Assistant Professor in Electrical & Electronics Engineering Syllabus

Assistant Professor in Electrical & Electronics Engineering Syllabus: Kerala Public Service Commission has published Assistant Professor in Electrical & Electronics Engineering Syllabus. If you have applied for the post of Assistant Professor in Electrical & Electronics Engineering and would like to know the detailed syllabus, then your search ends right here. In order to crack the exam, one needs to have a clear understanding of the syllabus therefore read through Assistant Professor in Electrical & Electronics Engineering Syllabus to broaden your perspective. You can also download KPSC Assistant Professor in Electrical & Electronics Engineering Syllabus in pdf format.

Assistant Professor in Electrical & Electronics Engineering Syllabus 2023

Assistant Professor in Electrical & Electronics Engineering Syllabus: പരീക്ഷയ്ക്കുള്ള തയ്യാറെടുപ്പുകൾ ആരംഭിക്കാൻ  സമയമായി. പരീക്ഷയിൽ വിജയിക്കുന്നതിന്, സിലബസിനെക്കുറിച്ച് വ്യക്തമായ ധാരണ ഉണ്ടായിരിക്കണം, അതിനാൽ കേരള PSC അസിസ്റ്റന്റ് പ്രൊഫസർ ഇൻ ഇലക്ട്രിക്കൽ ആൻഡ് ഇലക്‌ട്രോണിക്‌സ് എഞ്ചിനീയറിംഗ് സിലബസ് വിശദമായി വായിച്ച് മനസിലാക്കുക. നിങ്ങൾക്ക് Assistant Professor in Electrical & Electronics Engineering Syllabus PDF രൂപത്തിൽ ഡൗൺലോഡ് ചെയ്യാവുന്നതാണ്.

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Kerala PSC Assistant Professor in Electrical & Electronics Engineering Syllabus: Overview

ചുവടെ നൽകിയിരിക്കുന്ന പട്ടികയിൽ Kerala PSC Assistant Professor in Electrical & Electronics Engineering Syllabus സംബന്ധമായ എല്ലാ പ്രധാനപ്പെട്ട വിവരങ്ങളും ലഭിക്കും.

Assistant Professor in Electrical & Electronics Engineering Exam Pattern

Assistant Professor in Electrical & Electronics Engineering Syllabus PDF Download

Assistant Professor in Electrical & Electronics Engineering Syllabus PDF ഡൗൺലോഡ് ചെയ്യാൻ, താഴെ നൽകിയിരിക്കുന്ന ലിങ്കിൽ ക്ലിക്ക് ചെയ്യുക.

Assistant Professor in Electrical & Electronics Engineering Syllabus PDF Download

Assistant Professor in Electrical & Electronics Engineering Syallbus

Module I – Electric and Magnetic Circuits [12 marks]

• Ideal voltage and current sources, dependent sources, R, L, C, and M elements; Network solution methods: KCL, KVL, Node and Mesh analysis; Network theorems: Thevenin’s, Norton’s, Millman’s, superposition and 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.
• MMF, field strength, flux density, reluctance, electromagnetic induction
• Filters – low pass, high pass and band-pass filters

Module II – Field Theory [6 marks]

• Gauss’s law and applications, electric field, electric potential, electric field lines, electric dipoles, potential gradient, conductors, dielectrics, capacitance, polarisation, method of images, dielectric strength, Biot-Savart’s law, Ampere’s circuital law, Stoke’s theorem, scalar, and vector magnetic potential, the force between current carrying wires, Maxwell’s equation – wave equation – Poynting theorem.

Module III – Signals and Systems [6 marks]

• 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. RMS value, average value calculation for any general periodic waveform.

Module IV – Electrical Machines [12 marks]

• Single phase and three phase transformers – leakage reactance, equivalent circuit, losses and efficiency, voltage regulation, OC, SC and Sumpner’s tests, Distribution transformer, all day efficiency, autotransformer – saving of copper three-phase transformer – connections, vector groupings, parallel operation.
• DC machines – Types of excitation, constructional features, characteristics, applications
• DC generator – Emf equation, armature reaction & commutation, characteristics, voltage build-up, applications.
• DC motor – Torque equation, characteristics of shunt, series & compound motors, necessity & types of starters, speed control, applications, Swinburne’s test, Hopkinson’s test.
• Synchronous machines: – constructional features, winding factor, characteristics
• Alternator: Types, synchronous reactance, voltage regulation, emf and mmf methods, short circuit ratio, two reaction theory, alternator on the infinite bus, power angle characteristics, parallel operation, effect of variation of power input & excitation.
• Synchronous motor – the principle of operation, methods of starting, hunting & its reduction.
• Three-phase induction motor – constructional features, types, slip rotor frequency, power flow, Torque – slip curve, the effect of rotor resistance, starting methods, speed control.
• Single phase induction motor – double field revolving theory, starting methods.

