8 course diary - mvjce€¦ · · 2016-02-27electronics and communication engineering viii...

ELECTRONICS AND COMMUNICATION ENGINEERING VIII SEMESTER COURSE DIARY

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VIII SEMESTER


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06EC81- WIRELESS COMMUNICATION


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WIRELESS COMMUNICATION

Subject Code : 06EC81 IA Marks : 25 No. of Lecture Hrs/Week : 04 Exam Hours : 03 Total no. of Lecture Hrs. : 52 Exam Marks : 100

PART - A UNIT - 1 Introduction to wireless telecommunication systems and Networks, History and Evolution Different generations of wireless cellular networks 1G, 2g,3G and 4G networks. 6 Hours UNIT - 2 Common Cellular System components, Common cellular network components, Hardware and software, views of cellular networks, 3G cellular systems components, Cellular component identification Call establishment.6 Hours UNIT - 3 Wireless network architecture and operation, Cellular concept Cell fundamentals, Capacity expansion techniques, Cellular backbone networks, Mobility management, Radio resources and power management Wireless network security 6 Hours UNIT - 4 GSM and TDMA techniques, GSM system overview, GSM Network and system Architecture, GSM channel concepts, GSM identifiers 6 Hours

PART - B

UNIT - 5 GSM system operation, Traffic cases, Cal handoff, Roaming, GSM protocol architecture. TDMA systems 6 Hours UNIT - 6 CDMA technology, CDMA overview, CDMA channel concept CDM operations. 8 Hours UNIT - 7 Wireless Modulation techniques and Hardware, Characteristics of air interface, Path loss models, wireless coding techniques, Digital modulation techniques, OFDM, UWB radio techniques, Diversity techniques, Typical GSM Hardware. 6 Hours UNIT - 8 Introduction to wireless LAN 802.11X technologies, Evolution of Wireless LAN Introduction to 802.15X technologies in PAN Application and architecture Bluetooth Introduction to Broadband wireless MAN, 802.16X technologies. 8 Hours TEXT BOOK:

1. Wireless Telecom Systems and networks, Mullet: Thomson Learning 2006.

REFERENCE BOOKS: 1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002. 2. Wireless communication - D P Agrawal: 2nd Edition Thomson learning 2007. 3. Fundamentals of Wireless Communication, David Tse, Pramod


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LESSON PLAN

Class: VIII semester Subject code: 06EC81

Subject: WIRELESS COMMUNICATION

Hours Topics to be Covered

Unit 1

1 Introduction to wireless telecommunication systems and Networks, 2 History and Evolution Different generations of wireless cellular networks: 3 1G

4 2G

5 3G

6 4G

UNIT –2:

7 Common Cellular System components

8 Common cellular network components

9 Hardware and software

10 Views of cellular networks

11 3G cellular systems components

12 3G cellular systems components

13 Cellular component identification Call establishment.

UNIT –3:

14 Wireless network architecture and operation

15 Wireless network architecture and operation

16 Cellular concept Cell fundamentals

17 Capacity expansion techniques

18 Cellular backbone networks

19 Mobility management 20 Radio resources and power management 21 Wireless network security

UNIT –4:

22 GSM and TDMA techniques, 23 GSM and TDMA techniques, 24 GSM system overview, 25 GSM Network and system Architecture

26 GSM Network and system Architecture

27 GSM channel concepts, 28 GSM identifiers

PART B

UNIT –5

29 GSM system operation

30 Traffic cases

31 Cal handoff

32 Roaming

33 GSM protocol architecture

34 GSM protocol architecture

35 TDMA systems


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UNIT –6

36 CDMA technology

37 CDMA technology 38 CDMA overview

39 CDMA overview 40 CDMA channel concept 41 CDMA channel concept 42 CDMA operations

43 CDMA operations

UNIT –7 44 Wireless Modulation techniques and Hardware

45 Characteristics of air interface 46 Path loss models

47 Wireless coding techniques

48 Wireless coding techniques

49 Digital modulation techniques 50 OFDM

51 UWB radio techniques 52 Diversity techniques

53 Diversity techniques

54 Typical GSM Hardware

UNIT –8

55 Introduction to wireless LAN 802.11X technologies.

56 Evolution of Wireless LAN 57 Introduction to 802.15X technologies in PAN 58 Introduction to 802.15X technologies in PAN 59 Application and architecture of Blue tooth 60 Application and architecture of Blue tooth 61 Introduction to Broadband wireless MAN

