LESSON PLAN - LBRCE
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LESSON PLAN Dt: 19-02-18 CLASS : M.Tech (PED)
Name of the faculty: G.SRINIVASARAO Semester: II A.Y: 2017-18 Course Title: MODERN CONTROL THEORY Branch : EEE Code : 17PE10
Lecture
No.
Date as per
Aca. Calendar
Content
Teaching
Methodology
Faculty
Approach
Student
approach
Learning outcome Remarks
Actual Date
1 19/02/2018 UNIT-I :
MODAL CONTROL DM1 Explanation
Listens and participate
Introduction to Modern Control Theory
2 21/02/2018 Introduction to controllability and
observability DM1 Explanation
Listens and participate
Analyze controllability and
Observability
3 22/02/2018
Examples of Controllability DM1 Explanation Listens and participate
Analyze the different Examples of Controllability
4 23/02/2018
Examples of Observability DM1 Explanation Listens and participate
Analyze the different Examples of Observability
5 26/02/2018 Effect of state feedback on
controllability DM1 Explanation
Listens and participate
Discussion on the Effect of state
feedback on controllability
6 28/02/2018 Effect of state feedback on
Observability DM1 Explanation
Listens and participate
Discussion on the Effect of state
feedback on controllability
7 01/03/2018 Design of State Feedback Control
through Pole placement DM1 Explanation
Listens and participate
Understand the design concept
LAKIREDDY BALI REDDY COLLEGE OF ENGINEERING (Autonomous) L.B. Reddy Nagar, Mylavaram-521 230. Andhra Pradesh, INDIA
Affiliated to JNTUK, Kakinada & Approved by AICTE New Delhi NAAC Accredited with “A” grade, Accredited by NBA,
New Delhi & Certified by ISO 9001:2008, http://www.lbrce.ac.in
DEPARTMENT OF ELECTRICAL & ELECTRONICS ENGINEERING Phone: 08659-222933/Extn: 203 [email protected], [email protected]
Lecture
No.
Date as per
Aca. Calendar
Content
Teaching
Methodology
Faculty
Approach
Student
approach
Learning outcome Remarks
Actual Date
8 05/03/2018
Full order observer DM1 Explanation Listens and participate
Understand the design concept
9 07/03/2018
Reduced order observer DM-1 Explanation Listens and participate
Understand the design concept
10 08/03/2018 Problems on Controllability and
Observability DM1 Explanation
Listens and participate
Understand the problems on Controllability and observability
11 09/03/2018
Seminar- 1 DM-2 Facilitates Listens and participate
Discussion on Controllability and Observability
12 12/03/2018
Problems DM1 Explanation Listens and participate
Understand the problems on Controllability
13 14/03/2018
Problems DM1 Explanation Listens and participate
Understand the problems on Observability
14 15/03/2018 UNIT-II :
DESCRIBING FUNCTION
ANALYSIS DM1 Explanation
Listens and participate
Introduction to describing function analysis
15 16/03/2018
Introduction to Non Linear Systems DM1 Explanation Listens and participate
Understand Non Linear Systems
16 19/03/2018
Behaviour of nonlinear systems DM1 Explanation Listens and participate
Understand Behaviour of
nonlinear systems
17 21/03/2018
properties of Nonlinear Systems DM1 Explanation Listens and participate
Interpret the properties of
Nonlinear Systems
18 22/03/2018
Types of Nonlinearities DM1 Explanation Listens and participate
Interpret Types of Nonlinearities
19 23/03/2018 Introduction to Linearization of
nonlinear systems DM1 Explanation
Listens and participate
Understand Non Linear Systems
Lecture
No.
Date as per
Aca. Calendar
Content
Teaching
Methodology
Faculty
Approach
Student
approach
Learning outcome Remarks
Actual Date
20 26/03/2018
Describing function (DF) DM1 Explanation Listens and participate
Discussion on Describing function
21 28/03/2018 Derivation of general DF, DF for
different nonlinearities
DM1
Explanation Listens and Participates
Determination of DF of different
nonlinearities
22 29/03/2018
Describing function of saturation and Deadzone Nonlinearity
DM1
Explanation
Listens and participate
Determination of DF of
saturation and Dead zone Nonlinearity
23 02/04/2018
Describing function of saturation Nonlinearity
DM1
Explanation
Listens and participate
Determination of DF of saturation nonlinearity
24 04/04/2018 Describing function of Deadzone
Nonlinearity DM1 Explanation
Listens and participate
Determination of DF of Dead zone nonlinearity
25 06/04/2018 Describing function of backlash
Nonlinearity DM1 Explanation
Listens and participate
Determination of DF of backlash nonlinearity
26 16/04/2018
Seminar-2 DM-2 Facilitates Listens and participate
Discussion on Describing function
27 18/04/2018 Describing function of Hysteresis-
Backlash Nonlinearity DM1 Explanation
Listens and Participates
Determination of DF of Hysteresis-Backlash Nonlinearity
28 19/04/2018 Describing function of Hysteresis
Nonlinearity DM1 Explanation
Listens and participate
Determination of DF of Hysteresis Nonlinearity
29 20/04/2018 Stability analysis of Non – Linear
systems through describing
functions
DM1 Explanation Listens and participate
Discussion on Stability analysis of
Non – Linear systems
30 23/04/2018
Problems DM1 Explanation Listens and participate
Understand the problems on DF
31 25/04/2018
problems DM1 Explanation Listens and participate
Understand the problems on DF
Lecture
No.
Date as per
Aca. Calendar
Content
Teaching
Methodolo
gy
Faculty
Approach
Student
approach
Learning outcome
Remarks
Actual Date
32 26/04/2018 UNIT-III :
PHASE PLANE ANALYSIS DM1 Explanation
Listens and participate
Introduction to phase plane analysis
33 27/04/2018
Introduction to phase plane analysis
DM1
Explanation Listens and participate
Introduction to phase plane analysis
34 30/04/2018 Singular points, and their
classification
DM1
Explanation Listens and participate Discussion about singular points
35 02/05/2018 Limit cycle and behaviour of limit
cycle Analytical method for constructing
Trajectories
DM1
Explanation
Listens and participate
Discussion about limit cycles Understand the Analytical method
36 03/05/2018
Seminar-3
DM-2
Facilitates
Listens and participate
Discussion on construction of
Phase trajectories
37 04/05/2018
Isoclines method for constructing
Trajectories
DM1
Explanation
Listens and Participates Understand the Isoclines method
38 07/05/2018 Isoclines method for constructing
Trajectories
DM1
Explanation Listens and participate
Understand the Isoclines method
39 09/05/2018 Delta method for constructing
Trajectories
DM1 Explanation Listens and
participate Understand the Delta method
40 10/05/2018 Delta method for constructing
Trajectories
DM1 Explanation Listens and
participate Understand the Delta method
41 11/05/2018
problems DM1 Explanation Listens and participate
Understand the problems on phase plane analysis
42 14/05/2018
problems DM1 Explanation Listens and participate
Understand the problems on phase plane analysis
43 16/05/2018 UNIT-IV :
STABILITY ANALYSIS DM1 Explanation
Listens and participate
Introduction
Lectur
e No.
Date as per
Aca. Calendar
Content
Teaching
Methodolo
gy
Faculty
Approach
Student
approach
Learning outcome
Remarks
Actual Date
44 17/05/2018
Introduction to stability DM1 Explanation Listens and participate
Understand the stability
45 18/05/2018 Stability of equilibrium state
Asymptotic stability DM1
Explanation
Listens and participate
Discussion on equilibrium state Understand Asymptotic stability
46 04/06/2018
Graphical representation DM1 Explanation Listens and participate
Analyse the Graphical
representation of stability
47 06/06/2018 Lyapunov stability theorem
DM1
Explanation
Explanation
Listens and Participates
Understand Lyapunov stability
theorem
48 07/06/2018 Stability analysis of linear and
nonlinear systems DM1
Explanation
Listens and participate
Discussion on Stability analysis of
linear and nonlinear systems
49 08/06/2018
Seminar-4 DM-2 Facilitates Listens and
participate Analyse Lyapunov stability
theorem
50 11/06/2018 Stability analysis of linear and
nonlinear systems DM1
Explanation
Listens and participate
Discussion on Stability analysis of
linear and nonlinear systems
51 13/06/2018 Construction of Lyapunov functions
using Krasovskii method DM1
Explanation
Listens and participate
Understand Krasovskii method
52 14/06/2018 Construction of Lyapunov functions
using variable gradient method DM1
Explanation Listens and participate
Understand variable gradient
method
53 15/06/2018 UNIT-V :
OPTIMAL CONTROL DM1 Explanation
Listens and participate
Introduction
54 18/06/2018 Introduction of optimal control
problems DM1 Explanation
Listens and participate
Understand optimal control
problems
Stability analysis of linear
and nonlinear systems DM1
Explanation Listens and participate
Discussion on Stability
analysis of linear and
nonlinear systems
Lectur
e No.
