Teacher: HEENA BHALLA File Name: LP- EEC 501-HB ... - ABES IT

Teacher: HEENA BHALLA File Name: LP- EEC 501-HB.docSubject Code: EEC-501Subject: INTEGRATED CIRCUITSSession 2012-13 Group 10ECA, 10ECBLect.No.Ref.Pt.Topics to be coveredUNIT-I Analog Integrated circuit Design: an overview1 1.1 The 741 IC Op-Amp: Bias circuit, short circuit protection circuitry, the inputstage e, the second stage, the output stage2 1.2 device parameters3 1.3 Small Signal Analysis of input stage, the second stage, the output stage4 1.4 DC Analysis of 7415 1.5 A Simplified Model, Slew Rate, Relationship Between ft and SR FrequencyResponse of 741,6 1.6 Current Mirrors using BJT and MOSFETs, Simple current Mirror, Basecurrent compensated current Mirror7 1.7 Widlar Current source8 1.8 Cascode current MirrorUNIT- II Linear Applications of IC op-amps9 2.1 An Overview of Op-Amp (ideal and non ideal) based Circuits V-I and I-Vconverters,10 2.2 Generalized Impedance converter11 2.3 simulation of inductors12 2.4 Filters: First and second order LP, HP, BP BS13 2.5 All pass active filters, KHN,Tow-Thomas14 2.6 State Variable Biquad filters15 2.7 Sinusoidal oscillators16 2.8 Sinusoidal oscillatorsUNIT –III Digital Integrated Circuit Design-An Overview17 3.1 CMOS Logic Gate Circuits: Basic Structure CMOS realization of InvertersAND, OR, NAND and NOR Gates18 3.2 Basic Structure CMOS realization of Inverters AND, OR, NAND and NORGates19 3.3 Basic Structure CMOS realization of Inverters AND, OR, NAND and NORGates20 3.4 Latches and Flip flops: The Latch, The SR Flip-flop, CMOS Implementation ofSR Flip-flops21 3.5 Latches and Flip flops: The Latch, The SR Flip-flop, CMOS Implementation ofSR Flip-flops,22 3.6 A Simpler CMOS Implementation of the Clocked SR Flip-flop23 3.7 A Simpler CMOS Implementation of the Clocked SR Flip-flop24 3.8 D Flip-flop CircuitUNIT-IV Non-Linear applications of IC Op-amps26 4.1 Log–Anti Log Amplifiers27 4.2 Precision Rectifiers, Peak Detectors28 4.3 Simple and Hold Circuits, Analog Multipliers and their applications.29 4.4 Op-amp as a comparator

4.5 Zero crossing detector, Schmitt Trigger30 4.6 Astable multivibrator31 4.7 Monostable multivibrator,32 4.8 Generation of Triangular WaveformsUNIT-V D/A and A/D converters33 5.1 Integrated Circuit Timer: The 555 Circuit, Implementing a MonostableMultivibrator Using the 555 IC34 5.2 Astable Multivibrator Using the 555 IC35 5.3 Phase locked loops (PLL): Ex-OR Gates and multipliers as phase detectors,36 5.4 Ex-OR Gates and multipliers as phase detectors37 5.5 Block Diagram of IC PLL38 5.6 Working of PLL39 5.7 Application of PLLText Book:[1] Sedra and Smith, “Microelectronic Circuits”, 4thEdition, Oxford University Press.Reference Books[2] Michael Jacob, `Applications and Design with Analog Integrated Circuits’, PHI, 2Nd Edn, 2006[3]Jacob Milliman and Arvin Grabel, “Microelectronics”, 2Nd Edition, TMH, 2008.Teacher: SwatiSubject Code: EEC-502Session: 2012-13File Name: LP-EEC502-SWS.docSubject Name: POCGroup: 10ECA, 10ECBLect.No.Ref.Pt.Topics to be coveredUnit 11 1.1 Introduction2 1.2 Communication channelsNeed for modulation, Baseband and Pass band signals3 1.3 Amplitude Modulation : Double side band without Carrier (DSB-SC)4 1.4 DSB-SC Modulator and demodulator5 1.5 Double side band with Carrier (DSB-C) and its Modulator & demodulator6 1.6 Single Side Band Modulation, SSB Modulator & Demodulators7 1.7 Vestigial Side Band (VSB), Quadrature Amplitude Modulator8 1.8 Radio Transmitter and Receiver.9 1.8 Radio Transmitter and Receiver continued….Unit 210 2.1 Angle Modulation11 2.2 Arbitrary Modulated FM12 2.3 Tone Modulated FM Signal13 2.4 FM Modulators14 2.5 FM Demodulator15 2.6 Approximately Compatible SSB Systems16 2.7 Stereophonic FM Broadcasting17 2.8 Examples Based on Mat Lab.Unit 3