62 802.16X technologies

TEXT BOOK:

2. Wireless Telecom Systems and networks, Mullet: Thomson Learning 2006.

REFERENCE BOOKS: 1. Mobile Cellular Telecommunication, Lee W.C.Y, MGH, 2002. 2. Wireless communication - D P Agrawal: 2nd Edition Thomson learning 2007. 3. Fundamentals of Wireless Communication, David Tse, Pramod


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MODEL QUESTION PAPER

1. Define the following with respect to the wireless communication systems (a) Base station (b) Mobile station (c) Mobile switching center

2. Explain the trends in cellular radio and personnel communications 3. Describe the various hands of f strategies 4. Explain any two-outdoors propagation model in detail 5. Explain knife-edge diffraction with analysis for mobile radio propagation 6. With a block diagram explain spread spectrum channel impulse response

measurement system 7. Describe the fading effects due to multipath time delay spread 8. Explain GMSK transmitter and receiver 9. With analysis explain linear predictive coders 10. If GMS uses a frame structure where each frame consist of 8 time slots and

each time slot contain 156.25 bits and data is transmitted at 270.833kbps in the channel find (a) Time duration of a bit (b) Time duration of a slot (c) Time duration of a frame

11. Explain the concept of packet radio 12. For a wireless communication system explain TDMA, FDMA, CDMA 13. In an adaptive PCM system for a speech coding the input speech signal is

sampled at 8KHz, each sample is represented by a 8 bits the quantizer step size is recomputated every 10 msec and it is encoded for a transmission using 5 bits. Compute the transmission bit rate of such a speech coder. What would be the average and peak Sqnr of the system?

14. Explain Vocoders. 15. If a normal GSM time slot consist of 6 trailing bits 8.25 guard bits, 26 training bits

and 2 traffic bursts of 58 bits of data find the frame efficiency 16. How many users can be supported for a 0.5 blocking probability for the following

number of trunked channel in a blocked calls cleared system? (a) 1 (b) 5 (c) 10(d) 20(e) 100 Assume each user generates 0.1 erlangs of a

traffic. 17.Explain different characteristics of speech signal and explain the importance of

each of this 18.Explain trunking and grade of servile with respect to the wireless communication system

19. Derive an equation for relating power to electric field in a large-scale path. 20. Explain any two practical link budget design using path loss model 21. If Pt=10,Gt=0db and Fc=900MHz, Find Pr in watts at a speech space distance

of 1km 22. Find the first zero crossing Rf band width of a rectangular pulse which has

ts=41.06 microsecends compare this to the band width of rised cosine filter pulse with ts=41.06 microseconds and alpha=0.35

23. Explain quantization technique 24. Explain Hybrid spread spectrum technique 25. Explain nyquist criterion for ISI cancellation


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06EC82

EMBEDDED SYSTEM DESIGN


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EMBEDDED SYSTEM DESIGN Subject Code : 06EC82 IA Marks : 25 No. of Lecture Hrs/Week : 04 Exam Hours : 03 Total no. of Lecture Hrs. : 52 Exam Marks : 100

PART - A UNIT - 1 INTRODUCTION: Overview of embedded systems, embedded system design challenges, common design metrics and optimizing them. Survey of different embedded system design technologies, trade-offs. Custom Single-Purpose Processors, Design of custom single purpose processors. 4 Hours UNIT - 2 SINGLE-PURPOSE PROCESSORS: Hardware, Combinational Logic,Sequential Logic, RT level Combinational and Sequential Components,Optimizing single-purpose processors. Single-Purpose Processors: Software,Basic Architecture, Operation, Programmer’s View, DevelopmentEnvironment, ASIPS. 6 Hours UNIT - 3 Standard Single-Purpose Peripherals, Timers, Counters, UART, PWM, LCD Controllers, Keypad controllers, Stepper Motor Controller, A to D Converters, examples. 6 Hours UNIT - 4 MEMORY: Introduction, Common memory Types, Compulsory memory,Memory Hierarchy and Cache, Advanced RAM. Interfacing, Communication Basics, Microprocessor Interfacing, Arbitration, Advanced Communication Principles, Protocolos - Serial, Parallel and Wireless. 8 Hours

