Overview
Syllabus
1. History of Dynamics; Motion in Moving Reference Frames.
2. Newton's Laws & Describing the Kinematics of Particles.
3. Motion of Center of Mass; Acceleration in Rotating Ref. Frames.
4. Movement of a Particle in Circular Motion w/ Polar Coordinates.
R2. Velocity and Acceleration in Translating and Rotating Frames.
5. Impulse, Torque, & Angular Momentum for a System of Particles.
6. Torque & the Time Rate of Change of Angular Momentum.
R3. Motion in Moving Reference Frames.
7. Degrees of Freedom, Free Body Diagrams, & Fictitious Forces.
8. Fictitious Forces & Rotating Mass.
R4. Free Body Diagrams.
9. Rotating Imbalance.
10. Equations of Motion, Torque, Angular Momentum of Rigid Bodies.
R5. Equations of Motion.
11. Mass Moment of Inertia of Rigid Bodies.
12. Problem Solving Methods for Rotating Rigid Bodies.
R6. Angular Momentum and Torque.
13. Four Classes of Problems With Rotational Motion.
14. More Complex Rotational Problems & Their Equations of Motion.
R7. Cart and Pendulum, Direct Method.
Notation Systems.
15. Introduction to Lagrange With Examples.
R8. Cart and Pendulum, Lagrange Method.
16. Kinematic Approach to Finding Generalized Forces.
17. Practice Finding EOM Using Lagrange Equations.
R9. Generalized Forces.
18. Quiz Review From Optional Problem Set 8.
19. Introduction to Mechanical Vibration.
20. Linear System Modeling a Single Degree of Freedom Oscillator.
21. Vibration Isolation.
22. Finding Natural Frequencies & Mode Shapes of a 2 DOF System.
R10. Steady State Dynamics.
23. Vibration by Mode Superposition.
24. Modal Analysis: Orthogonality, Mass Stiffness, Damping Matrix.
R11. Double Pendulum System.
25. Modal Analysis: Response to IC's and to Harmonic Forces.
26. Response of 2-DOF Systems by the Use of Transfer Functions.
27. Vibration of Continuous Structures: Strings, Beams, Rods, etc..
R12. Modal Analysis of a Double Pendulum System.
Taught by
Prof. J. Kim Vandiver and Prof. David Gossard
Tags
Reviews
5.0 rating, based on 3 Class Central reviews
-
The "Engineering Dynamics" course from MIT, offered via MIT OpenCourseWare, is an exceptional resource for students and professionals looking to deepen their understanding of classical mechanics. The course covers key concepts such as Newton's laws, motion analysis, energy methods, and angular momentum, with a strong emphasis on problem-solving. The lectures are clear and well-structured, supplemented by comprehensive problem sets that reinforce the material. The course also includes detailed notes and solutions, making it accessible for self-paced learning. Overall, this course is an invaluable tool for anyone pursuing a career in engineering, offering both theoretical knowledge and practical application.
-
Sometimes the course gets harder faster than you can get better at it .If you are struggling or behind it would help to spend additional time on simpler problem sets until you can build up your knowledge toward dealing with the hard ones. This is the real problem, finding the additional time and resolve. Eventually the subject will make sense even if it takes longer.
Dynamics is like the right of passage to more complex subjects like vibrations and controls and fluid mechanics. All the struggle to overcome this hurdle will be rewarded with a new way of thinking, a special ability to unlock new parts of the game. -
Wow this is a marvelous course place and learn wary well this course is very beautifull and this is godd to increase my skills