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Posts
- Category: Modeling and Simulation of Aerospace Vehicle Dynamics (continued)
- Five-Degrees-of-Freedom Simulation
- ROCKET3: Three-Stage Rocket Simulation
- GHAME3: Hypersonic Vehicle Simulation
- Simulations
- Turbojet propulsion
- Rocket propulsion
- Propulsion
- Parabolic Drag Polar
- Gravitational Attraction
- Subsystem Models
- Polar Equations
- Cartesian Equations
- Equations of Motion
- Three-Degrees-of-Freedom Simulation
- Roll/yaw inertial coupling
- Aerodynamically induced rolling moment
- Aerodynamic cross coupling
- Perturbation Equations of Agile Missile
- Aerodynamic expansions
- Perturbation Equations of Unsteady Flight
- Flight-Path-Angle State Equations
- Pitch Dynamic Equations
- Roll Transfer Function
- Perturbation Equations of Steady Flight
- Derivative maps
- Configurational symmetries
- Aerodynamic Symmetry of Aircraft and Missiles
- Aerodynamic Forces and Moments
- Unsteady Reference Flight
- Steady Reference Flight
- Linear and Angular Momentum Equations
- Perturbation Techniques
- Perturbation Equations
- Integrals of Motion
- Kinetic Energy
- Precession and Nutation Modes
- Gyrodynamics
- Clustered Bodies
- Top
- Euler’s law, like Newton’s second law, must be referred to an inertial frame and, for simplicity’s sake, should be referred to the vehicle’s c. m. Yet, just as in Sec. 5.3, we ask what are the correction terms if we change to a noninertial reference frame or an arbitrary body point.. Noninertial reference frame
- Free Flight
- Euler’s law according to Goldstein
- Two Approaches
- Euler’s Law
- Angular Momentum of Clusters of Bodies
- Angular Momentum of Rigid Bodies
- Angular Momentum
- Inertia Ellipsoid
- Displacement Theorems
- Definition of Moment-of-lnertia Tensor
- Inertia Tensor
- Attitude Dynamics
- Six-Degrees-of-Freedom Simulations
- Five-Degrees-of-Freedom Simulations
- Three-Degrees-of-Freedom Simulations
- Simulation Implementation
- Grubin Transformation
- Coriolis Transformation
- Transformations
- Newton’s Second Law
- Newtonian Dynamics
- Linear Momentum
- Translational Dynamics
- Rotation tensor
- Differential equations
- . Rotation quaternion
- Quaternion Differential Equations
- Euler Angle Differential Equations
- Rotation Tensor Differential Equations
- Attitude Determination
- Properties of angular velocities
- Euler Transformation
- Angular Velocity
- Linear Velocity and Acceleration
- Rotational Time Derivative
- Kinematics of Changing Times
- Small Rotations
- Axis and Angle of Rotation
- General rotation
- Special Rotations
- Properties of the Rotation Tensor
- Rotation Tensor
- Kinematics of Translation and Rotation
- Local-level coordinate system
- Wind coordinate systems
- Body coordinate system
- Geographic coordinate system
- 3.2.2.2 Earth coordinate system
- Heliocentric and inertial coordinate systems
- Coordinate Systems and Their Transformations
- Coordinate Transformation Matrix
- Coordinate Systems
- Reference Frames
- Frame Positioning
- Frames
- Frames and Coordinate Systems
- Reflection Tensor
- Plane Projection Tensor
- Normal Form of a Plane
- Plane