EF1F EG1F Physics I: 3+2+0 II: 3+2+2
Classical mechanics (kinematics, dynamics, conservation laws, rotational dynamics, non- inertial frames, fluid dynamics, special theory of relativity, gravitation, waves, phase and group velocity of waves, elements of collision theory, mechanical oscillations, physics of fluids). Molecular physics and thermodynamics (molecular and kinetic theory, Maxwell- Boltzmann distribution, first and second principle of thermodynamics, real gases). Optics (geometrical optics, physical optics, interference, diffraction, electromagnetic waves, polarization, interaction of electromagnetic waves with matter).
EF1M1 EG1M1 Mathematich 1 I: 4+4+0
Boolean algebra. Predicate calculus. Combinatorics and graphs. General algebra (groups, isomorphism and homomorphism, rings, fields). Polynomials and rational functions. Linear algebra (vector spaces, orthogonal spaces, linear operators, matrices, determinants, Cronecker-Capelli's theorem, eigenvalues and eigenvectors, Cayley-Hamilton's theorem, unitary spaces).
EF1M2 EG1M2 Mathematich 2 II: 4+4+0
Metric and compact spaces. Limits of series and functions (limes, iterations, Banach's theorem). Differential calculus (left and right derivative, differential, higher order derivatives and differentials, Taylor's formula). Integral calculus (integrability, Riemann integrals, Darboux sums, methods of integration, Newton-Leibnitz theorem). Differential equations (elementary and liner differential equations, variation of constants, systems of linear differential equations). Series (convergence criteria of Dalambert, Cauchy and Gauss, alternative series, functional series, Cauchy-Hadamard theorem).
EF1OT EG1OT Fundamentals of electrical engineering I: 4+3+0 II:4+4+1
BASIC CONCEPTS. ELECTROSTATICS. The Coulomb law and the electric-field vector. Potential. The Gauss law. Conductors and dielectrics in electrostatic field. Electric fores and energy. Motion of a charged particle in the electrostatic field. TIME-CONSTANT ELECTRIC CURRENTS. Basic concepts and the First Kirchhoff law. Conductivity and resistivity. Resistors and the Ohm law. The Joule law. Electric generators and the Second Kirchhoff law. Methods for solving electric circuits (loop currents and node potentials). Theorems of electric circuits (superposition theorem, reciprocity theorem, the Thevenin theorem, compensation theorem, conservation of energy). Basic electrical measurements. Electric circuits with capacitors. TIME-CONSTANT MAGNETIC FIELD. The Biot-Savart law. Magnetic forces and torques. Magnetic flux. Motion of a charged particle in the magnetic field. The Ampere law. Generalized form of the Ampere law. Magnetic properties of materials. Magnetic circuits. TIME-VARYING ELECTRIC AND MAGNETIC FIELDS. The Faraday law. Self inductance and mutual inductance. Energy and forces in the magnetic field. The general electromagnetic field equations. ELECTRIC CIRCUITS WITH TIME-VARYING CURRENTS. Basic equations. Circuits with time-harmonic currents. The Kirchhoff laws in complex form. Three-phase systems. Basic electrical measurements. Basic concepts on transients.
EF1ORT EG1ORT Fundamentals of computer engineering I: 2+2+0 II: 2+2+0
Boolean algebra. Switching functions and circuits. Minimization of switching functions (Karnaugh maps). Combinational and sequential systems (coders, decoders, multiplexers, demultiplexers, adders, arithmetic and logic units). Sequential systems (types, flip-flops, static and shift registers, counters). Memory elements (ROM, RAM). Analysis and design of combinational and sequential systems.
EF1S EG1S Sociology I: 2+1+0 II: 2+0+0
The concept and meaning of sociology as a social science. Problems of society and its structure (family, classes, nation and national problems, governing over society, the state, bureaucracy and technocracy). Human culture and civilization (religion, ethics, philosophy, science and ideology). Social changes and development.