RGPV 3rd Sem CBCS Electrical & Electronics Engg Syllabus | RGPV Electrical and Electronics Syllabus CBCS 2nd Year
RGPV 3rd Sem Electrical & Electronics Engineering Subjects
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RGPV 4th Sem Electrical & Electronics Engineering Subjects
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Mathematics-III
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DC Electrical Measurements and Instrumentation
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DC
Network Analysis
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DC
Analog Electronics
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DC
Signals and Systems
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HU
Communication Skills
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DC
Idea Generation
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DC
Learning Through Experts
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Electrical Machine-I
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EAS
System Engineering
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DC Digital Electronics Logic Design
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DC
Power System -I
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DC
Control Systems
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EAS
Material Science
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EAS Residential Load Simulation Lab
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HU
NSS/NCC
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RGPV 2nd year CBCS Electrical & Electronics Syllabus (3rd Sem Syllabus)
Now RGPV Bhopal announced the 2nd year 3rd sem syllabus of Electrical & Electronics branch; it contain above mentioned subjects. The RGPV also give the detail of 3rd sem CBCS Electrical & Electronics practical list. If you want to download RGPV 3rd sem CBCS Practical list of Electrical & Electronics branch; please follow below links:
RGPV CBCS 3rd Sem Electrical and Electronics Engineering Syllabus
RGPV CBCS 3rd Sem Electrical Measurements and Instrumentation Syllabus
Galvanometers – Theory, principle of operation and construction of ballistic galvanometer, D’arsonal galvanometer, Definition of analog & digital instruments, Classification of analog instruments, their operating principle, Operating force, Types of supports, Damping, Controlling.
Different types of Ammeter & Voltmeter – PMMC, MI, Electrodynamometer, Induction, Expression for control & deflection torque, their advantages, disadvantages & error, Extension of range of instruments using shunt & multiplier.
Digital Voltmeter, Ammeter, Multimeter and Wattmeter.
Instrument transformers: Potential and current transformers, ratio and phase angle errors, testing of instrument transformers, Difference between CT and PT, errors and reduction of errors.
Measurement of power: Power in AC and DC Circuit, Electrodynamometer type of wattmeter, Construction, theory, operation & error, Low power factor & UPF wattmeter, Double element and three element dynamometer wattmeter, Measurement of power in three phase circuit, one, two & three wattmeter method, Measurement of reactive power by single wattmeter, Measurement of power using CTs & PTs.
Measurement of Energy: Single phase and three phasedigital / Electronic energy meter – construction & operation – Energy flow and power calculations, errors – Testing by phantom loading, Tri-vector meter, Maximum demand meter, Ampere hour meter.
Power factor meter– Single phase and three phase Electro-dynamometer type & moving iron type.
Frequency meter – Vibrating reed, Resonance type & Weston type, Synchronoscope,
Ohmmeter –series & stunt type, Megger & Ratio meter.
Resistance Measurement – Classification of low, medium & high resistance – Voltmeter-Ammeter method, Wheatstone Bridge, Kelvin’s double bridge & loss of charge methods for resistance measurement, Earth resistancemeasurement.
Magnetic Measurement – B-H Curve, Hysteresis Loop determination, Power loss in sheet metal – Lloyd Fischer square for measurement of power loss.
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RGPV CBCS 3rd Sem Network Analysis Syllabus
Introduction to circuit elements R,L,C and their characteristics in terms of linearity & time dependent nature, voltage & current sources controlled & uncontrolled sources KCL and KVL analysis, Nodal & mesh analysis, analysis of magnetically coupled circuits,
Transient analysis :- Transients in RL, RC&RLC Circuits, initial conditions, time constants. Steady state analysis- Concept of phasor & vector, impedance & admittance, Network topology, concept of Network graph, Tree, Tree branch & link, Incidence matrix, cut set and tie set matrices, dual networks, Dot convention, coupling co- efficient, tuned circuits, Series & parallel resonance.
