Bachelor of Engineering SoE & · PDF fileHigh frequency limitations of conventional microwave...
Transcript of Bachelor of Engineering SoE & · PDF fileHigh frequency limitations of conventional microwave...
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
Hingna Road, Wanadongri, Nagpur - 441 110
Bachelor of Engineering
SoE & Syllabus 2014
Telecommunication Engineering
Update on May 2017
7 Semester
Electronics &
L T P Total MSE I MSE II TA ESE
Contact HoursCR
% WeightageS. N. Sub Code Subject
ESE
Duration
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering(An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
B.E. SCHEME OF EXAMINATION 2014
Electronics and Telecommunication Engineering
1 ET1401 RF & Microwave 4 0 0 4 4 15 15 10 60 3 Hrs
2 ET1402 Lab.: RF & Microwave 0 0 2 2 1 40 60
3 ET1403 Principles of Image Processing 4 0 0 4 4 15 15 10 60 3 Hrs
4 ET1404 Lab. : Principles of Image Processing 0 0 2 2 1 40 60
ET1405 PE III : Optical Communication
ET1407 PE III : Microwave Integrated circuit
ET1409 PE III : Communication Networks
ET1431 PE III : Analog VLSI
ET1406 Lab. :PE III : Optical Communication
ET1408 Lab. :PE III : Microwave Integrated circuits
ET1410 Lab. :PE III : Communication Networks
ET1432 Lab. :PE III : Analog VLSI
7 ET1413 Industrial Training/ CRT 0 0 0 0 2 100
8 ET1414 Project phase -I 0 0 4 4 4 40 60
11 0 10 21 20
1 ET1415 Antenna Theory & Design 4 0 0 4 4 15 15 10 60 3 Hrs
2 ET1416 Lab.: Antenna Theory & Design 0 0 2 2 1 40 60
3 ET1417 CMOS VLSI Design 4 0 0 4 4 15 15 10 60 3 Hrs
4 ET1418 Lab.: CMOS VLSI Design 0 0 2 2 1 40 60
ET1419 PE IV : Power Electronics
ET1420 PE IV : Wireless Mobile Communication Systems
ET1433PE IV : Satellite Communication & RADAR
Engineering
ET1434 PE IV: Biomedical Instrumentation
ET1422 PE V : Fuzzy Logic & Neural Networks
ET1424 PE V : RF Circuit Design
ET1426 PE V : Multimedia Communications
ET1435 PE V:Advances in Communication
ET1423 Lab.: PE V : Fuzzy Logic & Neural Networks
ET1425 Lab.: PE V : RF Circuit Design
ET1427 Lab.: PE V : Multimedia Communications
ET1436 Lab.: PE V: Advances in Communication
8 ET1428 Project Phase-II 0 0 8 8 8 40 60
9 ET1429 Comprehensive Viva-voce 0 0 0 0 3 100
10 ET1430 Extra/co curricular Activities 0 0 0 0 2 100
14 0 14 28 30
0
3 3 15 15
Lab.: Professional Elective V
0
15 15
3 0
Professional Elective IV
5
Professional Elective V
3
0 0
5 0
3 Hrs
6
7
EIGHTH SEMESTER
2 2 1
3 0 0
2 1
33
15 15 10 60
10 60
10 60
SEVENTH SEMESTER
Total
Lab.:Professional Elective -III
Professional Elective-III
40 606
3
2
60
3 3 Hrs
0
Chairperson Version 1.00Applicable for AY 2016-17
OnwardsDean (Acad. Matters) Date of Release May 2016
Total
0
40
3 Hrs
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 66
7th
Semester
ET1401 RF and Microwave L= 4 T = 0 P = 0 Credits = 4
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Course Objective Students should be able to
1. Know various resonant and non resonant microwave power generators.
2. Study the concept of scattering matrix.
3. Understand working of various microwave passive devices
4. Know the various microwave measurement techniques.
5. Learn the working principle of microwave solid state devices.
Course Outcome Students will be able to 1. Analyze behavior of linear beam tubes. 2. Discuss the working of cross field tubes. 3. Apply s-parameters to model output response of microwave
transmission lines. 4. Analyze behavior of different passive components using s-
matrix. 5. Measure performance parameters of microwave devices 6. Explore various microwave solid state devices.
