syllabus - charusat · syllabus secondyear b.tech ... 5. combinational logic with msi and lsi 07 6....

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Second Year B.Tech.Electronics & Communication Engineering

Charotar University of Science & Technology

Faculty of Technology & Engineering

Department of Electronics & Comm. Engineering

Effective From: 2011‐12Authored by: Charusat

Theory Practical Total Internal External Internal External

MA202 Engineering Mathematics - III 4 4 4 30 70 100

EC201 Digital Electronics & Logic Design 4 2 6 5 30 70 25 25 150

EC202 Network Theory 4 2 6 5 30 70 25 25 150

EC203 Solid State Electronics 4 2 6 5 30 70 25 25 150

EE221 Electrical Technology 3 2 5 4 30 70 25 25 150

EC204.01 Electronics Instruments & Measurement 3 2 5 4 30 70 25 25 150

Assignment Practice 2

Student Counselling 2

22 10 36 27 180 420 125 125 850

MA203 Engineering Mathematics - IV 4 4 4 30 70 100

EC207 Control Systems 4 2 6 5 30 70 25 25 150

EC208 Analog Electronic Circuits 4 2 6 5 30 70 25 25 150

EC209 Microprocessors & Microcontoller 4 2 6 5 30 70 25 25 150

EC210 Analog Communication 4 2 6 5 30 70 25 25 150

EM201.01 Fundamentals of Management 4 4 4 30 70 100

Assignment Practice 2

Student Counselling 2

24 8 36 28 180 420 100 100 800

SY S

EM

4

Contact Hrs.

SY S

EM

3

Course title

Teaching Scheme

TotalPracticalSem Course CodeCredits

Theory

Examination Scheme

CHAROTAR UNIVERSITY OF SCIENCE & TECHNOLOGY (CHARUSAT)TEACHING & EXAMINATION SCHEME FOR B TECH ELECTRONICS & COMMUNICATION ENGINEERING

B. Tech. (Electronics & Communication Engineering) Programme

SYLLABI (Semester – 3)

CHAROTAR UNIVERSITY OF SCIENCE AND TECHNOLOGY

CHAROTAR UNIVERSITY OF SCIENCE & TECHNOLOGY

FACULTY OF TECHNOLOGY & ENGINEERING V. T. PATEL DEPARTMENT OF ELECTRONICS & COMMUNICATION

ENGINEERING

B. TECH. (ELECTRONICS & COMMUNICATION)

2ND YEAR SEMESTER: III

EC 201: DIGITAL ELECTRONICS & LOGIC DESIGN ______________________________________________________________________

Credit Hours: Teaching Scheme Theory Practical Total Credit

Hours/week 4 2 6 5

Marks 100 50 150

A. Objective of the Course: This course will introduce the students about fundamentals of digital electronics including number systems, Boolean algebra and logic gates, combinational logic, designing of combinational and sequential circuits.

A. Out line of the Course:

Sr.

No.

Title of the Unit Minimum Number of

Hours

1. Number Systems 03

2. Boolean Algebra and Logic Gates 06

3. Simplification of Boolean Functions 06

4. Combinational Logic 08

5. Combinational Logic With MSI AND LSI 07 6. Sequential Logic 15 7. Registers, Counters and the Memory Unit 15

Total Hours (Theory):60

Total Hours (Lab): 30

Total Hours:90

A. Detailed Syllabus: 1. Number Systems 3 Hrs 5%

1.1 Digital Computer And Digital Systems, Binary Number, Number Base Conversion Octal And Hexadecimal Number

1 Hr

1.2 Complements, Binary Codes 1 Hr

1.3 Binary Storage And Register, Binary Logic, Integrated Circuit 1 Hr

2. Boolean Algebra And Logic Gates 6 Hrs 10%

2.1 Basic Definition, Axiomatic Definition of Boolean Algebra, Minterm And Maxterms

2 Hrs

2.2 Basic Theorem And Properties of Boolean Algebra 3 Hrs

2.3 Logic Operations, Digital Logic Gates, IC Digital Logic Families 1 Hr

3. Simplification of Boolean Functions 6 Hrs 10%

3.1 Two-Three Variable K-Map, Four- Five Variable K-Map 1 Hr

3.2 Product of Sum Simplification, NAND or NOR Implementation 2 Hrs

3.3 Don’t Care Condition 1 Hr

3.4 Tabulation Method 2 Hrs

4. Combinational Logic 8 Hrs 12%

4.1 Introduction, Design Procedure, Hazards 3 Hrs

4.2 Adder, Sub tractor 2 Hrs

4.3 Code Conversion, Universal Gate, Exclusive OR & Equivalence Functions 3 Hrs

5. Combinational Logic With MSI And LSI 7 Hrs 11%

5.1 Introduction, Binary Parallel Adder 1 Hr

5.2 Decimal Adder, Magnitude Comparator 2 Hrs

5.3 Decoder, Multiplexer 2 Hrs

5.4 ROM, PLA, PAL 2 Hrs

6. Sequential Logic 15 Hrs 22%

6.1 Introduction, RS,JK,D,T Flip-Flops, Triggering of Flip-Flops 4 Hrs

6.2 Flip-Flop Excitation Tables, Analysis of Clocked Sequential Circuits 3 Hrs

6.3 State Reduction And Assignment Design Procedure 4 Hrs

6.4 Design of Counters, Design With State Equations 4 Hrs

7. Registers, Counters And The Memory Unit 15 Hrs 23%

7.1 Introduction, Registers, Shift Registers 5 Hrs

7.2 Ripple Counters, Synchronous Counters 5 Hrs

7.3 Timing Sequences, Memory Unit, Johnson Counter 5 Hrs

D. Instructional Method and Pedagogy:

• Multimedia Projector • OHP • Chapter wise Assignments • Quiz • Audio Visual Presentations • Chalk + Board • White Board • Online Demo

