B.Tech (Electrical & Electronics) Syllabus

Semester V

  • COURSE CODE
    COURSE NAME
    CREDITS
  • JEEE-501

    Power System Analysis I:

    UNIT-I

    Power System Components: Single line Diagram of Power system, Brief description of power system Elements: Synchronous machine, transformer, transmission line, bus bar, circuit breaker and isolator.
    Supply System: Different kinds of supply system and their comparison, choice of transmission voltage
    Transmission Lines: Configurations, types of conductors, resistance of line, skin effect, Kelvin’s law. Proximity effect.

    UNIT-II

    Over Head Transmission Lines: Calculation of inductance and capacitance of single phase, three phase, single circuit and double circuit transmission lines, Representation and performance of short, medium and long transmission lines, Ferranti effect. Surge impedance loading.

    UNIT-III

    Corona and Interference: Phenomenon of corona, corona formation, calculation of potential gradient, corona loss, factors affecting corona, methods of reducing corona and interference. Electrostatic and electromagnetic interference with communication lines. Overhead line Insulators: Type of insulators and their applications, potential distribution over a string of insulators, methods of equalizing the potential, string efficiency.

    UNIT-IV

    Mechanical Design of transmission line: Catenary curve, calculation of sag & tension, effects of wind and ice loading, sag template, vibration dampers.
    Insulated cables: Type of cables and their construction, dielectric stress, grading of cables, insulation resistance, capacitance of single phase and three phase cables, dielectric loss, heating of cables.

    UNIT-V

    Neutral grounding: Necessity of neutral grounding, various methods of neutral grounding, earthing transformer, grounding practices.
    Electrical Design of Transmission Line: Design consideration of EHV transmission lines, choice of voltage, number of circuits, conductor configuration, insulation design, selection of ground wires.
    EHV AC and HVDC Transmission: Introduction to EHV AC and HVDC transmission and their comparison, use of bundle conductors, kinds of DC links, and incorporation of HVDC into AC system.

    Books:

    • 1. W. D. Stevenson, “Element of Power System Analysis”, McGraw Hill,
    • 2. C. L. Wadhwa, “Electrical Power Systems” New Age International Ltd.
    • 3. Asfaq Hussain, “'Power System”, CBS Publishers and Distributors,
    • 4. B. R. Gupta, “Power System Analysis and Design”, S. Chand & Co.
    • 5. M. V. Deshpande, “Electrical Power System Design” Tata Mc Graw Hill.
    • 6. M. V. Deshpandey, “Elements of Power System Design”, Tata McGraw Hill,
    • 7. Soni, Gupta & Bhatnagar, “A Course in Electrical Power”, Dhanpat Rai & Sons,
    • 8. S. L. Uppal, “Electric Power”, Khanna Publishers
    • 9. S. N. Singh, “Electric Power Generation, Transmission& distribution.” PHI Learning
    04
  • JEEE-502

    Control System:

    UNIT-I

    The Control System: Open loop & closed control; servomechanism, Physical examples. Transfer functions, Block diagram algebra, Signal flow graph, Mason’s gain formula Reduction of parameter variation and effects of disturbance by using negative feedback.

    UNIT-II

    Time Response analysis: Standard test signals, time response of first and second order systems, time response specifications, steady state errors and error constants. Design specifications of second order systems: Derivative error, derivative output, integral error and PID compensations, design considerations for higher order systems, performance indices.

    UNIT-III

    Control System Components: Constructional and working concept of ac servomotor, synchros and stepper motor.
    Stability and Algebraic Criteria: concept of stability and necessary conditions, Routh-Hurwitz criteria and limitations.
    Root Locus Technique: The root locus concepts, construction of root loci.

    UNIT-IV

    Frequency response Analysis: Frequency response, correlation between time and frequency responses, polar and inverse polar plots, Bode plots.
    Stability in Frequency Domain: Nyquist stability criterion, assessment of relative stability: gain margin and phase margin, constant M & N circles

    UNIT-V

    Introduction to Design :The design problem and preliminary considerations lead, lag and lead-lag networks, design of closed loop systems using compensation techniques in time domain and frequency domain.
    Review of state variable technique: Review of state variable technique, conversion of state variable model to transfer function model and vice-versa, diagonalization, Controllability and observability and their testing.

