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DEPARTMENT OF ELECTRICAL ENGINEERING
Syllabus Scheme for Batch 2018 onwards (
rd
th
semester)
BACHELOR OF TECHNOLOGY IN ELECTRICAL ENGINEERING
NOTE:
- Institutional/Industrial Training of Four weeks shall be held in summer vacation after 2nd^ semester and marks/credit shall be awarded in 3rd^ semester itself.
There will be one period per week for Mentoring and Professional Development, final evaluation of this course will be done based on the combined assessment of Odd and
Even semester of respective year of study
SEMESTER - 3 RD
S.
No. Course Type Course Code Course Title Subject Type Hours per week Internal Marks External Marks Total Credits L T P
- Basic Science BSEE- 101 Engineering Mathematics-III (Probability and Statistics) Theory 3 0 0 40 60 100 3
- Humanities/ Social Sciences/ Management
HSMEE- 101
Education, Technology and Society Theory 3 0 0 40 60 100 3
- Professional Core PCEE- 101 Electrical Circuit Analysis Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 102 Analog Electronics Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 103 Electrical Machines-I (Transformer & DC Machines) Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 104 Electromagnetic Fields Theory 3 0 0 40 60 100 3
- Professional Core LPCEE- 101 Analog Electronics Laboratory Practical 0 0 2 30 20 50 1
- Professional Core LPCEE- 102 Electrical Machines Laboratory-I Practical 0 0 2 30 20 50 1
- Training*^ TR- 101 Training-I Practical - - - 60 40 100 1 TOTAL 18 3 4+1#^360 440 800
NOTE: $ Marks of non-credit courses are excluded from total and minimum 40% score required to pass.
SEMESTER - 4 TH
S.
No. Course Type Course Code Course Title Subject Type Hours per week Internal Marks External Marks Total Credits L T P
- Professional Core PCEE- 105 Digital Electronics Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 106 Electrical Machines-II (Asynchronous & Synchronous Machines) Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 107 Power Electronics Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 108 Signals and Systems Theory 3 1 0 40 60 100 4
- Professional Core LPCEE- 103 Digital Electronics Laboratory Practical 0 0 2 30 20 50 1
- Professional Core LPCEE- 104 Electrical Machines Laboratory-II Practical 0 0 2 30 20 50 1
- Professional Core LPCEE- 105 Power Electronics Laboratory Practical 0 0 2 30 20 50 1
- Seminar PREE- 101 Seminar and Technical Report Writing Practical 0 0 2 50 0 50 1
- Mandatory Course$^ MCEE- 101 Environmental Science Theory 2 0 0 50 0 50 S/US
- Mentoring MPD- 102 Mentoring & Professional Development Practical 0 0 1 100 0 100 1 TOTAL 14 4 9 450 300 750 21
SEMESTER - 6 TH
S.
No. Course Type Course Code Course Title Subject Type Hours per week Internal Marks External Marks Total Credits L T P
- Professional Core PCEE- 114 Power Systems – II (Operation and Control) Theory 3 1 0 40 60 100 4
- Professional Core PCEE- 115 Industrial Drives and Control Theory 3 0 0 40 60 100 3
- Professional Elective PEEE-XXX Elective-I Theory 3 1 0 40 60 100 4
- Professional Elective PEEE-XXX Elective-II Theory 3 1 0 40 60 100 4
- Open Elective OEXX-XXX Open Elective-I Theory 3 0 0 40 60 100 3
- Professional Core LPCEE- 109 Power Systems Laboratory-II Practical 0 0 2 30 20 50 1
- Professional Core LPCEE- 110 Measurements and Instrumentation Laboratory Practical 0 0 2 30 20 50 1
- Professional Core LPCEE- 111 Industrial Drives and Control Laboratory Practical 0 0 2 30 20 50 1
- Project PREE- 102 Minor Project Practical 0 0 2 50 50 100 1
- Mentoring MPD- 103 Mentoring & Professional Development Practical 0 0 1 100 0 100 1 TOTAL 15 3 9 440 410 850 23
SEMESTER - 7 TH
S.