E. Student Learning Outcomes:

• To Design combinational circuits on bread board • To design different flip-flops • To simulate on VHDL software

F. Recommended Study Material: Reference Books:

1. Digital Logic and Computer Design By M Morris Mano, PHI- Publication 2002

2. Digital Principles and Application by Malvino & Leach, THI-1999

3. Digital System Design Using VHDL , Charles H. Roth, Thomson,2002

Web Materials/ Reading Material:

http://zebu.uoregon.edu/~rayfrey/432/DigitalNotes.pdf

http://smendes.com/el10b/gates1.gif

1) Lab Manuals

2) Hand Outs

3) Assignments

4) Question Bank



ENGINEERING



EC 202: NETWORK THEORY ______________________________________________________________________


Hours/week 4 2 6 5

Marks 100 50 150

A. Objective of the Course: The objective of the course is to introduce the student to the study fundamentals of Network theory including its concepts, initial and final condition of components, transient ant steady state response , network theorems, two-port network, state space variable analysis, With this they will have the knowledge of how to evaluate any complex network . B. Out line of the Course: Sr.

No.


Hours

1. Basic of Concept and Network Representation 03

2. Basic of Concept and Network Representation 06

3. Time Domain Analysis 10

4. Frequency Domain Analysis 08

5. Impedance Functions and Network Theorems & Network

Functions: Poles and Zeros

04

6. Two Port Parameters 15

7. Sinusoidal Steady -State Analysis 11 8. Frequency Response Plots 03


Total Hours (Lab): 30 Total Hours: 90

C. Detailed Syllabus: 1. Basic Of Concept And Network Representation 3Hrs 5%

1.1 Introduction 1 Hr

1.2 Analysis ,Convention ,Synthesis 1 Hr

1.3 Types of Network 1 Hr

2. Formulation And Transformation 6Hrs 10%

2.1 Kirchoff's Law, The Number of Network Equations, Source Transformations

2 Hrs

2.2 Examples of The Formulations of Networks, Loop Variable Analysis, Node Variable Analysis

3 Hrs

2.3 Determinants: Minors and The Gaus Method, Duality, State Variable Analysis

1 Hr

3. Time Domain Analysis 10Hrs

10%

3.1 Initial Conditions in Networks Differential Equations 2 Hrs

3.2 Second-Order Equation 2 Hrs

3.3 Internal Excitation 2 Hrs

3.4 Networks Excited by External Energy Sources Response As Related To The S-Plane Location of Roots

4 Hrs

4. Frequency Domain Analysis 8Hrs

12%

4.1 Introduction, The Laplace Transformation ,Some Basic Theorems For The Laplace Transformation, Examples of The Solution of Problems With The Laplace

2 Hrs

4.2 Transformation ,Partial Fraction Expansion , Heaviside's Expansion Theorem, Examples of Solution By The Laplace Transformation

2 Hrs

4.3 The Shifted Unit Step Function, The Ramp And Impulse Functions, Waveform Synthesis The Initial And Final Value of F (T) From F (S)

4 Hrs

5. Impedance Functions And Network Theorems & Network Functions: Poles And Zeros 4Hrs

11%

5.1 The Concept of Complex Frequency Transform Impedance And Transforms Circuits Series and Parallel Combinations of Elements

1 Hr

5.2 Superposition And Reciprocity Thevenin's Theorem And Norton's Theorem 1 Hr

5.3 Terminal Pairs or Port Network Functions For The one Port And Two Port, The Calculation of Network Functions Ladder Networkgeneral Networks

1 Hr

5.4 Poles And Zeros of Network Functions ,Restrictions on Pole And Zero Locations For Transfer Functions

1 Hr

6. Two Port Parameters 15Hrs 22%

6.1 Relationship of Two-Port Variables, Short-Circuit Admittance Parameters 4 Hrs

6.2 The Open Circuit Impedance Parameters, Transmission Parameters 5 Hrs

6.3 The Hybrid Parameters, Relationships Between Parameters Sets, Parallel Connections of Two-Port Networks

6 Hrs

7. Sinusoidal Steady -State Analysis 11Hrs 23%

7.1 The Sinusoidal Steady State 3 Hrs

7.2 The Sinusoidal And E +- Jwt, Solution Using E +- Jwt ,Solution Using E +- Jwt or Im E +- Jwt

5 Hrs

7.3 Phasors and Phasor Diagrams 3 Hrs

8. Frequency Response Plots 3Hrs 7%

8.1 Parts of Network Functions , Magnitude And Phase Plots, Complex Loci Plots From S-Plane Phasors , Bode Diagrams, The Nyquist Criterion

3 Hrs


• Multimedia Projector • OHP • Audio Visual Presentations • Chalk + Board • White Board • Online Demo •

E. Student Learning Outcomes :

• To Design a circuit and network. • To analyze circuit characteristics • To identify current and potential value in network. • To simplify any two port network.