UNIT I : KLYSTRONS High frequency limitations of conventional microwave devices,Two cavity Klystron Amplifier – Mechanism and mode of Operation, Power output and Efficiency, Applegate diagram, applications, Reflex Klystron Oscillator – Mechanism and mode of Operation Power output, efficiency, Electronic Admittance.
09 Hrs UNIT II : MAGNETRONS Helix, TWT, BWO Slow Wave Structures Magnetron Oscillator – Hull cut-off voltage, Mechanism of Operation, Mode separation, Phase focusing effect, Power output and Efficiency, Cylindrical magnetron, parallel plate magnetron, Types of strapping, Tuning of magnetron. Applications, Numerical Problems.
08 Hrs UNIT III : MICROWAVE NETWORK ANALYSIS Introduction, Symmetrical Z and Y matrices for reciprocal network, Scattering matrix representation of multi port networks, comparison between [S], [Z] and [Y] matrices. Inter relationship between impedance matrix, admittance matrix and Scattering matrix, properties of scattering matrix. Scattering matrix of transmission lines, ABCD parameters with S parameters, Numerical Problems .
08Hrs UNIT IV : MICROWAVE PASSIVE DEVICES (RECIPROCAL AND NON RECIPROCAL): Wave guide Tees - E plane Tee, H plane Tee, Magic Tee and their applications, , Directional couplers, Wave guide Corners, Bends and Twists ,Attenuators, Isolators, Gyrators, Circulators, Phase shifter, Scattering matrix derivation for all components.
09Hrs UNIT V: MICROWAVE MEASUREMENT: Introduction, Tunable detector, Slotted line Carriage, VSWR meter, Power measurements sensor, Bolo meter sensor, power sensor, Low and High power measurement, Insertion loss and Attenuation measurement, VSWR measurement – Low and High VSWR, Impedance measurement. Frequency measurement, Measurement of cavity Q, Dielectric measurement, Microwave filters-design methods : Image parameter method, Insertion loss method.
07Hrs UNIT VI: MICROWAVE SOLID STATE DEVICES AND CIRCUITS: Microwave diodes – Gunn diode – Mode of operation, Crystal diode, PIN diode –, IMPATT diodes, Application as Oscillator and Amplifiers, Varactor diode, parametric amplifier, Microwave transistors, MASER, Strip lines- Micro Strip lines, Parallel Strip lines.
07Hrs
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 67
7th
Semester
ET1401 RF and Microwave L= 4 T = 0 P = 0 Credits = 4
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Text books:
1 Microwave device and circuits Third Edition Samuel Y.Lio Pearson Education
2 Foundations of microwave engineering
Second Edition 1992 R.E. Collins Tata Mc-Graw Hill
3 Microwave engineering Second Edition 1992 R Chatterjee.
4 Microwave Engineering Third Ed. 2007 David Pozar Wiley Ind. Pub.
Reference books:
1 Microwave communication 1989 Hund
2 Microwave theory and measurement
G. Lance
3 Microwave Engineering 2
nd Edition
Reprint 2001 Annapurna Das, Sisir. K.Das
Tata McGraw-Hill Co., Ltd.
4 Microwave 1978 Reich J.H.et al East West Press,
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 68
7th
Semester
ET1402 Lab. : RF & Microwave L = 0 T = 0 P = 2 Credits = 1
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to : 1. Understand working principle of various antennas &
their radiation pattern. 2. Study performance characteristics of active devices. 3. Learn the behavior of various passive devices at
microwave frequencies 4. Understand various microwave measurement
techniques.
Course outcomes Students will be able to: 1. Analyze performance of various types of antennas. 2. Analyze the behavior of active microwave devices. 3. Verify behavior of various passive components. 4. Perform various microwave measurements.
Sr. No.
Experiments based on
1 Active RF Devices
2 Passive RF Devices
3 Microwave Measurement
4 MIC Components
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 69
7th
Semester
ET1403 Principles of Image Processing L= 4 T = 0 P = 0 Credits = 4
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Course Objective Students should be able to 1. Understand the principles of image
formation, sampling and quantization. 2. Learn the algorithms of intensity
transformation, filtering and segmentation.