PART - B UNIT - 5 INTERRUPTS: Basics - Shared Data Problem - Interrupt latency. Survey of Software Architecture, Round Robin, Round Robin with Interrupts – Function Queues - scheduling - RTOS architecture. 8 Hours UNIT - 6 INTRODUCTION TO RTOS: Tasks - states - Data - Semaphores and shared data. More operating systems services - Massage Queues - Mail Boxes -Timers – Events - Memory Management. 8 Hours UNIT – 7&8 Basic Design Using RTOS, Principles- An example, Encapsulating semaphores and Queues. Hard real-time scheduling considerations – Saving Memory space and power. Hardware software co-design aspects in embedded systems. 12 Hours TEXT BOOKS: 1. Embedded System Design: A Unified Hardware/Software Introduction - Frank Vahid, Tony Givargis, John Wiley & Sons, Inc.2002 2. An Embedded software Primer - David E. Simon: Pearson Education, 1999


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Lesson plan

Class: VIII Semester Subject code: 06EC82 Subject: EMBEDDED SYSTEM DESIGN


Unit 1

1 Introduction: Overview of embedded systems, embedded system design

challenges,

2 Common design metrics and optimizing them

3 Survey of different embedded system design technologies, trade-offs.

4 Custom Single-Purpose Processors,

5 Design of custom single purpose processors

UNIT –2:

6 SINGLE-PURPOSE PROCESSORS: Hardware, Combinational Logic,

7 Sequential Logic,

8 RT level Combinational and Sequential Components

9 Optimizing single-purpose processors

10 Single-Purpose Processors: Software, Basic Architecture, Operation,

Programmer’s View,

11 Development Environment,.

12 ASIPS

UNIT –3:

13 Standard Single-Purpose Peripherals, Timers,

14 Counters, UART

15 PWM

16 LCD Controllers, Keypad controllers

17 Stepper Motor Controller

18 Stepper Motor Controller without driver

19 A to D Converters

20 Examples

UNIT –4:

21 MEMORY: Introduction, Common memory Types

22 Compulsory memory

23 Memory Hierarchy and Cache

24 Memory Hierarchy and Cache

25 Advanced RAM

26 Interfacing, Communication Basics

27 Microprocessor Interfacing, Arbitration,

28 Advanced Communication Principles

29 Protocolos - Serial, Parallel and Wireless

PART B UNIT –5

30 INTERRUPTS: Basics - Shared Data Problem., ,

31 Interrupt latency

32 Survey of Software Architecture

33 Survey of Software Architecture

34 Round Robin

35 Round Robin with Interrupts – Function Queues - scheduling

36 Round Robin with Interrupts – Function Queues - scheduling

37 RTOS architecture


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38 RTOS architecture

UNIT –6

39 INTRODUCTION TO RTOS: Tasks - states - Data

40 Semaphores

41 Semaphores

42 Shared data

43 Problems on shared data

44 More operating systems services

45 Massage Queues

46 Mail Boxes

47 Timers – Events

48 Memory Management

49 Memory Management

UNIT 7 & 8

50 Basic Design Using RTOS,

51 Principles of RTOS

52 Example

53 Encapsulating Semaphores and Queues.

54 Encapsulating Semaphores and Queues

55 Encapsulating Semaphores and Queues

56 Hard real-time scheduling considerations

57 Hard real-time scheduling considerations

58 Example

59 Saving Memory space and power

60 Saving Memory space and power

61 Hardware software co-design aspects in embedded systems

62 Hardware software co-design aspects in embedded systems

TEXT BOOKS: 1. Embedded System Design: A Unified Hardware/Software Introduction - Frank Vahid, Tony Givargis, John Wiley & Sons, Inc.2002 2. An Embedded software Primer - David E. Simon: Pearson Education, 1999 REFERENCE BOOKS: 1. Embedded Systems: Architecture and Programming, Raj Kamal, TMH. 2008 2. Embedded Systems Architecture – A Comprehensive Guide for Engineers and Programmers, Tammy Noergaard, Elsevier Publication, 2005 3. Embedded C programming, Barnett, Cox & O’cull, Thomson


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MODEL QUESTION PAPER

1) Explain the various metrics that need to be optimized while designing an

embedded system.

2) Explain the three main processor technologies that can be used with embedded

system. Also highlight the benefits of each.

3) Explain how the top-down design process improves the productivity.

4) Explain the various steps involved in designing a custom single-purpose

processor.

5) Explain the concept of ‘data path’ in the embedded system.

6) Design a single-purpose processor that outputs Fibonacci numbers upto n. Start

with a function computing the desired result, translate it into a state diagram and

sketch a probable datapath.