F. Recommended Study Material:

Reference Books:

1.Network Analysis By Van Valkenburg,3rd Edition, McGraw-Hill Science/Engineering/Math

2.Circuit and Networks by Sudhakar McGraw-Hill Science/Engineering/Math

3. Network Analysis and Synthesis By G.K.mithal 4.Electrical Circuit Analysis by C.L.Vadhwa, New Age International

Web Materials/ Reading Material: www.educypedia.be/electronics/electricitycircuits.htm www.ebookchm.com/ebook___network-analysis-in-circuit-theory-ppt_.html

1) Lab Manuals 2) Hand Outs 3) Assignments 4) Question Bank



ENGINEERING



EC 203: SOLID STATE ELECTRONICS ______________________________________________________________________


Hours/week 4 2 6 5

Marks 100 50 150

A. Objective of the Course: This course will introduce the students about various analog electronic devices and circuits such as Diodes, Transistor Characteristics, Transistor Biasing and Thermal Stabilization, Field Effect Transistor, Multistage Amplifiers. With this they can design the circuits as per the applications. B. Out line of the Course:

Sr. No. Title of the Unit Minimum Number of

Hours

1. Semiconductor Physics 8

2. Semiconductor Diode Characteristics 8

3. Transistor Characteristics and Transistors Biasing and Thermal Stabilization

10

4. BJT as Small Signal Low Frequency Amplifier 10

5. Field Effect Transistor 8

6. Transistor at High Frequencies 8

7. Multistage Amplifiers 8



Total Hours: 90

C. Detailed Syllabus:

1. Semiconductor Physics 8 Hrs

10%

1.1 The Energy Band Theory of Crystals, Insulators, Semiconductors and Metals, Mobility and Conductivity, Electrons and Holes In An Intrinsic Semiconductor, Donor and Acceptor Impurities, Charge Densities

1 Hr

1.2 Mobility and Conductivity, Electrons and Holes in an Intrinsic

Semiconductor, Donor and Acceptor Impurities, Charge Densities

1 Hr

1.3 Hall Effect, Conductivity Modulation, Generation And Recombination of Charges Diffusion

1 Hr

1.4 Continuity Equation, Injected Minority Carrier Charge, Potential Variation Within a Graded Semiconductor

1 Hr

1.5 Energy Distribution of Electrons in a Metal, Fermi-Dirac Function, Densities of States, Electron Emission From A Metal

2 Hrs

1.6 Carrier Concentration In An Intrinsic Semi, Fermi-Level, Band Structure of An Open-Circuit PN Characteristic, Dynamic Diffusion Capacitance

2 Hrs

2. Semiconductor Diode Characteristics 8 Hrs

10%

2.1 Open-Circuited PN Junction, P-N Junction as A Rectifier, Current Components in A PN Junction Diode

2 Hrs

2.2 Volt-Ampere Characteristics, Photo-Diode, Temperature Dependence of Diode Characteristic, Transition Capacitance (CT), Diffusion Capacitance

3 Hrs

2.3 Diode Resistance, Charge Control Description of A Diode, Rectifiers, Full Wave Circuits, C, LC, II Filters

3 Hrs

3. Transistor Characteristics And Transistors Biasing and Thermal Stabilization 10 Hrs

10%

3.1 Junction Transistor, Transistor Action, Transistor Currents Component, Transistor as a Amplifier

3 Hrs

3.2 Transistor Configurations- CB, CC, CE, CE Cutoff, And Saturation Regions, Maximum Voltage Rating, DC Operating Point

3 Hrs

3.3 Bias Stabilization, Stabilization Techniques, Bias Compensation, Thermal Runaway, Phototransistor

4 Hrs

4. BJT As Small Signal Low Frequency Amplifier 10 Hrs

15%

4.1 Transistor As An Amplifier, General Characteristics Of An Amplifier, Hybrid Model, Determination Of H-Parameters From Characteristics.

2 Hrs

4.2 Analysis Of Amplifier Circuit Using H-Parameters. Common Emitter Circuit, Common Collector Or Emitter Follower Circuit, Common Base Circuit,

3 Hrs

4.3 Analysis Of Common Emitter Amplifier With Collector To Base Bias, Comparison Of Transistor Amplifier Configurations, Linear Analysis Of A Transistor,

3 Hrs

4.4 Miller’s Theorem And It’s Dual, Cascading Transistor Amplifiers, Simplified CE And CC Hybrid Model

2 Hrs

5. Field Effect Transistor 8 Hrs

15%

5.1 Construction Of JFET, Operation Of JFET, JFET Characteristics, Pinch-Off Voltage,

2 Hrs

5.2 JFET Volt-Ampere Characteristics, FET Small Signal, MOSFET, FET As A VVR FET Biasing,

2 Hrs

5.3 Fixed Bias Circuit, Voltage Divider Biasing Circuit, Self Bias Circuit, Biasing For Depletion Type MOSFET,

2 Hrs

5.4 JFET As An Amplifier, JFET Low Frequency Small Signal Model, Common Source Circuit, Common Drain Circuit

2 Hrs

6. Transistor At High Frequencies 8 Hrs

20%

6.1 Hybrid II CE Transistor, Hybrid II Conductance, Hybrid II Capacitance. Validity At Hybrid II Model, Variation Of Hybrid II Parameters

3 Hrs

6.2 CE Short-Circuit Current Gain, Current Gain With Resistive Load, Single Stage CE Transistor Amplifier Response

3 Hrs

6.3 Gain- Bandwidth Product, Emitter Follower At High Frequency 2 Hrs

7. Multistage Amplifiers 8 Hrs

20%

7.1 Classification of Amplifiers, Distortion in Amplifiers, Frequency Response of an Amplifier, Step Response of an Amplifier.

3 Hrs

7.2 Bandpass of Cascaded Stages, Two Stage RC Amplifier, Low Frequency Response of An RC-Coupled Stage. Effect of An Emitter Bypass Capacitor on Low Frequency Response

3 Hrs

7.3 High Frequency Response of Two Cascaded CE Transistor Stages, Multistage CE Amplifier Cascade At High Frequencies

2 Hrs

D. Instructional Methods and Pedagogy

• OHP • Chapter wise Assignments • Quiz • Audio Visual Presentations • Chalk + Board • White Board • Online Demo

D. Student Learning Outcomes:

• Upon completion of this course, students will understand the operation, function and

interaction between various components and its characteristics.

