
Explore electric circuits, focusing on si units, charges, current, voltage, and energy and power, with methods to convert units and model circuits mathematically.
Identify and differentiate independent and dependent sources, including current-controlled and voltage-controlled sources, and interpret their symbols and control relationships within circuits.
Explore Ohm's law and circuit topology, covering resistance, resistivity, and conductance, and analyze series and parallel branches, nodes, and KCL concepts, including short and open circuit cases.
Learn kvl part 2 by applying current division and voltage division to resistors in series and parallel, and determine currents, voltages, and equivalent resistance.
Solve advanced circuit problems by applying current division, identifying equivalent resistances, and using Kirchhoff's laws and Ohm's law to compute voltages and branch currents.
Master delta-wye and wye-delta conversions to simplify resistor networks, convert delta to wye, and calculate equivalent resistances and currents in circuits.
apply the maximum power transfer theorem using the Thevenin equivalent to maximize load power, by finding open-circuit voltage, Thevenin resistance, and using P_max = V_th^2/(4 R_th).
Master steady state analysis of electric circuits using phasors and complex numbers. Convert between polar and Cartesian forms, analyze sinusoidal signals, and compute capacitor and inductor impedances.
Learn electric circuits and circuit analysis from ground up to advanced level
In this course you will learn:
-System of units(SI).
-Charge and current.
-Voltage.
-Power and energy.
-Circuit elements.
-passive and active elements.
-Ohm's law.
-Nodes and branches and loops.
-Kirchhoff's laws(KVL,KCL).
-Series resistors & voltage division.
-Parallel resistors & current division.
-Wye to Delta & Delta to Wye conversion.
-Nodal analysis & Super node.
-Mesh analysis & Super mesh.
-Superposition.
-Source transformation.
-Thevenin's theorem.
-Norton's theorem.
-Maximum power transfer.
-Capacitors.
-Series and parallel capacitors.
-Inductors.
-Series and parallel inductors.
-Complex numbers.
-Sinusoids & phasors.
-Converting from time domain to phasor domain.
-Impedance for capacitors & Inductors.