    Books:

    • 1. Nagrath & Gopal, “Control System Engineering”, New age International.
    • 2. K. Ogata, “Modern Control Engineering”, Prentice Hall of India.
    • 3. B.C. Kuo & Farid Golnaraghi, “Automatic Control System” Wiley IndiaLtd.
    • 4. D. Roy Choudhary, “Modern Control Engineering”, Prentice Hall of India.
    • 5. Norman S. Mise, Control System Engineering 4th edition, Wiley Pub. Co.
    • 6. Ajit K Mandal, “Introduction to Control Engineering” New Age Intl, 2006.
    • 7. R.T. Stefani, B. Shahian, C.J. Savant and G.H. Hostetter, “Design of Feedback Control Systems” Oxford University Press.
    • 8. N.C. Jagan, “Control Systems”, B.S. Publications.
    04
  • JEEE-503

    Microprocessor and Microcontroller:

    UNIT-I

    Introduction to Digital Computers & Microprocessor: General architecture and brief description of elements, instruction execution, instruction format, and instruction set, addressing modes.
    Buses and CPU Timings: Bus size and signals, machine cycle timing diagram Microprocessor and Microprocessor Development Systems: Evolution of Microprocessor, Functional block diagram of microprocessor, Microprocessor architecture and its operations, memory, inputs-outputs (I/Os), data transfer schemes, architecture advancements of microprocessors.

    UNIT-II

    8-bit Microprocessors, 8085 microprocessor: pin configuration, internal architecture. Timing & Signals: control and status, interrupt: ALU, machine cycles,Instruction Set of 8085: Addressing Modes: Register addressing, direct addressing; register indirect addressing, immediate addressing, and implicit addressing. Instruction format, op-codes, mnemonics, no. of bytes, RTL, no. of machine cycles and T states.
    Instruction Classification: Data transfer, arithmetic operations-arithmetic operations related to memory, logical operations-rotate ad compare, branching operation - conditional CALL and return instruction, machine control, The 8085 Interrupt.

    UNIT-III

    Programming: Stack, Subroutine, Programming techniques: looping, counting and indexing, counter and time delays, Illustrative program: Hexadecimal counter, zero-to-nine, (module ten) counter. Writing assembly language program of 8085 16-bit Microprocessors: Architecture: Architecture of INTEL 8086 (Bus Interface unit-, Execution unit-), register organization, memory addressing, memory segmentation, Operating Modes.

    UNIT-IV

    Introduction to Microcontrollers and Embedded processors, Overview of the 8051, Inside the 8051, Addressing modes. Fundamental of Programming: development of algorithms, flowcharts in terms of structures, (series, parallel, if-then-else etc.) Microcontrollers: Introduction to 8051 assembly programming, Assembling and running an 8051 program.

    UNIT-V

    Interfacing: Serial and parallel communication, Memory I/O mapped I/Os, peripheral mapped I/Os, Interfacing devices, Peripheral Devices: 8237 DMA controller, 8255-Programmable peripheral interface, 8253/8254 Programmable timer/counter. 8259 programmable Interrupt Controller.

    Books:

    • 1. Gaonkar, Ramesh S, “Microprocessor Architecture, programming and applications with the 8085” Pen ram International Publishing 5th Ed.
    • 2. Hall D.V., “Microprocessors Interfacing” Tata Mc Graw Hill.
    • 3. Ray, A.K. & Burchandi, K.M., “Advanced Microprocessors and Peripherals: Architecture, Programming and Interfacing” Tata Mc. Graw Hill.
    • 4. Uffenbeck, John, “Microcomputers and Microprocessors” PHI/ 3rd Edition.
    • 5. Krishna Kant, “Microprocessors and Microcontrollers” PHI Learning.
    • 6. Brey, Barry B. “INTEL Microprocessors” Prentice Hall ( India)
    • 7. ADitya P Mathur, “Introduction to Microprocessor” Tata Mc Graw Hill
    • 8. M. Rafiquzzaman, “Microprocessors- Theory and applications” PHI
    • 9. B. Ram, “Advanced Microprocessor & Interfacing” Tata McGraw Hill
    • 10. Renu Singh & B.P.Singh, “Microprocessor and Interfacing and applications” New Age International
    04
  • JEEE-504

    Special Electrical Machines:

    UNIT-I

    Poly-phase AC Machines: Construction and performance of double cage and deep bar three phase induction motors, e.m.f. injection in rotor circuit of slip ring induction motor, concept of constant torque and constant power controls, static slip power recovery control schemes (constant torque and constant power).

