1. Systems, definitions, classification in terms of control theory, automation, automated control systems, terminology management, control, regulation and binding on the technical means of control metallurgical processes, identification, modeling and simulation group linked to technological processes.
2. Theory of logic circuits, combination and sequence circuits, minimization, gate and contact analogy, software implementation of combinational functions.
3. Analysis and synthesis of combinational logic circuits, encoders, decoders, converters, multiplexers, codes and coding, security codes, redundancy and backup reliability logic circuits, design and solve practical problems from engineering practice. Software models of processes controlled by logic functions.
4. Analysis and synthesis of sequential logic circuits, design of practical tasks including control of dynamic systems. Software models of processes controlled by logic functions. Types of flip-flop circuits and their design and use, memory, sliding registers, counters, frequency dividers, practical applications in the management of technological processes.
5. Technological processes as dynamic systems, system distributions, linear, nonlinear, continuous, discontinuous, time variant, time variant and their application in metallurgy and related fields.
6. Descriptions of linear systems, solution of linear differential equations with constant coefficients, Laplace transformation and transitions of corresponding differential equations. Static characteristics, transient and impulse functions and characteristics of dynamic systems.
7. Frequency transmission and frequency characteristics in complex plane, frequency and logarithmic frequency characteristics of amplitude and phase, basic elements.
8. Dynamic properties of technological processes. Static systems, present systems, derivation systems and systems with traffic delays, their mathematical description and properties and their software model implementation.
9. Block algebra and its use in solution of dynamic systems, description of systems creation of logarithmic frequency characteristics.
10. Information page of control circuits and their parts, functions and description, calculation of basic transmissions and characteristics in time and frequency domain. Binding to technical means and used signals.
11. Regulators, mathematical description, function and choice of controller type. Non-linear regulators, Smith regulator, digital controllers and their software implementation, and practical application to technological processes.
12. Simulation of control circuits and comparison of properties of different types of regulators and different types of regulated systems.
2. Theory of logic circuits, combination and sequence circuits, minimization, gate and contact analogy, software implementation of combinational functions.
3. Analysis and synthesis of combinational logic circuits, encoders, decoders, converters, multiplexers, codes and coding, security codes, redundancy and backup reliability logic circuits, design and solve practical problems from engineering practice. Software models of processes controlled by logic functions.
4. Analysis and synthesis of sequential logic circuits, design of practical tasks including control of dynamic systems. Software models of processes controlled by logic functions. Types of flip-flop circuits and their design and use, memory, sliding registers, counters, frequency dividers, practical applications in the management of technological processes.
5. Technological processes as dynamic systems, system distributions, linear, nonlinear, continuous, discontinuous, time variant, time variant and their application in metallurgy and related fields.
6. Descriptions of linear systems, solution of linear differential equations with constant coefficients, Laplace transformation and transitions of corresponding differential equations. Static characteristics, transient and impulse functions and characteristics of dynamic systems.
7. Frequency transmission and frequency characteristics in complex plane, frequency and logarithmic frequency characteristics of amplitude and phase, basic elements.
8. Dynamic properties of technological processes. Static systems, present systems, derivation systems and systems with traffic delays, their mathematical description and properties and their software model implementation.
9. Block algebra and its use in solution of dynamic systems, description of systems creation of logarithmic frequency characteristics.
10. Information page of control circuits and their parts, functions and description, calculation of basic transmissions and characteristics in time and frequency domain. Binding to technical means and used signals.
11. Regulators, mathematical description, function and choice of controller type. Non-linear regulators, Smith regulator, digital controllers and their software implementation, and practical application to technological processes.
12. Simulation of control circuits and comparison of properties of different types of regulators and different types of regulated systems.