Lesson Plan. Topic (including assignment /test )

Transcription

1 Lesson Plan Name of the Faculty: Labh Singh Discipline: Electrical Engg. Semester: 4th Subject: Control System Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, -02 System / Plant model, types of models, illustrative examples of plants & their inputs and outputs, controller Servomechanism, regulating system 1 To study A.C. servo motor and to plot its torque-speed characteristics. Linear time-invariant (LTI) system Time-varying system, causal system 2 nd open loop & closed loop control system & their illustrative examples 2 To study D.C. servo motor and to plot its torque speed characteristics Continuous time and sampled data control systems 3 rd Effects of feedback on sensitivity (to parameter variations) Stability, external disturbance (noise) 3 To study the magnetic amplifier and to plot its load current v/s control current characteristics for: (a) series connected mode overall gain, etc. Introductory remarks about non-linear control systems

2 Concept of transfer function, relationship between transfer function and impulse response 4 th Order of a system, block diagram algebra 4 To study the magnetic amplifier and to plot its load current v/s control current characteristics for: (b) parallel connected mode Order of a system, block diagram algebra Signal flow graphs: Mason s gain formula & its application 5 th Signal flow graphs: Mason s gain formula & its application 5 To plot the load current v/s control current characteristics for self exited mode of the magnetic amplifier. characteristic equation, derivation of transfer functions of electrical and electromechanical systems 6 th Transfer functions of cascaded and non-loading cascaded elements Typical test signals, time response of first order systems to various standard inputs Time response of order system to step input, relationship between location of roots of characteristics equation. 6 To study the synchro & to: (a) Use the synchro pair (synchro transmitter & control transformer) as an error detector.

3 7 th ω and ω n, time domain specifications of a general and an under-damped order system steady state error and error constants 7 To study the synchro & to: (b) Plot stator voltage v/s rotor angle for synchro transmitter i.e. to use the synchro transmitter as position transducer. Dominant closed loop poles Concept of stability 8 th Pole-zero configuration and stability 8 To use the synchro pair (synchro transmitter & synchro motor) as a torque transmitter. Necessary and sufficient conditions for stability Hurwitz stability criterion 9 th Routh stability criterion and relative stability 9 (a) To demonstrate simple motor-driven closed-loop position control system.. Root locus concept

4 Development of root loci for various systems 10 th Stability 10 (b) To study and demonstrate simple closed-loop speed control system Considerations Relationship between frequency response and time-response for order system 11 th Polar, Nyquist Plot 11 To study the lead, lag, lead-lag compensators and to draw their magnitude and phase plots. Bode plots, stability Gain-margin and Phase Margin 12 th Gain-margin and Phase Margin 12 To study a stepper motor & to execute microprocessor or computer-based control of the same by changing number of steps, direction of rotation & speed. Relative stability, frequency response specifications

5 Necessity of compensation, compensation networks 13 th Application of lag and lead compensation 13 To implement a PID controller for level control of a pilot plant. Basic modes of feedback control Proportional,integral controllers 14 th Derivative controllers 14 To implement a PID controller for temperature control of a pilot plant. Illustrative examples. Synchros, servomotors 15 th Stepper motors 15 To study the MATLAB package for simulation of control system design. Magnetic amplifier

6 Lesson Plan Name of the Faculty: Pawan Siswal Discipline: Electrical Engg. Semester: 4th Subject: Electrical Machine-I Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, -02 Single Phase Transformer: Principle construction 1 To find turns ratio & polarity of a 1-phase transformer. E.M.F equation Operation of transformer 2 nd Phasor diagram, Equivalent parameter determination 2 To perform open & short circuit tests on a 1-phase transformer. Equivalent circuit, voltage regulation 3 rd Losses, separation of iron losses Efficiency, All day efficiency 3 To perform Sumpner's back to back test on 1-phase transformers. Open-circuit test, short circuit test

7 Sumpner s test 4 th P.U representation 4 Parallel operation of two 1- phase transformers. Parallel operation of 1-Phase transformer Auto-transformer: Principle, construction 5 th Comparison with two winding transformers 5 To convert three phase to twophase By Scott-connection. saving of conductor material and its applications Three Phase Transformer: Principle, construction 6 th connection, operation, advantages 6 To perform load test on DC shunt generator. various types of connection of three phase transformer

8 Inrush of magnetizing current 7 th Harmonic phenomenon 7 Speed control of DC shunt motor. Cooling, rating Parallel operation 8 th Three to two phase, three to six phase 8 Swinburne s test of DC shunt motor. Three to twelve phase conversions. Scott connection 9 th Current transformer(c.t) and their applications 9 Hopkinson s test of DC shunt machines. Potential transformer (P.T) and their applications

9 D.C Generator: Principal, Construction 10 th E.M.F equation 10 Ward Leonard method of speed control of D.C. motor. Types & characteristics voltage buildup phenomenon in self excited generator 11 th simplex lap and wave windings 11 Applications Armature reaction 12 th Commutation, method of improving commutation 12 Parallel operation

10 D.C Motor: Principle, construction 13 th Torque equation 13 Types & characteristics starting and starters 14 th Speed control 14 Speed control Losses, efficiency 15 th swinburne s test, hopkinson s test 15 Braking