3. Learn restoration and compression of digital images through various algorithms
4. Study the performance of digital images in frequency domain
Course Outcome Students will be able to 1. Analyze the image sampling, quantization and intensity
transformation techniques. 2. Apply basic image processing algorithms for image enhancement 3. Implement and evaluate the methodologies for image
segmentation. 4. Deal with noise models and degradation process for image
restoration. 5. Implement the algorithms for image compression. 6. Interpret the digital images in frequency domain by using various
transform techniques
UNIT-1: Digital Image fundamental Fundamental steps and components of an image processing system, elements of visual perception, Image formation and acquisition, Image sampling and quantization, some basic relationship between the pixels, mathematical tools used in digital image processing. Intensity Transformation Background, Some basic intensity transformation technique, Histogram Processing
08Hrs UNIT-2: Filtering in spatial and frequency domain Spatial Filtering: Fundamentals,Smoothing linear filters, order statistics(nonlinear) filter. Sharpening Filtering: Foundation, Laplacian, Unsharp masking, High boost filtering and Gradient. Filtering in Frequency Domain: Introduction to Fourier transform and frequency domain, Smoothing frequency domain filters, sharpening frequency domain filters, properties of Fourier transform, homomorphic filtering.
08Hrs UNIT-3 Image Restoration Image degradation/restoration process, noise model, restoration in presence of noise, periodic noise reduction, linear, position invariant degradation, estimating degradation function, Inverse filtering, Wiener filtering, constrained least squares filtering, geometric mean filter.
08Hrs UNIT-4: Image Segmentation Fundamentals, Detection of discontinuities, Edge linking and boundary detection, Thresholding: Foundation, basic global thresholding, optimal global thresholding, multiple thresholds, variable thresholding, multivariable thresholding. Region based segmentation: Formulation, region growing, split and merge
08Hrs UNIT-5 Image Transforms 2-D FFT, Properties, Discrete cosine Transform , Discrete sine transform, Hadamard Transform,, Haar transform, Slant transform, Hoteling transform
08Hrs UNIT-6: Image compression, Redundancies and their removal methods, Fidelity criteria, Image compression models, Source encoder and decoder, Error free compression, Lossy compression.
08Hrs
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 70
7th
Semester
ET1403 Principles of Image Processing L= 4 T = 0 P = 0 Credits = 4
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Text books:
1 Digital Image processing 2
nd Education,
2002. R. C. Gonzalez & R. E. Woods
Addison Wesley/ Pearson education
2 Fundamentals of Digital Image processing
1989 A. K. Jain PHI
Reference books:
1 Digital Image processing using MAT LAB
Edition, PEA, 2004
Rafael C. Gonzalez, Richard E Woods and Steven L
Pearson
2 Digital Image Processing 3
rd Edition,
2004 William K. Pratt, John Wiley
4 Industrial Instrumentation D.P. Eckman Wiley Eastern Ltd.
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 71
7th
Semester
ET1404 Lab. : Principles of Image
Processing L = 0 T = 0 P = 2 Credits = 1
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to 1. Learn the mathematical concepts for manipulation
of digital images 2. Study implementation of intensity transformation
and histogram processing for image enhancement. 3. Learn and understand spatial domain and
frequency domain filtering techniques 4. Understand the process of image restoration,
segmentation and compression
Course outcomes Students will be able to
1. Develop a program to perform basic operation on digital images
2. Implement intensity transformation and histogram processing techniques
3. Design filters for spatial and frequency domain analysis of digital images
4. Develop and analyze the algorithms for image segmentation, restoration and compression
Sr. No.
Experiments based on
1 Statistical properties of image and displaying histogram and profile
2 Histogram modification.
3 Image smoothing operations.
4 Edge detection.
5 Segmentation using threshold.
6 Region based segmentation.
7 Image transforms.
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 72
7th
Semester
ET1405 PE III: Optical Communication L= 3 T = 0 P = 0 Credits = 3
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Course Objective Students should be able to
1. Learn the principles of step index and graded index optical fiber.
2. Know the types of losses in optical fiber.
3. Understand Transceiver systems in optical communication.
4. Learn concept of active, passive devices and measurements in optical communication.
Course Outcome Students will be able to 1. Design and analyze an Optical Communication System. 2. Differentiate the types of losses in optical system. 3. Explore different types of sources in fiber optics. 4. Analyze different types of receivers in fiber optics 5. Use different splicing techniques and connectors 6. Explore different methods of loss measurement in fiber
optics.