Date as per
Aca. Calendar
Content
Teaching
Methodolo
gy
Faculty
Approach
Student
approach
Learning outcome
Remarks
Actual Date
55 20/06/2018
Minimum time, Minimum energy, DM1 Explanation Listens and participate
Discussion on Minimum time,
Minimum energy
56 21/06/2018
State regulator problem DM1 Explanation Listens and Participates
Discussion on State regulator
problem
57 22/06/2018 Output regulator problem
Tracking problem, calculus of
variations
DM1
Explanation
Listens and participate
Discussion on Tracking problem,
calculus of variations
58 25/06/2018
fundamental concepts
minimization of function
DM1
DM1
Explanation
Explanation
Listens and participate
Listens and participate
Discussion on fundamental
concepts
Understand the minimization of
function
59 27/06/2018
Linear quadratic regulator DM-1 Explanation Listens and Participates
Understand the design
60 28/06/2018
Linear Quadratic Gaussian(LQG) DM-1 Explanation Listens and Participates
Understand the design
61 29/06/2018 Formulation of optimal control
problems DM1 Explanation
Listens and participate
Formulation of optimal control
problems
NOTE: DELIVERY METHODS : DM1: Lecture interspersed with discussions/BB, DM2: Tutorial,
DM3: Lecture with a quiz, DM4: Assignment/Test, DM5: Demonstration ( laboratory, field visit ),
DM6: Group Discussion, DM7: Group Assignment/ Project, DM8: Presentations/PPT, DM9:Asynchronous Discussion..
Signature
Name of the faculty
Name of the course Co-ordinator
Name of the Module Co-ordinator HOD
G.SRINIVASARAO
LAKKIREDDY BALI REDDY COLLEGE OF ENGINEERING
DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING (Autonomous & Affiliated to JNTUK, Kakinada & Approved by AICTE, New Delhi,
NAAC Accredited with ‘A’ grade, Accredited by NBA, Certified by ISO 9001:2015)
L B Reddy Nagar, Mylavaram-521 230, Krishna District, Andhra Pradesh.
COURSE HANDOUT
PROGRAM : M.Tech., II-Sem., EEE(PED)
ACADEMIC YEAR : 2017-18
COURSE NAME & CODE : Switched Mode Power Conversion – 17PE11
L-T-P STRUCTURE : 2-2-0
COURSE CREDITS : 3
COURSE INSTRUCTOR : P.Deepak Reddy
COURSE COORDINATOR : P.Deepak Reddy
PRE-REQUISITE: Analysis of Power Converters
COURSE OBJECTIVE : This course enables the student to understand principles and basic topologies of switched mode power converters.
COURSE OUTCOMES(COs)
After completion of the course, the student will be able to
CO1: Identify various types of switched mode converter topologies
CO2: Deign DC-DC converters of different topologies.
CO3: Analyze soft switching techniques.
CO4: Analyze different types of power factor correction circuits.
COURSE ARTICULATION MATRIX (Correlation between COs&POs,PSOs):
COs PO1 PO2 PO3 PO4 PO5 PO6
CO1 2 2 2 2 2
CO2 2 2 2 2 2
CO3 2 2 2 2 2
CO4 2 2 2 2 2
Note: Enter Correlation Levels 1 or 2 or 3. If there is no correlation, put ‘-’
1- Slight(Low), 2 - Moderate(Medium), 3 - Substantial (High).
BOS APPROVED TEXT BOOKS:
T1 Ned Mohan, Undeland and Robbin, “Power Electronics: Converters, Application and
design”, John Wiley and sons, Newyork, 2007.
T2 Robert Erickon and Dragon Maksivimovic “ Fundamentals of Power Electronics”, Springer Publications,
2nd edition, 2001.
BOS APPROVED REFERENCE BOOKS:
R1 Philip T.Krein “ Elements of Power Electronic”, Oxford University Press, 2nd edition, 2014.
R2
R3
R4
L.Umanand “Power Electronics Essentials & Applications”, Wiley India Private
Limited, 2011.
Issa Batarseh “Power Electronics Circuits”, John Wiely, 2006.
Md.H.Rahid “Power Electronics”, Pearson Education, 4th edition, 2014.
COURSE DELIVERY PLAN (LESSON PLAN): Section-A & B
UNIT-I: NON ISOLATED SWICHMODE POWER CONVERSION
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
1. Introduction 1 19-02-2018 TLM1 CO2 T1
2. Analysis of Buck converter, CCM,DCM
1 20-02-2018 TLM1 CO2 T1
3. Designing of Buck converter, CCM,DCM
1 22-02-2018
TLM1 CO2 T1
4. Analysis of Boost converter, CCM,DCM
1 23-02-2018 TLM1 CO2 T1
5. Designing of Boost converter, CCM,DCM
1 26-02-2018 TLM1 CO2 T1
6. Analysis of Buck-Boost converter,
CCM,DCM 1 27-02-2018 TLM1 CO2 T1
7. Designing of Buck-Boost converter,
CCM,DCM 1 01-03-2018 TLM1 CO2 T1
8. Analysis of Cuk converter, CCM,DCM
1 05-03-2018 TLM1 CO2 T1
9. Designing of Cuk converter, CCM,DCM 1 06-03-2018 TLM1 CO2 T1
10. applications, problems 1 08-03-2018 TLM1 CO2 T1
11. problems 1 09-03-2018 TLM1 CO2 T1
12. problems 1 12-03-2018 TLM1 CO2 T1
13. Seminar-1 1 13-03-2018 TLM1
14. Assignment-1 1 15-03-2018 TLM6
No. of classes required to complete UNIT-I 14 No. of classes taken:
UNITII: ISOLATED SWICHMODE POWER CONVERSION
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
15. Requirement for isolation in the switch-
mode converters, transformer connection 1 16-03-2018 TLM1
CO1 T1
16. Forward converter, power circuit and
steady state analysis-Applications. 1 19-03-2018 TLM1 CO1 T1
17. fly back converter, power circuit and
steady state analysis-Applications. 1 20-03-2018 TLM1 CO1 T1
18. Push Pull Converters: Power circuit and
steady state analysis 1 22-03-2018 TLM1 CO1 T1
19. utilization of magnetic circuits in single
switch and push-pull topologies 1 23-03-2018 TLM1 CO1 T1
20. full bridge converter- Power circuit and
steady state analysis 1 26-03-2018 TLM1 CO1 T1
21. Half bridge converter- Power circuit and
steady state analysis 1 27-03-2018 TLM1 CO1 T1
22. Utilization of magnetic circuits 1 29-03-2018
TLM1 CO1 T1
23. comparison with previous topologies 1 30-03-2018
TLM1 CO1 T1
24. Seminar-2 1
02-04-2018 TLM1
25. Assignment-2 1
03-04-2018 TLM6
26. Repitition of Unit-2 1
05-04-2018 TLM2 CO1
T1
No. of classes required to complete UNIT-
II 12 No. of classes taken:
UNIT-III : SOFT SWITCHING CONVERTERS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
27. Classification of Resonant converters-Basic
resonant circuits 1
16-04-2018 TLM1 CO3 T2
28. Series resonant circuit 1
17-04-2018 TLM1 CO3 T2
29. Parallel resonant circuits 1
19-04-2018 TLM1 CO3 T2
30. Resonant switches, Concept of Zero voltage
switching 1
20-04-2018 TLM1 CO3 T2
31. Principle of operation, analysis of M-type
Buck Converter 1
23-04-2018 TLM1 CO3 T2
32. Principle of operation, analysis of L-type
Buck Converter 1
24-04-2018 TLM1 CO3 T2
33. Principle of operation, analysis of M-type
Boost Converter 1
26-04-2018 TLM1 CO3 T2
34. Principle of operation, analysis of L-type
Boost Converter 1
27-04-2018 TLM1 CO3 T2
35. Concept of Zero current switching 1
30-04-2018 TLM1 CO3 T2
36. Principle of operation, analysis of M-type
Buck Converter 1
01-05-2018 TLM1 CO3 T2
37. Principle of operation, analysis of L-type
Buck Converter 1
03-05-2018 TLM1 CO3 T2
38. Principle of operation, analysis of M-type
Boost Converter 1
04-05-2018 TLM1 CO3 T2
39. Principle of operation, analysis of L-type
Boost Converter 1
07-05-2018 TLM1 CO3 T2
40. Seminar-3 1
08-05-2018 TLM1
41. Assignment-3 1
10-05-2018 TLM6
No. of classes required to complete UNIT-III 15 No. of classes taken:
UNIT IV: POWER FACTOR CORRECTION CIRCUITS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
Cos
Text
Book
followed
HOD
Sign
Weekly
42. Introduction, Definition of PF and THD,
Power Factor Correction 1 11-05-2018
TLM1 CO4 T1
43. Energy Balance in PFC Circuits 1
14-05-2018 TLM1 CO4 T1
44. Passive Power Factor Corrector 1
15-05-2018 TLM2 CO4 T1
45. Basic Circuit Topologies of Active Power
Factor Correctors 1
17-05-2018 TLM2 CO4 T1
46. System Configurations of PFC Power
Supply 1
18-05-2018 TLM2 CO4 T1
47. CCM Shaping Technique 1
04-06-2018 TLM2 CO4 T1
48. Current Mode Control 1
05-06-2018 TLM2 CO4 T1
49. Voltage Mode Control 1
07-06-2018 TLM2 CO4 T1
50. Other PFC Techniques 1
08-06-2018 TLM2 CO4 T1
51. Seminar-4 1
11-06-2018 TLM1
52. Assignment-4 1
12-06-2018 TLM6
No. of classes required to complete UNIT-
IV 11 No. of classes taken:
UNIT V: CONTROL METHODS FOR SWITCHING POWER CONVERTERS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
Cos
Text
Book
followed
HOD
Sign
Weekly
53. Control methods for buck dc-dc converters
using State-space Modelling 1 14-06-2018 TLM2 CO4 T1
54. Control methods for boost dc-dc
converters using State-space Modelling 1
15-06-2018 TLM2 CO4 T1
55. Control methods for forward dc-dc
converters using State-space Modelling 1
18-06-2018 TLM2 CO4 T1
56. Converter Transfer Functions of buck dc-
dc converter 1
19-06-2018 TLM2 CO4 T1
57. Converter Transfer Functions of boost dc-
dc converter 1
21-06-2018 TLM2 CO4 T1
58. Converter Transfer Functions of forward
dc-dc converter 1
22-06-2018 TLM2 CO4 T1
59. Pulse Width Modulator Transfer Functions 1
25-06-2018 TLM2 CO4 T1
60. Pulse Width Modulator Transfer Functions 1 26-06-2018
TLM2 CO4 T1
61. Linear Feedback Design Ensuring Stability 1
28-06-2018 TLM2 CO4 T1
62. Assignment-5 1
29-06-2018 TLM6 CO4
No. of classes required to complete UNIT-
V 10 No. of classes taken:
Contents beyond the Syllabus
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
Cos
Text
Book
followed
HOD
Sign
Weekly
63.