11 Lesson Plan Name of the Faculty: Pawan Discipline: Electrical Engg Semester: 4th Subject: Network Analysis-II Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, -02 Characteristics and Parameters of two port networks Network Configurations 1 Transient response of RC circuit Short circuit Admittance parameters Open-circuit impedance parameters 2 nd Transmission parameters, hybrid parameters 2 Transient response of RL circuit. Condition for reciprocity & symmetry of two-port networks in different parameters 3 rd Condition for reciprocity & symmetry of two-port networks in different parameters Inter-relationships between parameters of two-port network 3. Transient Response of RLC Circuit Inter-relationships between parameters of two-port network

12 Expression of input & output impedances in terms of two port parameters 4 th Inter-connection of two port networks 4 To calculate and verify "Z" parameters of a two port network Analysis of typical two-port networks Image impedances 5 th Terminal pairs or Ports 5 To calculate and verify "Y" parameters of a two port network. Network functions for one-port and two-port networks Concept of poles and zeros in Network functions 6 th Restrictions on pole and zero Locations for driving point functions and transfer functions 6. To determine equivalent parameter of parallel connections of two port network. Restrictions on pole and zero Locations for driving point functions and transfer functions

13 Time domain behavior from the pole-zero plot 7 th Principles of network topology 7 To plot the frequency response of low pass filter and determine half-power frequency. Graph matrices Graph matrices 8 th Graph matrices 8 To plot the frequency response of high pass filter and determine the half-power frequency. Network analysis using graph theory 9 th Network analysis using graph theory Types of filters and their characteristics 9 To plot the frequency response of band-pass filter and determine the band-width. Filter fundamentals

14 Classification of Filter 10 th Analysis & design of prototype high-pass 10 To calculate and verify "ABCD" parameters of a two port network Prototype low-pass Prototype band-pass 11 th Prototype band-reject 11 To calculate and verify "h" parameters of a two port network. M-derived low-pass M-derived high-pass filters 12 th Low-pass filter and high-pass filter with RC & RL circuits 12 To determine equivalent parameter of series connections of two port network. Low-pass filter and high-pass filter with RC & RL circuits

15 Band pass filter with RLC circuit. 13 th Hurwitz polynomials, Properties of Hurwitz polynomials 13 To synthesize a network of a given network function and verify its response Positive real functions, procedure of testing of PRV functions Concept and procedure of network synthesis 14 th Properties of expressions of driving point immitances of LC networks 14 Introduction of P-Spice Foster s I & II Form Cauer s I & II form 15 th RC & RL Network synthesis 15 Foster s & Cauer s form of synthesis of lossy networks.

16 Lesson Plan Name of the Faculty: Ankit Aryan Discipline: Electrical Engg. Semester: 4th Subject: EMT Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03 1 Coulomb s Law, Gauss s Law 2 Potential function, field due to a continuous distribution of charge 3 Equi-potential surfaces, Gauss s Theorem 4 Poison s equation 2 nd 5 Laplace s equation 6 Method of electrical images 7 Capacitance, electro-static energy, boundary conditions 3 rd 8 The electro-static uniqueness theorem, far field of a charge distribution 9 Dirac-Delta representation for a point charge and an infinitesimal dipole

17 10 Faraday s law of Induction, Ampere s Work law in the differential vector form 4 th 11 Ampere's law for a current element, Ampere s Force Law 12 Magnetic field due to volume distribution of current and the Dirac-delta function, 13 Magnetic vector potential, vector potential (Alternative derivation) 5 th 14 Far field of a current distribution, equation of continuity 15 Equation of continuity for time varying fields, inconsistency of Ampere s law 16 Maxwell s field equations and their interpretation, solution for free space conditions 6 th 17 Electromagnetic waves in a homogeneous medium, propagation of uniform planewave 18 Relation between E & H in a uniform plane-wave, wave equations for conducting medium

18 19 Maxwell s equations using phasor notation 7 th 20 Wave propagation in a conducting medium 21 Conductors, dielectrics 22 Wave propagation in good conductor and good dielectric 8 th 23 Depth of penetration 24 Assignment 25 Polarization 9 th 26 Linear, circular and elliptical 27 Reflection and refraction of plane waves at the surface of a perfect conductor

19 28 Perfect dielectric (both normal incidence as well as oblique incidence) 10 th 29 Brewester's angle and Total Marks internal reflection 30 Brewester's angle and Total Marks internal reflection 31 Assignment 11 th 32 Reflection at the surfaces of a conductive medium 33 TEST 34 Reflection at the surfaces of a conductive medium 12 th 35 Surface impedance. Transmission-line analogy

20 Poynting theorem 13 th Interpretation of E x H Power loss in a plane conductor Transmission line as a distributed circuit 14 th Transmission line equation Travelling & standing waves Characteristic impedance 15 th Input impedance of terminated line, Reflection coefficient VSWR, Smith's chart and its applications.