7) Explain the various events that take place when a processor executes an

instruction. Explain how does pipelining improve the execution speed.

8) Explain the various addressing modes that are commonly used by processor.

9) Explain the steps involved in designing a general-purpose processor.

10) Explain how UART is used for communication highlighting the advantages of

UART.

11) Schematically explain how a PWM helps in controlling the speed of DC motor.

12) Highlight the advantages of using data in digital form over its analog form.

Explain the working of successive approximation type of analog to digital

converter.

13) Explain the various types of RAM highlight the features of each.

14) What is cache memory? Explain its need and how it helps in improving the

execution speed.

15) With neat diagram explain the advanced Ram architecture. Also explain how this

is extended to improve the performance through synchronous DRAM.

16) What is Multi-level bus architecture? Explain its need and also the reasons to

improve the processor performance by this architecture.

17) Explain the reasons that make the serial communication more preferred than the

parallel communication systems.

18) Explain how I2C bus structure in peripherals to communicate with the processor.

19) Explain the need for interrupts in processing systems. Also explain the various

events that take place when a processor is interrupted.


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20) Explain the problems associated with interrupts that deals with the shared-data.

Also suggest solutions to solve these problems.

21) What is interrupt latency? Explain the factors affecting it.

22) Explain the reasons why the systems with the conventional operating system fail

to respond the real time problems. Also explain how these are taken care in

RTOS.

23) Explain the concept of semaphores. How these help us in solving the shared-

data problem in embedded systems?

24) Differentiate between hard and soft RTOS highlighting the advantages and

disadvantages of each.

25) Differentiate between the fallowing.

a) Single purpose and general-purpose processor.

b) Full custom IC and PLD technologies.

26) Explain the following terms

a) Characteristics pf an embedded system.

b) Ideal top-down design process.


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06EC835:

HIGH PERFORMANCE COMPUTER NETWORKS


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HIGH PERFORMANCE COMPUTER NETWORKS

Subject Code : 06EC835 IA Marks : 25 No. of Lecture Hrs/Week : 04 Exam Hours : 03 Total no. of Lecture Hrs. : 52 Exam Marks : 100

PART - A

UNIT - 1 History of Communication Networks, Networking principles, Future networks Internet, Pure

TAM Network, Cable Network, Wireless. 6 Hours

UNIT - 2 NETWORK SERVICES AND LAYERED ARCHITECTURE: Applications, Traffic

characterization and quality of services, Network services, High performance networks,

Network Elements., Layered applications, Open data network model, Network architectures,

Network bottlenecks. 7 Hours

UNIT - 3 INTERNET AND TCP/IP NETWORKS: Multicast IP, Mobile IP, TCP and UDP,

Applications, FTP, SMTP. Internet success and limitations, Performance of TCP/IP Networks,

Performance of circuit switched networks. 7 Hours

UNIT - 4 SONET, DWDM, FTH, DSL, Intelligent networks CATV. 6 Hours

PART - B

UNIT - 5 ATM: Main features of ATM, Addressing, signaling and Routing, ATM header structure, ATM

AAL, Internetworking with ATM. 7 Hours

UNIT - 6 WIRELESS NETWORKS: Link level design, Channel Access, Network design, Wireless

networks today, Future networks, ad hoc networks, High speed Digital cellular, Home RF and

Blue tooth. 6 Hours

UNIT - 7 Control of networks, Objectives and methods of control, Circuit switched networks, Datagram

Networks Network economics, Derived demand for network services, ISPs, subscriber demand

model, Empirical model. 7 Hours

UNIT - 8 OPTICAL NETWORKS: WDM systems, Optical cross connects, Optical LANs, Optical paths

and networks. 7 Hours

TEXT BOOK: 1. High Performance Communication Networks, Warland and Varaiya: Morgan Kauffman/

Elsivier 2nd Edition 2000.

REFFRENCE BOOKS:

1. High-Speed Networks and Internet: Performance and Quality ofservice, William

Stallings, Pearson Edu., 2001.