UNIT I : INTRODUCTION TO OPTICAL FIBERS Evolution of fiber Optic system. Principle of optical communication-Attributes and structures of various fibers such as step index, graded index mode and multi mode fibers. Propagation in fibers-Ray mode, Numerical aperture and multipath dispersion in step index and graded index fibers structure. Electromagnetic wave equation in step index and graded index fibers Modes and Power flow in fibers
06Hrs UNIT II : SIGNAL DEGRADATION IN OPTICAL FIBERS Attenuation – Absorption losses, Scattering losses, Bending Losses, Core and Cladding losses, Signal Distortion in Optical Wave guides – Information Capacity determination – Group Delay – Material Dispersion, Wave guide Dispersion, Signal distortion in SM fibers – Polarization Mode dispersion, Intermodal dispersion, Pulse Broadening in GI fibers – Mode Coupling – Design Optimization of SM fibers – RI profile and cut-off wavelength
06Hrs UNIT III : FIBER OPTICAL SOURCES Direct and indirect Band gap materials – LED structures – Light source materials – Quantum efficiency and LED power, Modulation of a LED, Laser Diodes – Modes and Threshold condition – Rate equations – External Quantum efficiency – Resonant frequencies – Laser Diodes structures and radiation patterns – Single Mode lasers – Modulation of Laser Diodes, Temperature effects, Source launching and coupling. Fabry Perot cavity Quantum laser
06Hrs UNIT IV : FIBER OPTICAL RECEIVERS PIN and APD diodes – Photo detector noise, SNR, Detector Response time, Avalanche Multiplication Noise – Comparison of Photo detectors – Fundamental Receiver Operation – pre-amplifiers - Error Sources – Receiver Configuration – Probability of Error – The Quantum Limit
06Hrs UNIT V : POWER LAUNCHING AND COUPLING IN DIGITAL TRANMISSION SYSTEM Source to fiber power launching – Fiber to Fiber Joints – Fiber Splicing and connectors Line Coding - Error correction– Noise Effects on System Performance
06 Hrs UNIT VI : MEASUREMENT IN OPTICAL FIBERS Attenuation, Time domain dispersion and Frequency domain dispersion, NA measurement Refractive index profile and optical source characteristic measurements, OTDR, eye pattern
06 Hrs
Text books:
1 Optical Fiber Communication 2008 Gerd Keiser McGraw-Hill International,
Singapore
2 Optical Communication, Principles and Practice.
1992 J.Senior
Reference books:
1 Optical Communication System J. Gower Prentice Hall of India
2 Fiber-Optic Communication System
Third Edition
Govind Agrawal
John Willy & Sons
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 73
7th
Semester
ET1406 Lab. : PE III: Optical Communication L = 0 T = 0 P = 2 Credits = 1
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to 1. Observe and analyze various fiber optic data links
when used for both digital and analog transmission. 2. know the measurement of NA of an optical fiber. 3. know data transmission using modulation techniques
such as PAM, PWM. 4. understand the use of OTDR in Optical fiber.
Course outcomes Students will be able to 1. explore both analog and digital optical fiber
communication. 2. analyze the NA measurements in different optical
fibers. 3. use different modulation techniques in optical fiber. 4. explore the OTDR in Optical Fiber.
Sr. No.
Experiments based on
1 Digital and analog link using optical fiber
2 Fiber Attenuation
3 Optical Sources Characteristics
4 Fiber Bandwidth/ Data Rate
5 Digital transmission in optical communication
6 Measurement in optical fiber
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 74
7th
Semester
ET1407 PE III: Microwave Integrated Circuits L= 3 T = 0 P = 0 Credits = 3
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Course Objective Students should be able to 1. Understand, design and analyze Planar
Transmission Lines. 2. Design Passive MIC components. 3. Study the concepts of microstrip patch
antenna. 4. Design & understand active MIC components. 5. Study the Hybrid MIC fabrication processes. 6. Study the Monolithic MIC fabrication
processes.