21 Lesson Plan Name of the Faculty: Pawan Discipline: Electrical Engg Semester: 4th Subject: Network Analysis-II Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, -02 Characteristics and Parameters of two port networks Network Configurations 1 Transient response of RC circuit Short circuit Admittance parameters Open-circuit impedance parameters 2 nd Transmission parameters, hybrid parameters 2 Transient response of RL circuit. Condition for reciprocity & symmetry of two-port networks in different parameters 3 rd Condition for reciprocity & symmetry of two-port networks in different parameters Inter-relationships between parameters of two-port network 3. Transient Response of RLC Circuit Inter-relationships between parameters of two-port network

22 Expression of input & output impedances in terms of two port parameters 4 th Inter-connection of two port networks 4 To calculate and verify "Z" parameters of a two port network Analysis of typical two-port networks Image impedances 5 th Terminal pairs or Ports 5 To calculate and verify "Y" parameters of a two port network. Network functions for one-port and two-port networks Concept of poles and zeros in Network functions 6 th Restrictions on pole and zero Locations for driving point functions and transfer functions 6. To determine equivalent parameter of parallel connections of two port network. Restrictions on pole and zero Locations for driving point functions and transfer functions

23 Time domain behavior from the pole-zero plot 7 th Principles of network topology 7 To plot the frequency response of low pass filter and determine half-power frequency. Graph matrices Graph matrices 8 th Graph matrices 8 To plot the frequency response of high pass filter and determine the half-power frequency. Network analysis using graph theory 9 th Network analysis using graph theory Types of filters and their characteristics 9 To plot the frequency response of band-pass filter and determine the band-width. Filter fundamentals

24 Classification of Filter 10 th Analysis & design of prototype high-pass 10 To calculate and verify "ABCD" parameters of a two port network Prototype low-pass Prototype band-pass 11 th Prototype band-reject 11 To calculate and verify "h" parameters of a two port network. M-derived low-pass M-derived high-pass filters 12 th Low-pass filter and high-pass filter with RC & RL circuits 12 To determine equivalent parameter of series connections of two port network. Low-pass filter and high-pass filter with RC & RL circuits

25 Band pass filter with RLC circuit. 13 th Hurwitz polynomials, Properties of Hurwitz polynomials 13 To synthesize a network of a given network function and verify its response Positive real functions, procedure of testing of PRV functions Concept and procedure of network synthesis 14 th Properties of expressions of driving point immitances of LC networks 14 Introduction of P-Spice Foster s I & II Form Cauer s I & II form 15 th RC & RL Network synthesis 15 Foster s & Cauer s form of synthesis of lossy networks.

26 Lesson Plan Name of the Faculty: Rinki Discipline: Electrical Engg. Semester: 6th Subject: Advanced Microprocessor & Microcontroller Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, Introduction to 8086 microprocessor 2 RISC and SISC processors 1 Write a well-documented program for copying 12 bytes from source to destination, on 8086 microprocessor kit. 3 Architecture and pin diagram of nd 4 Architecture and pin diagram of Description of various signals 2 Write a program for 8086 for division of a defined double word (stored in a data segment) by another double word and verify. 6 Register organization of rd 7 Description of address computations & memory segmentation 8 Segment override 3 Write a well-documented program for finding the square root of a given number, on 8086, microprocessor kit. 9 Instruction pipelining,

27 10 Timing diagrams, Addressing modes 4 th 11 Test 4 Write a program using 8086 for finding the square of a given number and verify. 12 Instruction set of nstruction execution timing 5 th 14 Instruction format, Data transfer instructions 5 Write a program for 8086 for finding square of a number using look-up table and verify. 15 Arithmetic instructions 6 th 16 Branch instructions 17 Loop instructions, NOP & HLT instructions, 6 Write a program to control the operation of stepper motor using 8086 microprocessor and 8255 chip.

28 19 Flag manipulation instructions 7 th 20 Logical instructions, Shift & Rotate instructions, 7 Write a program using 8086 to add a series of 16-bit numbers. 21 Directives & operators 22 Interrupts of th 23 Assembly language Programs using To study the architecture of 8051 microcontroller. 24 Assignment 25 The concept of microcontroller 9 th 26 comparison between Microcontrollers & Microprocessors 9 Write a program in 8051 to add and subtract two 8 bit numbers. 27 Architecture and Pin diagram of 8051 microcontroller

29 28 Architecture and Pin diagram of 8051 microcontroller 10 th 29 Memory organization. Special function registers 10 Write an ALP to generate square wave of 10 khz frequency using timer of 8051 microcontroller. 30 External memory, Reset operation. Instruction Set 31 Addressing modes 11 th 32 Arithmetic, Logical. Data transfer 11 To find average of Ten 8-bit numbers 33 Boolean variable manipulation 34 Program branching instructions etc 12 th 35 Programs based on various instructions 12 Write an ALP to interface LED and switches with 8051 microcontroller. 36 Programs based on various instructions

30 37 Timer operation, Timer Mode register 13 th 38 Timer Control register. Timer modes & overflow flag 13 Write a program to find (i) largest number and (ii) smallest number from an array using 8051 microcontroller. 39 Starting, Stopping & controlling the timers 40 Programs for generating square waves of various frequencies. 14 th 41 Serial port operation, UART 14 Write a program to generate square wave of 50 Hz frequency using timer of 8051 microcontroller. 42 Serial port control register, Modes of serial port operation. 43 Serial port baud rate. 15 th 44 Initialization & programming of serial port. Interrupts of 8051, SFRs related to interrupts, processing interrupts, 15 To control the operation of DC motor using 8051 microcontroller. 45 program design using interrupts. Interfacing with LED, DC motors, stepper motors

