec-09 Application of FDM to Advection-Diffusion and Computer Implementation Aspects

Mod-03 Lec-10 Computer Implementation of FDM for Steady State Heat Diffusion Problems

Mod-03 Lec-11 Computer Implementation of FDM for Steady State Heat Diffusion Problems -2

Mod-03 Lec-12 Computer Implementation of FDM for Steady State Heat Diffusion Problems -3

Mod-04 Lec-01 Solution of Discrete Algebraic Systems

Mod-04 Lec-02 Direct and Basic Iterative Methods for Linear Systems

Mod-04 Lec-03 Accelerated Iterative Methods for Linear Systems

Mod-05 Lec-01 Two Level and Multi-Level Methods for First Order IVPs

Mod-05 Lec-02 Two Level and Multi-Level Methods for First Order IVPs-2

Mod-05 Lec-03 Application to Unsteady Transport Problems

Mod-06 Lec-01 Introduction to Finite Volume Method

Mod-06 Lec-02 Finite Volume Interpolation Schemes

Mod-06 Lec-03 Application of FVM to Scalar Transport

Mod-07 Lec-01 Introduction to Finite Element Method

Mod-07 Lec-02 Finite Element Shape Functions and Numerical Integration

Mod-07 Lec-03 Finite Element Shape Functions and Numerical Integration-2

Mod-07 Lec-04 Application of FEM to Scalar Transport

Mod-08 Lec-01 Special Features of Navier-Stokes Equations

Mod-08 Lec-02 Time Integration Techniques for Navier-Stokes Equations

Mod-08 Lec-03 Implicit Pressure Correction Methods

Mod-08 Lec-04 SIMPLEC, SIMPLER and Fractional Step Methods

Mod-09 Lec-01 Turbulent Flows: Features and Simulation Strategies

Mod-09 Lec-02 Reynolds Averaging and RANS Simulation Models

Mod-09 Lec-03 RANS Turbulence Models and Large Eddy Simulation

Mod-10 Lec-01 Introduction to Grid Generation

Mod-10 Lec-02 Aspects of Practical CFD Analysis

Description:

Instructor: Dr. Krishna M. Singh, Department of Mechanical and Industrial Engineering, IIT Roorkee. This course looks at all the aspects theoretical, numerical, and application aspects of computational fluid dynamics. Computational fluid dynamics (CFD) has become an essential tool in the analysis and design of thermal and fluid flow systems in a wide range of industries. Few prominent areas of applications of CFD include meteorology, transport systems (aerospace, automobile, high-speed trains), energy systems, environment, electronics, biomedical (design of life support and drug delivery systems), etc. The correct use of CFD as a design analysis or diagnostic tool requires a thorough understanding of underlying physics, mathematical modeling and numerical techniques. The user must be fully aware of the properties and limitations of the numerical techniques incorporated in CFD software. This course aims to provide precisely these insights of CFD.

Computational Fluid Dynamics

NPTEL

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#Science #Physics #Fluid Mechanics #Fluid Dynamics #Computational Fluid Dynamics #Mathematics #Applied Mathematics #Numerical Methods #Engineering #Finite Element Analysis #Finite Element Method #Numerical Analysis #Finite Difference Method #Finite Volume Method #Turbulent Flows #Navier Stokes Equations

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