64.
65.
Teaching Learning Methods
TLM1 Chalk and Talk TLM5 ICT (NPTEL/Swayam Prabha/MOOCS)
TLM2 PPT TLM6 Assignment or Quiz
TLM3 Tutorial TLM7 Group Discussion/Project
TLM4 Demonstration (Lab/Field Visit)
Part - C
EVALUATION PROCESS:
Evaluation Task COs Marks
Assignment– 1 2 A1=5
Assignment – 2 1 A2=5
I-Mid Examination 1,2 B1=20
Assignment – 3 3 A3=5
Assignment – 4 4 A4=5
Assignment – 5 4 A5=5
II-Mid Examination 3,4 B2=20
Evaluation of Assignmen Marks: A=(A1+A2+A3+A4+A5)/5 1,2,3,4 A=5
Evaluation of Mid Marks: B=75% of Max(B1,B2)+25% of Min(B1,B2) 1,2,3,4 B=20
Cumulative Internal Examination : A+B 1,2,3,4 A+B=25
Semester End Examinations 1,2,3,4 C=75
Total Marks: A+B+C 1,2,3,4 100
PROGRAMME EDUCATIONAL OBJECTIVES (PEOs)
PROGRAMME OUTCOMES (POs)
PSOs
P.Deepak Reddy P.Deepak Reddy P.Deepak Reddy Dr.M.UmaVani
Course Instructor Course Coordinator Module Coordinator HOD
COURSE HANDOUT Part-A
PROGRAM : M.Tech., II-Sem., EEE (PE&D)
ACADEMIC YEAR : 2017-18
COURSE NAME & CODE : Control of Motor Drives-II – 17PE12
L-T-P STRUCTURE : 2-2-0
COURSE CREDITS : 3
COURSE INSTRUCTOR : J.Sivavara Prasad
COURSE COORDINATOR : J.Sivavara Prasad
PRE-REQUISITE: Power Electronics, Solid State Drives
COURSE OBJECTIVE : This course enables the student to illustrate the operation of electric drives controlled from a power electronic converter and to introduce the design concepts of controllers. It also deals with the steady state operation and transient dynamics of a motor- load system. COURSE OUTCOMES(CO)
CO1 Analyze DTC & sensor less vector controls of induction motor
CO2 Control AC drives with different controlling strategies
CO3 Identify different types of AC motor drives based on application
COURSE ARTICULATION MATRIX (Correlation between COs&POs,PSOs):
COs PO1 PO2 PO3 PO4 PO5 PO6
CO1 2 2 2 2 2
CO2 2 2 2 2 2
CO3 2 2 2 2 2
LAKIREDDY BALI REDDY COLLEGE OF ENGINEERING (Autonomous) L.B. Reddy Nagar, Mylavaram-521 230. Andhra Pradesh, INDIA
Affiliated to JNTUK, Kakinada & Approved by AICTE New Delhi
NAAC Accredited with “A” grade, Certified by ISO 9001:2015, http://www.lbrce.ac.in
DEPARTMENT OF ELECTRICAL & ELECTRONICS ENGINEERING Phone: 08659-222933/Extn: 203 [email protected], [email protected]
Note: Enter Correlation Levels 1 or 2 or 3. If there is no correlation, put ‘-’ 1- Slight(Low), 2 - Moderate(Medium), 3 - Substantial (High).
BOS APPROVED TEXT BOOKS:
T1 B. K. Bose “Modern Power Electronics and AC Drives”, Prentice Hall, 1st edition, 2001.
T2 MD Murphy & FG Turn Bull “Power Electronics control of AC motors”, Franklin Book
Co, 1st edition, 1998
BOS APPROVED REFERENCE BOOKS:
R1 R. Krishnan “Electric Motor Drives Modelling, Analysis and Control”, Pearson, 1st
edition, 2001.
R2 Venkataratnam “Special electrical Machines”, University press, 1st edition, 2008.
Part-B
COURSE DELIVERY PLAN (LESSON PLAN):
UNIT-I : DTC & SENSORLESS VECTOR CONTROL OF INDUCTION MOTOR
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
1. Introduction to Subject
1 19-02-18 TLM1 CO1
T1
2. Course Outcomes
3. Introduction to
UNIT-I
4.
Direct torque control
of induction motor
drives 1 20-02-18 TLM1 CO1
T1
5. Sensorless vector
control 1 21-02-18 TLM1
CO1 T1
6.
slip and speed
Estimation at low
performance 2
22-02-18 26-02-18
TLM1
CO1 T1
7. Rotor Angle and Flux
linkage Estimation at
high performance
1 27-02-18 TLM2 CO1 T1
8.
Rotor Speed
Estimation Scheme‐
estimators using rotor
slot harmonics
2 28-02-18 01-03-18
TLM1
CO1 T1
9. Model Reference
adaptive systems 1 05-03-18 TLM1
CO3 T1
10. Extended Kaman Filter 1 06-03-18 TLM2 CO3 T1
11. Injection of auxiliary
signal on salient rotor 2
07-03-18 08-03-18
TLM1 CO3 T1
12. Seminar-1 1 12-03-18 TLM1
TLM7 T1
13. Test on Unit-I
1 13-03-18
T1
No. of classes required to complete UNIT-I: 14 No. of classes taken:
UNIT-II : CONTROL OF SYNCHRONOUS MOTOR DRIVES
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
14. Synchronous motor
and its characteristics 1 14-03-18 TLM1
CO2 T1
15.
Control strategies-
Constant torque angle
control power factor
control
2 15-03-18 19-03-18
TLM1
CO3 T1
16. Constant flux control 1 20-03-18
TLM1 CO3 T1
17. Flux weakening
operation 1 21-03-18 TLM1
TLM2
CO2 T1
18.
Load commutated
inverter fed
synchronous motor
drive
2 22-03-18 26-03-18
TLM1
CO3 T1
19. Motoring and
regeneration 2
27-03-18 28-03-18
TLM1 CO2 T1
20. Phasor diagrams.
2 29-03-18 02-04-18
TLM1 CO2 T1
21. Seminar-2
1 03-04-18 TLM1
TLM7
T1
22. Test on unit-II
1 04-04-18
No. of classes required to complete UNIT-II : 13 No. of classes taken:
UNIT-III : CONTROL OF SWITCHED RELUCTANCE MOTOR DRIVES
S.No. Topics to be covered
No. of
Classes Required
Tentative
Date of Completion
Actual
Date of Completion
Teaching
Learning Methods
Learning
Outcome COs
Text
Book followed
HOD
Sign Weekly
23. Introduction of
SRM 1
16-04-18
TLM1
CO2 T2,R2
24. Principle of operation 1 17-04-18 TLM1 CO2 T2,R2
25. Design aspects of
stator and rotor pole
arcs
1 18-04-18
TLM1
TLM2
CO3 T2,R2
26. torque equation,
torque-speed
characteristics
1 19-04-18
TLM1
TLM2
CO2 T2,R2
27.