31 Lesson Plan Name of the Faculty: Pawan Siswal Discipline: Electrical Engg. Semester: 6th Subject: Conventional And Cad Of Electrical Machines Lesson Plan Duration: 15 (January, 2018 to April, 2018 Work Load (/) per (in hours): s-03, General features electrical machine design 2 Limitations of electrical machine design. 1 Yoke design of a transformer. 3 Types of enclosures 4 Heat dissipation 2 nd 5 Temperature rise heating and cooling cycles 2 L.V. & H.V. windings design of a transformer 6 Ratings of machine machines 7 Cooling media used 3 rd 8 Output equation and output coefficient 3 Calculation of losses & efficiency of a transformer 9 Output equation and output coefficient

32 10 Specific electric and magnetic loading 4 th 11 Specific electric and magnetic loading 4 Stator design of an induction motor. 12 Effect of size and ventilation 13 MMF calculation for air gun and iron parts of electrical machines 5 th 14 MMF calculation for air gun and iron parts of electrical machines 5 Rotor design of an induction motor. 15 Gap contraction coefficient 6 th 16 Real and apparent flux densities 6 Calculation of losses & efficiency of an induction motor. 17 Estimation of magnet current of transformers and rotating machines

33 19 Estimation of magnet current of transformers and rotating machines 7 th 20 No load current of transformers and induction motors 7 Stator design of a synchronous machine. 21 Leakage flux and reactance calculations for transformers and rotating machines 22 Leakage flux and reactance calculations for transformers and rotating machines 8 th 23 Design of field magnet 8 Rotor design of a synchronous machine. 24 Assignment 25 Design of transformer 9 th 26 Design of transformer 9 Calculation of losses & efficiency of a synchronous machine. 27 D.C. machines

34 28 D.C. machines 10 th 29 induction motor 10 Armature winding & field winding design of a D.C. motor. 30 induction motor 31 synchronous machine and their performance calculations 11 th 32 synchronous machine and their performance calculations 11 Armature core design of a D.C. motor. 33 TEST 34 Computerization of design Procedures 12 th 35 Computerization of design Procedures 12 Calculation of losses & efficiency of a D.C. motor. 36 Development of Computer program and performance prediction

35 37 Development of Computer program and performance prediction 13 th 38 Optimization techniques Optimization techniques 40 Optimization techniques 14 th 41 Optimization techniques Their applications to design Problems. 43 Their applications to design Problems. 15 th 44 ASSIGNMENT TEST

36 Lesson Plan Name of the Faculty: Pintu Discipline: Electrical Engg. Semester: 6th Subject: Communication System & Technology Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, Modulation, Demodulation 2 Radio Frequency Spectrum, Signals & their classification, Limitations & Advantages of a Communication System 1 To study and analyze various waveform of Digital modulation 3 Comparison of Analog & Digital Communication Systems 4 Historical Perspective 2 nd 5 Modes & Medias of Communication 2 To study different types of Filters. 6 Sources of Noise, External & Internal Noise 7 Noise Calculations 3 rd 8 Noise Figure, Noise Figure Calculation, 3 To study Amplitude Shift Keying (ASK) modulation. 9 Noise Temperature

37 10 Noise in Communication Systems, Band Pass Noise Model 4 th 11 Cascaded States & its Noise Figure Calculation, Signal in presence of Noise 4 To study Frequency Shift Keying (FSK) modulation. 12 Pre-Emphasis & De-Emphasis, Noise Quieting Effect, Capture Effect, 13 Noise in Modulation Systems 5 th 14 Basic definition & derivation for Modulation & Modulation Index 5 To study Phase Shift Keying (PSK) modulation. 15 Modulation & Demodulation of AM 16 Suppressed Carrier Modulation 6 th 6 To study Time Division Multiplexing (TDM). 17 Quadrature Amplitude Modulation

38 19 SSB-SC, DSB-SC, VSB Modulation & Demodulation, 7 th 20 Comparison of various AM Systems, Generation of AM waves. 7 To study Frequency Division Multiplexing (FDM). 21 Basic definition & derivation for Modulation & Modulation Index 22 Generation of FM waves, Comparison between PM & FM 8 th 23 Frequency Spectrum of FM, B.W. & required spectra, Types of FM 8 To study Binary Phase Shift Keying (BPSK) modulation. 24 vector representation of FM, Universal Curve, Multiple FM, 25 Demodulation of FM waves, Demodulation of PM waves, 9 th 26 Comparison between AM & FM 9 To study Phase Locked Loop (PLL). 27 Sampling theory, TDM, FDM

39 28 PAM, PWM, PPM 10 th 29 Modulation & Demodulation techniques of above all 10 To study Pulse amplitude modulation and demodulation. 30 Elements of Pulse Code Modulation 31 Noise in PCM Systems, Bandwidth of PCM Systems 11 th 32 Measure of Information, Channel Capacity 11 To study Pulse width Modulation(PWM). 33 Channel Capacity of PCM System 34 Differential Pulse Code Modulation (DPCM). 12 th 35 Delta Modulation (DM), Digital Modulation-ASK 12 To study Pulse Position Modulation(PPM) 36 FSK, PSK, DPSK

