Individual course details

Study programme

General physics, Computer and Applied Physics

Chosen research area (module)

Nature and level of studies

Undergraduate Studies

Name of the course

Introduction to  theoretical mechanics

Professor (lectures)

prof. dr Voja Radovanović, dr Duško Latas

Professor/associate (examples/practical)

Professor/associate (additional)

ECTS

6

Status (required/elective)

required

Access requirements

General physics 1

Aims of the course

This course was dedicated to the principles and applications of classical mechanics. The main aim was to make students familiar with the methodology of analytical mechanics through Hamilton’s Principle, Lagrangian and Hamiltonian formalism, and their application to the motion of the system near stable equilibrium, particle in central field and rigid body. In addition, students are introduced to the basic physical ideas and mathematical formalism of the special theory of relativity. The last part of the course is a brief introduction to the mechanics of the continuous deformable media.

Learning outcomes

Students should: have a understanding of Hamilton's principle, be able to solve mechanical problems using Lagrangian and Hamiltonian formalism, understand the role of symmetry in classical mechanics, have a working knowledge of special relativity.

Contents of the course

Lectures

1. The Kinematics of a particle. Velocity and acceleration. Absolute space and time in Newtonian Mechanics. Newton's laws of motion. Galilean transformations. 2. Mechanics of a system of particles. Types of forces. General theorems of Newtonian mechanics. Conservation laws. 3. Constraints. Generalized coordinates. Elements of calculus of variations. Hamilton’s principle. Lagrange's equations for a system with potential forces. 4. Lagrange’s equations with Lagrange multipliers. Nonpotential forces. 5. Symmetry properties and conservation theorems. The homogeneity of space and conservation of the momentum. The homogeneity of time and conservation of the energy. Isotropy of space and conservation of the angular momentum. 6. Small oscillations about a position of stable equilibrium. 7. Motion in central field. First integrals. Qualitative analysis of motion. Binet’s equation. Kepler's problem. 8. Motion of a rigid body. Rotations. Angular velocity. Distribution of velocities in a rigid body. Coriolis theorem. Momentum and angular momentum of a rigid body. Inertia tensor. Kinetic energy of a rigid body. 9. Euler’s equations of motion. Lagrange's method for a rigid body. Symmetrical top. 10. Inertial Forces. Hamilton's equations. Poisson bracket. 11. Einstein's postulates. Michelson–Morley experiment. Lorentz transformation. 12. Time dilation. Length contraction. Velocity addition. Minkowski space.  Four-velocity. 13. Four-momentum, four-force and energy of a relativistic particle. Scattering. Compton scattering. 14. Mechanics of continuous deformable media. Equation of continuity. Stress tensor. Equations of motion of an elastic medium. Perfect fluid. Euler's and Bernoulli's equation 15. Viscous fluid. Navier-Stokes equation.

Examples/ practical classes

Practical exercises are followed by lectures.

Recommended books

1

H. Goldstein, C. Poole and J. Safko, Classical Mechanics, Addison Wesley (2002)

2

L. D. Landau and E.M. Lifshitz, Mechanics, Butterworth-Heinemann (1976)

3

Đ.Mušicki, Teorijska mehanika, PMF Beograd, (1987)

4

V. Radovanović, Beleške za predavanja iz teorijske mehanike

5

Павленко Ю.Г., Задачи по теоретической механике, Физматлит (2003)

Number of classes (weekly)

Lectures

Examples&practicals

Student project

Additional

3

2

Teaching and learning methods

Lecturing, problem solving, homework assignments.

Assessment (maximal 100)

assesed coursework

mark

examination

mark

coursework

10

written examination

35

practicals

oral examination

35

papers

20

presentations