Stator Excitation,
techniques of sensor
less operation 1
23-04-18
TLM1 CO2 T2,R2
28. convertor topologies 1 24-04-18 TLM1 CO3 T2,R2
29.
SRM Waveforms,
SRM drive design
factor 1 25-04-18 TLM4
CO3 T2,R2
30. Torque controlled
SRM, Torque Ripple 1 26-04-18 TLM1
TLM2
CO2 T2,R2
31.
Instantaneous Torque
control using current
controllers-flux
controllers.
1 30-04-18
TLM1 CO2 T2,R2
32. Instantaneous Torque
control using flux
controller
1 01-05-18
TLM1 CO2 T2,R2
33. Seminar-3 1 02-05-18 TLM1
TLM7
34. Test on unit-III 1 03-05-18
No. of classes required to complete UNIT-III: 12 No. of classes taken:
UNIT-IV : CONTROL OF BLDC MOTOR DRIVES
S.No. Topics to be covered No. of
Classes
Required
Tentative Date of
Completion
Actual Date of
Completion
Teaching Learning
Methods
Learning Outcome
COs
Text Book
followed
HOD Sign
Weekly
35. Principle of operation
of BLDC Machine 1
07-05-18
TLM1 CO2 T2,R2
36. Sensing and logic
switching scheme 1 08-05-18
TLM1 CO2 T2,R2
37.
BLDM as Variable
Speed Synchronous
motor 2
09-05-18 10-05-18
TLM1 CO3 T2,R2
38. Methods of reducing
Torque pulsations 1
14-05-18
TLM1 CO2 T2,R2
39. Three-phase full wave
Brushless dc motor 2
15-05-18
TLM1 CO3 T2,R2
16-05-18
40. Sinusoidal type of
Brushless dc motor 1 17-05-18
TLM1 CO3 T2,R2
41. Current controlled
Brushless dc motor
Servo drive
1 04-06-18
TLM1 CO3 T2,R2
42. Seminar-4 1 05-06-18
TLM1
TLM7
43. Test on unit-IV 1 06-06-18
No. of classes required to complete UNIT-IV : 11 No. of classes taken:
UNIT-V : CONTROL OF LINEAR MOTORS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text Book
followed
HOD
Sign
Weekly
44. Types of linear motors
1 07-06-18
TLM1 CO2
T2,R2
45. construction details
1 11-06-18
TLM1 CO2 T2,R2
46. Flat LIMs, Tubular LIMs 1 12-06-18
TLM1 CO2 T2,R2
47. LIM equivalent circuit, Design
considerations 1
13-06-18
TLM1
TLM2 CO2 T2,R2
48. Applications of LIM 1 14-06-18
TLM1 CO3 T2,R2
49. Control of Linear induction motor 1 18-06-18
TLM1 CO2 T2,R2
50. Linear synchronous motor (LSM),
Principle of operation 1
19-06-18
TLM1 CO2 T2,R2
51. Types of LSM 1 20-06-18
TLM1
TLM2 CO2 T2,R2
52. Iron core LSM and Air core LSM
1 21-06-18
TLM1
TLM2 CO2 T2,R2
53. Control of LSM
1 25-06-18
TLM1
TLM2 CO3 T2,R2
54. Semianr-5
1 26-06-18
TLM1
TLM7
55. Test on unit-V
1 27-06-18
56. Revision
1 28-06-18
No. of classes required to complete UNIT-V: 13 No. of classes taken:
Teaching Learning Methods
TLM1 Chalk and Talk TLM5 ICT (NPTEL/Swayam Prabha/MOOCS)
TLM2 PPT TLM6 Assignment or Quiz
TLM3 Tutorial TLM7 Group Discussion/Project
TLM4 Demonstration (Lab/Field Visit)
ACADEMIC CALENDAR:
Description From To Weeks
I Phase of Instructions-1 19-02-2018 07-04-2018 7W
I Mid Examinations 09-04-2018 14-04-2018 1W
II Phase of Instructions-I 16-04-2018 19-05-2018 5W
Summer Vacation 21-05-2018 02-06-2018 2W
II Phase of Instructions-II 04-06-2018 30-06-2018 4W
II Mid Examinations 02-07-2018 07-07-2018 1W
Preparation and Practicals 09-07-2018 14-07-2018 1W
Semester End Examinations 16-07-2018 28-07-2018 2W
Part - C
EVALUATION PROCESS:
Evaluation Task COs Marks
I-Mid Examination 1,2,3 A1=40
II-Mid Examination 1,2,3 A2=40
Evaluation of Mid Marks: A=75% of Max(A1,A2)+25% of Min(A1,A2) 1,2,3 A=40
Semester End Examinations 1,2,3 B=60
Total Marks: A+B 1,2,3 100
PEOs( Program Educational Objectives):
PEO1. Design and develop products and services in the field of Power Electronics and Drives
PEO2. Apply the knowledge of Power Electronics and Drives to solve problems of social relevance, pursue higher education and
research
PEO3. Work effectively as individuals and as team members in multidisciplinary projects
PEO4. Engage in lifelong learning, career enhancement and adapt to changing professional and societal needs
PROGRAM OUTCOMES:
Engineering Post Graduates will be able to: PO1: Independently carry out research /investigation and development work to solve practical problems
PO2: Write and present a substantial technical report/document
PO3: Demonstrate a degree of mastery over the area as per the specialization of the program
PO4: Design green energy systems to conserve and protect environment
PO5: Develop power electronic based controllers for electrical systems to improve their performance
PO6: Develop innovative and entrepreneurial solutions
J.Sivavara Prasad
J.Sivavara Prasad J.Sivavara Prasad Dr.M.Uma
Vani
Course Instructor Course Coordinator Module Coordinator HOD
COURSE HANDOUT Part-A
PROGRAM : M.Tech., II-Sem., EEE (PE&D)
ACADEMIC YEAR : 2017-18
COURSE NAME & CODE : Control of Motor Drives-II – 17PE12
L-T-P STRUCTURE : 2-2-0
COURSE CREDITS : 3
COURSE INSTRUCTOR : S.Prem kumar
COURSE COORDINATOR : S.Prem kumar
PRE-REQUISITE: Electrical Power Transmission, Power Electronics
COURSE OBJECTIVE : This course enables the student to identify the power quality issues and suitable power conditioners for improvement
of power quality. COURSE OUTCOMES(CO)
CO1 Differentiate between different types of power quality problems
CO2 Identify the sources of power quality problems
CO3 Analyze the power quality monitoring equipment and power quality standards
CO4 Apply power quality mitigation methods to improve power quality
CO5 Interpret the power quality benchmarking process
COURSE ARTICULATION MATRIX (Correlation between COs&POs,PSOs):
COs PO1 PO2 PO3 PO4 PO5 PO6
CO1 3 2 2 2 1
CO2 3 2 2 2 1
CO3 3 2 2 2 1
LAKIREDDY BALI REDDY COLLEGE OF ENGINEERING (Autonomous) L.B. Reddy Nagar, Mylavaram-521 230. Andhra Pradesh, INDIA
Affiliated to JNTUK, Kakinada & Approved by AICTE New Delhi
NAAC Accredited with “A” grade, Certified by ISO 9001:2015, http://www.lbrce.ac.in
DEPARTMENT OF ELECTRICAL & ELECTRONICS ENGINEERING Phone: 08659-222933/Extn: 203 [email protected], [email protected]
CO4 3 2 2 2 1
CO5 3 2 2 2 1
Note: Enter Correlation Levels 1 or 2 or 3. If there is no correlation, put ‘-’ 1- Slight(Low), 2 - Moderate(Medium), 3 - Substantial (High).
BOS APPROVED TEXT BOOKS:
T1 H.J Bollen, “Understanding Power Quality Problems: Voltage Sags and Interruptions”,
New York: IEEE Press, 2000.
T2 Roger. C. Dugan, Mark. F. McGranagham, Surya Santoso, H.Wayne Beaty, “Electrical
Power Systems Quality” McGraw Hill,3rd edition,2012.
BOS APPROVED REFERENCE BOOKS:
R1 G.T. Heydt, “Electric Power Quality”, 2nd Edition, West Lafayette Stars Circle
Publications, 1994.
R2 J. Arrillaga, N.R. Watson, S. Chen, “Power System Quality Assessment”, New York:
Wiley, 2003.
Part-B
COURSE DELIVERY PLAN (LESSON PLAN):
UNIT-I : DTC & SENSORLESS VECTOR CONTROL OF INDUCTION MOTOR
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
1. Introduction to Subject
1 19-02-18 TLM1 CO1
T1
2. Course Outcomes
3. Introduction to UNIT-I
4. Power quality (PQ)
problem 1 20-02-18 TLM1 CO1
T1
5. Voltage sag 1 21-02-18 TLM1 CO1 T1
6. Voltage Surges
2 22-02-18 26-02-18
TLM1 CO1 T1
7. Harmonics over
voltages 1 27-02-18 TLM2
CO1 T1
8. spikes, Voltage
fluctuations 2 28-02-18 01-03-18
TLM1
CO1 T1
9.