40 37 Transmit & receive antennas 13 th 38 Link budget, line of sight systems 13 To deliver seminar by each student on advance communication system 39 Satellite-link-GT ratio of earth stations 40 VSATS & GPSS 14 th 41 Types of optical fibres - step, index & graded index Multi mode & single mode, attenuation & dispersion in fibres 43 Optical transmitters LEDS & laser Diode 15 th 44 Optical Receivers-PIN & APDS Optical fiber link

41 Lesson Plan Name of the Faculty: Pawan Discipline: Electrical Engg. Semester: 6th Subject: Electrical Power Generation Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03 1 Energy sources, their availability 2 Recent trends in Power Generation 3 Interconnected Generation of Power Plants 4 Load forecasting 2 nd 5 Load curves 6 Load duration curve 7 Base load and Peak load Power Plants 3 rd 8 Connected Load, 9 Maximum demand

42 10 Demand factor 4 th 11 Group diversity factor, Load factor 12 Significance of load factor 13 Plant factor, capacity factor 5 th 14 Selection of unit size, No. of Units, Reserves 15 Cost of power generation, Depreciation, tariff 16 Selection of site 6 th 17 capacity calculations 18 Classification, advantages, disadvantages

43 19 Schematic diagram and working of Thermal Power Stations 7 th 20 Schematic diagram and working of Thermal Power Stations 21 Schematic diagram and working of Nuclear Power Plant 22 Schematic diagram and working of Nuclear Power Plant 8 th 23 ASSIGNMENT 24 TEST 25 Selection of site 9 th 26 capacity calculations 27 capacity calculations

44 28 Classification, advantages, disadvantages 10 th 29 Schematic diagram and working of Hydro Electric Plant 30 Schematic diagram and working of Hydro Electric Plant 31 Schematic diagram and working of Hydro Electric Plant 11 th 32 Schematic diagram and working of Diesel Power Stations 33 Schematic diagram and working of Diesel Power Stations 34 Schematic diagram and working of Diesel Power Stations 12 th 35 ASSIGNMENT TEST

45 Wind 13 th Solar Solar Tidal 14 th Ocean Geothermal sources of Energy fuel cell 15 th Magneto Hydro Dynamic (MHD) system Magneto Hydro Dynamic (MHD) system

46 Lesson Plan Name of the Faculty: Rinki Discipline: Electrical Engg. Semester: 6th Subject: Embedded System & Applications Lesson Plan Duration: 15 (January, 2018 to April, 2018 Work Load (/) per (in hours): s-03 1 Different types of microcontrollers: Embedded microcontrollers 2 External memory microcontrollers 3 Processor Architectures: Harvard V/S Princeton 4 CISC V/S RISC 2 nd 5 Microcontrollers memory types 6 Microcontrollers features: clocking, i/o pins 7 Interrupts, Timers, Peripherals 3 rd 8 Introduction to PIC microcontrollers 9 Architecture and pipelining

47 10 Program memory considerations 4 th 11 Assignments 12 Addressing modes 13 CPU registers 5 th 14 Instruction set, 15 Simple operations, Interrupt logic 16 Timer 2 scalar initialization 6 th 17 Int Service Interrupt service routine 18 Loop time subroutine

48 19 External interrupts and timers 7 th 20 Synchronous serial port module 21 Serial pheriphal device 22 O/p port Expansion 8 th 23 I/p port expansion 24 UART. 25 Development tools/ environments 9 th 26 Assembly language programming style 27 Interpreters, High level languages

49 28 Intel hex format object files, Debugging 10 th 29 Arithmetic operations, Bit addressing 30 Loop control, Stack operation, Subroutines 31 RAM direct addressing 11 th 32 State machines, Oscillators 33 Timer Interrupts 34 Memory mapped I/O. 12 th 35 Interfacing an LCD to the interfacing to ADC

50 Sensors, Interfacing a Stepper Motor 13 th 8051 interfacing to the keyboard Interfacing a DAC to the Interfacing with 8031/51, 8051/31 interfacing to external memory 14 th 8255 Interfacing with 8031/51, 8051/31 interfacing to external memory Music box, Mouse wheel turning PWM motor control, Aircraft Demonstration 15 th Ultra sonic distance measuring, Temperature Sensor Pressure Sensor, Magnetic field Sensor.

51 Lesson Plan Name of the Faculty: Labh Singh Discipline: Electrical Engg. Semester: 6th Subject: Power System-II Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, Transients on a transmission line short circuit of synchronous machine at no load and on full load 1 To draw the operating characteristics of IDMT over current relay. 3 Symmetrical component transformation 2 nd 4 phase shift in star-delta transformation 5 sequence impedances 2 To draw the operating characteristics of IDMT under Voltage relay. 6 Single line to ground fault 7 line to line fault 3 rd 8 double line to ground fault, 3 To draw the operating characteristics of IDMT over Voltage relay 9 open conductor fault.

