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COMPUTER ENGINEERING

SPECIALTY: COMPUTER SYSTEMS AND NETWORKS

Higher Mathematics.

Lectures - 175 hr., Seminars - 122 hr., Self-learning- 223 hr., Consultations  - 20 hr., 1st, 2nd and 3rd semesters - examination, 4th semester - test.

Determinants, matrices and operations on them, systems of linear algebraic equations and methods of their solving, vectors and operations on them, line in a plane, plane and line in space, second order curves, second order surfaces, sequences, functions, limits, differential calculus, complex numbers, polynomials, rational functions, indefinite integral, definite integral, improper integral, multivariable functions, differential, ordinary differential equations, systems of ordinary differential equations, stability, numerical series, functional series, power series, Fourier series, Fourier integral and transformation, multiple, curvilinear and surface integrals, elements of the field theory, functions of complex variables.

Prerequisite: not required.

Physics.

Lectures - 124 hr., Seminars - 18 hr., Labs - 106 hr., Consultations  - 20 hr., Self-learning - 157 hr., 1st and 2nd semesters - examination, 3rd semester - test.

Mechanics: kinematics, dynamics; forces of inertia; laws of conservation of momentum, angular momentum, energy; relativistic mechanics. Molecular physics and thermodynamics: kinetic theory; 1st and 2nd laws of thermodynamics, entropy. Electromagnetism: electrostatic field; conductors and dielectrics in electrostatic field; magnetic field; electromagnetic induction; Maxwells equations. Oscillations: harmonic, damped, forced mechanical and electromagnetic oscillations. Wave physics: mechanical, electromagnetic waves; interference, diffraction, dispersion, polarisation. Quantum physics: quantum properties of radiation; Schroedingers equation; atom and molecule spectra. Solid state physics: quantum statistics; zone theory.

Prerequisite: Higher mathematics.

Engineering graphics.

Lectures - 17 hr., Seminars - 35 hr., Self-learning - 73 hr., Consultations - 10 hr., 1st and 2nd semesters - test.

Engineering  graphics: theoretical fundamentals and ways of construction of projective images of objects, method of projecting, orthogonal projections. Monge method. Point, straight line, plane. Transformation of projective drawing. Surfaces. Axonometry. Views, full sections, sections. Dimensioning on drawings. Releasable and permanent connections. Sketches of detail. Assembly drawing. Fulfilment of working drawing. Schemes. Introduction to SAPR and computer graphics. Drawing the base elements in AutoCad.

Prerequisite: Higher mathematics.

Discrete Mathematics.

Lectures - 34 hr., Seminars  - 17 hr., Self-learning - 57 hr., 5th semester - examination.

Algebraic systems. Set theory. Binary relations. Databases. Combinatorial analysis. Mathematical logic. Predicates. Graph theory. Models of decision-making in intellectual systems. Formalization and solution of problems by means of discrete mathematics. Simulation in condition of information incompleteness.

Operations on sets. Basic identities. Operations on binary relations. Definition of combinatorial class problems and their solution. Operations on logical propositions. Determination of graph number characteristics.

Prerequisite: Higher mathematics.

Theory of Probability and Mathematical Statistics.

Lectures - 34 hr., Seminars - 17 hr., Self-learning - 30 hr., 3rd semester - test.

Random events. Space of random events. Classical definition of probability. Conditional probabilities. Bayes' formula. Binomial experiment. Discrete and continuous random variables. Mathematical expectation and variance. Main distributions of random variables. Limit theorems. Systems of random variables. Functions of random variables. Parent population and sampling. Point estimations. Interval estimations. Testing of statistical hypotheses. Method of least squares. Covariance and correlation.

The sample space and events. The classical definition of probability. Conditional Probabilities. Bayes' formula. The binomial experiment. Discrete and continuous random variables. Expectation and variance. Main distributions. Limit theorems. Systems of random variables. Functions of random variables. Population and sample. Point estimations. Interval  estimations. Testing of  statistical hypotheses. Least squares method. Correlation.

Prerequisite: Higher mathematics.