2. Building High-Speed Networks, Tere Parnell, TMGH, 2000.


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LESSON PLAN Class: VIII semester Subject code: 06EC835

Subject: HIGH PERFORMANCE COMPUTER NETWORKS


Unit 1

1 History of Communication Networks

2 Networking principles

3 Future networks Internet 4 Pure TAM Network

5 Cable Network

6 Wireless

UNIT –2:

7 Network services and layered architecture: Applications

8 Traffic characterization and quality of services 9 Network services

10 High performance networks 11 Network Elements

12 Layered applications 13 Open data network model 14 Network architectures

15 Network bottlenecks UNIT –3:

16 Internet and tcp/ip networks: Multicast IP

17 Mobile IP

18 TCP and UDP

19 TCP and UDP - Applications 20 FTP

21 SMTP 22 Internet success and limitations, 23 Performance of TCP/IP Networks

24 Performance of circuit switched networks UNIT –4:

25 SONET

26 SONET 27 DWDM

28 DWDM 29 FTH

30 FTH 31 DSL

32 DSL 33 Intelligent networks CATV

PART B

UNIT –5 34 ATM: Main features of ATM

35 Addressing

36 Signaling and Routing

37 ATM header structure


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38 ATM AAL

39 Internetworking with ATM

UNIT –6

40 Wireless networks: Link level design

41 Channel Access

42 Network design 43 Wireless networks today, Future networks

44 Ad hoc networks

45 High speed Digital cellular 46 Home RF and Blue tooth

UNIT –7

47 Control of networks 48 Objectives and methods of control 49 Circuit switched networks

50 Datagram Networks Network economics

51 Derived demand for network services

52 ISPs

53 ISPs 54 Subscriber demand model 55 Empirical model

UNIT –8

56 Optical networks: WDM systems

57 Optical cross connects

58 Optical cross connects 59 Optical LANs

60 Optical LANs 61 Optical paths and networks

62 Optical paths and networks


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Model Question Paper

1. Explain the principles of networking. 2. Explain the OSI model in detail. 3. Explain about distributed algorithm in detail with suitable example. 4. Draw the block diagram to explain about the operation of DQDB Protocol. 5. What are the parameters which specify the IP headers. 6. Explain IPV4 and IPV6 header. 7. With mathematical model of circuit switched network, obtain the equation which

places a lower bound on blocking probabilities. 8. what are the functions of SONET Switch? 9. Explain the ISDN Architecture, services, and standards. 10. Explain the main features of ATM Bearer service. 11. Write short notes on PNNI Routing. 12. Write short notes on VPI and VCI. 13. Explain the types of losses in a wireless channels. 14. what are SI and GI fibers. 15. What is meant by WDM Systems 16. Explain the types of Optical LANs. 17. Explain in detail the attributes of Global Network. 18. Specify the parameters which define the QOS of a network along with examples

related to wireless access to multimedia networks and Video Compression. 19. Explain about a Multi-hop LAN

20. Explain about the networking elements along with a neat diagrams 21. (a) What are the services provided by ATM adaptation layer? Explain the operations

of various AAL protocols. (b) What ate the major strengths of fiber channel. Explain. (c) Compare Gigabit and Fast Ethernet. (d) Give the ATM cell format. Explain how ATM cells are transmitted.

22.Describe 1) SONET/SDH frame formats 2) SONET/SDH Rings


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06EC841: MULTIMEDIA COMMUNICATIONS


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MULTIMEDIA COMMUNICATIONS

Subject Code : 06EC841 IA Marks : 25 No. of Lecture Hrs/Week : 04 Exam Hours : 03 Total no. of Lecture Hrs. : 52 Exam Marks :100

PART – A UNIT - 1 MULTIMEDIA COMMUNICATIONS: Introduction, multimedia information representation, multimedia networks, multimedia applications, media types, communication modes, network types, multipoint conferencing, network QoS application QoS. 7 Hours UNIT - 2 MULTIMEDIA INFORMATION REPRESENTATION: Introduction, digital principles, text, images, audio, video. 5 Hours UNIT - 3 TEXT AND IMAGE COMPRESSION: Introduction, compression principles, text compression, image compression. 7 Hours

UNIT - 4 AUDIO AND VIDEO COMPRESSION: Introduction, audio compression, DPCM, ADPCM, APC, LPC, video compression, video compression principles, H.261, H.263, MPEG, MPEG-1, MPEG-2, and MPEG-4. 7 Hours

PART – B

UNIT - 5MULTIMEDIA INFORMATION NETWORKS: Introduction, LANs, Ethernet, Token ring, Bridges, FDDI High-speed LANs, LAN protocol. 7 Hours UNIT - 6 THE INTERNET: Introduction, IP Datagrams, Fragmentation, IP Address, ARP and RARP, QoS Support, IPv8. 7 Hours UNIT - 7 BROADBAND ATM NETWORKS: Introduction, Cell format, Switfh and Protocol Architecture ATM LANs. 6 Hours UNIT - 8 TRANSPORT PROTOCOL: Introduction, TCP/IP, TCP, UDP, RTP and RTCP. 6 Hours TEXT BOOK:

1. Multimedia Communications: Applications, Networks, Protocols and Standards, Fred Halsall, Pearson Education, Asia, Second Indian reprint 2002.