52 10 Assignment 4 th 11 Test 4 To draw the operating characteristics of Differential current relay. 12 of arc initiation and interruption 13 Restriking voltage transients 5 th 14 Current chopping 5 To draw the operating characteristics of negative sequence relay. 15 Circuit breaker ratings 16 Duties of switch gear 6 th 17 Automatic switch 6 To study 33KV substation 18 Air circuit breaker

53 19 Bulk oil 7 th 20 Minimum oil 7 Single line diagram of electrical power flow of campus 21 Air blast 22 SF 6 CB 8 th 23 Vacuum and DC circuit breakers 8 To study and designing of Earthing / Grounding. 24 Testing of Circuit breaker 25 Essential qualities of relay 9 th 26 Relay classification 9 Study the burden effect on the performance of CT and measure ratio error 27 Principal types of electromagnetic relays

54 28 Attracted armature 10 th 29 Induction disc induction cup types 10 Find out the sequence components of currents in three 1-Phase transformers and 3-Phase transformer and compare their results. 30 Over- current, instantaneous over-current 11 th IDMT, directional and differential relays, distance relays Plain impedance, mho, reactance relays 11 (i) Study over current relay. (ii) Draw the current-time characteristic of an over current relay for TMS=1 & 0.5and PSM=1.25 & Zone of protection, primary and backup protections 12 th Transmission line & feeder protection Pilot wire and carrier current protection, Transforme 12 (i) Study percentage bias differential relay. (ii) Plot the characteristics of a percentage bias differential relay for 20%, 30% and 40% biasing. 36 Generator, motor and bus zone protection.

55 37 Classification of static relays 13 th 38 Amplitude and phase comparators 13 To perform gas actuated Buchholz relay. 39 Block-spike and block-average comparators 40 Rectifier type relays.. 14 th 41 Introduction to digital relay: basic principles. 14 Design and simulation of HV transmission line. 42 Application of microprocessors and computers - recent Trends. 15 th 43 Travelling wave relay, relaying schemes based on microwave and optical fiber link 15 Study filtration and Treatment of transformer oil Determine dielectric strength of transformer oil

56 Lesson Plan Name of the Faculty: Labh Singh Discipline: Electrical Engg. Semester: 6th Subject: Power System-II Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, Transients on a transmission line short circuit of synchronous machine at no load and on full load 1 To draw the operating characteristics of IDMT over current relay. 3 Symmetrical component transformation 2 nd 4 phase shift in star-delta transformation 5 sequence impedances 2 To draw the operating characteristics of IDMT under Voltage relay. 6 Single line to ground fault 7 line to line fault 3 rd 8 double line to ground fault, 3 To draw the operating characteristics of IDMT over Voltage relay 9 open conductor fault.

57 10 Assignment 4 th 11 Test 4 To draw the operating characteristics of Differential current relay. 12 of arc initiation and interruption 13 Restriking voltage transients 5 th 14 Current chopping 5 To draw the operating characteristics of negative sequence relay. 15 Circuit breaker ratings 16 Duties of switch gear 6 th 17 Automatic switch 6 To study 33KV substation 18 Air circuit breaker

58 19 Bulk oil 7 th 20 Minimum oil 7 Single line diagram of electrical power flow of campus 21 Air blast 22 SF 6 CB 8 th 23 Vacuum and DC circuit breakers 8 To study and designing of Earthing / Grounding. 24 Testing of Circuit breaker 25 Essential qualities of relay 9 th 26 Relay classification 9 Study the burden effect on the performance of CT and measure ratio error 27 Principal types of electromagnetic relays

59 28 Attracted armature 10 th 29 Induction disc induction cup types 10 Find out the sequence components of currents in three 1-Phase transformers and 3-Phase transformer and compare their results. 30 Over- current, instantaneous over-current 11 th IDMT, directional and differential relays, distance relays Plain impedance, mho, reactance relays 11 (i) Study over current relay. (ii) Draw the current-time characteristic of an over current relay for TMS=1 & 0.5and PSM=1.25 & Zone of protection, primary and backup protections 12 th Transmission line & feeder protection Pilot wire and carrier current protection, Transforme 12 (i) Study percentage bias differential relay. (ii) Plot the characteristics of a percentage bias differential relay for 20%, 30% and 40% biasing. 36 Generator, motor and bus zone protection.

60 37 Classification of static relays 13 th 38 Amplitude and phase comparators 13 To perform gas actuated Buchholz relay. 39 Block-spike and block-average comparators 40 Rectifier type relays.. 14 th 41 Introduction to digital relay: basic principles. 14 Design and simulation of HV transmission line. 42 Application of microprocessors and computers - recent Trends. 15 th 43 Travelling wave relay, relaying schemes based on microwave and optical fiber link 44 Assignment 15 Study filtration and Treatment of transformer oil Determine dielectric strength of transformer oil 45 Test

61 Lesson Plan Name of the Faculty: Pawan Siswal Discipline: Electrical Engg. Semester: 8th Subject: Advanced Control System Lesson Plan Duration: 15 (January, 2018 to April, 2018 Work Load (/) per (in hours): s-03 1 State variable representation of systems by various methods 2 State variable representation of systems by various methods 3 Solution of state equations-state transition matrix 4 Solution of state equations-state transition matrix 2 nd 5 Transfer function from state variable model 6 Controllability & Observability of state variable model 7 Controllability & Observability of state variable model 3 rd 8 Controllability & Observability of state variable model 9 Observer system

62 10 Phase portrait of linear second order systems. 4 th 11 Method of isoclines 12 phase portrait of second order system with non-linearities 13 phase portrait of second order system with non-linearities 5 th 14 phase portrait of second order system with non-linearities 15 limit cycle, 16 singular points 6 th 17 stability of nonlinear system. 18 stability of nonlinear system.