Numerical Methods.

Lectures - 17 hr., Labs - 17 hr., Self-learning - 47 hr., 5th semester - test.

Numerical methods f linear algebra. Numerical solution of  linear algebraic equations. Solution of  nonlinear equations. Root finding by bisections, Secant method, simple iterations. Polynomial approximation of functions. Lagranges and Newtons formulae for polynomial interpolation . Spline interpolation.  Least squares method . Numerical integration. Numerical solution of ordinary differential equations. Eulers method. Runge- Kutta method.

Prerequisite: Higher mathematics; Theory of probability and mathematical statistics.

Electric and Magnetic Circuit Theory.

Lectures - 51 hr., Labs - 34 hr., Consultations - 5 hr., Self-learning- 72 hr., 3rd semester - examination.

Basic elements of electric circuits. Direct current (DC) circuits. Kirchhoffs laws. Electric circuit transformations. Mesh and nodal analysis. Thenevins and Nortons theorems. Alternating current (AC) circuits. Complex representation of sinusoidal current and voltage. Response of R, L and C elements to sinusoidal disturbance. Phase shift. Vector diagrams. Series and parallel connections of R, L, and C elements. Power of sinusoidal current. Current and voltage resonance. Circuits with coefficient of mutual inductance. Three-phase circuits. Transient processes in DC circuits. Nonlinear electrical and magnetic DC circuits. Classic and operator methods of transient currents calculation. Nonlinear electric and magnetic DC circuits. Kirchhoffs laws for magnetic circuits. Nonlinear electrics and magnetic circuits of sinusoidal current.

Prerequisite: Higher mathematics; Physics.

Programming.

Lectures - 87 hr., Seminars - 35 hr., Labs - 52 hr., Consultations - 5 hr., Self-learning - 91 hr., 1st semester - examination, 2nd semester - test.

High level programming languages: Pascal and C/C++, their syntax and semantics. Declarations and definitions for variables and constants of different types. Expressions, operators, assignments, and structured programming statements in high level languages. Programming with branches. Cycle programming for array indexes and iterations. Procedures and functions as basics of modular programming. Developing algorithms and programs to meet specifications. Programming basics for solving  mathematical and technical tasks with high level languages. Goal-directed conversions for correct and compact program obtaining.

Prerequisites: Higher mathematics.

Information Theory and Encoding.

Lectures - 34 hr., Labs - 17 hr., Self-learning - 57 hr., 5th semester - examination.

The Air Traffic Service Provider (ATSP) calibrating, classification and correction of errors. Quantization of signals. Ideal ATSP and its work. Discretion of signals, the Kotelnikovs theorem. Basic descriptions and the ATSP and Transport Service Access Point (TSAP) classification. Notion of data communication systems. Spectra of non-modulated and modulated signals. Information content and entropy of source. Carrying capacity of channels and optimum encoding. Notion of correcting codes and their description, examples of elementary correcting codes. Notion about cyclic correcting codas, theorems about cyclic codas.

Prerequisite: Higher mathematics.

Computer Electronics.

Lectures - 70 hr., Labs - 35 hr., Consultations  - 10 hr., Self-learning - 111 hr., 3rd semester - examination, 4th semester - test.

Physical basics of microelectronics. Semiconductor diodes. Bipolar transistors. Field-effect transistors. Features of integrated circuit elements. Logical elements. Flip-flops. Optoelectronics components and technical means for information displaying. Electronic amplifiers. Feedbacks in amplifiers. DC amplifiers. Pulse signal generators. Transistor switches. Multivibrators. Power sources. Study of rectifying diodes; Zener diodes; transistors; transistor and integrated circuit amplifier; dividing, integrating, and differentiating circuits based; electronic switches based on bipolar and field-effect transistors; multivibrators; rectifier circuits; integrated circuit flip-flops; univibrators.

Prerequisite: Higher mathematics; Physics; Digital computers.

Circuit Engineering of Computers.

Lectures - 34 hr., Labs - 34 hr., Self-learning - 94 hr., 5th semester - examination.

