RADIO ENGINEERING
SPECIALTY: RADIO ELECTRONIC DEVICES, SYSTEMS AND COMPLEXES
Higher Mathematics.
Lectures - 175 hr., Seminars - 193 hr., Self-learning - 206 hr., Consultations - 20 hr., 1st and 3rd semesters - examination, 2nd and 4th semesters - test.
Linear algebra: determinants, matrices, systems of linear algebraic equations; analytical geometry: vectors, line on a plane, plane and line in space, second order curves, second order surfaces; differential calculus of one-variable function: sequences, functions, limits, derivatives, differential; complex numbers; polynomials; rational functions; integral calculus of one-variable function: indefinite integral, definite integral, improper integral, differential calculus of multivariable function; differential equations, system of differential equations; stability theory; series: number series, functional series, power series, Fourier series; Fourier integral and transformation; multiple, linear and surface integrals; elements of field theory; functions of a complex variable: Taylor series, Laurent series, residues; numerical methods; elements of operational calculus; theory of probability and statistics.
Prerequisite: not required.
Physics.
Lectures - 104 hr., Seminars - 52 hr., Labs - 96 hr., Consultations - 20 hr., Self-learning - 133 hr., 1st and 2nd semester - examination, 3rd semester - test.
Subject of physics. Investigation and description methods of mechanical motion. Newtons laws. Conservation laws. Molecular structure of substance. Statistical regularities. Laws of ideal and real gases. Thermodynamics laws. Electromagnetic phenomena. Direct current laws. Mechanical and electromagnetic oscillations and waves. Wave and quantum optics. Crystalline and amorphous solids. Quantum distributions. Superconductivity. Semiconductors. Contact phenomena. Atomic nucleus structure. Nuclear reactions. Elementary particles. Problems of contemporary physics.
Laboratory and practical classes. Physical measurements. Errors. Laboratory research and practical application of physical laws. Investigation of statistical regularities. Observation of optical and electromagnetic phenomena. Value determination of fundamental physical constants.
Prerequisite: Higher mathematics.
Engineering and Computer Graphics.
Lectures - 35 hr., Seminars - 17 hr., Labs - 18 hr., Self-learning - 55 hr., Consultations - 10 hr., 1st and 2nd semesters - test.
Types of products, kinds and completeness of design documents on stages of their elaboration. Monge multi-view drawing. Projecting methods and display modes of the basic geometrical images (point, straight line, plane, curves and surfaces), details and assembly drawing of radio-electronic devices, systems and complexes in different projective systems. Projective transformations of drawings connected with determination of forms, sizes, relative positioning of objects (geometrical plotting). Sketches and ways of technical drawing of details with various shaded modelling. Types of details connection. Assembly drawings, specification, general view and detailed drawing. Notation graphic conventions of radioelements and their drawing on diagrams. Graphic design of circuits and printed circuit boards. Development of text and graphic design documentation on a speciality according to the state and international standards and its representation in electronic form using text and graphic editors.
Prerequisite: Higher mathematics; Computer science.
Computer Science.
Lectures - 70 hr., Labs - 70 hr., Self-learning - 103 hr., 1st semester - examination, 2nd semester - test.
Computer system software: primary information on OS operating system. Purpose of operating system. Main constituents of OS operating system. Boot-up of OS. Resident programs. OS file system and main commands. Files and directories. OS programs. System configuration. Shell program Norton Commander (FAR manager). Text editor of the operating system.
Programming in ++ high level language: history of development. Notation systems. Elements of language. Data types. Operations and operators. Control structures. Operators. Empty operator. Composite operator. Expression statement. IF statement. FOR statement. WHILE and DO statements. SWITCH statement. RETURN statement. Functions. Declaration of functions in ++. Argument transmission and outcome returning. Functions realizing operations NEW and DELETE. Structure of programs and files. Pointers and arrays. Structures. Introduction to classes. Construction of class. Member functions of class. Member data of class. Constructors and destructors. Syntax of constructors and destructors. Call to members of class. Pointers on members of class. Derived classes. Construction of derived class. Protected members of class. Creation of new type of data. Pointer arrays and reference. Introduction to the input-output system. Classes of the input-output system. Standard input-output streams. Use of the input-output system. Graphics abilities of the C ++ language. Visual programming environment Builder C ++. Components of Builder C ++. Development of programs for Windows. Graphics and multimedia. Development of programs for operation with databases.
Use of C ++ in engineering tasks: algorithms and programs of elementary calculations. Operations with appropriated to reality numbers. Operations and functions with complex numbers and variables. Calculation of power polynomials and rational functions. Operations with matrixes. Transformation of coordinates and vector analysis. Algorithms and programs of implementation of the main numerical methods. Solution of linear equation systems. Interpolation and extrapolation. Search for extremums of one-variable and multivariable functions. Numerical differentiation. Calculation of definite integrals. Solution of differential equations. Calculation of eigenvalues of vectors and matrixes. Statistical analysis and histograms preparation.
Hardware support of computer: design feature of computer. Structure of computer. System block construction. Rim computer. Data storage devices. Input-output devices. Motherboard. Microprocessor.
Prerequisite: not required.