Module V – Power System [12 marks]

• Conventional and non-conventional systems of power generation, power plant economics, load factor, demand factor, diversity factor, Transmission line parameters – inductance and capacitance of transmission lines, T and Π models, GMD and GMR, ABCD constants, overhead lines – arrangement of conductors – sag, economic span, choice of transmission voltage, types of insulators, string efficiency, distribution systems – types, comparison of DC and AC single phase and 3 phase systems.
• Per unit quantities, formation of Y bus and Z Bus. Load flow studies – Gauss Seidel, Newton Raphson and Fast decoupled load flow methods.
• Faults on power systems – LG, LL, LLG and 3-phase faults. Fault analysis using Z Bus.
• Power system stability, steady state transient and dynamic stability, equal area criterion, swing curve.
• Protective relays: types and operation, protective zones, different protection schemes.
• Circuit breakers – types and operations, selection of circuit breakers, calculation of fault KVA, protection against lightning and overvoltages.
• Electric traction – speed – time curves – mechanics Electric heating – Advantages, types and applications.
• Tariff, Corona, UG cables

Module VI – Electrical System Design [4 marks]

• Functions of MCB, MCCB, RCCB, the necessity of earthing, types of lamps, illumination design.

Module VII – Control System [12 marks]

• Open loop and closed loop system – transfer function, force-voltage & force-current analogy, block diagrams, signal flow graphs – Mason’s gain formula – characteristic equation, time domain analysis – transient & steady state responses – time domain specifications & steady-state error. Concept of stability – Routh’s stability criterion – Root locus – effect of addition of poles and zeros. Frequency domain analysis – Nyquist & Bode plots, gain margins and phase margin, lag, lead and lag-lead compensators and their design using Bode plot.
• State space analysis of system – state space models, state transition matrix, relationship between state equations and transfer function, controllability and observability.
• Nonlinear system – characteristics, types of non-linearities, describing functions, analysis – concept, singular points – focus, center, node and saddle points – limit cycle.
• Types of signals and systems, sampling process, sampling theorem, convolution of discrete-time signals, analysis of LTI systems using Z transforms. DFT and FFT,
• Types of digital filters.

Module VIII – Measurements and Instrumentation [6 marks]

• Principles of PMMC, moving iron, and electrodynamometer type instruments, error analysis, measurement of voltage, current, power energy and power factor, induction type watt-hour meter, DC bridges and AC bridges, magnetic measurements, Instrument transformers, digital voltmeters and multimeters, digital measurements of frequency, phase angle and time interval.
• The electronic energy meter, high voltage measurements, oscilloscopes, and data acquisition systems.
• Transducers for temperature, force, flow and pressure.

Module IX – Analog and Digital Electronics [12 marks]

• BJT and FET amplifiers – biasing circuits, types of amplifiers, low-frequency and high-frequency considerations. Oscillators and feedback amplifiers.
• Operational amplifier parameters, circuits and applications – simple active filters. VCOs and timers.
• Combinational and sequential logic circuits – comparators, parity generators and checkers, encoders, decoders, BCD to seven segment decoder, code converters, multiplexers, demultiplexers, adders, flip flops, counters, shift registers, TTL & CMOS logic families.
• Schmitt trigger, multivibrators, sample and hold circuits, A to D and D to A converters

Module X – Power Electronics [12 marks]

• Thyristors, triacs, GTOs MOSFETs & IGBTs – principles of operation, triggering circuits, phase-controlled rectifiers, bridge converters – fully controlled and half controlled.
• Inverters – voltage source inverters– single-phase half-bridge & full bridge inverter, pulse width modulation.
• DC-DC converters – step-down and step-up choppers – single quadrant, two-quadrant & four quadrant chopper – pulse width modulation.
• Switching regulators – buck, boost & buck-boost, Voltage Regulators, SMPS
• Basic concepts of ac and dc drives.

Module XI – Microprocessor and Computer Systems [6 marks]

• 8-bit and 16-bit microprocessor basics, architecture, programming, and interfacing. ROM, PROM, EPROM & RAM, memory organization.
• Computer arithmetic – signed and unsigned numbers – addition and subtraction – logical operations.
• Basic Structure of computers – functional units, network protocols.

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