Logic elements. Flip-flops. Registers. Counters. Decoders. Coders. Multiplexers and demultiplexers. Comparators. Test circuits. Adders. Operation units. Code converters. AD and DA converters. Microprocessors. Large-scale integration programmable logic arrays (LSI PLA). Computer memory. Logic elements. Transistor-transistor logic (TTL) and emitter-coupled logic (ECL) systems. Parallel and shift registers. Counters. Decoders. Coders. Multiplexers. Demultiplexers. One-bit and ulti-bit adders. Single-chip microprocessors. Microcontrollers.

Prerequisite: Computer electronics; Computers and microprocessor systems; Digital computers.

Computers and Microprocessor Systems.

Lectures - 36 hr., Labs - 36 hr., Self-learning - 90 hr., 4th semester - examination.

Architecture-functional principles and informational basics for computer building. Arithmetic and algorithmic basics for computer functioning. Logical basics for computer devices building. Central processor unit. Computer memory hierarchal system. Interruption system. Information input-output system. Personal computer hardware. Computer test and diagnostic system. Computer systems and networks.

Numbering systems. Computer information presentation. Arithmetic basics of computer. Logical description of electron circuits. Central processor unit. Memory segment-page organization. Computer memory. Address decoder. Computer external memory. Interruption system. Direct memory access (DMA). Computer connection with slow periphery. Computer networks.

Prerequisite: Higher mathematics; Physics; Electric and magnetic circuit theory; Computer electronics.

Digital Computers.

Lectures - 70 hr., Labs - 35 hr., Self-learning - 137 hr., 6th semester - test, 7th semester - examination.

Basic structures of computers. Regimes of computer operation. Random-access memory (RAM). Read-only memory (ROM). Semiconductor RAM memory. Semiconductor ROM memory. Organization of bit cells in a memory chip. Memory system considerations. Multiple-module memories and interleaving. Cache memories. Arithmetic and logic unit (ALU). Specialized ALUs. Control unit. Micro-programmed control. Up-to-date processor architectures. Mainframe computers. Interrupt system. Input-output system. Computer interfaces. Microprocessor very-large scale integrated circuits (VLSI). High performance computer systems.

Dynamic RAM. Data processing unit using very large integration circuits (VLIC) microprocessor. Microprogram control unit. Building of processor on the base of microprocessors complete set. Single-chip microprocessors. Computer input/output system. Computer interruption system. Control automata network. Control automata synthesis using programmable logic arrays (PLA).

Prerequisite: Computer electronics; Computers and microprocessor systems; Computer circuit engineering.

Fundamentals of Computer Devices Automatic Design.

Lectures - 34 hr., Labs - 34 hr., Self-learning- 67 hr., 7th semester - test.

Design of complex objects and systems. Basics of computer aided design (CAD) of complex objects and systems. CAD classifications. Trends in CAD software development. Information support of CAD. Linguistic basics of CAD. Mathematical modelling in CAD. Basics of construction for automated systems of technological preparation of manufacturing.

Auto CAD system. Peculiarities of CAD application. Design of complex objects and systems in Auto CAD. 3D images in Auto CAD. Design documentation and specifications in Auto CAD. Input and output specifications in Auto CAD. Representation of 3D objects in Auto CAD.

Prerequisite: Higher mathematics; Physics; Programming; Computer electronics; Circuit engineering of computers; Computers and microprocessor systems.

System Programming.

Lectures - 70 hr., Labs - 35 hr., Self-learning - 111 hr., 3rd semester - test, 4th semester - examination.

Problem of system programming, generalized structure of computer systems, languages for system programming, compilers, interpreters and debuggers. Operating systems (OS), kernel of OS and its basic elements, single- and multitasking OS, application of interruption mechanisms. Organization of data bases (DB), DB system management, data access, remote access, Structured query language (SQL). Computer-oriented programming languages, execution of assembler programs. Bases of intellectualization of the computer systems. Forming of queries to DB in the SQL language, acquaintance with and study of the main system programs for working with Assembler, interruption commands.

