Elective II:- 2EE705:-Advanced Power Electronics 2EE706:-Advanced Microcontroller 2EE707:-Special Electrical Machines Elective III: - 2EE708:-Dynamics &Modelling of Electrical Machines 2EE709:-Electrical Machine Design 2EE710:-Power System Practice & Design 2EE711:-HVDC & FACTS Elective IV:- 2EE712:- Energy Conservation, Audit & Management 2EE713:- Modern Control System 2EE714:-Digital Signal Processing GANPAT UNIVERSITY FACULTY OF ENGINEERING & TECHNOLOGY TEACHING AND EXAMINATION SCHEME Program me Bachelor of Technology Branch/Spec. Electrical Engineering Semester VII Effective from Academic Year 2017-18 Effective for the batch Admitted in July 2017 Subject Code Subject Name Teaching scheme Examination scheme (Marks) Credit Hours (per week) Theory Practical Lecture(DT) Practical(Lab.) Lecture(DT) Practical(Lab.) CE SEE Total CE SEE Total L TU Total P TW Total L TU Total P TW Total 2EE 701 Commissioning, Testing &Maintenance of Electrical Equipment 3 0 3 1 0 1 3 0 3 2 0 2 40 60 100 30 20 50 2EE702 Power system protection & switchgear 3 0 3 1 0 1 3 0 3 2 0 2 40 60 100 30 20 50 2EE703 Power System Operation & Control 3 0 3 1 0 1 3 0 3 2 0 2 40 60 100 30 20 50 2EE70E Elective II 3 0 3 1 0 1 3 0 3 2 0 2 40 60 100 30 20 50 2EE71E Elective III 3 0 3 1 0 1 3 0 3 2 0 2 40 60 100 30 20 50 2EE72E Elective IV 3 0 3 0 0 0 3 0 3 0 0 0 40 60 100 00 00 00 2EE704 Industrial Training 0 0 0 1 0 1 0 0 0 2 0 2 0 0 0 30 20 50 Total 18 0 18 6 0 6 18 0 18 12 0 12 240 360 600 180 120 300
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Elective II:-
2EE705:-Advanced Power Electronics
2EE706:-Advanced Microcontroller
2EE707:-Special Electrical Machines
Elective III: -
2EE708:-Dynamics &Modelling of Electrical Machines
2EE709:-Electrical Machine Design
2EE710:-Power System Practice & Design
2EE711:-HVDC & FACTS
Elective IV:-
2EE712:- Energy Conservation, Audit & Management
2EE713:- Modern Control System
2EE714:-Digital Signal Processing
GANPAT UNIVERSITY
FACULTY OF ENGINEERING & TECHNOLOGY
TEACHING AND EXAMINATION SCHEME
Program
me
Bachelor of Technology Branch/Spec. Electrical Engineering
Semester VII
Effective from Academic Year 2017-18 Effective for the batch Admitted in July 2017
Subject
Code Subject Name
Teaching scheme Examination scheme (Marks)
Credit Hours (per week) Theory Practical
Lecture(DT) Practical(Lab.) Lecture(DT) Practical(Lab.) CE SEE Total CE SEE Total
L TU Total P TW Total L TU Total P TW Total 2EE 701 Commissioning, Testing
inter-turn protection, Protective systems for transformers, Buchholz relay, Earth fault
or leakage protection, Circulating current scheme for transformer protection, Different
bus-bar protection scheme.
07
7
Digital Protection:
Digital relay, Merits and demerits, Block diagram, Digital over current relay, Digital
earth fault relay, Digital protection of transformer. 04
Practical content
Practicals, assignments and tutorials are based on above syllabus.
Text Books
1 V.K. Mehta and Rohit Mehta, “Principle of Power System”, S. Chand.
2 Badri Ram and D.N.Vishwakarma, “Power System Protection and Switchgear”,
TMHpublishing company.
Reference Books
1 Bhavesh Bhalja, R. P. Maheshwari and N. G. Chothani, “Protection and Switchgear”, Oxford
University Press, New Delhi, 1st edition, 2011.
2 B. Ravindranath and M. Chander, “Power System Protection and Switchgear”, New age
International.