Transients,
interruption overview
of power quality
phenomenon
1 05-03-18 TLM1
CO3 T1
10.
Transients,
interruption overview
of power quality
phenomenon
1 06-03-18 TLM2
CO3 T1
11. Remedies to improve
power quality 2
07-03-18 08-03-18
TLM1 CO3 T1
12. power quality
monitoring 1 12-03-18
TLM1
TLM7 T1
13. Test on Unit-I
1 13-03-18
T1
No. of classes required to complete UNIT-I: 14 No. of classes taken:
UNIT-II : CONTROL OF SYNCHRONOUS MOTOR DRIVES
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
14. Sources of sags and
interruptions 1 14-03-18 TLM1
CO2 T1
15. Estimating Voltage
sag performance 2
15-03-18 19-03-18
TLM1 CO3 T1
16.
Fundamental
principles protection-
Solutions at the End
User level
1
20-03-18
TLM1
CO3 T1
17.
Evaluating the
economics of different
ride through
alternatives
1 21-03-18 TLM1
TLM2
CO2 T1
18.
Evaluating the
economics of different
ride through
alternatives and Motor
starting sags
2 22-03-18 26-03-18
TLM1
CO3 T1
19.
Evaluating the
economics of different
ride through
alternatives and Motor
starting swells
2 27-03-18 28-03-18
TLM1
CO2 T1
20. Utility system fault
clearing issues. 2 29-03-18 02-04-18
TLM1
CO2 T1
21.
Utility system fault
clearing issues in
different cases 1 03-04-18
TLM1
TLM7
T1
22. Test on unit-II
1 04-04-18
No. of classes required to complete UNIT-II : 13 No. of classes taken:
UNIT-III : CONTROL OF SWITCHED RELUCTANCE MOTOR DRIVES
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
23. Harmonic Distortion-
Voltage versus current
distortion
1
16-04-18
TLM1
CO2 T2,R2
24.
Harmonic versus
Transients 1 17-04-18 TLM1
CO2 T2,R2
25.
Power system
Quantities under non
sinusoidal conditions
1 18-04-18
TLM1
TLM2
CO3 T2,R2
26.
Harmonic indices-
Harmonic sources
from commercial
loads
1 19-04-18
TLM1
TLM2
CO2 T2,R2
27. Harmonic sources
from industrial loads 1 23-04-18
TLM1 CO2 T2,R2
28. Locating harmonic
sources 1 24-04-18
TLM1 CO3 T2,R2
29. System response
characteristics 1 25-04-18 TLM4
CO3 T2,R2
30. Effects of harmonic
distortion 1 26-04-18 TLM1
TLM2
CO2 T2,R2
31.
Inter harmonics-
Harmonic Distortion
Evaluation 1
30-04-18
TLM1 CO2 T2,R2
32. Principles of
Controlling
Harmonics-
1 01-05-18
TLM1 CO2 T2,R2
33. Harmonic studies-
Devices for
controllingHarmonics
1 02-05-18
TLM1
TLM7
34. Harmonic filter
Design 1
03-05-18
No. of classes required to complete UNIT-III: 12 No. of classes taken:
UNIT-IV : CONTROL OF BLDC MOTOR DRIVES
S.No. Topics to be covered No. of
Classes
Required
Tentative Date of
Completion
Actual Date of
Completion
Teaching Learning
Methods
Learning Outcome
COs
Text Book
followed
HOD Sign
Weekly
35. Monitoring
considerations 1
07-05-18
TLM1 CO2 T2,R2
36. Historical perspective
of power quality 1 08-05-18
TLM1 CO2 T2,R2
measuring
instruments
37. Power quality
measurement
equipment
2 09-05-18 10-05-18
TLM1 CO3 T2,R2
38.
Assessment of power
quality measurement
data- Application of
intelligent systems
1 14-05-18
TLM1 CO2 T2,R2
39. Power quality
monitoring standards 2
15-05-18
16-05-18
TLM1 CO3 T2,R2
40.
Overview of
mitigation methods
from fault to trip,
reducing the number
of faults
1 17-05-18
TLM1 CO3 T2,R2
41. reducing the fault
clearing time, 1
04-06-18
TLM1 CO3 T2,R2
42. changing the power
system, installing
mitigation equipment
1 05-06-18
TLM1
TLM7
43.
improving equipment
immunity, different
events and mitigation
methods
1 06-06-18
TLM1
No. of classes required to complete UNIT-IV : 11 No. of classes taken:
UNIT-V : CONTROL OF LINEAR MOTORS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text Book
followed
HOD
Sign
Weekly
44. Introduction, Benchmarking
process, 1
07-06-18
TLM1 CO2
T2,R2
45. Power quality contracts 1 11-06-18
TLM1 CO2 T2,R2
46. power quality insurance, 1 12-06-18
TLM1 CO2 T2,R2
47. power quality state estimation, 1 13-06-18
TLM1
TLM2 CO2 T2,R2
48. power quality in distribution
planning. 1
14-06-18
TLM1 CO3 T2,R2
49. Wiring and Grounding:
Definitions 1
18-06-18
TLM1 CO2 T2,R2
50. resources, reasons for grounding, 1 19-06-18
TLM1 CO2 T2,R2
51. typical wiring and grounding
problems, 1
20-06-18
TLM1 TLM2
CO2 T2,R2
52. Solutions to wiring and grounding
problems. 1
21-06-18
TLM1
TLM2 CO2 T2,R2
53. Solutions to wiring and grounding
problems(advanced) 1
25-06-18
TLM1
TLM2 CO3 T2,R2
54. Semianr-5
1 26-06-18
TLM1
TLM7
55. Revision
1 27-06-18
56. Revision
1 28-06-18
No. of classes required to complete UNIT-V: 13 No. of classes taken:
Teaching Learning Methods
TLM1 Chalk and Talk TLM5 ICT (NPTEL/Swayam Prabha/MOOCS)
TLM2 PPT TLM6 Assignment or Quiz
TLM3 Tutorial TLM7 Group Discussion/Project
TLM4 Demonstration (Lab/Field Visit)
ACADEMIC CALENDAR:
Description From To Weeks
I Phase of Instructions-1 19-02-2018 07-04-2018 7W
I Mid Examinations 09-04-2018 14-04-2018 1W
II Phase of Instructions-I 16-04-2018 19-05-2018 5W
Summer Vacation 21-05-2018 02-06-2018 2W
II Phase of Instructions-II 04-06-2018 30-06-2018 4W
II Mid Examinations 02-07-2018 07-07-2018 1W
Preparation and Practicals 09-07-2018 14-07-2018 1W
Semester End Examinations 16-07-2018 28-07-2018 2W
Part - C
EVALUATION PROCESS:
Evaluation Task COs Marks
I-Mid Examination 1,2,3 A1=40
II-Mid Examination 1,2,3 A2=40
Evaluation of Mid Marks: A=75% of Max(A1,A2)+25% of Min(A1,A2) 1,2,3 A=40
Semester End Examinations 1,2,3 B=60
Total Marks: A+B 1,2,3 100
PEOs( Program Educational Objectives):
PEO1. Design and develop products and services in the field of Power Electronics and Drives
PEO2. Apply the knowledge of Power Electronics and Drives to solve problems of social relevance, pursue higher education and
research
PEO3. Work effectively as individuals and as team members in multidisciplinary projects
PEO4. Engage in lifelong learning, career enhancement and adapt to changing professional and societal needs
PROGRAM OUTCOMES: Engineering Post Graduates will be able to: PO1: Independently carry out research /investigation and development work to solve practical problems
PO2: Write and present a substantial technical report/document
PO3: Demonstrate a degree of mastery over the area as per the specialization of the program
PO4: Design green energy systems to conserve and protect environment
PO5: Develop power electronic based controllers for electrical systems to improve their performance
PO6: Develop innovative and entrepreneurial solutions
S.Prem kumar
S.Prem kumar
J.Sivavara Prasad Dr.M.Uma
Vani
Course Instructor Course Coordinator Module Coordinator HOD
LAKKIREDDY BALI REDDY COLLEGE OF ENGINEERING
DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING (Autonomous & Affiliated to JNTUK, Kakinada & Approved by AICTE, New Delhi,
NAAC Accredited with ‘A’ grade, Accredited by NBA, Certified by ISO 9001:2015)
L B Reddy Nagar, Mylavaram-521 230, Krishna District, Andhra Pradesh.
COURSE HANDOUT
PROGRAM : M.Tech., II-Sem., EEE(PED)
ACADEMIC YEAR : 2017-18
COURSE NAME & CODE : APPLICATION OF ARTIFICAL INTELLIGENCE TECHNIQUES – 17PE17
L-T-P STRUCTURE : 2-2-0
COURSE CREDITS : 3
COURSE INSTRUCTOR : Mr.J.V.Pavan Chand
COURSE COORDINATOR :
PRE-REQUISITE:
COURSE OBJECTIVE : This course will enable the basic principles of soft computing techniques. It covers simple representation schemes,
problem solving paradigms of ANN, fuzzy & genetic algorithms and their applications to power electronics.