• Students will also get detail study of Rectifiers, Transistor Biasing, H-Parameters,

FET, Multistage Amplifiers. F. Recommended Study Materials

Reference Book & Text Book:

1.Electronics Devices and Circuit Theory ( sixth Edition) by Boylestead & Louis Nashelsky published by Pearson Education Asia 2.Integrated Electronics by Jacob Millman Grable Tata McGraw-Hill Edition 1991

Web Materials / Reading Materials:

www.educypedia.be/electronics/electricitycircuits.htm

1) Lecture notes 2) Handouts 3) Chapter wise Assignment



ENGINEERING



EC 204.01: ELECTRONICS INSTRUMENTS & MEASUREMENTS ______________________________________________________________________


Hours/week 3 2 5 4

Marks 100 50 150

A. Objective of the Course: The objective of the course is to introduce the student fundamentals of Electronics Instruments and Measurement providing an in-depth understanding of Measurement errors, Bridge measurements, Digital Storage Oscilloscope, Function Generator and Analyzer, Display devices, Data acquisition systems and transducers.

B.Out Line of the Course: Sr.

No.


Hours

1. Measurement Errors 03

2. Bridge Measurements 07

3. Digital Instruments 08

4. Digital Storage Oscilloscope 04

5. Function Generator And Analyzer 07

6. Display Devices 09

7. Data Acquisition Systems And Transducers 07



Total Hours: 75

C. Detailed Syllabus: 1. Measurement Errors 3 Hrs 6%

1.1 Introduction to Subject, Definitions 1 Hr

1.2 Accuracy and Precision, Significant Figures, Types of Error 1 Hr

1.3 Statistical Analysis, Probability of Errors, Limiting Errors 1 Hr

2. Bridge Measurements 7 Hrs 15%

2.1 Wheatstone Bridge, Kelvin Bridge 2 Hrs

2.2 AC Bridge And Their Applications, Maxwell Bridge, Hay’s Bridge 1 Hr

2.3 Unbalance Conditions, Wein Bridge 1 Hr

2.4 Anderson’s Bridge, De Sautys Bridge, Schering Bridge 2 Hrs

3. Digital Instruments 8 Hrs 18% 3.1 Digital Frequency Meter, Circuit For Measurement of Frequency,

Simplified Composite Circuit For Digital Frequency Meter High Frequency Measurements

3 Hr

3.2 Period Measurement, Ratio And Multiple Ratio Measurements, Time Interval Measurements, Resolution in Digital Meter Sensitivity of Digital Meters

3 Hrs

3.3 Accuracy Specification of Digital Multimeters, Digital L, C And R Measurements, Digital LCR Meter and Q Meter

2Hr

4. Digital Storage Oscilloscope 4 Hrs 9% 4.1 Introduction, Oscilloscope Block Diagram, Cathode Ray Tube 1 Hr

4.2 Block Diagram Of DSO , Its Principle and Working, Advantages And Applications

2 Hrs

4.3 Special Oscilloscope 1 Hr

5. Function Generator And Analyzer 7 Hrs 16% 5.1 Introduction, The Sine Wave Generator, Frequency Synthesized Signal

Generator 2 Hrs

5.2 Frequency Divider Generator, Vector Signal Generator 1 Hr

5.3 Sweep Frequency Generator, Pulse And Square Wave Generator, Function Generator,

2 Hrs

5.4 Wave Analyzer, Harmonic Distortion Analyzer, Spectrum Analyzer, Logic Analyzer

2 Hrs

6. Display Devices 9 Hrs 20%

6.1 Digital Display Methods, Digital Display Units, Segmental Displays 2 Hrs

6.2 Dot Matrices, Rear Projection Display, Light Emitting Diode, Liquid Crystal Diodes

2 Hrs

6.3 Segmental Gas Discharge Displays, Decade Counting Assembly’s, Display Systems, Decimal Decoders, BCD To 7-Segment Converter

2 Hrs

6.4 BCD To Dot Matrix Converter 1 Hr

6.5 Sensitivity Of Digital Meters, Accuracy Specification of Digital Multimeters

2 Hrs

7. Data Acquisition Systems And Transducers 7 Hrs 16% 7.1 Objective of DAS, signal conditioning of the inputs, single channel DAS 1 Hr

7.2 Electrical transducer, selecting a transducer, resistive transducer 1 Hr

7.3 Strain gauges, resistance thermometer, thermistor, inductive transducer 2 Hrs

7.4 Differential output transducer, LVDT, pressure inductive transducer, capacitive transducer, load cell

2 Hrs

7.5 Piezo electric transducer, photo electric transducer, photo voltaic cell 1 Hr

D. Instructional Methods and Pedagogy

• Multimedia Projector • OHP • Chapter wise Assignments • Quiz • Chalk + Board • White Board • Online Demo • Charts


• To Understand operation of different instruments • To Describe different terminology related to measurements


Text and Reference books:

1. Modern electronics Instrumentation and measurement techniques by Albert D. Helfrick And William D. Cooper

2. Electronic Instruments and Measurements by David Bell

3. A course in Electrical and electronics measurement and instrumentation by A.K.Sawhney, 2nd Edition by Dhanpatrai.

4. Electronic instrumentation by H.S. Kalsi, 2nd Edition ,Tata McGraw Hill Publications

5. Electrical circuit and theory by John bird, 3rd Edition, copyright by Newness.

Web materials/ Reading Material :

http://www.engr.sjsu.edu/bjfurman/courses/ME120/me120pdf/Temperature_measurement.pdf

http://grove.ufl.edu/~jnchung/Uncertainty%20Lecture.ppt

1) Lab Manuals 2) Hand Outs 3) Assignments 4) Question Bank 5) EMI kits

B. Tech. (Electronics & Communication Engineering) Programme

SYLLABI (Semester – 4)

CHAROTAR UNIVERSITY OF SCIENCE AND TECHNOLOGY



ENGINEERING


2ND YEAR SEMESTER: IV

EC207: CONTROL SYSTEMS


Hours/week 4 2 6 5

Marks 100 50 150

A. Objective Of The Course:

The Goals of The Course are To Introduce the Student to Different Types of Control Systems and

Its Characteristics. It Also Shows Different Representation Ways of Control Systems To Find Out

Various Analysis Results. Learn Different Techniques Like Routh-Hurwtiz Stability Criterion,

Root Locus, Time and Frequency Domain Analysis. It is Also Shown Different Ways to Judge the

Performance of Control System.