3 Sunil S Rao, “Switchgear and Protection”, Khanna Publishers.
4 Bhuvnesh Oza, Nirmalkumar Nair, Rashesh Mehta and Vijay Makwana,” Power System
Protection And Switchgear”, Tata McGraw Hill Education Private Limited
5 Y. G. Paithankar, “Fundamentals of Power System Protection”, PHI Publication.
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec. Electrical Engineering Semester VII Version 1.0.0.0 Effective from Academic Year 2016-17 Effective for the batch Admitted in July2017
Subject code 2EE703 Subject Name Power System Operation & Control Teaching scheme Examination scheme(Marks) (Per week) Lecture(DT) Practical(Lab.) Total CE SEE Total
L TU P TW Credit 3 0 1 0 4 Theory 40 60 100 Hours 3 0 2 0 5 Practical 30 20 50 Pre-requisites: - Learning Outcome:
On successful completion of the subject, students should be able to
Understand power flow and losses in different lines in power system and voltages at different
buses.
Solve problems posing different problem models related to Economic Load Dispatch, Load
Frequency Control and reactive power control.
Model power-frequency dynamics and to design power-frequency controller.
Model reactive power-voltage interaction and the control actions to maintain the voltage profile.
Theorysyllabus
Unit Content Hrs
1.
Load Flow Studies:
Network model formulation, formation of Y bus, power flow problem, different types
of buses, Approximate power flow, Gauss Seidel method, Newton-Raphson method,
Decoupled power flow studies, Fast decoupled power flow studies, Comparison of
power flow methods.
11
2.
Economic load dispatch and Unit Commitment :
Economic dispatch of thermal units and methods of solution, Transmission losses, B
matrix loss formula, Composite generation production cost function-solution by
gradient search techniques, Constraints in unit commitment, Spinning reserve,
Dynamic programming solution.
11
3.
Automatic generation control :
Single area load frequency control, Speed governing system and characteristics, Multi
area load frequency control; Flat frequency, Flat tie-line load and tie-line load bias
control, Economic dispatch and AGC.
08
4.
Control of Voltage and Reactive Power
Introduction, Generation and absorption of reactive power, Relation between voltage,
power and reactive power at a node, Single machine infinite bus systems, Methods of
voltage control.
07
5.
Power System Stability:
Dynamics of a synchronous machine, Power angle equation, Node elimination
technique, Simple system, Steady state stability, Transient stability, Equal area
criterion.
08
Practical content Practicals, assignments and tutorials are based on above syllabus
Text Books 1 Nagrath& Kothari, “Power System Engineering”, TMH publishing Company Ltd.
2 C.L.Wadhwa, “Electrical Power Systems”, New Age International Publishers. Reference Books
1. S. S. Vadhera, “Power System Analysis and Stability”, Khanna Publisher
2 Sivanagaraju, Sreenivasan, “Power System Operation and Control”, Pearson, 1st Ed.
3. W. D. Stevenson, “Element of Power System Analysis”, Mc Graw Hill.
5. A. J. Wood and B.F. Wollenberg, “Power Generation Operation and Control”, John Wiley &
Sons, ICN.
2nd Edition. 6. Abhijit Chakrabarti, Sunita Halder, „Power System Analysis Operation and Control‟, PHI
learning Pvt. Ltd., New Delhi, Third Edition, 2010.
7. Kundur P., „Power System Stability and Control, Tata McGraw Hill Education Pvt. Ltd., New
Delhi, 10th reprint, 2010. 8. Hadi Saadat, „Power System Analysis‟, Tata McGraw Hill Education Pvt. Ltd., New Delhi,
21st reprint, 2010.
4. N.V.Ramana, “Power System Operation and Control,” Pearson, 2011.
GANPAT UNIVERSITY
FACULTY OF ENGINEERING & TECHNOLOGY Programme Bachelor of Technology Branch/Spec. Electrical Engineering
Semester VII Version 1.0.0.0
Effective from Academic
Year
2017-18 Effective for the batch
Admitted in
July 2017
Subject code 2EE705 Subject Name Advanced Power Electronics
Teaching scheme Examination scheme (Marks)
(Per
week)
Lecture(DT) Practical(Lab.) Total CE SEE Total
L TU P TW
Credit 3 0 1 0 4 Theory 40 60 100
Hours 3 0 2 0 5 Practical 30 20 50
Pre-requisites:
-
Learning Outcome:
On successful completion of the subject, students should be able to
Identify gate drive requirement for various semiconductor switching devices.