63 19 Definition, limitations 7 th 20 Use of describing function for stability analysis 21 Describing function of ideal relay 22 Relay with hysteresis & dead zone 8 th 23 Relay with hysteresis & dead zone 24 Saturation/coulomb friction & backlash, 25 Liapunov s 2 nd method 9 th 26 Liapunov s 2 nd method 27 Liapunov s 2 nd method

64 28 Construction of Liapunov Function 10 th 29 Construction of Liapunov Function 30 Construction of Liapunov Function 31 Variation calculus: fundamental concepts 11 th 32 Variation calculus: fundamental concepts 33 Functionals of a single function 34 Functionals of a single function 12 th 35 Fixed end point problems-euler-lagrange equation 36 Fixed end point problems-euler-lagrange equation

65 37 variable end point problem and the transversality conditions 13 th 38 variable end point problem and the transversality conditions 39 variable end point problem and the transversality conditions 40 Limitations of calculus of variation 14 th 41 Limitations of calculus of variation 42 Limitations of calculus of variation 43 Pontryagin s minimum principle 15 th 44 Pontryagin s minimum principle 45 Pontryagin s minimum principle

66 Lesson Plan Name of the Faculty: Pawan Discipline: Electrical Engg. Semester: 8th Subject: Advanced Instrumentations Lesson Plan Duration: 15 (January, 2018 to April, 2018 Work Load (/) per (in hours): s-03 1 Functional block diagram of generalized Instrumentation system. 2 Functional block diagram of generalized Instrumentation system. 3 Input-output configuration 4 Input-output configuration 2 nd 5 Input-output configuration 6 Specifications under steady and transient state & their performance characteristics. 7 Specifications under steady and transient state & their performance characteristics. 3 rd 8 9 Specifications under steady and transient state & their performance characteristics. Temperature

67 10 Temperature 4 th 11 Temperature 12 Pressure 13 Pressure 5 th 14 displacement, 15 displacement, 16 Velocity 6 th 17 Velocity 18 Acceleration

68 19 Acceleration 7 th 20 Strain and torque type. 21 Strain and torque type. 22 Current & voltage sensitive bridges 8 th 23 Current & voltage sensitive bridges 24 Blumlein Bridges 25 Shielding & grounding 9 th 26 Shielding & grounding 27 Instrumentation Amplifier & its Characteristics

69 28 Instrumentation Amplifier & its Characteristics 10 th 29 Linearizing circuits 30 Wave form and frequency conversion 31 Wave form and frequency conversion 11 th 32 Acitve filters 33 Acitve filters 34 A/D & D/A converters 12 th 35 A/D & D/A converters 36 Balanced modulators & demodulators

70 37 Balanced modulators & demodulators 13 th 38 Interfacing of 8051 Microcontroller with (a) ADC and DAC 39 Interfacing of 8051 Microcontroller with (a) ADC and DAC 40 Interfacing of 8051 Microcontroller with Alphanumeric Devices (Sixteen-segment Display 14 th 41 Interfacing of 8051 Microcontroller with Alphanumeric Devices (Sixteen-segment Display 42 Interfacing of 8051 Microcontroller with Dot Matrix Displays 43 Interfacing of 8051 Microcontroller with Dot Matrix Displays 15 th 44 Interfacing of 8051 Microcontroller with LCD Display 45 Interfacing of 8051 Microcontroller with LCD Display

71 Lesson Plan Name of the Faculty: Labh Singh Discipline: Electrical Engg Semester: 8th Subject: CAPSA Lesson Plan Duration: 15 (January, 2018 to April, 2018) Work Load (/) per (in hours): s-03, Power Flow equations 2 Circle diagram 1 Draw the flow chart and develop the computer program for the formation of the Y Bus of a generalized network 3 Travelling waves in power Systems 4 Introduction to graph theory 2 nd 5 Tree graph 2 Draw the flow chart and develop the computer program for the formation of the Z Bus of a generalized network 6 Tree graph 7 Co-tree etc 3 rd 8 Co-tree etc 3 To plot the swing curve and observe the stability 9 Bus Admittance Matrix

72 10 Formation of Y Bus 4 th 11 Primitive admittance matrix 4 To perform load flow study using Gauss-Siedel method. 12 Bus Incidence matrix 13 Formulation of Y Bus using singular transformation 5 th 14 Formation of twing admittance matrix 5 Perform short circuit study for any type of fault 15 Formation of twing admittance matrix 16 Formation of Z loop 6 th 17 Bus Impedance matrix 6 To observe transmission losses and efficiency with variations in power for the given example 18 Algorithm for formulation of Z- Bus

73 19 Algorithm for formulation of Z- Bus 7 th 20 All types of modifications 7 Design of distribution system 21 All types of modifications 22 Load flow equations 8 th 23 Approximate Load flow study 8 To study the features of EMTP 24 Gauss-Seidel method for Load flow Study 25 Gauss-Seidel method for Load flow Study 9 th 26 Algorithm and flow Chart for Computer application to Load flow studies 9 To study the MATLAB Power System block set features 27 Newton-Raphson method for Load flow studies

74 28 Newton-Raphson method for Load flow studies 10 th 29 Algorithm and flow chart for Computer Application Decoupled Load flow Studies 31 Decoupled Load flow Studies 11 th 32 Fast Decoupled Load flow Fast Decoupled Load flow 34 Comparison between G-S & N-R methods 12 th 35 Comparison between G-S & N-R methods Symmetrical Components