Course Outcome Students will be able to
1. Analyze different types of planar transmission lines. 2. Use the concept of Microstrip lines for designing different
passive RF components. 3. Design and analyze Microstrip circuits. 4. Understand the designing of active MIC components. 5. Understand the Hybrid MIC fabrication processes. 6. Understand the Monolithic MIC fabrication processes.
UNIT-1: Micro strip line: Analysis using conformal transformation and Hybrid mode method. Characteristic impedance, Guide wavelength and loss, Slot line – Wave-guide analysis, coupling coaxial and micro strip lines Coplanar line: analysis using conformal transformation and Hybrid mode method
06 Hrs UNIT-2: Micro strip line devices: Directional couplers, Micro strip coupler and branch-line couplers, even and odd mode analysis, coupling coefficient and bandwidth. Impedance transformers and filters, Lumped elements for MIC design and fabrication of inductors, resistors and capacitors, Non-reciprocal components, micro strip circulators, isolators, phase shifters
06 Hrs UNIT-3: Micro strip Antennas: Radiation mechanism, radiation fields, patch antennas, traveling wave antennas, slot antennas, excitation techniques, surface waves
06 Hrs UNIT-4: Design of micro strip circuits: High power circuits – Transistor Oscillator, step recovery diode frequency multiplier, avalanche diode oscillator, PIN diode switch, low power circuits Schottky diode, Balanced mixer, parametric amplifier, PIN diode limiter, Diode phase shifter
06 Hrs UNIT-5: Hybrid MICs: Dielectric Substrates, thick film technology, thin film technology, methods of testing, encapsulation of devices, mounting
06 Hrs UNIT-6: Monolithic MICs fabrication: Epitaxial growth, Diffusion, Ion implantation, Electron Beam technology for pattern delineation
06 Hrs
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 75
7th
Semester
ET1407 PE III: Microwave Integrated Circuits L= 3 T = 0 P = 0 Credits = 3
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Text books:
1. Antennas and Radio Wave Propagation 1985 R.E.Collin McGraw Hill Publishers
2. Microwave Devices and Circuits Third Edition Samuel Liao Prentice-Hall of India Ltd
3. Radio Frequency and Microwave Electronics
M.M. Radmanesh
2001, Pearson Education Asia,
4. Microwave Engineering Third Edition David Pozar Wiley Ind. Pub.
5. Strip line Transmission Line for MIC
Bharti Bhat, S. K. Koul
New Age International
Reference books:
1 Microwave Integrated Circuits 1974 K. C. Gupta and Amarjit Singh
Wiley East. Ltd
2 Micro strip Antennas 1980 I.J. Bahl and P. Bhartia
Artech House
3 Strip line Transmission Line for MIC
Bharti Bhat, S. K. Koul
New Age International
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 76
7th
Semester
ET1408 Lab. : PEIII: Microwave Integrated
Circuits L = 0 T = 0 P = 2 Credits = 1
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to 1. To understand the various microwave Integrated circuits
components 2. To Develop the hands-on Trainer Kits of MIC. 3. To analyze the various passive & active MIC components . 4. To get hands on spectrum analyzer. and analyze different
microstrip component on it.
Course Outcomes Students will be able to 1. Identify the different MIC components. 2. Set up the Test bench of MIC. 3. Analyze the components. 4. Use the spectrum analyzer for the analysis of
MIC components.
Sr. No. Experiments based on
1 Directional coupler
2 Power Divider
3 Measurement of antenna pattern : parabolic antenna, slot antenna, Horn antenna
4 A micro strip antenna
5 Ferrite Devices / Components
6 Micro strip Filters.
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 77
7th
Semester
ET1409 PE III: Communication Networks L= 3 T = 0 P = 0 Credits = 3
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Course Objective Students should be able to 1. Understand Networks, Network topologies and
service primitives. 2. Learn basics of LAN, MAN, WAN. 3. Learn the structure and applications of
connecting devices. 4. Understand OSI and TCP/IP architecture. 5. Comprehend Network applications and
Network Securities.
Course Outcome Students will be able to 1. Compare different LAN Topologies. 2. Apply the knowledge of LAN structure to design
autonomous system. 3. Detect Data transmission errors. 4. Compare data transmission protocols. 5. Describe the applications of communication network. 6. Solve network security issues.