    UNIT-II

    Single phase Induction Motors: Construction, starting characteristics and applications of split phase, capacitor start, capacitor run, capacitor start capacitor-run and shaded pole motors.
    Two Phase AC Servomotors: Construction, torque-speed characteristics, performance and applications.

    UNIT-III

    Stepper Motors: Principle of operation, variable reluctance, permanent magnet and hybrid stepper motors, characteristics, drive circuits and applications.
    Switched Reluctance Motors: Construction; principle of operation; torque production, modes of operation, drive circuits.

    UNIT-IV

    Permanent Magnet Machines: Types of permanent magnets and their magnetization characteristics, demagnetizing effect, permanent magnet dc motors, sinusoidal PM ac motors, brushless dc motors and their important features and applications, PCB motors. Single phase synchronous motor; construction, operating principle and characteristics of reluctance and hysteresis motors; introduction to permanent magnet generators.

    UNIT-V

    Single Phase Commutator Motors: Construction, principle of operation, characteristics of universal and repulsion motors, Linear Induction Motors. Construction, principle of operation, Linear force, and applications.

    Books:

    • 1. P.S. Bimbhra “Generalized Theory of Electrical Machines” Khanna Publishers.
    • 2. P.C. Sen “Principles of Electrical Machines and Power Electronics” John willey & Sons.
    • 3. G.K.Dubey “Fundamentals of Electric Drives” Narosa Publishing House.
    • 4. Cyril G. Veinott “Fractional and Sub-fractional Horse Power Electric Motors” McGraw Hill International, 1987
    • 5. M.G. Say “Alternating Current Machines” Pitman & Sons
    04
  • JEEE-505

    Engineering Electromagnetic:

    UNIT-I

    Coordinate systems and transformation: Cartesian coordinates, Cylindrical coordinates, Spherical coordinates, Vector calculus: Differential length, area and volume, Line, surface and volume integrals, Del operator, Gradient of a scalar, Divergence of a vector and divergence theorem; Curl of a vector and Stokes’ theorem, Laplacian of a scalar.

    UNIT-II

    Electrostatics: Electrostatic fields; Coulomb’s law and field intensity; Electric field due to charge distribution; Electric flux density; Gauss’ Law; Electric dipole and flux lines; energy density in electrostatic fields.
    Electric field in material space: Properties of materials; Convection and conduction currents; Conductors; Polarization in dielectrics; Dielectric constants; Continuity equation and relaxation time; Boundary conditions.
    Electrostatic boundary value problems: Poisson’s and Laplace’s equations; General procedures for solving Poisson’s and Laplace’s equations; Resistance and capacitance; Method of images.

    UNIT-III

    Plane Waves: Maxwell’s equations; Wave equation in an isotropic homogeneous medium and its solution: Phasor notation, Polarization of waves, Reflection and refraction of plane waves at plane boundaries; Poynting vector.

    UNIT-IV

    Waveguides: Electromagnetic fields: Parallel-plate, Rectangular and circular waveguides; TE and TM modes; Wave impedance; Wave velocities; Attenuation in waveguides.

    UNIT-V

    Planar Transmission Line: Electromagnetic fields: Strip-lines, Micro-strip-lines, Co-planar waveguides; Transmission line parameters; Transmission line equations; Input impedance; Standing wave ratio and power; Smith chart; Some applications of transmission lines.
    Cavity Resonators: Electromagnetic fields in rectangular and cylindrical resonators; Degeneracy of modes.

