EEE 101: Electrical Circuits I
January 2018 Semester
Level-1 Term-I
Section-C
Course Content:
Circuit variables: voltage, current, power and energy, Voltage and current independent and depended sources, Circuit elements resistance, inductance and capacitance. Modeling of practical circuits, Ohm’s law and Kirchhoff’s laws, Solution of simple circuits with both dependent and independent sources, Series-parallel resistance circuits and their equivalents, Voltage and current divider circuits, Delta-Wye equivalent circuits, Techniques of general DC circuit analysis (containing both independent and dependent sources): Node-voltage method, Mesh-current method, Source transformations. Thevenin and Norton equivalents, Maximum power transfer. Superposition technique. Properties of Inductances and capacitances. Series-parallel combinations of inductances and capacitances; Concepts of transient and steady state response with dc source.
Definitions of ac voltage, current, power, volt-ampere and various factors (including power, peak, form factors etc.) , Introduction to sinusoidal steady state analysis: Sinusoidal sources, phasor, impedance, admittance, reactance, susceptance; voltage, current, power of R, L, C, R-L, R-C, R-L-C circuits with sinusoidal source, Series - parallel and Delta-Wye simplifications of circuits with R, L, Cs. Techniques of general ac circuit analysis (containing both independent and dependent sources): Node-voltage method, Mesh current method, Source transformations, Thevenin and Norton Equivalents, Phasor diagrams. Sinusoidal steady state power calculations, RMS values, Real and reactive power. Maximum power transfer, impedance matching. Steady state voltage, current.
Find your attendance and assignment marks from the link below.
Attendance and assginment marks (Updated on August 8, 2018 September 26, 2018)
Class Test 1
Syllabus: Circuit variables: voltage, current, power and energy, Voltage and current independent and depended sources, Circuit elements resistance, inductance and capacitance. Modeling of practical circuits, Ohm’s law and Kirchhoff’s laws, Solution of simple circuits with both dependent and independent sources, Series-parallel resistance circuits and their equivalents, Voltage and current divider circuits, Delta-Wye equivalent circuits, Techniques of general DC circuit analysis (containing both independent and dependent sources): Node-voltage method, Mesh-current method.
Class Test 2
Syllabus: Linearity, Source transformations, Superposition technique, Thevenin and Norton equivalents, Maximum power transfer.
Class Test 3
Syllabus: Properties of Inductances and capacitances. Series-parallel combinations of inductances and capacitances; Concepts of transient and steady state response with dc source.
Class Test 4
Syllabus: Definitions of ac voltage, current, power, volt-ampere and various factors (including power, peak, form factors etc.) , Introduction to sinusoidal steady state analysis: Sinusoidal sources, phasor, impedance, admittance, reactance, susceptance; voltage, current, power of R, L, C, R-L, R-C, R-L-C circuits with sinusoidal source, Series - parallel and Delta-Wye simplifications of circuits with R, L, Cs. Techniques of general ac circuit analysis (containing both independent and dependent sources): Node-voltage method, Mesh current method, Source transformations, Thevenin and Norton Equivalents.
Find your attendance and assignment marks from the link below.
Attendance and assginment marks (Updated on August 8, 2018 September 26, 2018)