Description

Particle dynamics â€“ systems of particles - Lagrange and Hamilton Equations â€“ Impulsive response â€“Kinematics and Dynamics of rigid bodies - impulsive motion â€“ Differential approach to equations of motion â€“ Integral approach to equations of motion â€“ Transpositional Relations.

Program

M.Sc. In Mechanical Engineering

Objectives

The aim of this course is to present the dynamics of particles and rigid bodies in some breadth, with examples illustrating the strengths and weaknesses of the various methods of dynamical analysis. In the course there is some emphasis on systems of great generality. Geometrical approaches are used to illustrate the nature of constraints.

Textbook

Data will be available soon!

Course Content

content serial	Description
1	Introduction to particle dynamics â€“ particle motion.
2	Systems of particles.
3	Constraints and configuration on space-work, energy and momentum â€“ impulse response
4	Lagrange and Hamilton Equationsrnrn
5	Hamiltonâ€™s equation â€“ integrals of motion
6	Impulsive response â€“ analytical methods
7	Kinematics and dynamics of rigid bodies â€“ kinematical preliminaries / 7th week evaluation.
8	Dyadic notation â€“ basic rigid body dynamics
9	Impulsive motion
10	Equations of motion: differential approach
11	Boltzman-Hamel equation â€“ the general dynamical equation â€“ a fundamental equation
12	The Gibbs-Appell Equation â€“ constraints and energy rates / 12th week evaluation
13	Equation of motion: Integral approach
14	Tranpositional relations
15	Introduction to numerical methods
16	Final Examination

Markets and Career

Generation, transmission, distribution and utilization of electrical power for public and private sectors to secure both continuous and emergency demands.
Electrical power feeding for civil and military marine and aviation utilities.
Electrical works in construction engineering.

Degree Master
Code: ME 755
Credit hrs: 3
Prequisites: None

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Advanced Dynamics