EEE Department

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Course Outcomes (CO's):

Course Name: BASIC ELECTRICAL CIRCUITS

After completing the course, the student should be able to do the following
Given a network, find the equivalent impedance by using network reduction techniques and determine the current through any element and voltage across and power through any element.
Given a circuit and the excitation, determine the real power, reactive power, power factor etc,.
Apply the network theorems suitably.
Determine the Dual of the Network, develop the Cut Set and Tie-set Matrices for a given Circuit. Also understand various basic definitions and concepts.

Course Name: ELECTRICAL CIRCUIT ANALYSIS

Understand the analysis of three phase balanced and unbalanced circuits and to measure active and reactive powers in three phase circuits.
To get knowledge about how to determine the transient response of R-L, R-C, R-L-C series circuits for D.C and A.C excitations.
Applications of Fourier transforms to electrical circuits excited by non- sinusoidal sources are known.
To design filters and equalizers.

Course Name: ELECTRICAL CIRCUITS- II

Determine the transient response of R-L, R-C, R-L-C circuits for D.C. and A.C. Excitations
Analyze three phase balanced and unbalanced circuits and determine line
Voltages, line currents, phase voltages and phase currents
Measure active and reactive power consumed by a given three phase circuit
Apply Fourier transforms to electrical circuits excited by non-sinusoidal sources
Analysis of electrical networks, duality and dual networks
Design different types of filters
Simulate D.C. Circuits

Course Name: DC MACHINES & TRANSFORMERS

Understand the concepts of magnetic circuits, principle and operations of DC machines, starters and single and three phase transformers
Analyze armature reaction, parallel operation, speed control and characteristics of DC machines. Also analyze the performance characteristics with the help of OC and SC tests of transformer
Evaluate generated emf, back emf, speed, efficiency and regulations of DC machines and efficiency and regulation of transformer also load sharing of parallel connected transformers
Design winding diagrams of DC machines and equivalent circuit of transformer

Course Name: POWER ELECTRONICS

Understand the operation, characteristics and usage of basic Power Semiconductor Devices.
Understand different types of Rectifier circuits with different operating conditions.
Understand DC-DC converters operation and analysis of their characteristics.
Understand the construction and operation of voltage source inverters, Voltage Controllers and Cyclo Converters.
Apply all the above concepts to solve various numerical problem solving.

Course Name: AC MACHINES

Understand the basics of ac machine windings, construction, principle of working, equivalent circuit of induction and synchronous machines.
Analyze the phasor diagrams of induction and synchronous machine, parallel operation of alternators, synchronization and load division of synchronous generators.
Apply the concepts to determine V and inverted V curves and power circles of synchronous motor.
Analyze the various methods of starting in both induction and synchronous machines.

Course Name: ELECTROMAGNETIC FIELD THEORY

Understand the concept of electrostatics
Understand the concepts of Conductors and Dielectrics
Understand the fundamental laws related to Magneto Statics
Understand the concepts of Magnetic Potential and Time varying Fields

Course Name: POWER SYSTEM ARCHITECTURE

Remember and understand the concepts of conventional and nonconventional power generating systems.
Apply the economic aspects to the power generating systems.
Analyse the transmission lines and obtain the transmission line parameters and constants.
Design and develop the schemes to improve the generation and capability of transmission line to meet the day-to-day power requirements.

Course Name: CONTROL SYSTEMS

Understand the concepts of control systems classification, feedback effect, mathematical modelling, time response and frequency response characteristics, state space analysis
Apply the concepts of Block diagram reduction, Signal flow graph method and state space formulation for obtaining mathematical and Root locus, Bode, Nyquist, Polar plots for stability calculations, controllability and observability and demonstrate the use of these techniques.
Analyse time response analysis, error constants, and stability characteristics of a given mathematical model using different methods.
Design and develop different compensators, controllers and their performance evaluation for various conditions. Implement them in solving various engineering applications.

Course Name: MEASUREMENTS & SENSORS

Able to Understand the working of various instruments and equipment's used for the measurement of various electrical engineering parameters like voltage, current, power, phase etc in industry as well as in power generation, transmission and distribution sectors.
Able to analyze and solve the varieties of problems and issues coming up in the vast field of electrical measurements.
Analyse the different operation of extension range ammeters and voltmeters, DC and AC bridge for measurement of parameters and different characteristics of periodic and aperiodic signals using CRO.
Design and development of various voltage and current measuring meters and the varieties of issues coming up in the field of electrical measurements.

Course Name: POWER ELECTRONICS DRIVES

Understand the various drive mechanisms and methods for energy conservation.
Apply power electronic converters to control the speed of DC motors and induction motors.
Evaluate the motor and power converter for a specific application.
Develop closed loop control strategies of drives

Course Name: POWER QUALITY

Understand the basic concepts of different power quality issues and to mitigate them, principles of regulation of long duration voltage variations
Analyze voltage disturbances and power transients that are occurring in power systems.
Understand the concept of harmonics in the system and their effect on different power system equipment.
Apply the knowledge about different power quality measuring and monitoring concepts.