No. Course Type Course Code Course Title Subject Type Hours per week Internal Marks External Marks Total Credits L T P
- Professional Elective PEEE-XXX Elective-III Theory 3 1 0 40 60 100 4
- Professional Elective PEEE-XXX Elective-IV Theory 3 1 0 40 60 100 4
- Open Elective OEXX-XXX Open Elective-II Theory 3 0 0 40 60 100 3
- Project PREE- 103 Project-I Practical 0 0 6 50 50 100 3
- Training*^ TR- 103 Training-III Practical - - - 100 50 150 2
- Mandatory Course$^ MCI- 103 Organisational Behavior Theory 2 0 0 50 0 50 S/US TOTAL 11 2 6 +1#^320 280 600 NOTE:
- Institutional/Industrial Training of Six weeks shall be held in summer vacation after 6 thsemester and marks/credit shall be awarded in 7 thsemester itself. $ Marks of non-credit courses are excluded from total and minimum 40% score required to pass.
There will be one period per week for Mentoring and Professional Development, final evaluation of this course will be done based on the combined assessment of
Odd and Even semester of respective year of study. SEMESTER - 8 TH S. No. Course Type Course Code Course Title Subject Type Hours per week Internal Marks External Marks Total Credits L T P
- Professional Elective PEEE-XXX Elective-V Theory 3 1 0 40 60 100 4
- Professional Elective PEEE-XXX Elective-VI Theory 3 1 0 40 60 100 4
- Open Elective OEXX-XXX Open Elective-III Theory 3 0 0 40 60 100 3
- Project PREE- 104 Project-II Practical 0 0 6 50 50 100 3
- Mentoring MPD- 104 Mentoring & Professional Development Practical 0 0 1 100 0 100 1 TOTAL 9 2 7 270 230 500 15
Subject Code: BSEE- 101 Subject Name: ENGINEERING MATHEMATICS-III (PROBABILITY AND STATISTICS) Programme: B.Tech (EE) L: 3 T: 0 P: 0 Semester: 3 Teaching Hours : 40 Theory/Practical: Theory Credits: 3 Internal marks: 40 Percentage of Numerical/Design/ Programming Problems: 8 0% External Marks: 60 Duration of End Semester exam (ESE): 3 hr Total marks: 100 Elective Status: Compulsory Prerequisites: Knowledge of Integration, Differential Calculus Additional Material allowed in ESE : Scientific Calculator On Completion of the course, the student will have the ability to: CO# Course Outcomes (CO)
- Apply probability theory via Bayes’ Rule.
- Formulate the marginal and conditional distributions of bivariate random variables.
- Verify the predicted data sets using Binomial, Poisson and normal distribution.
- Predict the linear regression parameters and correlation coefficient.
- Select a critical value from a normal and chi - square distribution. DETAILED CONTENTS PART-A MODULE 1: BASIC PROBABILITY (12 Hours) Probability spaces, theorems of Probability, addition multiplication and Baye’s theorem, conditional probability, independence; Discrete random variables, Independent random variables, Poisson approximation to the binomial distribution, sums of independent random variables; Expectation of Discrete Random Variables, Variance. MODULE 2: CONTINUOUS PROBABILITY AND BIVARIATE DISTRIBUTIONS (8 Hours) Continuous random variables and their properties, distribution functions and densities, normal, exponential densities. Bivariate distributions and their properties, distribution of sums and quotients. PART-B MODULE 3: BASIC STATISTICS (8 Hours) Measures of Central tendency: Moments, skewness and Kurtosis - Probability distributions: Binomial, Poisson and Normal-evaluation of statistical parameters for these three distributions, Correlation and regression – Rank correlation. MODULE 4: APPLIED STATISTICS (8 Hours) Curve fitting by the method of least squares- fitting of straight lines, second degree parabolas and more general curves. Test of significance: Large sample test for single proportion, difference of proportions, single mean, difference of means, and difference of standard deviations MODULE 5: SMALL SAMPLES (4 Hours) Test for single mean, difference of means and correlation coefficients, test for ratio of variances - Chi-square test for goodness of fit and independence of attributes. Text / References:
- E. Kreyszig, “Advanced Engineering Mathematics”, John Wiley & Sons, 2006.
- P. G. Hoel, S. C. Port and C. J. Stone, “Introduction to Probability Theory” , Universal Book Stall, 2003.
- S. Ross, “A First Course in Probability” , Pearson Education India, 2002.
- W. Feller, “An Introduction to Probability Theory and its Applications” , Vol. 1, Wiley, 1968.
- N.P. Bali and M. Goyal, “A text book of Engineering Mathematics”, Laxmi Publications, 2010.
- B.S. Grewal, “Higher Engineering Mathematics”, Khanna Publishers, 2000.
- T. Veerarajan, “Engineering Mathematics”, Tata McGraw-Hill, New Delhi, 2010.