    Books:

    • 1. E.C.Jordan, K.G. Balmain: “E.M.Waves & Radiating Systems”, Pearson Education, 2006
    • 2. William H. Hayt, John A. Buck “Engineering Electromagnetics“, McGraw-Hill Publishing Co.; 6th Edition edition (July 1, 2001)
    • 3. Kraus, J.D. and Fleisch, D.A., Electromagnetics with Applications, McGraw Hill.
    • 4. Matthew N.O.Sadiku, Principles of Electromagnetics, Oxford University Press
    • 5. Kaduskar, “Principles of Electromagnetics”, Wiley India
    • 6. IDA, “Engineering Electromagnetics”, Springer
    • 7. Kodali, “Engineering Electromagnetic Compatibility”, John Wiley & sons
    04
  • JEEE-551

    Power System and High Voltage Lab:

    Note: Minimum 8 Experiment should be performed :

    • 1. Study the construction of disc insulators and determination of the voltage distribution across an artificial string of disc insulators
    • 2. Study the construction of an artificial transmission line and determine ABCD constants with and without series compensation.
    • 3. Determine ABCD, H, Z and image parameters of medium line for both T and π network/ Digital simulation of transmission line.
    • 4. Determine dry one minute withstands and dry flash-over 50Hz voltages for an 11 kV pin insulator.
    • 5. Calibration of a given voltmeter connected on low voltage side of testing transformer in terms of high voltage side, with help of sphere gap.
    • 6. Power Quality Assessment
    • 7. Study of steady-state stability limit of a transmission line.
    • 8. Study and analysis of (i) Radial distribution network (ii) Ring main distribution network.
    • 9. To determine negative and zero sequence reactance’s of an alternator.
    • 10. To study operation of oil testing set.
    • 11. To determine Xd and Xq of a three phase salient pole synchronous machine using the slip test and draw the power-angle curve
    • 1. Nagrath and Kothari, Power System Analysis, 3rd edition (TMH).
    • 2. BR Gupta, Power System Analysis and Design.
    • 3. Grainger and Stevenson, Power System Analysis (McGraw Hill).
    • 4. Hadi Saadat, Power System Analysis, (TMH).
    02
  • JEEE-552

    Control System Lab:

    Note: The minimum of 10 experiments are to be performed from the following, out of which at least three should be software based.

    • 1. To determine response of first order and second order systems for step input for various values of constant ’K’ using linear simulator UNIT- and compare theoretical and practical results.
    • 2. To study P, PI and PID temperature controller for an oven and compare their performance.
    • 3. To study and calibrate temperature using resistance temperature detector (RTD)
    • 4. To design Lag, Lead and Lag-Lead compensators using Bode plot.
    • 5. To study DC position control system
    • 6. To study synchro-transmitter and receiver and obtain output V/S input characteristics
    • 7. To determine speed-torque characteristics of an ac servomotor.
    • 8. To study performance of servo voltage stabilizer at various loads using load bank.
    • 9. To study behaviour of separately excited dc motor in open loop and closed loop conditions at various loads.
    • 10. To study PID Controller for simulation proves like transportation lag.
    • 11. Software based experiments (Use MATLAB, LABVIEW software etc.)
    • 12. To determine time domain response of a second order systems for step input and obtain performance parameters.
    • 13. To convert transfer function of a system into state space form and vice-versa.
    • 14. To plot root locus diagram of an open loop transfer function and determine range of gain ‘k’ stability.
    • 15. To plot a Bode diagram of an open loop transfer function.
    • 16. To draw a Nyquist plot of an open loop transfer functions and examines the stability of the closed loop system.
    • 1. K. Ogata, “Modern Control Engineering” Prentice Hall of India.
    • 2. Norman S.Nise, “Control System Engineering”, John Wiley & Sons.
    • 3. M.Gopal, “Control Systems: Principles & Design” Tata Mc Graw Hill
    02
  • JEEE-553

    Microprocessor Lab:

    • 1. To study 8085 based microprocessor system
    • 2. To study 8086 microprocessor system.
    • 3. To develop and run a program for finding out the largest/smallest number from a given set of numbers.
    • 4. To perform conversion of temperature from 0F to oC.
    • 5. To perform computation of square root of a given number
    • 6. To develop and execute a program to multiply or divide the given numbers
    • 7. To develop and execute a program for arranging the given number in ascending or descending order
    • 8. To develop and execute a program to multiply a number by 2 using bit rotation technique.
    • 9. To obtain interfacing of RAM chip to 8085/8086
    • 10. To perform interfacing of Keyboard controller.
    • 11. To perform interfacing of DMA controller
    • 12. To obtain interfacing of UART/USART
    02
  • JEEE-554

    Seminar I

    02
  • JGP-401

    General Proficiency

    02
  • Total Credits
     
    30