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Lecturer(s)
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Course content
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DC & AC circuits - Ohm's Law, Kirchhoff's Law, Current Loop Method, Voltage Node Method, Thevenin's and Norton's theorem Transient and steady state of linear circuits - differential equations, Laplace Transform Characteristics of frequency filters Laws in electrostatics - Electric Intensity, Induction, Potential, Voltage Laws in electromagnetics Maxwell equations
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Learning activities and teaching methods
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unspecified
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Learning outcomes
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Get knowledge of basic methods of solving linear circuits (circuits analysis), steady and transient state of circuits, basic characteristics of frequency filters, Maxwell equations (integral and derivative form), electromagnetic waves on conductors and in free space.
Students are able to orientate in electrostatics, steady currents, static magnetic field, electromagnetic fields, Maxwell equations and wave propagation problems. They can analyze DC and AC circuits (transients and steady states).
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Prerequisites
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Knowledge of differentiation and integration, linear algebra (solution of system of equations), complex numbers
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Assessment methods and criteria
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Oral examination, Written examination
Students are able to orientate in electrostatics, steady currents, static magnetic field, electromagnetic fields, Maxwell equations and wave propagation problems. They can analyze DC and AC circuits (transients and steady states).
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Recommended literature
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