COURSE OUTCOMES(COs)
Af the enf of the course, student will be able to:
CO1: Apply AI technique to engineering problems.
CO2: Understand different types of perceptron models.
CO3: Understand different types of fuzzy sets, member ship functions and their implementation methods.
CO4: Apply genetic algorithms to power electronics
COURSE ARTICULATION MATRIX (Correlation between COs&POs,PSOs):
COs PO1 PO2 PO3 PO4 PO5 PO6
CO1 2 2 2 2 2
CO2 2 2 2 2 2
CO3 2 2 2 2 2
CO4 2 2 2 2 2
Note: Enter Correlation Levels 1 or 2 or 3. If there is no correlation, put ‘-’
1- Slight(Low), 2 - Moderate(Medium), 3 - Substantial (High).
BOS APPROVED TEXT BOOKS:
T1 Jacek M. Zuarda, “Introduction to Artificial Neural Systems”, Jaico Publishing House,
1999.
T2 Timothy J Ross, “Fuzzy logic with engineering application”, Wiley publications, Third
edition, 2010.
BOS APPROVED REFERENCE BOOKS:
1. James A Freeman and Davis Skapura, “Neural Networks” ,Pearson Education, 2003.
2. Rajasekharan and Pai, “Neural Networks, Fuzzy logic, Genetic algorithms: synthesis and aplications” ,PHI Publication, 2003.
3. Samir Roy, Udit Chakraborty, “Introduction to Sift Computing: Neuro Fuzzy & Genetic Algorithms, Pearson Publications.
4. C.Kamalakannan, L.Padma Suresh, “Power Electronics and Renewable energy systems”, Spriger, 2015
5. Devendra K.Chaturvedi, “Soft Computing: Techniques & its applications in Electrical Engineering, Springer Science.
6. B.K.Bose, “Neuran network applications in power electronics and motor drives-An introduction and perspective”, IEEE transaction on
Industrial Electronics, Volume 54, No 1, February, 2007.
7. Gilberto C.D.Sousa, Bimal K.Bose, “Fuzzy logic applications to power electronics and drives-An overview”, IEEE conference, 1995, pages
57-62.
8. Peter Vas, “Artificial-Intellegence based electrical machines and drives”, Oxford university press.
9. Naziha Ahmad Azil, Shahrinmd Ayob, Norkharzian Mohd Nayan, “Particle Swarm Optimization and its application in power converter
systems”, IEEE conference.
10. Susana Estefany De, Hugo Calleja, Jesus Aquayo Alquicira, “Metaheuristic optimization methods applied to power converters:A review”,
IEEE transaction on power electronics, volume 30, issue 12, December 2015.
COURSE DELIVERY PLAN (LESSON PLAN): Section-A
UNIT-I: ARTIFICIAL NEURAL NETWORKS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
66. UNIT-I : Evolution of neural networks
1 19-02-2018
TLM1 CO1 T1
67. Artificial Neural Network: Basic model,
Classification 1
20-02-2018
TLM1 CO1 T1
68. Feed forward and Recurrent topologies, Activation functions
1 21-02-2018
TLM1 CO1 T1
69. Learning algorithms: Supervised, Un-supervised and Reinforcement 1
22-02-2018
TLM1 CO1 T1
70. McCulloach – Pits model,
1 26-02-2018
TLM1 CO1 T1
71. Perceptron
1 27-02-2018
TLM1 CO2 T1
72. Adaline, Madaline
1 28-02-2018
TLM1 CO2 T1
73. Topology of Multi-layer perceptron, Back
propagation learning algorithm 1 01-03-2018
TLM1 CO2 T1
74. Topology of Multi-layer perceptron, Back
propagation learning algorithm 1
05-03-2018
TLM1 CO2 T1
75. Kohenen’s self-organising network: Topology
1 06-03-2018
TLM1 CO2 T1
76. Bidirectional associative memory
Topology 1
07-03-2018
TLM1 CO2 T1
77. Hopfield network: Topology 1 08-03-2018
TLM1 CO2 T1
78.
Neural network applications in
power electronics & motor drives
using feedforward and recurrent
architectures
1 12-03-2018
TLM1 CO2 T1
79. Seminar-1 1 13-03-2018
TLM6
80. Assignment-1 1 14-03-2018
TLM6
No. of classes required to complete UNIT-I 14 No. of classes taken:
UNITII: FUZZY LOGIC
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
81. Introduction to classical and fuzzy
sets, crisp sets, universal sets, 1
15-03-2018
TLM1 CO3
T2
82.
properties of crisp sets, partition and
covering, operations on crisp sets,
crisp relations, operations on
relations
1 19-03-2018
TLM1
CO3 T2
83. fuzzy sets- membership function,
properties of fuzzy sets, basic fuzzy
set operations
1 20-03-2018 TLM1
CO3 T2
84. fuzzy relations 1 21-03-2018
TLM1 CO3 T2
85. operations on fuzzy relations 1 22-03-2018
TLM1 CO3 T2
86. cardinality and relative of fuzzy
relations 1
26-03-2018 TLM1
CO3 T2
87. Fuzzification, development of rule
based system 1
27-03-2018
TLM1 CO3 T2
88. fuzzy propositions, fuzzy operators,
fuzzy quantifiers, fuzzy inference,
fuzzy decision making system
1
28-03-2018 TLM1
CO3 T2
89. defuzzification to crisp sets,
defuzzification methods
1 02-04-2018 TLM1 CO3 T2
90.
control of phase controlled dc
motor drive by using fuzzy logic
controllers.
1
03-04-2018 TLM1
CO3
T2
91. Seminar-2 1 04-04-2018
TLM6 CO3 T2
92. Assignment-2 1 05-04-2018
TLM2 CO3 T2
No. of classes required to complete UNIT-
II 12 No. of classes taken:
UNIT-III : GENETIC ALGORITHM
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
93. Introduction-Basic concepts of
Genetic AlgorithmS
1 16-04-2018 TLM1 CO4 R2
94. Basic concepts of Genetic
AlgorithmS
1 17-04-2018 TLM1 CO4 R2
95. Selection-Cross over-Mutation-
algorithm
1 18-04-2018 TLM1 CO4 R2
96. Selection-Cross over-Mutation-
algorithm
1 19-04-2018 TLM1
CO4 R2
97. Selection-Cross over-Mutation-
algorithm,
1 23-04-2018
TLM1 CO4 R2
98. steps-fitness function limitations of
GA
1 24-04-2018
TLM1 CO4 R2
99. steps-fitness function limitations of
GA
1 25-04-2018 TLM1
CO4 R2
100. function limitations of GA 1 26-04-2018
TLM1 CO4 R2
101. function limitations of GA 1 30-04-2018
TLM1 CO4 R2
102. Optimization of controllers using
genetic algorithm
1 01-05-2018 TLM1
CO4 R2
103. Optimization of controllers using
genetic algorithm
1 02-05-2018
TLM1 CO4 R2
104. Problems 1 03-05-2018
TLM1 CO4 R2
105. Repetition unit-iii 1 07-05-2018
TLM1 CO4 R2
106. Seminar-3 1 08-05-2018
TLM1
107. Assignment-3 1 09-05-2018
TLM6
No. of classes required to complete UNIT-III 15 No. of classes taken:
UNIT IV: PARTICLE SWARM OPTIMIZATION
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
Cos
Text
Book
followed
HOD
Sign
Weekly
108. PSO algorithm 1 10-05-2018
TLM1 R5
109. parameter selection 1 14-05-2018
TLM1 R5
110. Neighbourhoods and topologies 1 15-05-2018
TLM2 R5
111. Inner workings- Convergence,
Biases
1 16-05-2018 TLM2
R5
112. Variants- Hybridization 1 17-05-2018
TLM2 R5
113. Alleviate premature,
Simplifications
1 04-06-2018
TLM2 R5
114. Multi-objective optimization, 1 05-06-2018
TLM2 R5
115. Binary, discrete, and combinatoria 1 06-06-2018
TLM2 R5
116. PSO applications to power converter
systems
1 07-06-2018
TLM2 R5
117. Seminar-4 1 11-06-2018
TLM1
118. Assignment-4 1 12-06-2018
TLM6
No. of classes required to complete UNIT-
IV 11 No. of classes taken:
