Dynamics 2: Mathematical modeling & analysis of rigid bodies
Dynamics 2: Mathematical modeling & analysis of rigid bodies
Duration: 14:52:39 | .MP4 1280x720, 30 fps(r) | AAC, 44100 Hz, 2ch | 7.49 GB
Genre: eLearning | Language: English
Duration: 14:52:39 | .MP4 1280x720, 30 fps(r) | AAC, 44100 Hz, 2ch | 7.49 GB
Genre: eLearning | Language: English
Use Math to analyze & model rigid body systems! Master kinematics, dynamics, work, energy, impulse, momentum & Lagrange!
What you'll learn
How to analyze the motion of rigid bodies using kinematics (2D & 3D)
How to analyze the motion of rigid bodies using dynamics (2D & 3D)
How to model rigid body systems mathematically
How to use work & energy principles to simplify working with complicated systems
How to use impulse & momentum principles to simplify working with complicated systems
How to apply the Lagrangian mechanics to systems subject to conservative forces
Requirements
Functions, Derivatives and Integrals from Calculus
The concepts from Statics such as: vectors, forces, moments, equilibrium and friction.
The concepts from particle Dynamics such as: kinematics, forces & moments, work, energy, impulse and momentum
Description
How do you get a mathematical model for a system like a rotating wind turbine or a spinning gyroscope that you can later use in other fields, such as control systems?
Would you like to know how to analyze satellite motion using angular momentum and how to take advantage of work and energy to deal with complicated objects in a very easy way?
Would you like to learn how to take a simple vibrating system and describe its motion using Newton laws and Lagrange?
All that and much more, I will teach you here, in the course: Engineering Mechanics: Dynamics part 2 - Mathematical modeling and analysis of rigid bodies.
My name is Mark, and in this course, I will make sure that you will be fully equipped to model and analyze rigid bodies mathematically.
Knowing how to model rigid bodies is a "must" in engineering.
I have 3 control systems courses where I teach advanced controllers for autonomous cars and UAV-s. The basis for building a good controller is to have a good mathematical model.
In those courses, when I build those models, I rely heavily on topics taught here, such as inertia matrix (inertia tensor) and rotating frames.
For rigid bodies in 2D and 3D, we will cover kinematics, dynamics, work, energy, Lagrange, impulse and momentum.
You will get lots of problem solving, but you will also understand the intuition and reasoning behind the concepts.
Take a look at some of my free preview videos, and if you like what you see, ENROLL NOW, and let's get started!
See you inside!
Who this course is for:
Engineering students in Control systems and in Mechanical, Civil, Aerospace, Maritime engineering
Professional engineers in Control Systems and in Mechanics, Civil, Aerospace, Maritime engineering
More Info