Chemistry.
Lectures - 34 hr., Labs - 34 hr., Self-learning - 40 hr., 1st semester - examination.
Atomic-molecular concept. Fundamental laws of chemistry. Structure of atom and D.Mendeleev periodic law: contemporary view. Types of chemical bond (covalent, ionic, etc.). Fundamentals of coordination compounds chemistry. Quantum-mechanical description of covalent bonds: valence bonds (VB) and molecular orbitals (MO) methods. Chemical thermodynamics and thermochemistry. Chemical kinetics and catalysis. Dispersed systems and solutions. Physical and chemical properties of solutions of electrolytes and non-electrolytes. Oxidation-reduction processes and basics of electrochemistry. The general review of properties of metals and non-metals.
Main classes of chemical compounds and types of chemical reactions. Determination of metal equivalent by the water replacement method. The periodic trends in chemical properties of elements. Coordination compounds: properties and preparation. Chemical thermodynamics of ammonium chloride formation. Chemical kinetics (the rate law) of thiosulfuric acid decomposition. Determination of solutions concentrations and properties of electrolytes solutions. Oxidation-reduction reactions. Galvanic cells and electrolysis. General properties of metals and non-metals.
Prerequisite: not required.
Radio-Materials, Radio-Components, and Microelectronics.
Lectures - 34 hr., Labs - 17 hr., Self-learning - 30 hr., 3rd semester - test.
Classification of radio-materials and electronic devices. Passive and active components of radio devices. Physics of semiconductors. Construction and operation of semiconductor diodes, bipolar transistors, field-effect transistors, and thyristors. Parameters of semiconductor devices, equivalent circuits. Application of semiconductor devices.
Investigation of static and dynamic characteristics and parameters of semiconductor diodes, bipolar and field-effect transistors, and thyristors.
Prerequisite: Physics.
Theoretical Mechanics.
Lectures - 17 hr., Seminars - 17 hr., Self-learning - 20 hr., 3rd semester - test.
Assumptions of classical mechanics. Statics. Equivalent reduction of forces system. Conditions of body equilibrium. Kinematics of point. Complex motion of particles, Coriolis theorem. Kinematics of solid. Dynamics of point particles and system of point particles. Theorems on measures alteration of mechanical motion. Principle of possible displacements. General equation of dynamics. Second order Lagrange equations.
Prerequisite: . Higher mathematics; Physics.
Fundamentals of Circuit Theory.
Lectures - 87 hr.; Labs - 53 hr.; Seminars ‑ 17hr., Self-learning ‑ 113 hr., 3rd semester - home task and examination, 4th semester - course paper and examination.
Basic concepts of circuit theory. Simplest electric circuits under harmonic action. Analysis of linear electric circuits in steady-state conditions. Frequency characteristics of the simplest electric circuits. Analysis of transient processes in linear electric circuits with lumped parameters. Basics of classical filter theory. Linear circuits with distributed parameters. Computer methods of electric circuit analysis. Basic concepts, definitions and description of non-linear elements. Spectrum composition of current in non-linear elements. Inertialess non-linear conversions. Resonance multiplication of frequency. Amplitude modulator. Detection. Generation of harmonic oscillations. Steady-state conditions. Hard and soft regimes. Hartleys and Colpits oscillators. RC-generator harmonic oscillations. Stability of feedback circuits. Circuits with variable parameters. Frequency conversion in parametrical element circuits. Frequency conversion. Heterodyne oscillator. Synchronous detection. Parametrical amplification.
Prerequisite: Higher mathematics; Physics.
Analogue Electronic Devices.
Lectures - 36 hr., Labs - 36 hr., Self-learning - 63 hr., 4th semester - examination.
Backgrounds on electronic amplifiers. Typical sources of signals and external loads of amplifiers. Use of feedback in amplifiers. Typical circuits of amplifiers on transistors. Operational amplifiers. Typical circuits on operational amplifiers. The circuits of signals shaping. Devices of signals nonlinear processing. Analog-to-digital and digital-to-analog signal converters. Power supply of radioelectronic devices.
Experimental research of transistor amplifier circuits, operational amplifiers. Research of feedback influence on amplifier stage parameters. Research of operational modes of push-pull amplifier stages, oscillations, rectifiers.
Prerequisite: Higher mathematics; Physics; Radio-materials, radio-components and microelectronics.
Metrology and Measuring Equipment.
Lectures - 36 hr., Labs - 18 hr., Self-learning - 54 hr., 4th semester - home task and test.
Problems and contents of metrology. Metrology main concepts. Terms and definitions. Uniformity of measurements. Types of measuring equipment: standard, measure, measuring instrument, measuring converter, measuring apparatus, measuring system. Forms and methods of measurements. Standardization of metrological characteristics of measuring instruments. Errors of measurements and measuring instruments. Basics of measurement assurance. Measuring signals. Electromechanical instruments. Scaled measuring converters. Measurements of power and energy. Comparative measuring instruments. Electronic devices. Measuring converters of non-electrical quantities.
Processing of measurement results, measuring instruments calibration, measurement of current, voltage, resistance, application of AC devices, research on DC bridges and potenti