Prerequisite: Higher mathematics.

System Software.

Lectures - 70 hr., Labs - 35 hr., Self-learning - 111 hr., 4th semester - test, 5th semester - examination.

Destination of system software, structure, tasks, main functions. Programming languages, operating systems, network support. Features of organization of real-time information processing, centralized traffic control of calculable process. Organization of information exchange between interactive processes, co-operation of separate software modules, organization of interruption system.

Composition and structure of system software. Components of application technology of programming systems. Interruption commands. Commands of operations with stack. Interruption modeling of peripheral devices.

Prerequisite:Higher mathematics.

Peripheral Devices.

Lectures - 34 hr., Labs - 34 hr., Self-learning - 94 hr., 8th semester - test.

Input-output systems. External storage devices. Computer video systems. Printers. Plotters. Input devices. Testing of peripheral devices. On-line information input and devices for its realization.

Hard disks. Floppy disks. Displays. Matrix printers. Laser printers. Jet printers. Plotters. Scanners.

Prerequisite: Computer electronics; Computers and microprocessor systems; Digital computers; Microprocessor systems; Computer circuit engineering.

Computer Networks.

Lectures - 34 hr., Labs - 34 hr., Self-learning- 67 hr., 8th semester - examination.

Concepts. Applied programs and networks. Types of networks. Network architecture and communication lines. Network communications. Structure of networks and access methods. Network protocols. High-levels protocols. Physical realization. Manchester coding. Ethernet controller. Communication means of local networks. Principles of local networks building. Stack of Transmission Control Protocol / Internet Protocol (TCP/IP). Addressing in IP-networks. IP protocol of internetting. TCP and User Data Protocol (UDP) message delivery. Control messaging exchange  via Internet Control Message Protocol (ICMP). Message routing information exchange stack TCP/IP protocols.

Network architectures. Characteristics and application of wire communication lines. Characteristics of wireless communication lines. Application of wireless communication lines. Structure of networks.

Access methods to communication channel. Physical realization of transmitting and receiving signals in local networks. Coding and decoding time diagrams. Choosing of network type according to exploitation conditions. Network designing. Peculiarities of local network connection at dimensions enlargement. Using of routers. TCP/IP stack as internetting technology. Direct routing. Indirect routing. Popular protocols of information exchange in networks, according to leading firms designs.

Prerequisite: Higher mathematics; Physics; Computer electronics; Circuit engineering of computers; Computers and microprocessor systems; Basics of computer devices automatic design.

Computing Systems.

Lectures - 36 hr., Labs - 18 hr., Self-learning- 54 hr., 6th semester - test.

Base uniprocessor architecture. Classification of computing systems (CS). Architecture of conveyor CS. Classification of conveyors. Vector processors: methods of vector instructions realization. Structural organization of vector-conveyor computers. Application area of CS of the Single stream of instructions, single steam of data class. Common features of parallel CS: the basic types of parallel CS architectures, types of parallel CS topologies. General requirements to modern CS.

Simulation of time characteristics of CS. Finding of optimal modification of multiprocessing CS for effective calculation of arithmetic expressions.

Prerequisite: Higher mathematics; Programming; Computer electronics; Circuit engineering of computers; Digital computers; System programming; Computer circuit engineering.

Reliability, Control, Diagnostic and Exploitation of Computer.

Lectures - 17 hr., Labs - 34 hr., Self-learning- 57 hr., 7th semester - test.

Fundamentals of reliability, design, production and functioning of computing systems and networks, evaluation of reliability criteria of their constituents. Simulation of load processes; fundamentals of reliability analysis of complex systems. Aspects of development of testing, control, and technical diagnostics methods.

Study of hardware and software reliability. Failure probability. Function and coefficient of objects readiness, time-out function and coefficient. Calculation of reliability of separate elements.

Prerequisite: Theory of probability and mathematical statistics; System software; Computer modelling and simulation.

Safety of Life Activity.

Lectures - 17 hr., Seminars - 17 hr., Self-learning -20 hr., 5th semester - test.

