The UPSC IES/ESE Syllabus for the Category III Electrical Engineering is as given below. The syllabus for Paper II of the Preliminary (Stage-I Examination – objective type) and Paper-I and Paper – II of the Main (Stage-II Examination-Conventional type) is same.

Candidates can find below the detailed UPSC Syllabus for Category 3 – Electrical Engineering of Engineering Services Exam conducted by the Commission to recruit candidates for Indian Engineering Service.

• UPSC Exam Pattern
• Important Topics in Electricl Engineering Category
• Complete UPSC Syllabus

The UPSC Exam Pattern for ESE Prelims (Paper II) and Main (Paper I and Paper II) is as given below.

IES/ESE Prelims Electrical Engineering Category Paper III Pattern.

 Category-III Electrical Engineering Prelims Paper III SL. NO. Paper Subject Duration Maximum Marks 1. Paper-II Electrical Engineering 3 hours 300 TOTAL 300

IES/ESE MainElectricalEngineering Category Paper I and Paper II Pattern.

 CATEGORY-IIIElectricalENGINEERING SL. NO. PAPER DURATION MAXIMUM MARKS 1. ElectricalEngineering Paper-I 3 hours 300 2. ElectricalEngineering Paper-II 3 hours 300 TOTAL 600

Below-given is the list of major topics for prelims and main exam as mentioned in the UPSC Syllabus for IES/ESE

 List of Major topics in UPSC Syllabus for IES/ESE Electrical Engineering Category Topics in Paper I Topics in Paper II •         Engineering Mathematics •         Analog and Digital Electronics •         Electrical Materials •         Systems and Signal Processing •         Electric Circuits and Fields •         Control Systems •         Electrical and Electronic Measurements •         Electrical Machines •         Computer Fundamentals •         Power Systems •         Basic Electronics Engineering •         Power Electronics and Drives

Find below the detailed UPSC Syllabus for IES/ESE Electrical Engineering CategoryPrelims paper 2 and mains paper 1 and paper 2.

ELECTRICAL ENGINEERING PAPER –I SYLLABUS

1. Engineering Mathematics
Matrix theory, Eigen values & Eigen vectors, system of linear equations, Numerical methods for solution of non-linear algebraic equations and differential equations, integral calculus, partial derivatives, maxima and minima, Line, Surface and Volume Integrals. Fourier series, linear, non-linear and partial differential equations, initial and boundary value problems, complex variables, Taylor’s and Laurent’s series, residue theorem, probability and statistics fundamentals, Sampling theorem, random variables, Normal and Poisson distributions, correlation and regression analysis.
2. Electrical Materials
Electrical Engineering Materials, crystal structures and defects, ceramic materials, insulating materials, magnetic materials – basics, properties and applications; ferrities, ferro-magnetic materials and components; basics of solid state physics, conductors; Photo-conductivity; Basics of Nano materials and Superconductors.
3. Electric Circuits and Fields
Circuit elements, network graph, KCL, KVL, Node and Mesh analysis, ideal current and voltage sources, Thevenin’s, Norton’s, Superposition and Maximum Power Transfer theorems, transient response of DC and AC networks, Sinusoidal steady state analysis, basic filter concepts, two-port networks, three phase circuits, Magnetically coupled circuits, Gauss Theorem, electric field and potential due to point, line, plane and spherical charge distributions, Ampere’s and Biot-Savart’s laws; inductance, dielectrics, capacitance; Maxwell’s equations.
4. Electrical and Electronic Measurements:
Principles of measurement, accuracy, precision and standards; Bridges and potentiometers; moving coil, moving iron, dynamometer and induction type instruments, measurement of voltage, current, power, energy and power factor, instrument transformers, digital voltmeters and multi-meters, phase, time and frequency measurement, Q-meters, oscilloscopes, potentiometric recorders, error analysis, Basics of sensors, Transducers, basics of data acquisition systems
5. Computer Fundamentals:
Number systems, Boolean algebra, arithmetic functions, Basic Architecture, Central Processing Unit, I/O and Memory Organisation; peripheral devices, data represenation and programming, basics of Operating system and networking, virtual memory, file systems; Elements of programming languages, typical examples.
6. Basic Electronics Engineering:
Basics of Semiconductor diodes and transistors and characteristics, Junction and field effect transistors (BJT, FET and MOSFETS), different types of transistor amplifiers, equivalent circuits and frequency response; oscillators and other circuits, feedback amplifiers.

ELECTRICAL ENGINEERING PAPER –II SYLLABUS

1. Analog and Digital Electronics
Operational amplifiers – characteristics and applications, combinational and sequential logic circuits, multiplexers, multi-vibrators, sample and hold circuits, A/D and D/A converters, basics of filter circuits and applications, simple active filters; Microprocessor basics- interfaces and applications, basics of linear integrated circuits; Analog communication basics, Modulation and demodulation, noise and bandwidth, transmitters and receivers, signal to noise ratio, digital communication basics, sampling, quantizing, coding, frequency and time domain multiplexing, power line carrier communication systems.
2. Systems and Signal Processing:
Representation of continuous and discrete-time signals, shifting and scaling operations, linear, time-invariant and causal systems, Fourier series representation of continuous periodic signals, sampling theorem, Fourier and Laplace transforms, Z transforms, Discrete Fourier transform, FFT, linear convolution, discrete cosine transform, FIR filter, IIR filter, bilinear transformation.
3. Control Systems:
Principles of feedback, transfer function, block diagrams and signal flow graphs, steady-state errors, transforms and their applications; Routh-hurwitz criterion, Nyquist techniques, Bode plots, root loci, lag, lead and lead-lag compensation, stability analysis, transient and frequency response analysis, state space model, state transition matrix, controllability and observability, linear state variable feedback, PID and industrial controllers.
4. Electrical Machines:
Single phase transformers, three phase transformers – connections, parallel operation, auto-transformer, energy conversion principles, DC machines – types, windings, generator characteristics, armature reaction and commutation, starting and speed control of motors, Induction motors – principles, types, performance characteristics, starting and speed control, Synchronous machines – performance, regulation, parallel operation of generators, motor starting, characteristics and applications, servo and stepper motors.
5. Power Systems
Basic power generation concepts, steam, gas and water turbines, transmission line models and performance, cable performance, insulation, corona and radio interference, power factor correction, symmetrical components, fault analysis, principles of protection systems, basics of solid state relays and digital protection; Circuit breakers, Radial and ring-main distribution systems, Matrix representation of power systems, load flow analysis, voltage control and economic operation, System stability concepts, Swing curves and equal area criterion. HVDC transmission and FACTS concepts, Concepts of power system dynamics, distributed generation, solar and wind power, smart grid concepts, environmental implications, fundamentals of power economics.
6. Power Electronics and Drives
Semiconductor power diodes, transistors, thyristors, triacs, GTOs, MOSFETs and IGBTs – static characteristics and principles of operation, triggering circuits, phase control rectifiers, bridge converters – fully controlled and half controlled, principles of choppers and inverters, basis concepts of adjustable speed DC and AC drives, DC-DC switched mode converters, DC-AC switched mode converters, resonant converters, high frequency inductors and transformers, power supplies.