EEE GATE Course Topics
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Electric circuits |
Network elements: ideal voltage and current sources |
dependent sources, R, L, C, M elements |
Network solution |
methods: KCL, KVL, Node and Mesh analysis |
Network Theorems: Thevenin’s |
Norton’s, Superposition |
Maximum Power Transfer theorem |
Transient response of dc and ac networks |
sinusoidal steady-state analysis |
resonance |
two port networks |
balanced three phase circuits |
star-delta transformation |
complex power and power |
factor in ac circuits |
Electromagnetic Fields |
Coulombs Law |
Electric Field Intensity |
Electric Flux Density, Gauss Law |
Divergence, Electric field and potential due to point |
line, plane and spherical charge distributions |
Effect of dielectric medium |
Electric Flux Density |
Capacitance of simple configurations |
Biot‐Savart’s law |
Ampere’s law, Curl, Faraday’s law, Lorentz force, Inductance |
Magnetomotive force, Reluctance, Magnetic circuits, Self and Mutual inductance of simple configurations |
Signals and Systems |
Representation of continuous and discrete time signals shifting and scaling properties linear time invariant and |
causal systems, Fourier series representation of continuous and discrete time periodic signals, sampling theorem |
Applications of Fourier Transform for continuous and discrete time signals, Laplace Transform and Z transform |
Electrical Machines |
Basic concepts of electrical power generation, ac and dc transmission concepts, Models and performance of |
transmission lines and cables, Series and shunt compensation, Electric field distribution and insulators |
Distribution systems, Per‐unit quantities, Bus admittance matrix, Gauss- Seidel and Newton-Raphson load flow |
methods, Voltage and Frequency control, Power factor correction, Symmetrical components, Symmetrical and |
unsymmetrical fault analysis, Principles of over‐current, differential, directional and distance protection; Circuit |
breakers, System stability concepts, Equal area criterion, Economic Load Dispatch (with and without considering |
transmission losses |
Control Systems |
Mathematical modeling and representation of systems, Feedback principle, transfer function, Block diagrams and |
Signal flow graphs, Transient and Steady‐state analysis of linear time invariant systems, Stability analysis using |
Routh-Hurwitz and Nyquist criteria, Bode plots, Root loci, Lag, Lead and Lead‐Lag compensators; P, PI and PID |
controllers; State space model, Solution of state equations of LTI systems, R.M.S. value, average value |
calculation for any general periodic waveform |
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Electrical and Electronic Measurements |
Bridges and Potentiometers, Measurement of voltage, current, power, energy and power factor; Instrument |
transformers, Digital voltmeters and multimeters, Phase, Time and Frequency measurement; Oscilloscopes, Error analysis |
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Analog and Digital Electronics |
Simple diode circuits: clipping, clamping, rectifiers; Amplifiers: biasing, equivalent circuit and frequency |
response; oscillators and feedback amplifiers; operational amplifiers: characteristics and applications; single |
stage active filters, Sallen Key, Butterworth, VCOs and timers, combinatorial and sequential logic circuits,multiplexers, demultiplexers, Schmitt triggers, sample and hold circuits, A/D and D/A converters. |
Power Electronics |
Static V-I characteristics and firing/gating circuits for Thyristor, MOSFET, IGBT; DC to DC conversion: Buck |
Boost and Buck-Boost Converters; Single and three-phase configuration of uncontrolled rectifiers; Voltage and
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Current commutated Thyristor based converters; Bidirectional ac to dc voltage source converters; Magnitude and |
Phase of line current harmonics for uncontrolled and thyristor based converters; Power factor and Distortion |
Factor of ac to dc converters; Single-phase and three-phase voltage and current source inverters, sinusoidal pulse
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width modulation |
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