Identification of potential dangers. Definition of dangerous, harmful and hazardous factors. Forecasting of occasion and consequence effects of dangerous, harmful factors on human organism, and influence of hazardous factors on the human-environment system. Methodology of application of protective means from dangerous, harmful and hazardous factors. Planning of measures for creation of healthy and safe life and activity conditions in the human - environment system. Application of public, social-economical, legal, technical, environmental, medical-prevention and educational procedures, aimed at creation of healthy and safe life conditions in the modern environment.

Identification of dangers, prevention or elimination of consequences. Evaluation of correspondence of the environment state to the requirements of healthy and safe life conditions.

Prerequisite: Higher mathematics;  Physics.

Fundamentals of Ecology.

Lectures - 17 hr, Labs - 17 hr, Self-learning - 20 hr. 8th semester - test.

Objectives and problems of ecology. Evolution of relationship between the human society and the environment. Structure and existence conditions of the biosphere. Mineral, energy and climatic resources of the Earth. Main laws of ecology. Global ecological problems of the biosphere. Atmosphere protections. Main components and structure of the atmosphere. Classification of air pollutants sources. Air pollution control and hygienic standardization. Engineering methods of reducing of harmful substance emission into air. Protection of hydrosphere and lithosphere objects. Protection of environment against anthropogenic energetic loading. Environmental assessment. Environmental legislation and economics. International cooperation in environment protection.

Measurement of luminosity level, temperature, wind speed, atmospheric pressure and humidity in natural and artificial conditions. Determination of hardness and moisture of soils. Measurement of pH level of environment. Detection and concentration measurement of gaseous air pollutants via universal gaseous analyzer.

Prerequisite: Higher mathematics.

Fundamentals of Labour Protection.

Lectures - 18 hr., Labs - 18 hr., Self-learning - 18 hr., 6th semester - test.

Dangerous and harmful production factors, their negative influence on human organism, setting of their maximum permissible level. Legislation basics on labor protection, devices and methods of measuring of dangerous and harmful production factors, protective methods against electric current, static electricity, lightning and harmful substances, methods of accident prevention during running of lifting-transport means and vessels under pressure, protection methods against electromagnetic and ionizing radiation, requirements for fire and explosion safety.

Influence of electric current on human organism. Testing of dielectric individual protection means. Investigation of electric safety in AC power circuits with voltage up to 1000 V. Resistance measurement of electric equipment and power circuits. Estimation of protective grounding efficiency. Detection of air contamination by harmful substances in working area. Investigation of air parameters inside working area.

Prerequisite: Higher mathematics; Physics.

Computer Modelling and Simulation.

Lectures - 70 hr., Labs - 35 hr., Self-learning - 111 hr., 5th semester - test, 6th semester - examination.

Types of simulation. Analogue simulation. Data handling. Statistical techniques. Imitating simulation. Graphic-mathematical methods of simulation. Petri nets. Multi-level distributed real-time simulation based on the Time-triggered Message-triggered Object (TMO) modelling. Decision making simulation using computer mediated communication. Computer-based simulation models for problem-solving: communicating problem understanding.

Mathematical modelling. Structure modelling. Multi-level computer system modelling. Applied system modelling.

Prerequisite: Higher mathematics; Physics; Programming; Computer electronics; Circuit engineering of computers.

Bases of Metrology and Measurement Technique.

Lectures - 36 hr., Labs - 18 hr., Self-learning - 54 hr., 6th 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. Measurement of power and energy. Comparative measuring instruments. Electronic devices and oscilloscopes. Measuring converters of non-electrical quantities. Digital devices.

Processing of measurement results, measuring instruments calibration, measurement of current, voltage, resistance, application of AC devices, research on DC bridges and potentiometers, study of AC bridges, measurement of electric signal parameters with electronic oscilloscope.

Prerequisite: Higher mathematics; Physics.

Information Systems and Data Structures.

Lectures - 72 hr., Labs - 85 hr., Self-learning- 140 hr., 6th semester - test, 7th semester - examination.