75 37 Sequence networks for synchronous machines 13 th 38 Transforms and transmission Lines Transforms and transmission Lines 40 Single line to ground fault 14 th 41 Line to Line fault Double line to Ground fault 43 symmetrical fault 15 th 44 Consideration of Pre fault currents Consideration of Pre fault currents

76 Lesson Plan Name of the Faculty: Ankit Aryan Discipline: Electrical Engg Semester: 8th Subject: Electrical Power Quality Lesson Plan Duration: 15 (January, 2018 to April, 2018 Work Load (/) per (in hours): s-03 1 Power Quality 2 Concern in Power System 3 Power Quality Issues 4 Power Quality Issues 2 nd 5 Standards of Power Quality 6 Sources of Sags and Interruptions 7 Fundamental Principles of Protection 3 rd 8 Solutions at End User Level 9 Solutions at End User Level

77 10 Comparison of Different Ride-Through Alternatives 4 th 11 Comparison of Different Ride-Through Alternatives 12 Comparison of Different Ride-Through Alternatives 13 Sources of Transient Overvoltages 5 th 14 Principles of Overvoltage Protection 15 Devices for Overvoltage Protection 16 Devices for Overvoltage Protection 6 th 17 Strategies for Utility System Lightning Protection 18 Switching Transient Problems with Loads

78 19 Harmonics Distortion 7 th 20 Power System Quantities under Nonsinusoidal Conditions 21 Harmonic Indices 22 Harmonics Sources from Commercial and Industrial Loads 8 th 23 Harmonics Sources from Commercial and Industrial Loads 24 Effects of Harmonic Distortion on Power System Equipments 25 Reasons for Grounding 9 th 26 Typical Wiring and Grounding Problems 27 Solutions to wiring and Grounding Problems

79 28 Power Quality Monitoring and its Objective 10 th 29 Power Quality Measurement Equipments 30 Power Quality Measurement Equipments 31 Power Quality Evaluation 11 th 32 Power Quality Evaluation 33 Different Power Quality Indices used in Power Quality Evaluation 34 Different Power Quality Indices used in Power Quality Evaluation 12 th 35 Passive Filters 36 Active Filters

80 37 Hybrid Filters 13 th 38 STATCOM 39 DSTATCOM 40 DVR 14 th 41 UPQC 42 Distributed Generation and its Advantages and Disadvantages 43 Different Distributed Generation Technologies 15 th 44 Different Interfacing Electrical Systems 45 Power Quality Issues in Distributed Generation

81 Lesson Plan Name of the Faculty: Ankit Aryan Discipline: Electrical Engg. Semester: 2 nd Sem Subject: Principal of Electrical Engg. Lesson Plan Duration: 15 (January, 2018 to April, 2018 Work Load (/) per (in hours): s-03, -02 Basic concepts of electric circuits, Energy sources, Ohm s Law, Kirchhoff s laws, Node land Loop Analysis 1 To verify KCL and KVL The venin s and Norton s theorem The venin s and Norton s theorem 2 nd Reciprocity and Maximum Power Transfer Theorem 2 To verify Thevenin s & Norton's Theorems Reciprocity and Maximum Power Transfer Theorem Superposition and Milliman s Theorem 3 rd Superposition and Milliman s Theorem 3 To verify maximum power transfer theorem in D.C. Circuit Star-Delta or delta-star transformation

82 Star-Delta or delta-star transformation 4 th Problems 4 To verify reciprocity theorem Problems Sinusoidal signal, Phasors, Polar & rectangular, exponential & trigonometric representations. 5 th Sinusoidal signal, Phasors, Polar & rectangular, exponential & trigonometric representations. 5 To verify Superposition theorem Resistance, Inductance & Capacitance components Phasors relationship f o r elements circuit 6 th Instantaneous & peak values, average value 6 To study frequency response of a series R-L-C circuit and determine resonant frequency & Q- factor for various Values of R, L, C RMS values, Power,

83 Behavior of AC series 7 th Parallel circuits 7 To study frequency response of a parallel R-L-C circuit and determine resonant frequency & Q -Factor for various values of R, L, C. Series and parallel resonance Series and parallel resonance 8 th Problems 8 To perform direct load test of a transformer and plot efficiency Vs load characteristic Problems Phase and line 9 th voltages and currents, 9 To perform direct load test of a D.C. shunt generator and plot load voltage Vs load current curve Balanced star and delta circuits

84 Power equation 10 th Measurement of power by two wattmeter method To study various type of meters. Measurement of power by two wattmeter method Moving coil type instruments 11 th Moving coil type instruments Measurement of power by three voltmeters / three ammeters method. Moving iron type instruments Electro dynamo type wattmeter 12 th Induction type Energy meter Measurement of power in a three phase system by two watt meter method Ampere s law, Mutual Inductance

85 Construction of transformer 13 th Working principle Phasor diagrams of Single-phase transfor EMF equation 14 th Equivalent circuit of Singlephase transformer Testing, efficiency and regulation of single-phase transformer, Auto transformer Construction and working principle of dc motor and generator, Characteristics of dc motor and generator 15 th Construction and working principle of3-phase Induction machines Construction and working principle 3-phase synchronous machines, Torque- speed characteristics

86