18 3.1 Pulse Modulation Digital Transmission of Analog Signals, SamplingTheorem19 3.2 Sampling theorem’s Applications, Pulse Amplitude Modulation (PAM)20 3.3 Pulse Width Modulation, Pulse Position Modulation21 3.4 Generation and Demodulation of PPM,PWM &PAM22 3.5 Digital Representation of Analog Signals23 3.6 Pulse Code Modulation (PCM), PCM System24 3.7 Issues in digital transmission, Frequency Division Multiplexing25 3.8 Time Division Multiplexing26 3.9 Line Coding and their Power Spectral density27 3.10 T1 Digital System28 3.11 TDM HierarchyUnit 429 4.1 Differential Pulse Code Modulation30 4.2 Delta Modulation, Adaptive Delta Modulation,31 4.3 Voice Coders32 4.4 Sources of Noises , Frequency domain representation of Noise33 4.5 Super position of Noises, Linear filtering of Noises34 4.6 Mathematical Representation of Noise,Unit 535 5.1 Noise in Amplitude Modulation: Analysis of noise in SSB-SC systems36 5.2 Analysis of noise in DSB-SC systems37 5.3 Analysis of noise in DSB-C systems38 5.4 Noise in Frequency Modulation39 5.5 Pre emphasis ,De Emphasis and SNR Improvement40 5.6 Phase Locked Loops Analog and DigitalTeacher: Anagha Chougaonkar File Name: LP-EEC503Subject Code: EEC-503 Subject MicroprocessorSession: 2011-12 Group 10ECALect. Ref. Pt. Topics to be coveredNo.Unit 11 1.1 Introduction2 1.2 Microprocessor architecture and its operation,3 1.3,1.4 Overview of memory and I&O devices, Memory interfacing4 1.5 The 8085 MPU, Example of an 8085 based computerUnit 25 2.1 Basic interfacing concepts,6 2.2,2.3 Interfacing input devices, Interfacing output displays7 2.4,2.5 Memory mapped I/O, Flow chart symbols8 2.6 Data Transfer operations, Arithmetic operations9 2.7 Logic Operations, Branch operation,10 2.8 Writing assembly language programs ,Programming techniques: looping,counting and indexing.

11 Rivision on above topicsUnit 312 3.1 Additional data transfer and 16 bit arithmetic instruction13 3.2 Arithmetic operations related to memory, Logic operation: rotate,compare,14 3.3 Illustrative program: Hexadecimal counter, zero-to-nine15 3.4 (module ten) counter, generating pulse waveforms16 3.5 debugging counter and time delay,17 3.6 Stack, Subroutine18 3.7 Restart, Conditional call and return instructions19 3.8 Advance subroutine concepts20 3.9,3.10 The 8085 Interrupts, 8085 vector interruptsUnit 421 4.1 Program: BCD-to-Binary conversion22 4.2 Binary-to-BCD conversion, BCD-to-Seven segment code converter23 4.3 Binary-to-ASCII and ASCII-to-Binary code conversion,24 4.4 BCD Addition, BCD Subtraction25 4.5 Introduction to Advance instructions and Application26 4.6 Multiplication, Subtraction with carry.Unit 527 5.1 8255 Programmable peripheral interface28 5.2 Interfacing keyboard and seven segment display29 5.3 8254 (8253) programmable interval timer30 5.4 8259A programmable interrupt controller,31 5.5 Direct Memory Access and 8237 DMA controller.32,33 5.6 Introduction to 8086 microprocessor: Architecture of 8086 (Pindiagram, Functional block diagram, Register organization).34 RevisionTeacher:File Name:Manvi SharmaLP-EEC503-MS.DocSubject Code: EEC-503 Subject Name: MicroprocessorSession: 2012-13 Group: 10ECBLect.No.Ref.Pt.Topics to be coveredUnit i: Introduction of Microprocessor1. 1.1 Introduction of Microprocessor(MPU) and classification of MPU2. 1.2 MPU architecture and its operations,3. 1.3 Memory and Input& output devices4. 1.4 Logic devices for interfacing,5. 1.5Memory Interfacing, Memory read and write cycle