UNIT V: META-HEURISTICS TECHNIQUES
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
Cos
Text
Book
followed
HOD
Sign
Weekly
119. Properties 1 13-06-2018
TLM2 CO4 R5
120. Classification-Local search vs.
Global search
1 14-06-2018 TLM2 CO4 R5
121. Single-solution vs. Population-
based
1 18-06-2018 TLM2 CO4 R5
122. Hybridization and memetic
algorithms
1 19-06-2018
TLM2 CO4 R5
123. Parallel metaheuristics 1 20-06-2018
TLM2 CO4 R5
124. Nature-inspired metaheuristics 1 21-06-2018
TLM2 CO4 R5
125. Nature-inspired metaheuristics 1 25-06-2018
TLM2 CO4 R5
126. meta-heuristic applications in the area of
power converters
1 26-06-2018
TLM2 CO4 R5
127. meta-heuristic applications in the area of
power converters
1 27-06-2018
TLM2 CO4 R5
128. Assignment-5 1 28-06-2018
TLM6 CO4
No. of classes required to complete UNIT-
V 10 No. of classes taken:
Contents beyond the Syllabus
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
Cos
Text
Book
followed
HOD
Sign
Weekly
129. Neural Networks in Electrical
Engineering 1
28-6-2018
130. Fuzzy Logic in Electrical
Engineering 1
28-6-2018
131. Genatic algorthim in Electrical
Engineering 1
28-6-2018
Teaching Learning Methods
TLM1 Chalk and Talk TLM5 ICT (NPTEL/Swayam Prabha/MOOCS)
TLM2 PPT TLM6 Assignment or Quiz
TLM3 Tutorial TLM7 Group Discussion/Project
TLM4 Demonstration (Lab/Field Visit)
Part - C
EVALUATION PROCESS:
Evaluation Task COs Marks
Assignment– 1 2 A1=5
Assignment – 2 1 A2=5
I-Mid Examination 1,2 B1=35
Assignment – 3 3 A3=5
Assignment – 4 4 A4=5
Assignment – 5 4 A5=5
II-Mid Examination 3,4 B2=35
Evaluation of Assignmen Marks: A=(A1+A2+A3+A4+A5)/5 1,2,3,4 A=5
Evaluation of Mid Marks: B=75% of Max(B1,B2)+25% of Min(B1,B2) 1,2,3,4 B=20
Cumulative Internal Examination : A+B 1,2,3,4 A+B=40
Semester End Examinations 1,2,3,4 C=60
Total Marks: A+B+C 1,2,3,4 100
PROGRAMME EDUCATIONAL OBJECTIVES (PEOs)
PROGRAMME OUTCOMES (POs)
PSOs
LAKKIREDDY BALI REDDY COLLEGE OF ENGINEERING DEPARTMENT OF ELECTRONICS AND COMMUNICATION ENGINEERING
(Autonomous & Affiliated to JNTUK, Kakinada & Approved by AICTE, New Delhi,
NAAC Accredited with ‘A’ grade, Accredited by NBA, Certified by ISO 9001:2015) L B Reddy Nagar, Mylavaram-521 230, Krishna District, Andhra Pradesh.
COURSE HANDOUT
PROGRAM : M.Tech., II-Sem., PED
ACADEMIC YEAR : 2017-18
COURSE NAME & CODE : INTEGRATION OF RENEWABLE SOURCES- 17PE91
L-T-P STRUCTURE : 3-1-0
COURSE CREDITS : 3
COURSE INSTRUCTOR : A.V.G.A.MARTHANDA.
COURSE COORDINATOR :
PRE-REQUISITE: Power Electronics. Distributed Generation
COURSE OBJECTIVE : This course enables the students to introduce the concepts of
standalone and grid connected renewable energy systems with power conversion systems COURSE OUTCOMES(CO)
After completion of the course student will be able to:
CO1. Characterize various renewable energy technologies and their effective utilization
CO2. Design power electronic circuits for PV-Grid integration
CO3: Design power electronic circuits for Wind-Grid integration
CO4. Analyze various energy storage systems
COURSE ARTICULATION MATRIX (Correlation between COs&POs,PSOs):
COs PO 1
PO 2
PO 3
PO 4
PO 5
PO 6
PSO 1
PSO 2
PSO 3
CO1 3 2 2 2 1 2 3 3
CO2 3 2 2 2 1 2 3 3
CO3 3 2 2 2 1 2 3 3
CO4 3 2 2 2 1 3 3 3
Note: Enter Correlation Levels 1 or 2 or 3. If there is no correlation, put ‘-’ 1- Slight(Low), 2 - Moderate(Medium), 3 - Substantial (High).
BOS APPROVED TEXT BOOKS:
T1 Farret,M.Godoy.Simoe,”Integration of alternating sources of energy”wiley-IEEE press,
Dec 2005
T2 Freries.LL,”Wind energy conversion systems”Prentice Hall, UK
BOS APPROVED REFERENCE BOOKS:
R1 Farret,M.Godoy.Simoe,”Integration of alternating sources of energy”wiley-IEEE
press, Dec 2005
R2 Freries.LL,”Wind energy conversion systems”Prentice Hall, UK
COURSE DELIVERY PLAN (LESSON PLAN):
UNIT-I : SOLAR ENERGY
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
1.
UNIT - I: Review of Solar
energy-
1 19-02-2018 TLM1
1 T1 &R1
2. Applications of PV Systems- 1 20-02-2018
TLM1 1 T1 &R1
3. Commercially available
modules-
1 22-02-2018
TLM1 1 T1 &R1
4. FBC ETC collectors 1 23-02-2018
TLM1 1 T1 &R1
5. FBC ETC collectors 1 26-02-2018
TLM1 1 T1 &R1
6. switching devices for solar
energy conversion
1 27-02-2018
TLM1 1 T1 &R1
7. switching devices for solar
energy conversion - 1 01-03-2018
TLM1 1 T1 &R1
8. Maximum Power Point
Tracking (MPPT) and Its
Importance
1
05-03-2018
TLM4 1 T1 &R1
9. Maximum Power Point
Tracking (MPPT) and Its
Importance
1
06-03-2018
TLM3 1 T1 &R1
10. M PPT algorithms 1 08-03-2018
TLM1 1 T1 &R1
11. Performance analysis for
varying solar irradiance and
temperature-
1
09-03-2018
TLM1 1 T1 &R1
12. SEMINAR 1 12-03-2018
TLM1 1,4 T1 &R1
13. MPPT Techniques- - 1 13-03-2018
TLM3 1 T1 &R1
14. Comparison of various
techniques-
1 15-03-2018
TLM1 1,2 T1 &R1
15. Charge controllers 1 16-03-2018
TLM6 1,2 T1 &R1
16. Unit revision/assignment 1 16-03-2018
TLM2 1,2 T1 &R1
No. of classes required to complete
UNIT-I
No. of classes taken:
UNIT-II : pv based converter design & integration
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
17. Unit –II Introduction
1 20-03-2018 TLM1 1,2 T1 &R1
18. DC-DC Converter-Classification 1 22-03-2018 TLM1 2 T1 &R1
19. DC-DC Converter 1 23-03-2018 TLM1 2 T1 &R1
20. seminar 1 26-03-2018 TLM1 2 T1 &R1
21. DC-AC converters- Classification
of Inverters-
1 27-03-2018 TLM3 2 T1 &R1
22. DC-AC converters- Classification
of Inverters
1 29-03-2018 TLM1 2 T1 &R1
23. Applications- Photo Voltaic
inverter
1 30-03-2018 TLM1 2 T1 &R1
24. Grid-Tie Inverter
1 02-04-2018 TLM1 1,2 T1 &R1
25. Hybrid Inverter with batteries
and grid connected system-
inverter Topologies
1
03-04-2018
TLM3 2 T1 &R1
26. grid connected system- inverter
Topologies 1 05-04-2018 TLM1 1,2 T1 &R1
27. Seminar/unit revision 1 06-04-2018 TLM2 1,2 T1 &R1
No. of classes required to complete UNIT-
II
No. of classes taken:
UNIT-III :
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text Book
followed
HOD
Sign
Weekly
28. UNIT - III: WIND ENERGY
Overview of Wind Energy
1 16-04-2018 TLM1 1 T1 &R1
29. Conversion Systems (WECS), 1 17-04-2018 TLM1 1 T1 &R1
30. Wind turbine Technologies. 1 19-04-2018 TLM1 1 T1 &R1
31. classifications of WECS 1 20-04-2018 TLM1 1 T1 &R1
32. performance of induction
generators for WECS
1 23-04-2018 TLM3 1 T1 &R1
33. induction generators for WECS 1 24-04-2018 TLM1 1 T1 &R1
34. self excited induction
generator for isolated power
generators.
