Discipline: Theory of Electric Circuits

Lecture 1. Basic concepts and definitions

Lecture 2. Electrical circuits. Basic definitions

Lecture 3. Methods of analysis of linear electric circuits of direct current. The laws of Ohm and Kirchhoff

Lecture 4. The overlay method. The compensation method. The two-node method. The method of nodal potentials.

Lecture 5. Sinusoidal current circuits

Lecture 6. The laws of Ohm and Kirchhoff in a complex form

Lecture 7. Resonance in electrical circuits

Lecture 8. Connected circuits

Lecture 9. Three-phase circuits

Lecture 10. The asymmetric mode of the three-phase circuit

Lecture 11. Non-sinusoidal current circuits

 

 

Discipline: Theoretical Basics of Electrical Engineering

1st lecture. Linear electric circuits of direct current

2nd lecture. The laws of Ohm and Kirchhoff. Methods of analysis of simple and complex linear DC circuits

3rd lecture. Sinusoidal current circuits

4th lecture. Voltage resonance. Current resonance

5th lecture. Connected chains

6th lecture. Three-phase circuits

7th lecture. Transients in linear electrical circuits

8th lecture. Quadpolars

9th lecture. Nonlinear electrical circuits

10th lecture. Circuits with distributed parameters

 

 

Discipline: Celestrial mechanics

Lecture 1. Introduction to Celestial Mechanics

Lecture 2. Fundamentals of the theory of gravity

Lecture 3. Integral of motion. Keplerian orbital elements

Lecture 4. Elliptical, hyperbolic, parabolic, circular and rectilinear motion

Lecture 5. Definition of ephemeris of celestial bodies

Lecture 6. Definition of undisturbed orbits

Lecture 7. Definition of the osculating elements

Lecture 8. The small parameter method

Lecture 9. The three-body problem

Lecture 10. Libration points. Hill's Lines

Lecture 11. Modern theories of the motion of planets and moons