Lect. Ref.Topics to be coveredNo. Pt.6. 1.6 Example of an 8085 based computer7. 1.7The 8085 MPUUnit ii: Basic interfacing concept8. 2.1 Interfacing Input devices and output devices9. 2.2 Memory mapped I/O,10. 2.3 Arithmetic and logic operations11. 2.4 Writing assembly language program12. 2.5 programming technique: looping ,13. 2.6Programming counting and indexing14. 2.7Flow chart and Data transfer operationUnit iii: Instruction Set15. 3.1 Additional data transfer and 16-bit arithmetic instruction16. 3.2 Arithmetic operation related to memory17. 3.3 Logic operation: rotate, compare and counter and time delay18. 3.4 Hexadecimal counter, zero-to nine, pulse waveform,19. 3.5 Time delay, stack subroutine ,Restart, conditional call and return instruction20. 3.6 8085- Interrupt21. 3.78085 vector interrupt22. 3.8debugging counterUnit IV: Programs23. 4.1 BCD to binary conversion24. 4.2 Binary -to -ASCII,ASCII-to-binary code conversion, BCD addition25. 4.3 Introduction of advance instruction and application26. 4.4 Multiplication ,27. 4.5Substraction with carry and BCD substraction28. 4.6BCD to seven segment code converterUnit V: Interfacing29. 5.1 8255 PPI, Interfacing Keyboard and SSD(Seven segment display)30. 5.2 Programmable timer(8254)31. 5.3 Programmable interrupt controller(8259)32. 5.4 DMA33. 5.5 DMA controller(8237)34. 5.6 8086-MPU introduction,35. 5.7 8086-pin diagram and register organization

Teacher: RUCHI GUPTA File Name: LP-EEC504-RUG.docSubject Code: EEC504 Subject Name: Antenna & wave propagation.Session: 2012 Group: 10ECA, 10 ECBLect.No.Ref. Pt.Topics to be coveredUNIT 1: ANTENNA BASICS1 1.1 Introduction, Basic Antenna parameters, Patterns, Beam Area2-3 1.2 Radiation Intensity, Beam Efficiency, Directivity D and Gain G4 1.3 Directivity and Resolution ,Antenna Apertures, Effective Height5 1.4 The radio Communication Link, Fields from Oscillating Dipole6 1.5 Single-to-Noise Ratio(SNR), Antenna Impedance, Retarded Potential7-8 1.6 Far Field due to an alternating current element, Power radiated by aCurrent element9-10 1.7 Field variation due to sinusoidal current distributionUNIT 2: POINT SOURCES AND THEIR ARRAYS11 2.1 Introduction, Point Source, Power Theorem and its application to anisotropic source12-132.2 Radiation Intensity, Arrays of two isotropic point sources, Non Isotropicbut similar point sources14 2.3 Principle of pattern multiplication ,Pattern Synthesis by PatternMultiplication15 2.4 Linear Arrays of n Isotropic Point Sources of Equal Amplitude andSpacing16-172.5 Linear Broadside Arrays with Non-Uniform amplitude Distributions.General Considerations.ELECTRIC DIPOLES,THIN LINEAR ANTENNAS AND ARRAYSOF DIPOLES AND APERTURES18 2.6 The Short Electric Dipole, The Fields of a short dipole,19 2.7 Radiation Resistance of Short Electric Dipole ,Thin Linear Antenna20 2.8 Radiation Resistance of lamda/2, Antenna,21 2.9 Array of two driven lamda /2 Element: Broadside Case and End –FireCase22 2.10 Horizontal Antenna Above a plane ground, Vertical Antenna Above aplane ground,23 2.11 Yagi-Uda antenna design ,Long Wire Antennas, Folded Dipole AntennasUNIT 3:24 3.1 The Loop antenna ,Design and its Characteristics Properties25-2627 3.3 Slot Antenna, Horn antennas, Helical Antenna28 3.4 The Log-Periodic Antenna, Micro strip Antenna3.2 Application of Loop antennas ,Far Field Pattern of Circular loop Antennaswith Uniform Current

