EG2E Electronics III: 3+2+0 IV: 2+1+2
Semiconductor components: diode, bipolar transistor, Junction FET, MOSFET - types, biasing, modes of operation, static characteristics. Linear approximation of characteristics at the bias point, small signal equivalent circuit models. Switching properties of diode, BJT and MOSFET.
Linear electronics: basic amplifier stages with BJTs and MOSFETs, differential amplifiers, power amplifiers (classes A, B and AB), operational amplifier. Frequency response of amplifiers. Negative feedback concept, stability of feedback amplifiers, compensation. Rectifiers, regulated power supplies, linear oscillators.
Pulse and digital electronics: logic gates in different technologies, bistable circuits (latches and flip-flops), combinational and sequential digital circuits, comparators, time base generators, A/D and D/A converters, programmable logic components.
EG2THM Technical mechanics and hydraulics III: 3+2+0 IV: 2+2+0
EG2M3 Mathematics 3 III: 3+2+0 IV: 4+4+0
Metric spaces. Limits of functions in several variables. Continuity. Partial derivatives. Differentiability. Local extrema. Conditional extrema. Vector functions. Elements of differential geometry. Curvilinear integrals. Multiple integrals. Cylindrical and spherical coordinates. Surface integrals. Scalar and vector fields. Space derivatives. Trigonometric series. Fourier transformation. Systems of ordinary differential equations. Partial differential equations. Complex functions. Calculus of residues. Laplace transformation. Probability theory. Bayes' formulae. Poisons's and normal distribution. Numeric characteristic of random variables. Numeric analysis. Error analysis. Interpolations and approximations. Some iterative methods for solving problems in linear algebra ans calculus.
EG2TEK Electrical circuit theory III: 2+2+0 IV: 3+2+0
Physical circuits and their modeling. Fundamentals of circuit topology. Matrix formulation of Kirchoff's laws. Tellegen's theorem. Lumped and distributed circuits. Basic circuit elements. Electric power, work, stored energy, and passivity. Duality. Basic signal waveforms. Time domain circuit analysis: two main approaches - by solving scalar differential equation, and by solving a set of state equations. Natural (zero-input) response; forced (zero-state) response: step- and pulse response; complete response. Response to an arbitrary excitation: superposition and convolution integrals. Circuit analysis by using state equations. Frequency-domain analysis. Sinusoidal steady-state. Complex network functions. Resonance. Selective circuits. Periodic steady state. Fourier series. Signal and circuit analysis by using the Fourier transform. Circuit analysis by using the Laplace transform. Analysis of large-scale networks: mesh-, node, and modified node analysis. Two-port network analysis: network characterisation, equivalent networks, passive and active networks. Applications of two-port networks: filters, equalizers, matching networks. Analysis of distributed parameter networks. Transmission lines. Sinusoidal steady-state response. Incident and reflected waves. Matched transmission line. Applications of transmission lines. Computer-aided circuit analysis: basic computer routines (SPICE, MCAP). Three-phase electric circuits. Three-phase generators and loads. Phase interlinking: star- and delta connection. Symmetrical (balanced) three-phase circuit - reduction to the monophase equivalent circuit. Unsymmetrical (unbalanced) three-phase circuits. Complex power in three-phase circuit. Symmetrical components. Matrix relations and transformations. Network description in terms of symmetrical components; equivalent circuits: zero-phase, positive-phase (direct-) and negative-phase (inverse-) system. Fault analysis by using symmetrical components.
EG2ETM Materials in electrical engineering III: 2+0+2
EG2PJ Programming languages III: 3 + 2 + 0
General principles of computer programming. Representation of algorithms. Internal representation of integer and real numbers. The C programming language. How to prepare and run a C program on a computer. Data types. Declarations of variables. Data input and output, I/O conversions. Operators. Expressions. Library functions. Statements and control structures: sequence, selection, loop, branch. Arrays, characters, strings. Pointers and dynamic memory allocation. Functions - how to define and call a function, side effects, recursion, main program as a function. C preprocessor. Data structures in C. The FORTRAN programming language. Data types, input/output, FORMAT statement. Statements and control structures in FORTRAN. Subroutines and functions. Library functions. Specification statements (COMMON, EQUIVALENCE). Specific characteristics of FORTRAN, compared to C language.
EG2EM Measurings in electrical engineering IV: 2 + 0 + 3