UNIT I : Introduction, network and services: communication network, approaches to network design, types of network, two stage and three stage network. Uses of computer networks, LAN, MAN, WAN, design issues for layers, connection oriented and connectionless services, service primitives, Application and layered architecture, OSI reference model,
05 Hrs UNIT II : LAN network and medium access layer: LAN structure, random access, multiple access protocols, IEEE standard 802 for LAN and MAN, high speed LANS, repeaters, hubs, bridges, fast Ethernet, Wireless LAN
06 Hrs
UNIT III : Physical layer and data link layer: transmission media, PSTN. Data link layer design issues, error detection and correction methods, elementary data link protocols, sliding window protocols.
06 Hrs UNIT IV : Network layer and transport layer: network layer design issues, routing, congestion, internetworking, transport layer design issues, transport service primitives, internet transport protocol, TCP/IP architecture, TCP/IP protocol, IP packets, IP addressing, TCP/IP utilities ,wireless TCP and UDP, routers and gateways
06 Hrs UNIT V: Network Applications Application layer: domain name system, electronic mail system, multimedia, real time transport protocol, electronic mail, world wide web.
06 Hrs UNIT VI: Network Security: Network security cryptography, secrete key, public key, digital signature, e-mail security, web security, communication security.
06 Hrs
Text books:
1 Computer networks 3rd Edition Tanenbaum Amazon
2 Computer communication 2003 by W. Stanlling Prentice Hall
3 Data Communication and Networking 4
th Edition Forouzan McGrawHill
Reference books:
1 Telecommunication switching systems and networks
Paperback by vishwanathan
PHI
2 Computer Networks Third Edition
2003 Larry Peterson, Bruce Davie
MKP
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 78
7th
Semester
ET1410 Lab. : PE III: Communication Networks L = 0 T = 0 P = 2 Credits = 1
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to 1. Understand the design parameters of LAN topology. 2. Learn design specifications of stop and wait, go back
–n, selective repeat ARQ data link and transport layer protocols.
3. Study communication network securities issues. 4. Study methods of error free communication.
Course outcomes Students will be able to
1. Design autonomous system using LAN topologies. 2. Develop algorithms for stop and wait, go back –n,
selective repeat ARQ data link layer and transport protocols.
3. Develop algorithms for data encryption and decryption
4. Compare systems with single and burst error.
Sr. No. Experiments based on
1 Network design LAN, MAN ,WAN
2 PC to PC communication using RS-232 port
3 Sliding window protocol
4 Wireless TCP and UDP protocols
5 Bluetooth
6 Network security cryptography
7 Communication networks like Wi-Fi, Wimax
8 Routing protocols
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 79
7th
Semester
ET1431 PE III: Analog VLSI Circuits L= 3 T = 0 P = 0 Credits = 3
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Course Objective Students should be able to 1. Understand the current trends in Analog VLSI
technologies. 2. Study the various design methods of MOS
amplifier. 3. Study the single stage amplifier with various
loads. 4. Understand the basic concept of Differential
amplifier. 5. Study basics of operational amplifier design. 6. Study the basics of switch capacitor and analog
layout design.
Course Outcome Students will be able to 1. Apply mathematical methods to analyze Analog VLSI
circuits 2. Design MOS amplifier to improve the gain and operating
frequency range. 3. Design single stage amplifier with various loads and
analyze the various characteristic. 4. Design and analyze the differential amplifier.. 5. Design and analyze Op-AMP with two stage & Cascade
stage technique. 6. Make layout for various Analog circuits.
UNIT-1: MOS Device Physics General Consideration: MOSFET as a switch, MOSFET structure, MOS symbols; MOS Operation and I/V Characteristics: Threshold voltage, Derivation of I/V characteristics; Second order effects; MOS capacitances; MOS Small-Signal Model
06 Hrs UNIT-2: Analog CMOS Subcircuits MOS Diode/Active Resistor; Current Sinks and Sources: Simple MOS, Cascade MOS, Bootstrapped MOS, Regulated Cascoded; Current Mirrors: Simple, Cascode, Wilson, Wilder; Voltage and current references; Supply and Temperature independent biasing techniques.