Analysis and design of dc-dc converters.
Learn different pulse width modulation techniques and their applications using simulations.
Understand basic operation voltage source and current source inverters.
Learn basic concepts of advanced converters for high power applications.
Theory syllabus
Unit Content Hrs
1
Gate Drive Circuits:
Introduction, Pulse transformer, Opto isolators, Different schemes for gate firing,
Zero crossing detection, Drive circuit for MOSFET, BJT, IGBT and Thyristor. 08
characteristics,Armature reaction MMF , Synchronous Reactance , Sine wave motor
with practical windings.
10
5
Stepping Motors:
Constructional features, Principle of operation, Variable reluctance motor, Hybrid
motor, Single and multi-stack configurations, Theory of torque predictions, Linear
and non-linear analysis, Torque-speed characteristics, Drive circuits.
08
6
Energy Efficient Motors:
Standard motor efficiency, Concept of energy efficient motor, Efficiency evaluation
techniques, Direct measurement method, Losses segregation method, Energy efficient
motor standards, Motor life cycle.
05
Practical content
Practicals, assignments and tutorials are based on above syllabus.
Text Books
1 Mukherjee and Chakravorty, “Electrical Machines”, DhanpatRai Pub., New Delhi, 2005.
2 T.J.E Miller, “Brushless permanent magnet and reluctance motor drives”, Clarendon Press,
Oxford, 1989.
Reference Books
1 Nagrath and Kothari, “Electric Machines”, TMH, New Delhi, 2005.
2 M. G Say, “The performance and design of alternating current machines”, CBS Publishers and
Distributors.
3 Fitzgerald, Kingsley and Umans “Electric Machinery”:, TMH, New Delhi, 2003
4 P. S Bimbhra, “Electrical Machinery”, Khanna Pub., Delhi, 1998
5 V. V. Athani, “Stepper Motors: Fundamentals, Applications and Design”, New Age
International Pvt. Ltd.
6 V.K.Gaudani,” Energy Audit and Energy Mnagment”, Vol-I,IECC Press.
7. William H. Yeadon, Alan W. Yeadon, “Handbook of small electric motors”, McGraw-Hill
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec. Electrical Engineering Semester VII Version 1.0.0.0 Effective from Academic Year
2017-18 Effective for the batch Admitted in
July2017
Subject code 2EE708 Subject Name Dynamics and Modelling of Electrical Machines Teaching scheme Examination scheme(Marks) (Per week) Lecture(DT) Practical(Lab.) Total CE SEE Total
On successful completion of the subject, students should be able to Understand mathematical model of conventional electrical machines. Apply the concept of reference frame theory for various ac machines. Understand dynamics of electrical machines. Apply mathematical model for simulation and analysis.
Theory syllabus
Unit Content Hrs
1 Basic Principles for Electric Machine Analysis: Magnetically coupled circuits, Electromechanical energy conversion, Machine windings andair gap MMF, Winding inductances and voltageequations.
04
2
Direct-Current Machines: Introduction, Elementary direct-current machine, Basic types of direct-current machines, Voltage and torque equations.
05
3
Reference Frame Theory: Equations of transformation: Changes of variables, Stationary circuit variables transformed to the arbitrary reference frame, Commonly used reference frames, Transformation between reference frames, Transformation of balanced set, Balanced steady state phasor relationships, Balanced steady state voltage equations, Variables observed from various frames.
08
4
Symmetrical Induction Machines: Voltage and torque equations in machine variables, Equations of transformation for rotor circuits, Voltage and torque equations in arbitrary reference frame variables, Analysis of steady state operation: State-space model of induction machine in „d-q‟ variables, Free acceleration characteristics, Dynamic performance during sudden changes in load torque and during a 3 phase fault at the machine terminals.