Course Name: POWER SYSTEM ANALYSIS

Remember and understand the concepts of per unit values, Y Bus and Z bus formation, load flow studies, symmetrical and unsymmetrical fault calculations.
Apply the concepts of good algorithm for the given power system network and obtain the converged load flow solution and experiment some of these methods using modern tools and examine the results.
Analyse the symmetrical faults and unsymmetrical faults and done the fault calculations, analyse the stability of the system and improve the stability. Demonstrate the use of these techniques through good communication skills.
Develop accurate algorithms for different networks and determine load flow studies and zero, positive and negative sequence impedances to find fault calculations.

Course Name: HVDC AND FACTS

Understand the necessity of HVDC systems as emerging transmission networks
Understand the necessity of reactive power compensation devices
Design equivalent circuits of various HVDC system configurations
Design and analysis of various FACTS devices

Course Name: SEMICONDUCTOR DEVICES AND CIRCUITS

List various types of semiconductor devices
Study the characteristics of various types of semiconductor devices
Apply the characteristics of semiconductor devices to develop engineering solutions
Analyse functioning of various types of electronic devices and circuits

Course Name: ELECTRICAL MACHINE DESIGN

Understand various design factors, types of windings, choice of machine, selection and ratings
Able to design DC machine based on specified rating
Able to design 1-ϕ transformer based on specified rating
Able to design 3-ϕ Induction machine based on specified rating
Able to design 3-ϕ Synchronous machine based on specified rating

Course name: ELECTRICAL POWER GENERATING SYSTEMS

Estimate the coal requirement, cost per kWh generation and number of units
generated for thermal power station
Estimate the required flow of river water, cost of generation and number of units generated in Hydel power generation
Compute various factors like load factor, plant factor
Evaluate the tariffs to be charged for the consumers
Plot the load curve, load duration curve and hence determine the load capacity of the plant

Course Name: ELECTRICAL POWER TRANSMISSION SYSTEMS

Compute the transmission line parameters.
Model a given transmission line.
Estimate the performance of a given transmission line.
Analyze the effect of over voltages on transmission lines.
Explain the construction, types and grading of underground cables and analyze cable performance.

Course Name: NETWORKS SIGNALS AND SYSTEMS

Given network, find the equivalent impedance by the concept of two port network
Analyse the frequency response of electrical network using Laplace transformApply concepts of Fourier series to simply the electrical network
Synthesize the network using network functions

Course Name: POWER SYSTEM PROTECTION

Explain the principles of operation of various types of electromagnetic relays, Static relays as well as Microprocessor based relays
Understanding the protection of generators and determination of what %
generator winding is unprotected under fault occurrence
Understanding the protection of transformers and make design calculations to
determine the required CT ratio for transformer protection
Explain the use of relays in protecting Feeders, lines and bus bars
Solve numerical problems concerning the arc interruption and recovery in
circuit breakers
Understand why over voltages occur in power system and how to protect the system

Course Name: ELECTRICAL DISTRIBUTION SYSTEMS

Compute the various factors associated with power distribution
Make voltage drop calculations in given distribution networks
Learn principles of substation maintenance
Compute power factor improvement for a given system and load
Understand implementation of SCADA for distribution automation

Course Name: POWER SYSTEM OPERATION AND CONTROL

Develop the mathematical models of turbines and governors
Address the Load Frequency Control problem
Explain how shunt and series compensation helps in reactive power control
Explain the issues concerned with power system operation in competitive
environment

Course Name: UTILIZATION OF ELECTRICAL ENERGY

Develop a lighting scheme for a given practical case.
Analyze the performance of Heating and Welding methods
Make all numerical calculations associated with electric traction.
Assess the economic aspects in utilization of electrical energy

Course Name: ENERGY AUDITING & DEMAND SIDE MANAGEMENT

Conduct energy auditing and evaluate energy audit results
Carry out motor energy audit
Analyze demand side management concepts through case study

Course Name: POWER QUALITY

Address power quality issues to ensure meeting of standards
Apply the concepts of compensation for sags and swells using voltage regulating devices
Assess harmonic distortion and its mitigation.
Explain the power measurement data according to standards.

Course Name: INSTRUMENTATION

Identify and explain the types of errors occuring in measurement systems
Differentiate among the types of data transmission and modulation techniques
Apply digital techniques to measure voltage, frequency and speed
Choose suitable transducers for the measurement of non-electrical quantities.

Course Name: HVDC TRANSMISSION

Compare HVDC and HVAC transmission systems
Understand the operation of various converters used in HVDC transmission systems
Devise means to suppress / eliminate harmonics.
Design HVDC and AC Filters
A load frequency control problem.