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Posts
- Category: Fundamentals of Aerodynamics (continued)
- First Law of Thermodynamics
- Entropy and the Second Law of Thermodynamics
- Isentropic Relations
- Definition of Compressibility
- Governing Equations for Inviscid, Compressible Flow
- Definition of Total (Stagnation) Conditions
- Some Aspects of Supersonic Flow: Shock Waves
- Normal Shock Waves. and Related Topics
- The Basic Normal Shock Equations
- Speed of Sound
- Special Forms of the Energy Equation
- Category: Fundamentals of Modern Unsteady Aerodynamics
- Aerodynamics: The Outlook for the Future
- Finite Wing Flapping
- Flexible Airfoil Flapping
- Flapping Wing Theory
- Wing Rock
- The Vortex Lift (Polhamus Theory)
- Dynamic Stall
- Static Stall
- Modern Subjects
- Hypersonic Plane: Waverider
- Hypersonic Viscous Flow: Numerical Solutions
- High Temperature Effects in Hypersonic Flow
- Viscous Hypersonic Flow and Aerodynamic Heating
- Inviscid Hypersonic Flow: Numerical Solutions
- Improved Piston Theory: M2s2 = O( 1)
- The Piston Analogy
- Unsteady Newtonian Flow
- Improved Newton’s Theory
- Newton’s Impact Theory
- Hypersonic Flow
- Unsteady Transonic Flow Past Finite Wings
- Transonic Flow around a Finite Wing
- Unsteady Transonic Flow: General Approach
- Steady Transonic Flow, Non Linear Approach
- Unsteady Transonic Flow, Supersonic Approach
- Two Dimensional Transonic Flow, Local Linearization
- Transonic flow
- Munk’s Airship Theory
- Slender Body Theory
- Arbitrary Motion of a Profile in Supersonic Flow
- Supersonic Kernel Method
- Mach Box Method
- Supersonic Flow About Thin Wings
- Supersonic Flow About a Profile
- Unsteady Supersonic Flow
- Supersonic Flow
- Arbitrary Motion of a Profile in Subsonic Flow
- Doublet-Lattice Method
- Kernel Function Method for Subsonic Flows
- Subsonic Flow Past an Airfoil
- Subsonic Flow about a Thin Wing
- Subsonic Flow
- Subsonic and Supersonic Flows
- Low Aspect Ratio Wing
- . Effect of Sweep Angle
- Arbitrary Motion of a Thin Wing
- Numerical Solution
- Reissner’s Approach
- Unsteady Flow
- Low Aspect Ratio Wings
- Weissinger’s L-Method
- Lifting Line Theory
- Steady Flow
- Incompressible Flow About Thin Wings
- Gust Problem, Kussner Function
- Arbitrary Motion
- Loewy’s Problem: Returning Wake Problem
- Simple Harmonic Motion
- Unsteady Flow
- Steady Flow
- Incompressible Flow About an Airfoil
- Initial and Boundary Conditions
- Turbulence Modeling
- Aerodynamic Forces and Moments
- Incompressible Flow Navier-Stokes Equations
- Boundary Layer Equations
- Thin Shear Layer Navier-Stokes Equations
- Navier-Stokes Equations
- Equation of Motion in General Coordinates
- Energy Equation
- Momentum, Equation
- Global Continuity and the Continuity of the Species
- System and Control Volume Approaches
- Real Gas Flow
- Moving Coordinate System
- Acceleration Potential
- Linearization
- Boundary Conditions
- Potential Flow
- Fundamental Equations
- Modern Topics
- The Piston Theory
- Hypersonic Aerodynamics
- Slender Body Aerodynamics
- Compressible Unsteady Aerodynamics
- Unsteady Aerodynamics of Slender Wings
- Steady Aerodynamics of Thin Wings
- Unsteady Lifting Force Coefficient