12
5
Synchronous Machines: Voltage and torque equations in machine variables, Stator voltage equations in arbitrary reference frame variables, Voltage equations in rotor reference frame Variables: Park‟s equations, Torque equations in substitute variables, Analysis of steady state operation, Dynamic performance during a sudden changes in input torque and during a three phase fault at the machine terminals.
08
6
Computer Simulation of Electric Machines: Simulation of symmetrical induction machines, synchronous machines and DC machines, Thermal model of induction machine, Induction machine dynamics during starting, braking and reversing.
05
7
Linearized Machine Equations: Introduction, Linearization of induction and synchronous machine equations.
03
Practical content
Practicals, assignments and tutorials are based on above syllabus
Text Books 1 Paul C. Krause, Oleg Wasynczuk and Scott D. Sudhoff, “Analysis of Electric Machinery and
Drive Systems”, John Wiley & Sons, New York, 2nd
Edition, 2006.
2 P S Bimbhra,”Generalized theory of electrical machines”, 5th edition, Khanna Publishers Delhi. Reference Books
1 R Krishnan “Electrical Motor Drives, Modeling, Analysis, and Control”, Pearson Education.
2 J. Meisel, “Principles of Electromechanical Energy Conversion” McGraw Hill, 1966.
3 C.V. Jones, “Unified Theory of Electrical Machines” Butterworths Publishers.
GANPAT UNIVERSITY
FACULTY OF ENGINEERING & TECHNOLOGY Programme Bachelor of Technology Branch/Spec. Electrical Engineering
Semester VII Version 1.0.0.0
Effective from Academic Year 2017-18 Effective for the batch Admitted in July 2017
Subject code 2EE 709 Subject Name Electrical Machine Design
Teaching scheme Examination scheme (Marks)
(Per week) Lecture (DT) Practical(Lab) Total CE SEE Total
L TU P TW
Credit 3 0 1 0 4 Theory 40 60 100
Hours 3 0 2 0 5 Practical 30 20 50
Pre-requisites:
-
Learning Outcome:
On successful completion of the subject, students should be able to
Understand the calculation and rating of various types of electricalmachines.
Understand the concept of design of electrical machines.
Able to design the various electrical machines as per requirements.
Theory syllabus
Unit Content Hrs
1
General Aspects:
Insulating materials, Classifications, Heating of electrical machines, Cooling of transformer
and rotating machines, Electrical and magnetic loading, Output coefficient, Factors
affecting size of machines, Selection of Bav& ac, Duty cycle and equivalent ratings.
05
2
Three Phase Transformer:
Different types of windings, Methods for cooling, Different positions of tapping, Output
equation, Window space factor, Stacking factor, Selection of Bav and ac, Window ,Yoke
and overall core dimension calculations, Design of HV and LV windings, Estimation of
operating characteristics, Primary and secondary winding resistance, Leakage reactance
calculation, No load current calculations, Temperature rise, Design of tank with tubes,
Design for optimum cost and minimum loss, Variation of output and losses in transformer
with linear dimensions, Dry transformer, High frequency transformer.
13
3
DC Machine:
Output equation, MMF calculation, Selection of number of poles, Core length, Armature
diameter, Carter‟s fringing curves, Length of air gap, Design of armature winding, Design
of armature core, D.C. winding pole and interpole design, Design of field winding, Effects
of armature reaction and minimization, Design of commutator and brushes, Performance
calculation and design consideration for large machines and HV machines.
10
4
Induction Machines:
Output equation, Main dimensions, Choice of specific electric and magnetic loadings,
Design of stator & rotor windings, Stator & rotor slots and air-gap of slip ring and squirrel
cage motor, Calculation of rotor bar and end ring currents in cage rotor, Calculation of
equivalent circuit parameters and prediction of magnetizing current based on design data.
10
5
Alternators:
Output equation, Salient pole and turbo alternators, Main dimensions, Choice of specific
electric and magnetic loadings, Choice of speed and number of poles, Design of armature
conductors, Slots and winding, Design of air-gap, field system and damper winding,
Prediction of open circuit characteristics and regulation based on design data.
07
Practical content
Practicals, assignments and tutorials are based on above syllabus.