B. Out Line of The Course:

Sr. No.

Title of The Unit Minimum Number of Hours

1. Introduction To Control Systems 3 2. Mathematical Modeling of Dynamic Systems 5 3. Block Diagram Technique and Signal Flow Graphs 5 4. Feedback Characteristics of Control Systems 5 5. Control Systems and Components 7 6. Time Response Analysis & Design Specifications 7 7. Concept of Stability, and Algebraic Criterion 6

8. The Root Locus Technique 4 9

The Frequency Response Analysis 7

10 State Variable Analysis of Control System 6 11

Performance of Control Systems 5

Total Hours (Theory): 60


Total:90


1. Introduction To Control Systems 3 Hrs 5 %

1.1 Introduction To Control Systems, Classification of Control Systems, The

Open-Loop Control Systems & Closed-Loop Control Systems

1 Hr

1.2 Comparison of Open-Loop Control Systems & Closed-Loop Control

Systems, Servomechanism

1 Hr

1.3 Examples With Applications In Engineering Field 1 Hr

2 Mathematical Modeling of Dynamic Systems 5 Hrs 8 %

2.1 Introduction, Differential Equations of Physical Systems, Mechanical

Systems: Translational Elements, Rotational Elements, Electrical Systems,

Thermal Systems, Fluid Systems, Pneumatic Systems.

2 Hrs

2.2 Transfer Functions of Mechanical Systems & Electrical Systems With

Examples, Analogous System: Analogous In Force(Torque)-Voltage

Analogy & Force(Torque)-Current Analogy, Problems On Analogy

2 Hrs

2.3 Gear Trains : Design and Applications 1 Hr

3 Block Diagram Technique and Signal Flow Graphs 5 Hrs 8 %

3.1 Block Diagram of A Close Loop System, Rules of Block Diagram

Reduction Techniques

1 Hr

3.2 Various Terms of Signal, Flow Graphs, Construction of Signal Flow 2 Hrs

Graphs

3.3 Mason's Gain Formula ,Use of Mason's Gain Formula To Determine The

T.F. Problems

2 Hrs

4. Feedback Characteristics of Control Systems 5 Hrs 8 %

4.1 Feedback and Non-Feedback System 1 Hr

4.2 Reduction of Parameter Variations By Use of Feedback 1 Hr

4.3 Control of The Effects of Disturbance Signals By Use of Feedback,

Regenerative Feedback, Problems

3 Hrs

5. Control Systems and Components 7 Hrs 11 %

5.1 Comparison Between Ordinary Motor and Servo Motor 1 Hr

5.2 T.F. of Servo Motors: 1) Field Controlled D.C. Servo Motor, 2) Armature

Controlled D.C. Servo Motor, 3) Two Phase A.C. Servo Motor, Concept of

Pneumatic Components: Flapper Valve, Relay, Actuator, Bellows,

3 Hrs

5.3 Determination of T.F. of A Complex Control Systems, Introduction To

Stepper Motors & Its Applications, Problems

3 Hrs

6. Time Response Analysis & Design Specifications 7 Hrs 11 %

6.1 Introduction, Standard Test Signal 1 Hr

6.2 Time Response of First Order Control System, Time Response of A Second

Order Control System, Response of Second Order System To The Unit-

Step

1 Hr

6.3 Time Response Specifications, Derivation of Specifications of Second

Order System

1 Hr

6.4 Steady State Error and Error Constants, Types of Feedback Control

Systems, Compensation Methods Such As Derivative Error Compensation,

Derivative Output Compensation

3 Hr

6.5 Integral Error Compensation, Problems 1 Hr

7. Concept of Stability, and Algebraic Criterion 6 Hrs

11 %

7.1 Concept of Stability, Absolute Stability, Absolute Stability and Relative

Stability, Necessary Condition For Stability

1.5 Hrs

7.2 Hurwitz Stability Criterion, Routh Stability Criterion 1.5 Hrs

7.3 Special Cases of Routh Stability Criterion, Application of Routh Criterion

To Linear Feedback Control System, Relative Stability Analysis

1.5 Hrs

7.4 Nyquist Stability Criterion, Problems 1.5 Hrs

8. The Root Locus Technique 4 Hrs 8 %

81 The Concept of Root Locus 1.5 Hrs

8.2 Rules For Constructions of Root Locus Problems 2.5 Hrs

9. The Frequency Response Analysis 7 Hrs 12 %

9.1 Introduction Frequency Response, Frequency Domain Specifications 2 Hrs

9.2 Correlation Between Time and Frequency Response, Contraction of Polar

Plots, Contraction of Bode Plots

2.5 Hrs

9.3 Experimental Determinations of Transfer Functions, Determination of Gain

Margin and Phase Margin Gain For Find Stability In Frequency Domain,

Problems

2.5 Hrs

10. State Variable Analysis of Control System 6 Hrs

10 %

10.1 Introduction , Concepts of State, State Variables ,State Vectors, State Space 1.5 Hrs

10.2 State Space Equations, Correlation Between T.F.& State Space Equations 1.5 Hrs

10.3 Space Models 1.5 Hrs

10.4 Controllability & Observability, Problems 1.5 Hrs

11 Performance of Control Systems 5 Hrs 8 %

11.1 Time & Frequency Domain Analysis and Performance of Various Control 5 Hrs

Systems Using Control System Tool Box of Matlab


• Multimedia Projector • OHP • Audio Visual Presentations • Chalk + Board • White Board • Online Demo • Charts


Upon Successful Completion of This Course, Student Should Be Able To:

• Student Gets Ability To Identify Different Control System, Formulate and Solve Control System Problems.