UNIT 4: REFLECTOR ANTENNAS29 4.1 Flat Sheet Reflectors, Corner Reflector30 4.2 The Parabola-general Properties, The paraboloidal Reflector ,31 4.3 Patterns of Large Circular Apertures with Uniform iIIumination32 4.4 Reflector Types(summarized),Feed Methods for parabolic reflectors4.5 ANTENNA MEASUREMENTS33 4.6 Introduction ,Antenna measurement ranges34 4.7 Radiation Pattern Measurements, Gain and Directivity Measurements35 4.8 Spectrum AnalyzerUNIT 5: GROUND WAVE PROPAGATION36 5.1 Plane Earth Reflection, Space Wave and Surface WaveSPACE WAVE PROPAGATION37 5.2 Introduction, Field Strength Relation, Effects of Imperfect Earth, Effectsof Curvature of EarthSKY WAVE PROPAGATION38 5.3 Introduction structural Details of the ionosphere, Wave propagationMechanism39 5.4 Refraction and reflection of Sky Waves by ionosphere, Ray path40 5.5 Critical Frequency, MUF, LUF ,OF41 5.6 Virtual Height and Skip Distance42 5.7 Relation Between MUF and Skip Distance43 5.8 Multi Hop propagation ,wave characteristicsTeacher Richa Singh File Name : LP-EHU501-RIS.docSubject Code: EHU-501 Subject Name: Engineering & Managerial EconomicsSession 2012-13 Groups : 10CSA, 10CSB, 10ECA, 10ECB & 10EEELect.No.Ref.Pt.Topics to be covered2 UNIT II: BASIC CONCEPTS1 2.1,2.2 Demand Analysis, Law of Demand,Determinates of Demand,2 2.3.1 Elasticity of Demand- Price3 2.3.2 Measures to calculate Elasticity of Demand4 2.3.3,2.3.4Income Elasticity of Demand,Cross Elasticity of Demand5 2.3.5 Uses of Concept of Elasticity of Demand in Managerial Decision.6 2.4 Assignment7 2.5 Case Study1 UNIT I: INTRODUCTION8 1.1Introduction &Meaning of Economics,

9 1.2 Nature & Scope of Economics, Managerial Economics10 1.3,1.4Meaning of Science, Engineering and Technology.Scope of Managerial Economics in Engineering Perspective.11 1.5 Assignment3UNIT III: DEMAND FORECASTING12 3.1 Meaning, Significance and Methods of Demand Forecasting,13 3.1 Production Function,14 3.2.1 Laws of Returns to Scale &15 3.2.2 Law of Diminishing Returns to Scale16 3.3 An Overview of Short Run & Long Run Cost Curves Fixed Cost, Variable Cost, Average Cost, Marginal Cost & Opportunity Cost.17 3.4 Presentation By Students18 3.5 Presentation By Students4UNIT IV: MARKET STRUCTURE19 4.1 Perfect Competition,20 4.1 …21 4.2.1,4.2.2,Imperfect Competition –Monopolistic, Oligopoly & Duopoly4.2.322 4.3 Sorbent Features of Price Determination and Various Market Conditions23 4.4 Presentation By Students24 4.5 Presentation By Students25 5 UNIT V: NATIONAL INCOME, INFLATION AND BUSINESSCYCLES5.1 Concept of N.I. and Measurement.26 5.2 Inflation, Meaning of Inflation, Types of Inflation, Causes of Inflation, Prevention Methods of Inflation.27 5.3 Phases of Business Cycle.28 5.4 Presentation By Students29 5.5 Presentation By Students30 5.6 Doubt SessionTeacher Vaibhav Jain File Name: LP-EIC501-VJ.docSubject Code EIC-501 Subject Name Control System-ISession 2010-11 Group 10ECA & 10ECBNo. ofLectureRef.Pt.Name of the TopicUNIT – I