E-Books and online learning material:
- Convex Optimization by Boyd and Vandenberghehttp://stanford.edu/~boyd/cvxbook/bv_cvxslides.pdf
- Probability and Statistics by PrasannaSahoohttp://www.math.louisville.edu/~pksaho01/teaching/Math662TB-09S.pdf Online Courses and Video Lectures:
- Probability and Statistics bynptelhrdhttp://nptel.ac.in/courses/111105041/
- Probability and statistics by nptelhrdhttp://www.youtube.com/watch?v=VVYLpmKRfQ8&list=PLbMVogVj5nJQrzbAweTV ynH6-vG5A4aN
E-books and online learning material:
- Technology and Society By Jan L Harrington https://books.google.co.in/books?id=3y4LW3lAf9kC&printsec=frontcover&source=gbs_ge_sum mary_r&cad=0#v=onepage&q&f=false
- Non-Conventional energy Resources by B H Khan https://books.google.co.in/books?id=YVyv4WyA5QUC&printsec=frontcover&dq=Non- Conventional+energy+Resources+by+B+H+KHAN&hl=en&sa=X&ved=0ahUKEwin9_iHgebiA hVKfysKHVhtBQIQ6AEIKDAA#v=onepage&q&f=false Online Courses and Video Lectures:
- https://www.youtube.com/watch?v=fTNnsZGlV
Subject Code: PCEE- 101 Subject Name: ELECTRICAL CIRCUIT ANALYSIS Programme: B.Tech (EE) L: 3 T: 1 P: 0 Semester: 3 Teaching Hours : 40 Theory/Practical: Theory Credits: 4 Internal marks: 40 Percentage of Numerical/Design/ Programming Problems: 5 0% External Marks: 60 Duration of End Semester exam (ESE): 3 hr Total marks: 100 Elective Status: Compulsory Prerequisites: Basic Electrical Engineering. Additional Material allowed in ESE : Scientific Calculator On Completion of the course, the student will have the ability to: CO# Course Outcomes (CO)
- Apply network theorems for the analysis of electrical circuits.
- Obtain the steady-state and transient response of electrical circuits.
- Analyze circuits in the sinusoidal steady-state (single-phase and three-phase).
- Analyze electrical circuits using Laplace Transform
- Analyze various types of two port networks and their inter connection. DETAILED CONTENTS PART-A MODULE 1: NETWORK THEOREMS (10 Hours) Superposition theorem, Thevenin theorem, Norton theorem, Maximum power transfer theorem, Reciprocity theorem, Compensation theorem. Analysis with dependent current and voltage sources, Node and Mesh Analysis, .Concept of duality and dual networks. MODULE 2: SOLUTION OF FIRST AND SECOND ORDER NETWORKS ( 10 Hours) Solution of first and second order differential equations for Series and parallel R-L, R-C, R-L-C circuits, initial and final conditions in network elements, forced and free response, time constants, steady state and transient state response. PART-B MODULE 3: SINUSOIDAL STEADY STATE ANALYSIS ( 7 Hours) Representation of sine function as rotating phasor, phasor diagrams, impedances and admittances, AC circuit analysis, effective or RMS values, average power and complex power. Three-phase circuits, Mutual coupled circuits, Dot Convention in coupled circuits, Ideal Transformer. MODULE 4: ELECTRICAL CIRCUIT ANALYSIS USING LAPLACE TRANSFORMS ( 7 Hours) Review of Laplace Transform, Analysis of electrical circuits using Laplace Transform for standard inputs, convolution integral, inverse Laplace transform, transformed network with initial conditions. Transfer function representation. Poles and Zeros. Frequency response (magnitude and phase plots), series and parallel resonances MODULE 5: TWO PORT NETWORK AND NETWORK FUNCTIONS (6 Hours) Two Port Networks, terminal pairs, relationship of two port variables, impedance parameters, admittance parameters, transmission parameters and hybrid parameters, interconnections of two port networks, synthesis of network using Foster and Cauer Forms. Text / References:
- M. E. Van Valkenburg, “Network Analysis”, Prentice Hall, 2006.
- D. Roy Choudhury, “Networks and Systems”, New Age International Publications, 1998.
- W. H. Hayt and J. E. Kemmerly, “Engineering Circuit Analysis”, McGraw Hill Education, 2013.
- C. K. Alexander and M. N. O. Sadiku, “Electric Circuits”, McGraw Hill Education, 2004.