• Student Gets Manage Apply Knowledge and Understanding To Analyze Control Systems and Processes.

• Student Gets Capability To Design and Conduct Appropriate Control System and Draw Conclusions.


a. Reference Books:

1) Automatic Control Systems By B.C.Kuo.

2) Modern Control Engineering. By K. Ogata (Third Edition), Published By Prentice-Hall of India

Private, New Delhi.

3) Control System Engineering. By I.J. Nagrath & M. Gopal (Third Edition), Published By New Age

International Publishers, New Delhi.

4) Automatic Control Systems By S.N.Verma. 5) Linear Control Systems By B.S.Manke. 6) Automatic Control Engineering By Raven.

Reading Materials, Web Materials With Full Citations: Www.Mathworks.Com Http://En.Wikipedia.Org/Wiki/Control_Engineering Http://Www.Controlsrus.Com/Products.Html Nptel.Iitm.Ac.In Http://Www.Filestube.Com Http://Eprintsgla.Ac.Uk/3818

Other Materials

1. Lab Manuals

2. Control Engineering Kits

3. Hand Outs

4. Assignments

5. Question Bank



ENGINEERING



EC 208: ANALOG ELECTRONIC CIRCUITS

_______________________________________________________________________


Hours/week 4 2 6 5

Marks 100 50 150

A. Objective of The Course:

The Purposes or Goals or Objectives of The Course are To Introduce the Students about Different

Electronic Devices like Amplifiers, Oscillators, Switching Circuits & Time Base Generators So

They Can Get the Ideas for the Complex Electronic Projects.


Sr

No.

Title of The Unit Minimum Number of

Hours

1. Power Amplifier 2

2. Power Supply

2

3. Differential Amplifier

6

4. Feedback Amplifier 6

5. Oscillators

8

6. Clipping and Comparator Circuits 6

7. Clamping and Switching Circuits 6

8. Voltage Time Base Generators 6

9. Current Time Base Generator 6

10. Negative Resistance Devices 8

11. Analog To Digital and Digital To Analog Converters: 4



Total: 90


1. Power Amplifier 2 Hrs 6 %

1.1 Class A, Second Harmonics Distortion, Higher Order Harmonics Generation

1 Hr

1.2 Transformer-Coupled Audio Power Amplifiers, Efficiency, Push-Pull Amplifier, Class B, Class Ab

1 Hr

2. Power Supply 2 Hrs 6 %

2.1 Regulated Power Supply – Series Voltage Regulator Design, Short Circuit and Overload Protections, Voltage Regulator Ics.

2 Hrs

3 Differential Amplifier 6 Hrs

8 %

3.1 Principle, Circuit Analysis of Bjt Differential Amplifier, Cmrr, Use of

Current Source Circuit For Increasing Cmrr.

6 Hrs

4. Feedback Amplifiers 6 Hrs 10 %

4.1 Feedback Concept, Transfer Gain With Feedback, General Characteristics of Negative-Feedback Amplifiers, Input Resistance, Output Resistances, Method of Analysis of A Feedback Amplifier.

3 Hrs

4.2 Current-Shunt Feedback, Voltage-Shunt Feedback, Current-Series Feedback, Voltage-Series Feedback.

3 Hrs

5. Oscillators 8 Hrs 12 %

5.1 Sinusoidal Oscillator, Phase Shift Oscillators, Resonant-Circuit, Hartley

Oscillators, Colpitts Oscillators.

4 Hrs

5.2 Wien Bridge Oscillators, Crystals Oscillator

4 Hrs

6. Clipping and Comparator Circuits 6 Hrs 8 %

6.1 Clipping (Limiting) Circuits, Diode Clipper, Transistor Clipper, 3 Hrs

6.2 Clipping At Two Independent Levels, Emitter Coupled Clipper.

3 Hrs

7. Clamping and Switching Circuits 6 Hrs

8 %

7.1 Clamping Operation, Clamping Circuit Taking Source and Diode Resistance Into Account, Clamping Theorem, Practical Clamping,

3 Hrs

7.2 Effect of Diode Characteristics On Clamping Voltage, Transistor As A

Switch, Switch With Inductive and Capacitive Load

3 Hrs

8 Voltage Time Base Generators 6 Hrs 12 %

8.1 General Features of A Time-Base Signal, Method of Generating A Time

Base Waveform, Exponential Sweep Circuit, Negative Resistance

Switches,

3 Hrs

8.2 Transistor Constants Current Sweep, Miller and Bootstrap Transistor Miller, Transistor Bootstrap

3 Hrs

9 Current Time Base Generator 6 Hrs

10 %

9.1 Simple Current Sweep, Linearity Correction, Transistor Current Time-Base Generator,

3 Hrs

9.2 Methods of Linearity Improvement, Illustrative Current Sweep Circuits

3 Hrs

10 Negative Resistance Devices 8 Hrs

12 %

10.1 Tunnel Diode, Ujt, Negative Resistance Characteristic, Basic Ckt Principles, Mono-Stable, Bi-Stable and A-Stable Operations,

2 Hrs

10.2 Voltage Controlled Switching Ckts, Tunnel-Diode, Mono-Stable Ckt, Tunnel Diode A-Stable Ckt, Tunnel-Diode Comparator

3 Hrs

10.3 Tunnel-Diode Mono-Stable Ckt. Tunnel Diode Transistor Hybrid Ckt, Applications of Ujt

3 Hrs

11 Data Converters 4 Hrs 8 %

11.1 Digital To Analog Conversion, R-2r Ladder Type Dac, Weighted Resistor Type Dac, Switched Current Source Type Dac, Switched Capacitor Type Dac

2 Hrs

11.2 Analog To Digital Conversion, Counter Type A/D Converter, Tracking Type A/D Converter, Flash-Type A/D Converter, Dual Slope Type A/D Converter, Successive Approximation Type Adc.