Text Books
1 A. K. Sawhney, “ A course in electrical machine Design”,DhanpatRai& sons
2 Gray A, “Electrical Machine Design”, Macgraw Hill publications.
Reference Books
1 S. K. Sen,“Electrical Machine Design”, Oxford Publications.
2 V. N. Mittle, “ Electrical Machine Design”, TMH publications
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec.
Electrical Engineering Semester VII Version 1.0.0.0 Effective from Academic Year
2017-18 Effective for the batch Admitted in July2017
Subject code 2EE710 Subject Name Power System Practice & Design Teaching scheme Examination scheme(Marks) (Per week) Lecture(D
1 S. Kamakshaiah & V. Kamaraju, “HVDC Transmission”, Tata McGraw hill education 2 Barain G. Hingorani, “Understanding Facts”, IEEE Press, New York
Reference Books
1. K.R.Padiyar, “FACTS controllers in power transmission and Distribution‟ New Age international Publishers 1st edition -2007.
2. Mohan Mathur, Rajiv. K. Varma, “Thyristor – Based FACTS Controllers forElectrical Transmission Systems”, IEEE press and John Wiley & Sons.
3. Kimbark E.X., “Direct Current Transmission”, Wiley Interscience, New York
4. A.T.John, Y.H.Song, “Flexible AC Transmission Systems (FACTS)”, IEEE Series
5. Yong Hua Sung and Allan T. John (ed), “Flexible AC Transmission System (FACTS)”, The Institution ofElectrical Engineering, London 6. X.P. Zhang, C. Rehtanz and B. Pal, “Flexible AC Transmission Systems: Modeling and Control”, Birkhauser, 2006.
7. A. Chakraborty, D.P. Kothary, A.K. Mukhopadhyay, “The Performance, Operation and Control of EHV “,Wheeler Pub. Power Transmission Systems”, Wheeler Pub.
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec. Electrical Engineering
Semester VIII Version 1.0.0.0 Effective from Academic Year
2017-18 Effective for the batch Admitted in July2017 Subject code 2EE712 Subject Name Energy Conservation, Audit & Management Teachingscheme Examination scheme(Marks) (Per week)
4 S.Choudhury, “Projects: Planning, Analysis, Selection, Implementation and Review”, Tata
McGraw Hill.
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec. Electrical Engineering Semester VII Version 1.0.0.0 Effective from Academic Year
2017-18 Effective for the batch Admitted in July2017
Subject code 2EE713 Subject Name Modern Control System Teaching scheme Examination scheme(Marks) (Per week) Lecture(DT) Practical(Lab.) Total CE SEE Total
On successful completion of the subject, students should be able to
Apply linear algebra to complex real world problems in order to obtain models that are express
dusing state space equations.
Analyze the system behavior based on the mathematical model of that system where the model
maybe expressed in state-space domain.
Design controllers using the concept of state feedback and pole placement tech.
Write a report that effectively communicates the results of an analysis or design
Theory syllabus
Unit Content Hrs
1
State Space Analysis of Control Systems :
State variables; State-space representation of electrical and mechanical and
electromechanical systems, State space representation of nth order linear differential
equation, Transformation to phase variable canonical form, Relationship between
state equations and transfer functions, Characteristic equation, Eigen values and eigen
vectors ,Transformation to diagonal canonical form, Jordan canonical form,
Controllability canonical form, Observabilty canonical form, Decomposition of
transfer function-direct, Cascade and parallel decomposition, State diagram, Solution
of the time-invariant state equation, State transition matrix and its properties, Transfer
matrix; Transfer matrix of closed loop systems.
14
2
Controllability and Observability:
Concept of controllability and observability, Kalman‟s theorems on controllability, and observability, Alternative Tests (gilbert‟s method) of controllability and observability, Principle of duality, Relationship among controllability, Observability and transfer function.
05
3
State feedback controller:
Design of state feedback controller using pole placement technique, Ackerman‟s formula
05
4
Liapunov Stability Analysis :
Stability of equilibrium state in the sense of Liapunov, Graphical representation of stability, Asymptotic stability and instability, Sign-definiteness of scalar function, Second method of Liapunov, Stability analysis of linear systems, Krasovski‟s theorem, Liapunov function based on variable gradient method.