2. REFERENCE BOOKS: 1. Multimedia Information Networking, Nalin K. Sharda, PHI, 2003. 2. “Multimedia Fundamentals: Vol 1 - Media Coding and Content Processing”, Ralf Steinmetz, Klara Narstedt, Pearson Education, 2004. 3. “Multimedia Systems Design”, Prabhat K. Andleigh, Kiran Thakrar, PHI, 2004.

Multimedia Communication


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LESSON PLAN

Class: VIII semester Subject code: 06EC841

Subject: MULTIMEDIA COMMUNICATION

Sl.No Topics to be Covered

PART - A

UNIT – 1: MULTIMEDIA COMMUNICATIONS

1 Introduction, multimedia information representation

2 Multimedia networks, multimedia applications

3 Media types,

4 Communication modes

5 Network types

6 Multipoint conferencing

7 Network QoS application QoS

8 Revision , University Question Paper Discussion

UNIT – 2: MULTIMEDIA INFORMATION REPRESENTATION

9 Introduction

10 Digital principles

11 Text, images Representation

12 Images Representation

13 Audio Representation

14 Video Representation


UNIT – 3: TEXT AND IMAGE COMPRESSION

16 Introduction

17 Compression principles

18 text compression

19 text compression

20 Image compression

21 Image compression


UNIT – 4: AUDIO AND VIDEO COMPRESSION

23 Introduction, audio compression

24 DPCM

25 ADPCM

26 APC, LPC

27 LPC, video compression

28 Video compression principles,H.261, H.263

29 MPEG, MPEG-1, MPEG-2, and MPEG-4


PART - B

UNIT – 5: MULTIMEDIA INFORMATION NETWORKS

31 Introduction, LANs

32 Ethernet, Token ring

33 Token ring, Bridges

34 Bridges, FDDI High-speed LANs

35 LAN protocol


UNIT – 6: THE INTERNET

37 Introduction, IP Datagrams

38 IP Datagrams

39 Fragmentation

40 IP Address


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41 ARP and RARP

42 ARP and RARP

43 QoS Support

44 IPv8


UNIT – 7 BROADBAND ATM NETWORKS

45 Introduction, Cell format

46 Cell format

47 Switch and Protocol Architecture ATM LANs.



50 Switch and Protocol Architecture ATM LANs


UNIT – 8: TRANSPORT PROTOCOL

52 Introduction, TCP/IP

53 TCP

54 UDP

55 TCP and UDP

56 RTP

57 RTCP

58 RTP and RTCP

59 University Question Paper Discussion

60 Revision

61 Revision

62 Revision


PAGE 22 MVJCE

Model question paper

1. Discuss Multimedia networks in detail 2. Discuss the applications of multimedia in detail.

3. Discuss Multimedia Communication modes.

4. Discuss the following:

i) Unformatted/Plain text ii) Formatted/rich text

iii) Hypertext

5. Explain Graphics, digitized documents and digitized pictures in images. 6. Discuss Static Huffman coding.

7. Discuss Dynamic Huffman coding.

8. Discuss Arithmetic coding. 9. Discuss Graphics Interchange Format

10. Discuss Joint Photographic Experts Group

11. Discuss Video Compression principles-MPEG,MPEG2

12. Discuss DPCM and Adaptive Differential DPCM 13. Discuss Code excited LPC

14. Explain the principles of image compression

15. Discuss Frame transmission & reception in Token Ring 16. Discuss Frame Formats of Token Ring

17. Discuss bridges in detail

18. Discuss Ipv8.

19. Explain message formats of ARP/RARP 20. Discuss Fragmentation & reassembly

21. Discuss FDDI in brief.

22. Discuss Swifth & Protocol architecture. 23. Discuss TCP protocol in brief.

24. Discuss UDP protocol in brief

25. Discuss RTP protocol in brief.

8 course diary - mvjce€¦ · · 2016-02-27electronics and communication engineering viii...

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