Methods of design and creation of databases. Technologies of applications creation. Systems of transactions processing. Structures of data and their realization in  Structured Query Language (SQL) Server. Software tools for application development of databases access. Intersystem exchange of documents.

Delphi programming environment. Features of visual components. Methods of programming. Components of databases access.

Prerequisite: Programming; System software.

Microprocessor Systems.

Lectures - 68 hr., Seminars - 51 hr., Self-learning - 151 hr. 7th semester - examination, 8th semester - test.

Microprocessor (MP) architecture. Building of microprocessor systems (MPS) on the base of very-large scale integration (VLSI) microprocessor single-chips. Building of MPSs on the base of VLSI microprocessor multi-chips. Microcontrollers. MPS for data acquisition and processing (DAP). MPS interfaces. MPS design for DAP. MPS software.

MPS address interaction. Address space (AS) enlarging methods. MPS units interaction via the Common bus interface. Digital information coding for serial channel. Coupling facility (CF) with ISA. Coupling facility with Centronics. Coupling facility for RS-232C. MP on the base of 80386 MP. MPS coupling means with a controlled object. INTEL MCS-196 microcontrollers. Microcontrollers of M68HCxx family. Local area computer networks (LAN).

Prerequisite: Circuit engineering of computers; Computers and microprocessor systems; Digital computers; Computer circuit engineering.

Aviation on-Board Computing Machines.

Lectures - 17 hr., Labs - 17 hr., Self-learning- 47 hr., 8th semester - test.

Destination of on-board computing devices in automatic control systems of aircrafts. Automatic control of the on-board equipment technical condition. Information means and methods. On-board digital computers. Long-range aircraft navigation computing system. Complex on-board computing systems (BCS). Inspection and diagnostic system of complex BCSs. BCSs of up-to-date domestic aircrafts of n-70 and n-140 types.

Study and operation inspection of the trajectory control computing system. Operation control of on-board computer units with the help of testing and checking apparatuses. Simulation of aircraft stability processes. Microprogram control unit of on-board digital computer. Study of instructions system and addressing modes of the on-board computer.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems; Computer circuit engineering.

Computer Circuit Engineering.

Lectures - 36 hr., Labs - 18 hr., Self-learning- 108 hr., 4th semester - test.

Basic concepts and definitions of the computer circuit engineering. Digital circuits. Registers. Counters. Logical design. Reliable design and fault diagnosis. Basics of analog-to-digital converters (ADC). Examples of ADCs. Microprocessors and microprocessor systems.

Investigation of transistor-transistor logic (TTL) and emitter-coupling logic (ECL) elements; flip-flops, registers, counters, decoders and coders, multiplexers and demultiplexers, adders; Medium-Scale Integration (MSI) circuits; and single-chip 8-bit microprocessors.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems.

Ethics and Aesthetics.

Lectures - 17 hr., Seminars - 17 hr., Self-learning- 20 hr., 3rd semester - test.

Moral as social phenomenon. Moral consciousness. Categories of ethics. The moral world of human. Ethics as responsibility. The applied ethics. Aesthetics as a philosophical discipline. Aesthetic consciousness and aesthetic activity. Creative work. Categories of aesthetics. Art as the subject of aesthetic analysis and a form of man's spiritual and practical realization in the world. Ethics and Aesthetics of Antiquity, the Middle Ages, Renaissance, Modern Ages and the Age of Enlightenment. Ethic and Aesthetic principles of the XIX-th century philosophy. Man and the World of Men in the traditions of Ethics and Aesthetics in Ukrainian and Russian classic philosophies. Ethical and Aesthetical researches in the XX-th and at the beginning of the XXI centuries.

Prerequisite: not required.

Economics and Management.

Lectures - 34 hr., Seminars - 34 hr., Self-learning - 40 hr., 8th semester - test.

Organisation and technology for main producing processes; principles and methods of planning, organisational structure of an enterprise; structure of production funds and variables for characterising of their operating efficiency; efficiency of human recourse using; kinds of salary; economical sense of net cost, cost and price of production, enterprises services, methods of their calculation; economical sense of capital funds, planning and using amortisation payments at an enterprise; tax system of Ukraine; basics of investment projects evaluation, legislative materials in the field of management in Ukraine; technological, economical, social and psychological aspects of management.