06 Hrs UNIT-3: Single-Stage Amplifiers Basic Concepts; Common-Source Stage: Common-Source Stage with Resistive Load, CS Stage with Diode-Connected Load ,CS Stage with current source load, CS Stage with Triode Load , CS Stage with Source Degeneration; Source Follower, Common-Gate Stage; Cascade Stage: Folded Cascade
06 Hrs
UNIT-4: Differential Amplifiers Single-ended and Differential Operation; Basic Differential Pair: Qualitative and Quantitative Analysis; Common mode response; Differential pair with MOS loads; Gilbert cell.
06 Hrs
UNIT-5 : CMOS Operational Amplifiers Design of CMOS Op-Amps, Compensation of Op Amps, Design of Two-Stage Op Amps, Cascade Op Amps, Micropower Op Amps.
06 Hrs UNIT-6: Special Topics in Analog VLSI Bandgap References, Switch-Capacitor Circuits and Switch Capacitor Filter, Comparators Layout And Packaging General layout Consideration: Design rules, Antenna effect; Analog Layout Techniques; Packaging.
06 Hrs
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 80
7th
Semester
ET1431 PE III: Analog VLSI Circuits L= 3 T = 0 P = 0 Credits = 3
Evaluation Scheme
MSE-I MSE-II TA ESE Total ESE Duration
15 15 10 60 100 3 Hrs
Text books:
1 Design of Analog CMOS Integrated
Circuits First Edition Behzad Razavi TATA McGRAW HILL
2 CMOS Analog Circuit Design 2nd
Edition Philip Allen and Douglas Holberg
Oxford University Press
Reference books:
1 CMOS Circuit Design, Layout, and Simulation,
3rd Edition 2010
R. Jacob Baker Jonh Wiely publication
2 VLSI Design Techniques for Analog and Digital Circuits
Third edition, 2008
Randall Geiger, Phillip Allen, Noel Strader
Tata Mc Graw Hill
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 81
7th
Semester
ET1432 Lab. : PE III: Analog VLSI Circuits L = 0 T = 0 P = 2 Credits = 1
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to 1. Understand the difference between Analog VLSI and
digital VLSI. 2. Study the single stage amplifier with considering various
second order affect.. 3. Study the differential amplifier with various loads. 4. Understand the basic concept of OP-AMP.
Course outcomes Students will be able to
1. Design and analyze MOS circuit. 2. Design and analyze MOS amplifier with various loads
and estimate gain and bandwidth. 3. Design single stage amplifier with various loads and
estimate gain and bandwidth. 4. Design Differential amplifier and Op-AMP with various
loads and estimate gain and bandwidth.
Sr. No. Experiments based on
1 MOS I/V characteristics
2 Design MOS amplifier and consider various second order effects.
3 Single Stage Common Source Amplifier
4 Cascode Amplifier
5 Current Source and Sink
6 Design Current Mirrors
7 Design Differential Amplifier
8 Design two stage Op Amp
9 Design Comparators
10 Layout of Single Stage amplifier
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 82
7th
Semester
ET1413 Industrial Training/CRT L = 0 T = 0 P = 0 Credits = 2
Evaluation Scheme
Continuous Evaluation TA Total ESE Duration
100 100
* Evaluation Based on Seminar / Report.
Nagar Yuwak Shikshan Sanstha’s
Yeshwantrao Chavan College of Engineering (An Autonomous Institution affiliated to Rashtrasant Tukadoji Maharaj Nagpur University)
BE SoE and Syllabus 2014
Electronics & Telecommunication Engineering
Chairperson Version 1.01 Applicable for
AY 2017-18 Onwards Dean (Acad. Matters) Date of Release May 2017
P a g e | 83
7th
Semester
ET1414 Project Phase –I L = 0 T = 0 P = 4 Credits = 4
Evaluation Scheme
Continuous Evaluation ESE Total ESE Duration
40 60 100 2 Hrs
Course Objective Students should be able to 1. Understand the project problem statement by doing the
literature survey. 2. Define and prepare road map to get a desired output. 3. Gain knowledge about the project. 4. Improve the communication skills and stage daring through
effective presentation. 5. Write effective reports and design documentation.
Course Outcome Students will be able to
1. Identify, formulate and analyze complex engineering problems through literature survey.
2. Apply knowledge to assess health, social, safety and environmental issues.
3. Deal with multidisciplinary and industry based projects.
4. Communicate technical information by means of written reports and presentations.