- K. V. V. Murthy and M. S. Kamath, “Basic Circuit Analysis”, Jaico Publishers, 1999.
Subject Code: PCEE- 102 Subject Name: ANALOG ELECTRONICS Programme: B.Tech (EE) L: 3 T: 1 P: 0 Semester: 3 Teaching Hours : 40 Theory/Practical: Theory Credits: 4 Internal marks: 40 Percentage of Numerical/Design/ Programming Problems: 4 0% External Marks: 60 Duration of End Semester exam (ESE): 3 hr Total marks: 100 Elective Status: Compulsory Prerequisites: Basic Electrical Engineering Additional Material allowed in ESE : Scientific Calculator On Completion of the course, the student will have the ability to: CO# Course Outcomes (CO)
- Analyze basic diode circuits.
- Understand the characteristics of transistors.
- Understand the characteristics of MOSFET.
- Design and analyze various rectifier and amplifier circuits.
- Understand the functioning of OP-AMP and design OP-AMP based circuits. DETAILED CONTENTS PART-A MODULE 1: DIODE CIRCUITS (4 Hours) P-N junction diode, I-V characteristics of a diode; review of half-wave and full-wave rectifiers, Zener diodes, clamping and clipping circuits. MODULE 2: BJT CIRCUITS (8 Hours ) Structure and I-V characteristics of a BJT; BJT as a switch. BJT as an amplifier: small-signal model, biasing circuits, current mirror; common-emitter, common-base and common-collector amplifiers; Small signal equivalent circuits, high-frequency equivalent circuits MODULE 3: MOSFET CIRCUITS ( 9 Hours) MOSFET structure and I-V characteristics, MOSFET as a switch, MOSFET as an amplifier: small- signal model and biasing circuits, common-source, common-gate and common-drain amplifiers; small signal equivalent circuits - gain, input and output impedances, trans-conductance, high frequency equivalent circuit. PART-B MODULE 4: DIFFERENTIAL, MULTI-STAGE AND OPERATIONAL AMPLIFIERS (8 Hours) Differential amplifier; power amplifier; direct coupled multi-stage amplifier; internal structure of an operational amplifier, ideal op-amp, non-idealities in an op-amp (Output offset voltage, input bias current, input offset current, slew rate, gain bandwidth product) MODULE 5: LINEAR AND NONLINEAR APPLICATIONS OF OP-AMP ( 13 Hours) Idealized analysis of op-amp circuits. Inverting and non-inverting amplifier, differential amplifier, instrumentation amplifier, integrator, active filter, P, PI and PID controllers and lead/lag compensator using an op-amp, voltage regulator, oscillators (Wein bridge and phase shift). Analog to Digital Conversion. Hysteretic Comparator, Zero Crossing Detector, Square-wave and triangular- wave generators. Precision rectifier, peak detector. Text/References:
- A.S. Sedra and K. C. Smith, “Microelectronic Circuits”, New York, Oxford University Press,
- J. V. Wait, L. P. Huelsman and G. A. Korn, “Introduction to Operational Amplifier theory and applications”, McGraw Hill U. S., 1992.
- J. Millman and A. Grabel, “Microelectronics”, McGraw Hill Education, 1988.
- P. Horowitz and W. Hill, “The Art of Electronics”, Cambridge University Press, 1989.
- P.R. Gray, R.G. Meyer and S. Lewis, “Analysis and Design of Analog Integrated Circuits”, John Wiley & Sons, 2001.
