Lecture 1 - Introduction
Lecture 2 - An introduction to tensors - I
Lecture 3 - An introduction to tensors - II
Lecture 4 - An introduction to tensors - III
Lecture 5 - Fluid kinematics - I : Flow visualization
Lecture 6 - Fluid kinematics - II : Flow visualization
Lecture 7 - Fluid kinematics - III : Flow visualization
Lecture 8 - Fluid kinematics - IV : Fluid deformation
Lecture 9 - Fluid kinematics - V : Fluid deformation
Lecture 10 - Fluid kinematics - VI : Fluid deformation and Stress tensor
Lecture 11 - Conservation laws - I : Mass
Lecture 12 - Conservation laws - II : Momentum
Lecture 13 - Conservation laws - III : Momentum
Lecture 14 - Conservation laws - IV : Momentum conservation and Boundary conditions
Lecture 15 - Vorticity dynamics - I
Lecture 16 - Vorticity dynamics - II
Lecture 17 - Vorticity dynamics - III
Lecture 18 - Irrotational flow - I : Bernoulli's theorem and Potential flows
Lecture 19 - Irrotational flow - II : Two-dimensional potential flows
Lecture 20 - Irrotational flow - III : Potential flow past a circular cylinder
Lecture 21 - Irrotational flow - IV : Potential flow past a rotating circular cylinder
Lecture 22 - Irrotational flow - V : Translating rigid body in an inviscid flow
Lecture 23 - Irrotational flow - VI : D’Alembert’s paradox and Kutta–Joukowski theorem
Lecture 24 - Irrotational flow - VII : Added mass and Kutta condition
Lecture 25 - Viscous laminar steady flows - I : Introduction
Lecture 26 - Viscous laminar steady flows - II : 2D fully developed planer flows
Lecture 27 - Viscous laminar steady flows - III : 2D fully developed planer flows
Lecture 28 - Viscous laminar steady flows - IV : Hagen-Poiseuille flow
Lecture 29 - Viscous laminar unsteady flows - I : Stokes first problem
Lecture 30 - Viscous laminar unsteady flows - II : Stokes first problem
Lecture 31 - Viscous laminar unsteady flows - III : Stokes second problem
Lecture 32 - Boundary layer theory - I : Introduction
Lecture 33 - Boundary layer theory - II : Prandtl's boundary layer theory
Lecture 34 - Boundary layer theory - III : Prandtl's boundary layer theory
Lecture 35 - Boundary layer theory - IV : Blasius similarity solutions
Lecture 36 - Boundary layer theory - V : Blasius similarity solutions and Drag calculation
Lecture 37 - Boundary layer theory - VI : Drag calculation and Falkner-Skan equation
Lecture 38 - Boundary layer theory - VII : Von Kármán momentum integral equation and Drag calculation
Lecture 39 - Boundary layer theory - VIII : Boundary layer separation
Lecture 40 - Boundary layer theory - IX : External flows without surfaces
Lecture 41 - Introduction to hydrodynamic instability - I
Lecture 42 - Introduction to hydrodynamic instability - II