05
5
Describing Function Analysis of Nonlinear Control System :
Introduction to nonlinear systems, Describing functions for common types of
nonlinearities, Describing function analysis, Stability and limit cycles.
10
6
Phase Plane Analysis : Introduction : Analytical methods for constructing trajectories, graphical methods for constructing
trajectories, Isocline method, Delta method, Pell‟s method, Lienard‟s method, Classification of singular points, Limit cycles, Phase-place analysis of linear control
system, Phase-plane analysis of non-linear control system, Minimum time trajectory, Optimum Switching curve.
06
Text Books 1 Katsuhiko Ogata, “Modern Control Engineering”, Prentice-Hall of India, Second Edition,
1997. 2 B. C. Kuo, “Automatic Control Systems”, Prentice – Hall of India, Seventh Edition 1997.
Reference Books
1 L. J. Nagrath & M. Gopal, “Control Systems Engineering. Wiley Eastern Limited”, Second Edition, 1992.
2 M. Gopal, “Control System Principles and Design “,Tata – McGraw Hill, 1997.
3 John E. Gibson, “Non-linear Automatic Control “, Mc. Graw Hill Book C.(ISE)
4 Hasan K. Khalil, “Non-linear systems “, Prentice-Hall of India, 2002.
5 E Slotine, Weiping Li, “Applied Nonlinear Control “, Prentice-Hall
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec. Electrical Engineering
Semester VII Version 1.0.0.0 Effective from Academic Year
2017-2018 Effective for the batch Admitted in
July2017
Subject code 2EE714 Subject Name Digital Signal Processing Teaching scheme Examination scheme(Marks) (Per week) Lecture(DT) Practical(Lab) Total CE SEE Total
On successful completion of the subject, students should be able to
Represent signals in various forms for analysis
Analyze various signals in time domain and frequency domain systems
Carry out fourier analysis of continuous time and discrete time signals
Theory syllabus
Unit Content Hrs
1 Discrete Time Systems :
Z-transform, LT1 systems, Description by difference equations, System function, Impulse
response and frequency response. Realization structures for IIR and FIR filters. 10
2 DFT and FFT:
Discrete convolution, Discrete fourier transform, Fast FFT, Algorithms for efficient
Computation of DFT and FFT, Convolution, Correlation.
08
3 Digital filter Design :
FIR and IIR filters, linear phase filters, Analysis of finite word length effects. 10
4
Multirate digital signal processing:
Poly-phase decomposition, multistage decimators and interpolators, Digital filter Banks,
Adaptive filtering, Minimum mean square error criterion, Wiener filter. 06
5
DSP Processor:
Introduction to the TMS320F2XXX DSP Controller, its architecture, C2XXX DSP CPU
and instruction set, Assembly programming using the C2XXX DSP instruction Set,
General purpose input-output functionality in brief, Introduction to interrupts, Event
managers.
08
6
Applications:
Electric Motor (Stepper Motor, DC Motor, PMSM, Induction Motor etc.) control using
TMS320F2XXXX. 03
Text Books 1 Proakis and Manolkis : Digital Signal Processing – Principles algorithms and applications PHI
2 Sanjit Kumar Mitra,” igital Signal Processing: A Computer-Based Approach”, McGraw-Hill Education.
Reference Books
1 Lawrence R. Rabiner, BernardGold ,”Digital Signal Processing”, Prentice-Hall 2 N.G.Palan,” Digital Signal Processing”, Buck Pearson education publication 3. Texas Instruments handouts for TMS320LF2407 processor.
4. Oppeheim, Schafer ,“Discrete Time Signal Processing”, Buck Pearson education
5. Li Tan ,”Digital Signal Processing fundamentals and applications”, Elsevier
GANPAT UNIVERSITY FACULTY OF ENGINEERING &TECHNOLOGY
Programme Bachelor of Technology Branch/Spec. Electrical Engineering Semester VII Version 1.0.0.0 Effective from Academic Year
2017-2018 Effective for the batch Admitted in July2017
Subject code 2EE704 Subject Name Industrial Training Teaching scheme Examination scheme(Marks) (Per week) Lecture(DT) Practical(Lab.) Total CE SEE Total