2 Hrs


• Chapter Wise Assignments • OHP • Chalk – Board • Power Point Presentation • White Board • Online Demo • Charts


Upon Completion of This Course, Students Will Understand The Operation, Function and Interaction Between Various Components and Sub-Systems Used In Power Amplifier, Power Regulator, Clipper and Clamping, Feedback Amplifier, Oscillators, Voltage Time Base Generator, Current Time Generator, Negative Resistance Devices.


Reference Books:

1) Integrated Electronics By Jacob Millman and Christos C. Halkias, Tata Mcgraw-Hill Edition

2) Pulse, Digital and Switching Waveforms By Jacob Millman and Herbert Taub, Tata Mcgraw-

Hill Edition.

3) Electronics Devices and Circuits Theory ( Sixth Edition) By Boylestead & Nashelsky Phi Pub.

Reading Materials, Web Materials With Full Citations:

1) Lecture Notes

2) Hand Outs

3) Assignments

4) Project and Quiz

CHAROTAR UNIVERSITY OF SCIENCE & TECHNOLOGY FACULTY OF TECHNOLOGY AND ENGINNERING

V. T. PATEL DEPARTMENT OF ELECTRONICS & COMMUNICATION

ENGINEERING



EC209: MICROPROCESSORS & MICROCONTROLLER

_______________________________________________________________________

Credit Hours:

Teaching Scheme Theory Practical Total Credit

Hours/week 4 2 6 5

Marks 100 50 150

A. Objective of The Course:

The Purposes or Goals or Objectives of The Course Are To Introduce The Students To Become Familiar With The Architecture of A Specific Microprocessor 8085 and Microcontroller 8051 and Programmable Interfacing Devices.


Sr

No.

Title of The Unit Minimum Number

of Hours

1 Introduction of Microprocessors, Microcontrollers & Microcomputer System

1

2. 8085 Microprocessor Architecture and Memory Interfacing

3

3. Programmable Interface Devices-8255,8254,8251

10

4. Introduction and Architecture of 8051 10

5. Basic Assembly Language Programming Concepts

10

6. Moving Data, Logical Operations & Arithmetic 10 7. Jumps and Call Instructions 6 8. An 8051 Microcontroller Design 6 9. Serial Data Communication 4

Total Hours (Theory) : 60


Total: 90


1. Introduction of Microprocessors, Microcontrollers & Microcomputer System 1 Hrs

1.66 %

1.1 Basics of Microprocessors and Controllers and Comparision 0.5 Hr

1.2. Microprocessor Architecture and Operation, Memory I/O Devices 0.5 Hr

2. 8085 Microprocessor Architecture and Memory Interfacing 3 Hrs 5 %

2.1 8085 MPU, Example of 8085-Based Microcomputer

1 Hr

2.2 Memory Interfacing ,Interfacing 8155 Memory Segment 2 Hrs

3 Programmable Interface Devices-8255,8254,8251 10 Hrs 16.66 %

3.1 The 8255 Programmable Devices 4 Hrs

3.2 The 8254 Programmable Interval Timer 2 Hrs

3.3 The 8251 Programmable Communication Interface 4 Hrs

4. Introduction and Architecture of 8051 10 Hrs 16.66 %

4.1 8051 Microcontroller Hardware 2 Hrs

4.2 Input/Output Pins, Ports, and Circuits 3 Hrs

4.3 External Memory, Counter and Timers 2 Hrs

4.4 Serial Data Input/Output, Interrupts 3 Hrs

5. Basic Assembly Language Programming Concepts 10 Hrs 16.66 %

5.1 Generic Computers, Mechanics of Programming 2 Hrs

5.2 Assembly Language Programming Concepts, PAL Practice CPU 4 Hrs

5.3 Programming Tools and Techniques, Programming The 8051 4 Hrs

6. Moving Data, Logical Operations & Arithmetic Operations 10 Hrs 16.66 %

6.1 Byte& Bit Level Logical Operations, Rotate and Swap Operations, Example Programs

5 Hrs

6.2 Flags, Incrementing Decrementing, Addition, Subtractions, Multiplication and Division, Decimal Arithmetic, Example Programs

5 Hrs

7 Jumps and Call Instructions 6 Hrs 10 %

7.1 Jump and Call Program Range, Jumps 3 Hrs

7.2 Calls and Subroutines, Interrupts and Returns, Detail On Interrupt 3 Hrs

8 An 8051 Microcontroller Design 6 Hrs 10 %

8.1 Specification and Design, Testing The Design 2 Hrs

8.2 Timing Subroutines, Lookup Table For 8051 2 Hrs

8.3 Serial Data Transmission 2 Hrs

9. Serial Data Communication 4 Hrs 6.66 %

9.1 Network Configurations 2 Hrs

9.2 8051 Data Communication Modes Example 2 Hrs


• Multimedia Projector

• Chalk-Stick

• Overhead Projector

• Assignments Based On Noise Figure


Students Demonstrate That They Can Write Assembly Language Programs For A Microcontroller 8051 To Make It Perform Predefined Tasks.