1 1.1 Basic Components of a control system2 1.2 Feedback and its effect, types of feedback control systems.3, 4 1.3 Block diagrams Algebra5, 6 1.4 Signal flow graph, Mason’s gain formula7 1.5 Mechanical systems elements, equations of mechanical systems8, 9 1.6 Modelling of Physical systems: electrical networks10 1.7 Sensors and encoders in control systems, DC motors in control systems.UNIT – II11 2.1 State-Variable Analysis: Vector matrix representation of state equation12 2.2 State transition matrix13 2.3 State-transition equation, Solved examples14 2.4 Relationship between state equations and high-order differential equations15 2.5 Relationship between state equations and transfer functions.16 2.6 Controllability and observability and their testing17 2.7 Observability and their testingUNIT – III18 3.1 Time domain Analysis of Control Systems19 3.2 Time response of continuous data systems20 3.3 Typical test signals for the time response of control systems21 3.4 The unit step response and time-domain specifications22 3.5 Steady-State error of different system23 3.6 Time response of a first order system24 3.7 Transient response of a prototype second order system.UNIT – IV25 4.1 Stability of Linear Control Systems26 4.2 Bounded-input bounded-output stability continuous data systems27 4.3 Zero-input and asymptotic stability of continuous data systems28 4.4 Asymptotic stability of continuous data systems29 4.5 Methods of determining stability30, 31 4.6 Routh Hurwitz criterion with solved examples.UNIT – V32 5.1 Frequency Domain Analysis: Mr (resonant peak) and ωr (resonant frequency)33 5.2 Bandwidth of the prototype Second order system34 5.3 Effects of adding a zero to the forward path35 5.4 Effects of adding a pole to the forward path36, 37 5.5 Nyquist stability criterion38 5.6 Relative stability: gain margin and phase margin

39, 40 5.7 Stability analysis with the Bode plot41 5.8 Previous year Question Papers DiscussionText Book:-1B.C. Kuo & Farid Golnaraghi, “Automatic Control System” Wiley IndiaLtd,2008.Reference Books:-1 S. Mise, Control System Engineering 4th edition, Wiley Publishing Co.Ajit K Mandal, “Introduction to Control Engineering” New Age2International,2006.3 R.T. Stefani, B.Shahian, C.J.Savant and G.H. Hostetter, “ Design of FeedbackControl Systems” Oxford University Press4 N.C. Jagan, “ Control Systems”, B.S. Publications,2007.PRACTICAL LAB PLANTeacher: HEENA BHALLA Subject Code: EEC 551Subject Name: INTEGRATED CIRCUITS LABSession: 2012-2013 Group: 10ECA, 10ECBA. LIST OF EXPERIMENTS AS PER UNIVERSITY SYLLABUSClass Ref. Name of experimentNo. No.1. 1.1 Log and antilog amplifiers2. 1.2 Voltage comparator and zero crossing detectors3. 1.3 Second order filters using operational amplifier for–a. Low pass filter of cutoff frequency 1 KHz.b. High pass filter of frequency 12 KHz.4. 1.4 Second order filters using operational amplifier for–c. Band pass filter with unit gain of pass band from 1 KHz to 12 KHz.5. 1.5 Wien bridge oscillator using operational amplifier6. 1.6 Determine capture range; lock in range and free running frequency ofPLL7. 1.7 Voltage regulator using operational amplifier to produce output of 12Vwith maximum load current of 50mA.8. 1.8 A/D and D/A convertor

9. 1.9 Voltage to current and current to voltage convertors.10. 1.10 Function generator using operational amplifier (sine, triangular & squarewave)11. 1.11 Astable and monostable multivibrator using IC 555B. LAB EVALUATION/MARKING SCHEMENOTE: This is also tentative and only suggestive.Total internal marks: 20Attendance marks: 5Lab Record: 5Internal Viva/Quiz 10Teacher SWATISession 2012-13Subject Code EEC-552 Subject Name Communication Lab-IGroup 10ECA, 10ECBNo.of Ref. List of experiment as per MTU syllabusTurns No.1. 1.1 To study DSB/ SSB amplitude modulation & determine its modulationfactor & power in side bands2. 1.2 To study amplitude demodulation by linear diode detector.3. 1.3 To study frequency modulation and determine its modulation factor4. 1.4 To study PLL 565 as frequency demodulator5. 1.5 To study sampling and reconstruction of Pulse Amplitude modulationsystem.6. 1.6 To study Pulse Amplitude Modulationa. using switching methodb. by sample and hold circuit.7. 1.7 To demodulate the obtained PAM signal by 2nd order LPF.8. 1.8 To study Pulse Width Modulation and Pulse Position Modulation9. 1.9 Design and implement an FM radio receiver in 88-108 MHz.10. 1.10 Internal VivaTeacher: Anagha Chougaonkar File Name: LP-EEC553Subject Code: EEC-553 Subject Microprocessors LabSession: 2012-13 Group 10ECA