E-books and online learning material:
- Integrated Electronics: Analog and Digital circuits and systems by Jacob Milliman and Christos C Halkiashttp://www.introni.it/pdf/Millman%20Halkias%20-%20Integrated%20Electronics.pdf
- Principles of Analog Electronics by Giovanni Saggiohttps://books.google.co.in/books?id=eosAAgAACAAJ&printsec=frontcover&source=gbs _ge_summary_r&cad=0#v=onepage&q&f=false
- Analog Electronics by Hayrettin Köymenhttp://www.electronics.teipir.gr/personalpages/papageorgas/download/2/shmeiwseis/EL ECTRONIC_COMPONENTS/varistor/Analog_Electronics.pdf
- Analog Electronics Raymond E. Frey Physics Department University of Oregon https://pages.uoregon.edu/rayfrey/AnalogNotes.pdf
- Foundations of Analog and Digital Electronic Circuits anantagarwal and jeffrey h. langhttps://neurophysics.ucsd.edu/courses/physics_120/Agarwal%20and%20Lang%20(2005)% 0Foundations%20of%20Analog%20and%20Digital.pdf Online Courses and Video Lectures:
- https://nptel.ac.in/courses/108102095/
- https://nptel.ac.in/courses/108102095/
- https://nptel.ac.in/courses/108102095/
- https://nptel.ac.in/courses/108102095/
- https://nptel.ac.in/courses/108102095/
- https://nptel.ac.in/courses/108102095/
- https://nptel.ac.in/courses/108102095/
E-books and online learning material:
- https://nptel.ac.in/courses/108106071/
- https://drive.google.com/file/d/0B_jwSWRUH7bwbV83ZVpOd3dvdjA/view
- https://drive.google.com/file/d/0B_jwSWRUH7bwZGxaREwyTWVzN1k/view
- https://drive.google.com/file/d/0B_jwSWRUH7bwLUVRNk40X040RjQ/view
- https://drive.google.com/file/d/0B_jwSWRUH7bwR0xHMFRKelRTZGs/view Online Courses and Video Lectures:
- https://nptel.ac.in/courses/108105017/
- https://nptel.ac.in/courses/108105017/
- https://nptel.ac.in/courses/108105017/
- https://nptel.ac.in/courses/108105017/
- https://nptel.ac.in/courses/108105017/
- https://nptel.ac.in/courses/108105017/
- https://nptel.ac.in/courses/108105017/
Subject Code: PCEE- 104 Subject Name: ELECTROMAGNETIC FIELDS Programme: B.Tech (EE) L: 3 T: 0 P: 0 Semester: 3 Teaching Hours : 40 Theory/Practical: Theory Credits: 3 Internal marks: 40 Percentage of Numerical/Design/ Programming Problems: 4 0% External Marks: 60 Duration of End Semester exam (ESE): 3 hr Total marks: 100 Elective Status: Compulsory Prerequisites: Basic knowledge of Coordinate systems, Electric and Magnetic fields Additional Material allowed in ESE : Scientific Calculator On Completion of the course, the student will have the ability to: CO# Course Outcomes (CO)
- To understand the basic laws of electromagnetism.
- To obtain the electric and magnetic fields for simple configurations under static conditions.
- To analyze time varying electric and magnetic fields.
- To understand Maxwell’s equation in different forms and different media.
- To understand the propagation of EM waves. DETAILED CONTENTS PART-A MODULE 1: REVIEW OF VECTOR CALCULUS (6 Hours) Vector algebra-addition, subtraction, components of vectors, scalar and vector multiplications, triple products, three orthogonal coordinate systems (rectangular, cylindrical and spherical). Vector calculus-differentiation, partial differentiation, integration, vector operator del, gradient, divergence and curl, integral theorems of vectors. Conversion of a vector from one coordinate system to another. MODULE 2: STATIC ELECTRIC FIELD CONDUCTORS, DIELECTRICS AND CAPACITANCE ( 12 Hours) Coulomb’s law, Electric field intensity, Electrical field due to point charges. Line, Surface and Volume charge distributions. Gauss law and its applications. Absolute Electric potential, Potential difference, Calculation of potential differences for different configurations. Electric dipole, Electrostatic Energy and Energy density, Current and current density, Ohms Law in Point form, Continuity of current, Boundary conditions of perfect dielectric materials. Permittivity of dielectric materials, Capacitance, Capacitance of a two wire line, Poisson’s equation, Laplace’s equation, Solution of Laplace and Poisson’s equation, Application of Laplace’s and Poisson’s equations. PART-B MODULE 3: STATIC MAGNETIC FIELDs, FORCES, MATERIALS AND INDUCTANCE ( 10 Hours) Biot-Savart Law, Ampere Law, Magnetic flux and magnetic flux density, Scalar and Vector Magnetic potentials. Steady magnetic fields produced by current carrying conductors. Force on a moving charge, Force on a differential current element, Force between differential current elements, Nature of magnetic materials, Magnetization and permeability, Magnetic boundary conditions, Magnetic circuits, inductances and mutual inductances. MODULE 4: TIME VARYING FIELDS AND MAXWELL’S EQUATIONS (6 Hours) Faraday’s law for Electromagnetic induction, Displacement current, Point form of Maxwell’s equation, Integral form of Maxwell’s equations, Motional Electromotive forces, Boundary Conditions. MODULE 5: ELECTROMAGNETIC WAVES (6 Hours) Derivation of Wave Equation, Uniform Plane Waves, Maxwell’s equation in Phasor form, Wave equation in Phasor form, Plane waves in free space and in a homogenous material. Wave equation for a conducting medium, Plane waves in lossy dielectrics, Propagation in good conductors, Skin effect. Poynting theorem. Text / References:
- M. N. O. Sadiku, “Elements of Electromagnetics”, Oxford University Publication, 2014.