1. Reference Books:

1) Microprocessor Architecture Programming and Applications By R. S. Gaonkar –

Fourth Edition (WEL)

2) The 8051 Microcontroller – Architecture Programming & Application By K. J. Ayala- Second Edition (Penram International)

3) The 8051 Microcontroller MCS51 & It’s Variants By Prof. S.K.Shah –First

Edition (Oxford University Press )

2. Reading Materials, Web Materials With Full Citations:

• Lecture Notes

• IIT Lecture Notes

• NPTEL Web Course

CHAROTAR UNIVERSITY OF SCIENCE & TECHNOLOGY FACULTY OF TECHNOLOGY AND ENGINNERING

V. T. PATEL DEPARTMENT OF ELECTRONICS & COMMUNICATION

ENGINEERING



EC210: ANALOG COMMUNICATION _______________________________________________________________________


Hours/week 4 2 6 5

Marks 100 50 150

A Objective of The Course:

This Course Will Introduce The Student To The Various Analog Communication Fundamentals Viz., Amplitude Modulation and Demodulation, Angle Modulation and Demodulation. Noise and Performance of Various Receivers.

B Out Line of The Course:



Total: 90

Sr. No.

Title of The Unit Minimum Number of Hours

1. Analysis and Transmission of Signals 06 2. Amplitude Modulation 12 3. Single-Sideband Modulation 08 4. Angle Modulation 14 5. Receivers 10 6. Noise 10

C Detailed Syllabus:

1. Analysis and Transmission of Signals 6 Hrs 10 %

1.1 Aperiodic Signal Representation By Fourier Integral, Transform of Some Useful Function.

2 Hrs

1.2 Some Properties of The Fourier Transform. 2 Hrs

1.3 Signal Energy and Energy Spectral Density, Signal Power and Power Spectral Density.

2 Hrs

2. Amplitude Modulation 12 Hrs 20 %

2.1 Amplitude Modulation, Amplitude Modulation Index, Modulation Index For Sinusoidal AM, Frequency Spectrum For Sinusoidal AM.

2 Hrs

2.2. Average Power For Sinusoidal AM, Effective Voltage and Current For Sinusoidal AM

2 Hrs

2.3 Nonsinusoidal Modulation, Double-Sideband Suppressed Carrier (DSBSC) Modulation.

3 Hrs

2.4 Amplitude Modulator Circuits, Amplitude Demodulator Circuits. 3 Hrs

2.5 Amplitude-Modulated Transmitters, AM Receivers, Noise In AM Systems. 2 Hrs

3. Single-Sideband Modulation 8 Hrs 13 %

3.1 Single-Sideband Principles, Balanced Modulators 2 Hrs

3.2 SSB Generation, SSB Reception. 2 Hrs

3.3 Modified SSB Systems, SNR For SSB, Companded Single Sideband.

4 Hrs

4. Angle Modulation 14 Hrs 24 %

4.1 Frequency Modulation, Sinusoidal FM, Frequency Spectrum For Sinusoidal FM, Average Power In Sinusoidal FM.

2 Hrs

4.2 Non-Sinusoidal Modulation : Deviation Ratio, Measurement of Modulation Index For Sinusoidal FM, Phase Modulation.

3 Hrs

4.3 Equivalence Between PM and FM, Sinusoidal Phase Modulation, Digital Phase Modulation.

1 Hr

4.4 Angle Modulator Circuits. 2 Hrs

4.5 FM Transmitter, Angle Modulation Detectors. 4 Hrs

4.6 Automatic Frequency Control, Amplitude Limiters, Pre-Emphasis and De-Emphasis, FM Broadcast Receivers.

2 Hrs

5. Receivers 10 Hrs 17 %

5.1 Homodyne, Heterodyne and Super Heterodyne Receivers, Tuning Range, Tracking.

2 Hrs

5.2 Sensitivity and Gain, Image Rejection, Spurious Responses, Adjacent Channel Selectivity.

3 Hrs

5.3 AGC, Double Conversion. 3 Hrs

5.4 Electronically Tuned Receivers (Etrs), Integrated-Circuit Receivers. 2 Hrs

6. Noise 10 Hrs 16 %

6.1 Thermal Noise, Shot Noise, Partition Noise, Low Frequency or Flicker Noise, Burst Noise, Avalanche Noise, Bipolar Transistor Noise, Field-Effect Transistor Noise, Equivalent Input Noise.

3 Hrs

6.2 Generators and Comparison of Bjts and Fets, Signal – To – Noise Ratio, S/N Ratio of A Tandem Connection.

3 Hrs

6.3 Noise Factor, Amplifier Input Noise In Terms of F, Noise Factor of Cascade Systems, Noise Factor of A Lossy Network, Noise Equivalent Temperature, Measurement of Noise Temperature and Noise Factor, Narrowband Band-Pass Noise.

4 Hrs

D Instructional Method and Pedagogy:

• Multimedia Prosentation • OHP • Charts • Chalk + Board • White Board • Online Demo

E Student Learning Outcomes:

• Provide Knowledge of Various Amplitude Modulation and Demodulation Systems. • Deliver Knowledge of Different Angle Modulation and Demodulation Systems. • Provide Some Depth Analysis In Noise Performance of Various Receivers.


Reference Books:

1) Electronic Communications By Dennis Roddy & John Coolen IV Edition PHI.

2) Modern Digital and Analog Communication System III Edition By B.P.Lathi Pub

Oxford.

Reading Materials, Web Materials With Full Citations:

1)Http://Adp.Mmu.Edu.My/Enotes/Asma/DTC5038/Notes/Lecture%20Notes%203%20-%20Chapter%203.Pdf

2) Http://Web.Cecs.Pdx.Edu/~Ece2xx/ECE223/Slides/Communicationsx4.Pdf

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