1
26-04-2018
TLM1 1 T1 &R1
35. generator for isolated power
generators 1 27-04-2018 TLM1 1 T1 &R1
36. Seminar 1 30-04-2018 TLM3 1 T1 &R1
37. capacitance requirements. power
conditioning schemes
1 01-05-2018 TLM4 1,4 T1 &R1
38. power conditioning schemes 1 03-05-2018 TLM2 1,4 T1 &R1
39. Maximum Power Point Tracking
(MPPT) Control
1 04-05-2018
TLM1 1 T1 &R1
40. Maximum Power Point Tracking
(MPPT) Control 1 07-05-2018 TLM1 1 T1 &R1
41. Synchronous generators 1 08-05-2018 TLM1 1 T1 &R1
42. Synchronous generators 1 10-05-2018 TLM1 1 T1 &R1
No. of classes required to complete
UNIT-III
No. of classes taken:
UNIT-IV : WIND ENERGY BASED CONVERTER DESIGN & INTEGRATION
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
43. AC Voltage Controllers (Soft
Starters)-
1 11-05-2018 TLM1 3 T2 &R2
44. Interleaved Boost Converters-
1 14-05-2018 TLM1 3 T2 &R2
45. Two-Level Voltage Source
Converters-
1 15-05-2018 TLM1 3 T2 &R2
46. Three-Level Neutral Point
Clamped Converters-
1 17-05-2018 TLM1 3 T2 &R2
47. PWM Current Source
Converters 1 18-05-2018 TLM1 3 T2 &R2
48. PWM Current Source
Converters
1 04-06-2018 TLM3 3 T2 &R2
49. SEMINAR 1 05-06-2018 TLM4 3,4 T2 &R2
50. . Grid connectors concept 1 07-06-2018 TLM1 3 T2 &R2
51. grid related problems 1 08-06-2018 TLM1 3 T2 &R2
52. Control of Grid-Connected
Inverter
1 11-06-2018 TLM1 3 T2 &R2
53. Unit revision/seminar 1 12-06-2018 TLM1 3 T2 &R2
No. of classes required to complete
UNIT-IV 15
No. of classes taken:
UNIT-V : ENERGY STORAGE SYSTEMS
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
54. Energy storage parameters. Lead
acid batteries-Construction
1 14-06-2018 TLM1 3 T2 &R4
55. features-operating limits-
Maintenance
1 15-06-2018 TLM1 3 T2 &R4
56. seminar 1 18-06-2018 TLM1 3 T2 &R4
57. Ultra capacitors- double layer
capacitor-.
1
19-06-2018
TLM1 3,4 T2 &R4
58. double layer capacitor 1 20-06-2018 TLM3 3,4 T2 &R4
59. high energy capacitor-
applications
1 21-06-2018 TLM1 3 T2 &R4
60. Flywheels. Super conducting
magnetic storage system. storage
heat
1
22-06-2018
TLM1 3 T2 &R4
61. magnetic storage system. storage
heat
1 23-06-2018 TLM3 3 T2 &R4
62. Seminar/ unit revision 1 25-06-2018 TLM6 3,4 T2 &R4
No. of classes taken:
Contents beyond the Syllabus
S.No. Topics to be covered
No. of
Classes
Required
Tentative
Date of
Completion
Actual
Date of
Completion
Teaching
Learning
Methods
Learning
Outcome
COs
Text
Book
followed
HOD
Sign
Weekly
63. Advance topics-Hybrid
systems(solar-wind)
1 26-06-2018 TLM1
1,2,4 T1 &
R1
64. Advance topics-Hybrid
systems(solar-wind/fuel cells)
1 28-6-2018 TLM2
3,4 T2 &
R2
Teaching Learning Methods
TLM1 Chalk and Talk TLM4 Problem Solving TLM7 Seminars or GD
TLM2 PPT TLM5 Programming TLM8 Lab Demo
TLM3 Tutorial TLM6 Assignment or Quiz TLM9 Case Study
Description From To Weeks
I Phase of Instructions-1 19-02-2018 07-04-2018 7W
I Mid Examinations 09-04-2018 14-04-2018 1W
II Phase of Instructions-I 16-04-2018 19-05-2018 5W
Summer Vacation 21-05-2018 02-06-2018 2W
II Phase of Instructions-II 04-06-2018 30-06-2018 4W
II Mid Examinations 02-07-2018 07-07-2018 1W
Preparation and Practicals 09-07-2018 14-07-2018 1W
Semester End Examinations 16-07-2018 28-07-2018 2W
EVALUATION PROCESS:
Evaluation Task COs Marks
Assignment/Quiz – 1 1 A1=5
Assignment/Quiz – 2 2 A2=5
I-Mid Examination 1,2 B1=20
Assignment/Quiz – 3 3 A3=5
Assignment/Quiz – 4 4 A4=5
Assignment/Quiz – 5 5 A5=5
II-Mid Examination 3,4,5 B2=20
Evaluation of Assignment/Quiz Marks: A=(A1+A2+A3+A4+A5)/5 1,2,3,4,5 A=5
Evaluation of Mid Marks: B=75% of Max(B1,B2)+25% of Min(B1,B2) 1,2,3,4,5 B=20
Cumulative Internal Examination : A+B 1,2,3,4,5 A+B=25
Semester End Examinations 1,2,3,4,5 C=75
Total Marks: A+B+C 1,2,3,4,5 100
Signature
Name of the faculty Name of the course Co-ordinator Name of the Module Co-ordinator
HOD
Mr.AVGA.MARTHANDA Mr.AVGA.MARTHANDA Dr.M.Uma Vani
LAKIREDDY BALI REDDY COLLEGE OF ENGINEERING (Autonomous)
L.B. Reddy Nagar, Mylavaram-521230. Andhra Pradesh, INDIA
Affiliated to JNTUK, Kakinada & Approved by AICTE New Delhi
NAAC Accredited with “A” grade, Accredited by NBA,
New Delhi & Certified by ISO 9001:2015, http://www.lbrce.ac.in
DEPARTMENT OF ELECTRICAL & ELECTRONICS ENGINEERING
Course Title: POWER CONVERTERS & DRIVES-II LAB (17PE62) Branch:M.TECH.(PED) Year: I
Semester: II Academic Year: 2017-18
LIST OF EXPERIMENTS
1. Power factor correction of PIC micro converter based boost converter.
2. Speed control of PM synchronous motor by voltage control method.
3. Speed control of BLDC motor by voltage control method.
4. Speed control of three phase induction motor with DSP based V/F technique.
5. Single phase IGBT based inverter.
6. DC output voltage & AC link voltage characteristics of isolated dc-dc resonant converter.
7. Output voltage characteristics of DC-DC buck converter with R & RL loads using FPGA controller.
8. Digital to Analog converter (DAC) and Analog to Digital converter (ADC) using digital controller.
9. Generation of sinusoidal signal using digital controller.
10. Generation of three phase sine triangle PWM pulses using digital controller.
LAB SCHEDULE
DAY: WEDNESDAY (5,6Hours)
Batch: 17761D5401, 17761D5402, 17761D5403
H.T. No. I
Week
II
Week
III
Week
IV
Week
V
Week
VI
Week
VII
Week
VIII
Week
IX
Week
X
Week XI XII XIII XIV
XV XVI
Tentative date 21/2 28/2
7/3 14/3 21/3 28/3 4/4 18/4 25/4 2/5 9/
5
16/
5
6/6 13/6 20/
6
27/6
Actual date
17761D5401
17761D5402
17761D5403
Demo 1 2 3 4 5 Demo 6 7 8 9 10
RE
VIS
ION
OF
EX
PE
RIM
EN
TS
RE
VIS
ION
OF
EX
PE
RIM
EN
TS
PR
OJE
CT
BA
SE
DE
XP
ER
IME
NT
S
TEST
LAB INCHARGE HEAD OF THE DEPARTMENT
LAKIREDDY BALI REDDY COLLEGE OF ENGINEERING (Autonomous) L.B. Reddy Nagar, Mylavaram-521230. Andhra Pradesh, INDIA
Affiliated to JNTUK, Kakinada & Approved by AICTE New Delhi
NAAC Accredited with “A” grade, Accredited by NBA, New Delhi & Certified by ISO 9001:2015, http://www.lbrce.ac.in
DEPARTMENT OF ELECTRICAL & ELECTRONICS ENGINEERING Course Title: SIMULATION OF POWER CONVERTERS & DRIVES-II LAB(17PE63) Branch: M.TECH
Year: I Semester: II Academic 2017-18
LIST OF EXPERIMENTS CYCLE1
1. Power factor correction boost converter using PWM technique.
2. Load voltage & current characteristics of isolated DC-DC resonant converter using PWM technique.
3. Load voltage & current characteristics of DC-DC buck converter using PWM & pulse delay control techniques.
4. Load voltage & current characteristics of DC-DC buck boost converter with R & RL loads using hysteresis PWM technique.
5. Load voltage & current characteristics of DC-DC forward converter with R & RL loads using hysteresis PWM technique.
6. Load voltage & current characteristics of DC-DC Cuk converter with R & RL loads using PWM technique.
7. Load voltage & current characteristics of DC-DC flyback converter with R & RL loads using hysteresis PWM technique.
8. Speed control of PM synchronous motor by voltage control method.
9. Speed control of BLDC motor by voltage control method.
10. Speed control of switched reluctance motor by PWM control technique.
SCHEDULE
DAY: FRIDAY (2,3Hours)
Batches: 17761D5401,17761D5402,17761D5403
S.NO. H.T. Nos I
Week
II
Week
III
Week
IV
Week
V
Week
VI
Week
VII
Week
VIII
Week
IX
Week
X
Week
XI
Week
XII
Week
XIII
Week
XIV
Week
Tentative date 23/2/18 9/3/18 16/3/18 23/3/18 6/4/18 20/4/18 27/4/18 4/5/18 11/5/18 18/5/18 8/6/18 15/6/18 22/6/18 29/6/18
Actual date