Examples of calculation and analysis of debt recourses using efficiency; evaluation at choosing the most attractive investment project; finding recourses for increasing efficiency in production activity of an enterprise.

Prerequisite: not required.

Internet Technologies in Systems and Networks.

Lectures - 70 hr., Labs - 70 hr., Self-learning - 157 hr., 5th semester - test, 6th semester - examination.

Introduction to network technology. Network organization. The Global Network Internet. Addressing in networks. Programming technology used in the Internet. Programming of systems and networks using Internet technologies. Using of databases in networks. Programming tools for networks.

Using of Dreamwork software for creation of structured Hyper Text Markup Language (HTML)-code, Personal Home Page (PHP) programming language and MySQL database control systems.

Prerequisite: Programming, System programming.

Specialized Architectures of Computers.

Lectures - 34 hr., Labs - 34 hr., Self-learning- 67 hr., 7th semester - test.

Computers architecture. Classification of processors. Introduction to the discrete linear systems theory. Matrix processors. Telecommunication processors. Signal processors. MPC K1815 architecture and circuit engineering. Multimedia processors. Realization of Digital Signal Processors (DSP), coders, decoders, analog-to-digital (A-D) and digital-to-analog (D-A) converters of different companies.

Fourier transformations. Digital filtration. Fast Fourier transformation (FFT). Digital filters. FFT circuit realization. Sliding analysis of spectrum.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems; Digital computers; Computer circuit engineering.

Systems of Distributed Data Processing .

Lectures - 34 hr., Labs - 17 hr.; Self-learning,  8th semester - examination.

Architecture of distributed data processing systems: structural, functional, program, physical; interface. Types of system structures. Equipment of distributed systems: communications, data processing (multiprocessors and multimachine computing systems), specialized equipment. Functions of distributed systems: channels, highway, management of system, applied operational systems. Designing of distributed systems: mathematical models, optimization, programming.

Modelling, designing and programming in multiprocessors and multimachine systems of distributed data processing.

Prerequisite: Higher mathematics.

Professional Acquaintance Internship.

Seminars - 36 hr., 2nd semester - test.

Classification of aeronautical technique. Basic elements of aircrafts and helicopters, operation features of on-board main systems (including on-board computing complex) and flight control system. Typical structure and functioning of a computer centre. Operation  peculiarities of some flight services and their interaction. Features of productive activity of a future specialist of the Computer engineering direction, and the role and place of the National Aviation University in training of specialists for the aviation industry.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems.

Circuit Engineering Internship.

Seminars - 72 hr., 2nd semester - test.

Electric assembly technology. Basic electric and radio elements. Measuring devices: electronic voltmeter, and harmonic oscillator. Electronic oscillograph. RC-circuits: assembling of circuits and their investigation in time domain. Secondary power supply. Resistor cascade of amplification. Setting of transistor working point. Astable multivibrator. Digital logic circuits.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems.

Computer Internship.

Seminars - 108 hr., 4th semester - test.

Development of conceptual and logic models of the subject area. Creation of data bases (DB). Creation of screen forms for input and modification of DB input information using the Master mode and editing them in the Constructor mode. Creation of requests for tasks solution in the Designer mode by QBE (query by example) means. Creation of a query using SQL structured query language. Receiving information from external DB to be used in the table processor during analysis.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems; Digital computers.

Technological Internship.

Seminars - 108 hr., 6th semester - test.

Structure and functional tasks of National Aviation University computing centre. Structure of the computer class (CC) network equipment. Allocation of the device equipment on the work places of the CC technical service group members. Structure and destination of the CC equipment. Structure of the CC software. Connection of the CC local area computing network to the common network of the faculty.

Prerequisite: Computer electronics; Circuit engineering of computers; Computers and microprocessor systems; Digital computers; Computer circuit engineering.