Network Theorems for AC & DC circuits- Thevenins & Norton’s, Superpositions, Reciprocity, Compensation, Substitution, Maximum power transfer, and Millman’s theorem, Tellegen’s theorem, problems with dependent & independent sources.
Frequency domain analysis – Laplace transform solution of Integro-differential equations,
transform of waveform synthesized with step ramp, Gate and sinusoidal functions, Initial & final value theorem, Network Theorems in transform domain Concept of signal spectra, Fourier series co-efficient of a periodic waveform, symmetries as related to Fourier coefficients, Trigonometric & Exponential form of Fourier series.
Network function & Two port networks – concept of complex frequency, Network & Transfer functions for one port & two ports, poles and zeros, Necessary condition for driving point & transfer function. Two port parameters – Z, Y, ABCD, Hybrid parameters, their inverse & image parameters, relationship between parameters, Interconnection of two ports networks, Terminated two port network.
RGPV CBCS 3rd Sem Analog Electronics Syllabus
Semiconductor Diodes: Theory of P-N junction, temperature dependence and break down
characteristics, junction capacitances, Zener diode, Varactor diode, Tunnel diode, PIN diode, LED, Photo diode, Schottky diode, Diode applications: series –parallel configurations, full wave and half wave rectification, voltage multiplier circuits, diode testing
Transistors: BJT, types& configuration, working principal, characteristics, and region of operation, load line, biasing methods, Small signal analysis of transistor (low frequency) using h-parameters, thermal runaway and thermal stability.FET, MOSFET, Transistor as an amplifier, gain,bandwidth, frequency response,
Feedback amplifierand Oscillators: Feedback amplifier, negative feedback, voltage-series,
voltage shunt,current series and current shunt feedback, Sinusoidal oscillators, L-C (Hartley- Colpitts) oscillators, RC phase shift, Wien bridge, and Crystal oscillators. Power amplifiers, class A, class B, class A B, C amplifiers, their efficiency and power Dissipation, Push-pull and complimentary symmetry push-pull amplifier.
Wave Shaping circuits: Switching characteristics of diode and transistor, turn ON, OFF time, reverse recovery time, transistor as switch, Multivibrators, Bistable, Monostable, Astable multivibrators. Clipper and clamper circuit, Differential amplifier, calculation of differential, common mode gain and CMRR using h- parameters, Darlington pair, Boot strapping technique. Cascade and cascade amplifier.
Operational Amplifier: Operational amplifier basics, practical Op-amp circuits &
characteristics, slew rate , bandwidth, offset voltage ,basic current, application, inverting, noninverting amplifier, summer, average, differentiator, integrator, differential amplifier,
instrumentation amplifier, log and antilog amplifier, voltage to current and current to voltage converters, comparators Schmitt trigger , active filters, 555 timer and its application.
RGPV CBCS 3rd Sem Signals and Systems Syllabus
Classification of signals and systems: Continuous time signals (CT signals), Discrete time signals (DT signals) - Step, ramp, pulse, impulse, sinusoidal and exponential signals, basic operations on signals, classifications of CT and DT signals- Periodic and aperiodic signals, energy and power signals, random signals, CT systems and DT systems, basic properties of systems, basic properties of systems, linear time invariant systems and properties.
Analysis of continuous time signals: Time and frequency domain analysis, Fourier series analysis, spectrum of CT signals, Fourier transform and Laplace transform, region of convergence, wavelet transform.
Linear time invariant continuous time systems: Differential equations representation, block diagram representation, state variable representation and matrix representation of systems, impulse response, step response, frequency response, relizability of systems, analog filters.
Analysis of discrete time signals: Convolution sum and properties, sampling of CT signals and aliasing, DTFT and properties, Z transform and properties, inverse Z transform.
Linear time invariant discrete time systems: Difference equations, block diagram representation, impulse response, analysis of DT LTI systems using DTFT and Z transform, state variable equations and matrix representation of systems, Digital filters.
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