- A. Pramanik, “Electromagnetism - Theory and applications”, PHI Learning Pvt. Ltd, New Delhi,
Subject Code: LPCEE- 101 Subject Name: ANALOG ELECTRONICS LABORATORY Programme: B.Tech (EE) L: 0 T: 0 P: 2 Semester: 3 Teaching Hours : 26 Theory/Practical: Theory Credits: 1 Internal marks: 30 Percentage of Numerical/Design/ Programming Problems: 10 0% External Marks: 20 Duration of End Semester exam (ESE): 1.5hr Total marks: 50 Elective Status: Compulsory Prerequisites: Basic Electrical Engineering On Completion of the course, the student will have the ability to: CO# Course Outcomes (CO)
Ability to make circuits on bread-board and understand the use and importance of various types of equipment’s used in the laboratory.
Analyze, take measurements to understand circuit behavior and performance under different conditions.
Troubleshoot, design and create electronic circuits meant for different applications.
Acquire experience in creating and troubleshooting simple projects employing semiconductor devices.
Evaluate the performance electronic circuits and working small projects employing semiconductor devices Sr. No. Name of Practical
Design a full wave and half wave rectifier and observe the waveforms with and without filters (RC).
To design a voltage regulator using Zener diode and also see the effect of line and load regulation
To design various clippers and clampers using diodes.
To study the transistor characteristics in common emitter characteristics and also determine the h-parameters from the characteristics.
To design, study and compare various transistor biasing techniques and also see the effect on operating point (Q-point) when using various transistors at different temperatures.
Design different transistor biasing circuits and compare them.
Working of a transistor as current mirror and switch.
To plot the VI characteristics of FET.
Voltage follower circuit.
Op-Amp as an inverting and non-inverting amplifier.
Op-Amp as a summing and difference amplifier.
Op-Amp as a zero crossing detector.
Op-Amp as a Schmitt trigger.
Op-Amp as an integrator and differentiator.
RC phase shift oscillator using Op-Amp.
Wein bridge oscillator using Op-Amp.
To examine the operation of a PLL and to determine the free running frequency, the capture range and the lock in range of PLL. Reference Material Manual Available in lab
Subject Code: LPCEE- 102 Subject Name: ELECTRICAL MACHINES-I LABORATORY Programme: B.Tech (EE) L: 0 T: 0 P: 2 Semester: 3 Teaching Hours : 26 Theory/Practical: Theory Credits: 1 Internal marks: 30 Percentage of Numerical/Design/ Programming Problems: 10 0% External Marks: 20 Duration of End Semester exam (ESE): 1.5hr Total marks: 50 Elective Status: Compulsory Prerequisites: Basic Electrical Engineering On Completion of the course, the student will have the ability to: CO# Course Outcomes (CO)
- Evaluation of equivalent circuit parameters, efficiency and voltage regulation by performing various tests on transformer.
- Analyze three-phase transformer connections and parallel operation of transformers
- Analyze performance characteristics of DC generators.
- Evaluate various speed controls and starting methods of DC motor.
- Construct and analyze torque slip characteristics of DC motor. Sr. No. Name of Practical
- To perform open circuit and short circuit tests on a single-phase transformer and hence find equivalent circuit parameters, voltage regulation and efficiency.
- To find the efficiency and voltage regulation of single-phase transformer under different loading conditions.
- To perform back-to-back test (Sumpner’s Test) two single-phase transformers.
- To perform polarity test and parallel operation of two single-phase transformers.
- To make Scott connections on three-phase transformer to get two phase supply.
- To verify the outputs of various connections in three-phase transformer.
- To start the dc motor and study in detail the three-point and four-point starters.
- To measure armature and field resistance of direct current (d.c.) shunt generator and to obtain its open circuit characteristics.
- To perform speed control on dc shunt motor by field current and armature voltage.
- To draw speed-torque characteristics of dc shunt/series /compound motor.
- To perform Swinburne's test (no load test) to determine losses of dc shunt motor.
- Application of MATLAB for solution of problems regarding transformers and dc machines. Reference Material Manual Available in lab
