Modeling Flight Dynamics With Tensors
Published 2/2023
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 3.30 GB | Duration: 8h 15m
My Master Class
What you'll learn
Using tensor mechanics instead of vector mechanics to model flight dynamics
Deriving equations of motion in three-, five- and six degrees-of-freedom
Applying perturbation techniques to flight dynamics
Modeling aerodynamics with linear and non-linear derivatives
Creating linear equations-of-motion for steady and unsteady flight
Learning about gyrodynamics
Solving thirty problems relevant to tensor flight dynamics
Requirements
Comprehensive knowledge of traditional flight dynamics
Matrix algebra, but no prior knowledge of tensor algeba
Some prior familiarity with tensor flight dynamics
Access to MATLAB or SCILAB for problem solving
Description
Join me and take your knowledge of tensor flight dynamics to the next higher level.After some historical background and definitions, tensor algebra lays the foundation for the tensorial treatment of flight dynamics, together with the two pillars of kinematics, namely the rotational time derivative and Euler's transformation.Newton's Second Law, expressed in an invariant tensor form, independent of coordinate systems, gives rise to three-, five-, and six degrees-of-freedom equations-of-motions.Euler's Law provides the attitude equations-of-motion, and insight into the strange behavior of gyrodynamics, as experienced by pilots flying single-engine aircraft.While the introductory treatment of tensor flight dynamics starts with rigid bodies, here, at the advanced level, I apply the dynamic laws first to particles and then combine them to form rigid bodies.Of great importance to engineers is my perturbation technique that leads to linearized state equations. This tensorial approach enables the formulation of the perturbation equations-of-motion not only for steady, but also for unsteady reference flight. And the expansion of aerodynamic derivatives to higher orders permits the treatment of nonlinear aerodynamic phenomena.Practice makes perfect by solving the three problems after each lecture. For verification and for assistance the detailed solutions are included.The content of this course is based on the graduate lectures I gave at the University of Florida over a span of 15 years.
Overview
Section 1: Introduction and Fundamentals
Lecture 1 Introduction
Lecture 2 Tensor Alebra
Lecture 3 Reference Frames and Coordinate Systems
Section 2: Newton's Second Law
Lecture 4 Rotation Tensor
Lecture 5 Kinematics
Lecture 6 Translational Equations-of-Motion
Section 3: Euler's Law
Lecture 7 Angular Momentum
Lecture 8 Attitude Equations-of-Motion
Lecture 9 Gyrodynamics
Section 4: Perturbations
Lecture 10 Theory of Perturbations
Lecture 11 Aerodynamic Derivatives
Lecture 12 Linear Equations-of-Motion
Aeropsace Engineers desiring to deepen their understanding of tensor flight dynamics,Students fascinated by the formulation of flight dynamics with tensors,Instructrors aspiring to teach modern flight dynamics
Homepage
https://www.udemy.com/course/modeling-flight-dynamics-with-tensors/
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