EXPERIMENTNO.Ref.Pt.NAME OF PRACTICAL1 1.1 Write a program using 8085 Microprocessor for Decimal, Hexadecimaladdition and subtraction of two numbers.2 1.2 Write a program using 8085 Microprocessor for addition and subtractionof two BCD numbers.3 1.3 To perform multiplication and division of two 8 bit numbers using 8085.4 1.4 To find the largest and smallest number in an array of data using 8085instruction set.5 1.5 To write a program to arrange an array of data in ascending anddescending order6 1.6 To convert given Hexadecimal number into its equivalent ASCII numberand vice versa using 8085 instruction set.7 1.7 To write a program to initiate 8251 and to check the transmission andreception of character.8 1.8 To interface 8253 programmable interval timer to 8085 and verify theoperation of 8253 in six different modes9 1.9 To interface DAC with 8085 to demonstrate the generation of square, sawtooth and triangular wave.INTERNAL EXAMTeacher: Manvi SharmaSession:2012-13Subject Code: EEC-553 Subject Name: Microprocessor LabGroup:10ECBNo. of List of experimentTurns1. 1.1 Write a program using 8085 Microprocessor for Decimal, Hexadecimaladdition and subtraction of two Numbers.2. 1.2 Write a program using 8085 Microprocessor for addition and subtraction oftwo BCD numbers3. 1.3 Perform multiplication and division of two 8 bit numbers using 8085.4. 1.4 To find the largest and smallest number in an array of data using 8085instruction set.5. 1.5 To write a program to arrange an array of data in ascending and descendingorder.

6. 1.6 To convert given Hexadecimal number into its equivalent ASCIInumber and vice versa using 8085 instruction set.7. 1.7 To write a program to initiate 8251 and to check the transmission andreception of character.8. 1.8 To interface 8253 programmable interval timer to 8085 and verify theoperation of 8253 in six different modes.9. 1.9 To interface DAC with 8085 to demonstrate the generation of square, sawtooth and triangular wave10. 1.10 Internal VivaTeacher: VAIBHAV JAIN Subject Code: EIC-551Subject Name: CONTROL SYSTEM LAB Session: 2012-13Group: 10ECA & 10ECBA. LIST OF EXPERIMENTS AS PER UNIVERSITY SYLLABUSClass Ref. Name of experimentNo. No.1. 1.1 SYNCHRO TRANSMITTER / RECEIVERTo study of Synchro Transmitter in term of Position v/s Phase andvoltage magnitude with respect to Rotor Voltage Magnitude/Phase2. 1.2 DC SPEED CONTROL SYSTEM(a) To study D.C. speed control system on open loop and close loop.(b) To study of Transient performance, another time signal is added atthe input of control Circuit.(c) To study how current breaking eddy is being disturbance rejected byclose and open loop.3. 1.3 DC MOTOR POSITION CONTROL(a) To study of potentiometer displacement constant on D.C. motorposition control.(b) To study of D. C. position control through continuous command.(c) To study of D.C. position control through step command.(d) To study of D.C. position control through Dynamic response.4. 1.4 AC MOTOR POSITION CONTROL(a) To study of A.C. motor position control through continuouscommand.(b) To study of error detector on A.C. motor position control throughstep command.(c) To study of A.C. position control through dynamic response.5. 1.5 PID CONTROLLER(a) To observe open loop performance of building block and calibration

of PID Controls.(b) To study P, PI and PID controller with type 0 system with delay.(c) To study P, PI and PID controller with type 1 system.6. 1.6 LEAD LAG COMPENSATOR(a) To study the open loop response on compensator.(b) Close loop transient response.7. 1.7 . LINEAR SYSTEM SIMULATOR(a) Open loop response(i) Error detector with gain, (ii) Time constant, (iii) Integrator(b) Close loop system(I) First order system (II) Second order system (III) Third order system8. 1.8 MAGNETIC AMPLIFIER(a) To study Input / Output characteristic of a magnetic amplifier inmode (i) Saturable Reactor, (ii) Self Saturable Reactor.B. LAB EVALUATION/MARKING SCHEMENOTE: This is also tentative and only suggestive.Total internal marks: 20Attendance marks: 5Lab Record: 5Internal Viva/Quiz 10