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15th June 2015, 04:48 PM
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ME EXTC Syllabus Shivaji University
I want to do M.E. (Electronics & Telecommunication) from Shivaji University .Will you please provide the M.E. (Electronics & Telecommunication) syllabus of Shivaji University?
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16th June 2015, 10:04 AM
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Re: ME EXTC Syllabus Shivaji University
Here I am providing the M.E. (Electronics & Telecommunication) syllabus of Shivaji University which you are looking for . Semester -I Advanced Light wave Communication Linear Algebra & Error Control Techniques Advanced Network Systems Random Processes Elective-I Seminar -I Semester -II RF & Microwave Circuit Design Wireless Communication Adaptive Signal Processing Elective II Elective III Seminar II Semester -III Seminar III Dissertation Phase I Semester -IV Dissertation Phase II M.E. (Electronics & Telecommunication) Semester.- I 1. ADVANCED LIGHTWAVE COMMUNICATIONS Lectures:- 3 Hrs/week Theory:- 100 marks Practical:- 2 Hrs/week Term Work:- 25 marks. 1. Introduction to guided optical communication. Optical Fibers, types of fibers & optical Cables, Study of losses during transmission through viz. Attenuation by Absorption & Scattering, Consideration of losses in designing of High Speed / High bandwidth optical communication systems, Selection of fiber for such systems. (8) 2. Optical Sources: Types of LEDs used in optical communication, their construction & operating principle, Types of Lasers. Principle of working of Lasers, solid state & injection Lasers, Optical amplifiers, EDFA, Soliton Systems & design of system required in LAN & WAN type of applications. Calculations of Power budgets and feasibility of system design for above optical sources. (7) 3. Optical Detectors: Introduction & study of type of detectors characteristics. Spectral spread and availability of detectors for 980 nm, 1.3 µm & 1.55 µm _ systems. Calculation of detector sensitivity and design considerations of suitable receivers for LAN, WAN applications. (8) 4. Multiplexing Components & Techniques : Concepts of WDM, DWDM system design parameters, Optical multiplex / Demultiplex design considerations- Angular dispersive devices, Dielectric thin film filter type devices, Hybrid & planer wave guide devices, Active WDM devices, Wavelength non selective devices, System application. (8) 5. Long Haul High Band Width Tx System : Designing systems for long haul high band width consideration-Outage, Bit error rate, Cross connect, Low & high speed interphases, Multiplex / Demultiplex consideration, Regenerator spacing, Degeneration & Allowances, Application consideration. (8) Practicals: Minimum eight experiments based on above syllabus. Reference Books: 1. Optical Communication Systems by John Gowar (PHI) 2. Optical Fiber Communication by Gerd Keiser (MGH) . 3. Optical Fiber Communication Principles & Practice by John M. Senior (PHI pub. 1996.) Recommended Journals 1. IEEE Proceeding In Optics. 2. Journal of Optical Society of America. 3. AT&T, Alcatel Optics Journals. 4. Hand book of Optics Vol I & II (MGH.) 5. Optics & Opto Electrics, vol I & II, Nigihawan & Gupta, (Narsoa publication.) 6. Advance In Light Wave Nypters Research Journals of AT & T ,Vol. 66 7. IIT Rourkee Compiled Seminar Proceeding of Fiber Optics in 1994. Web sites of University of Rochester, IIT Delhi, Miles Grieut Laser equipment. M.E. (Electronics & Telecommunication) Semester.- I 2. LINEAR ALGEBRA & ERROR CONTROL TECHNIQUES Lectures:- 3 Hrs/week Theory:- 100 marks Tutorial:- 1 Hr/week Term Work:- 25 marks. Section – I 1. Finite Dimension vector space, sub spaces, linear independent spaces & dimensions. (6) 2. Algebra of transformations, linear transformations, matrix algebra, simultaneous equations. (5) 3. Sum & intersection of subspaces, invariant sub spaces, Eigen Values, Characteristic vectors. (5) 4. Introduction to Inner product, Space, Schwarz’s Inequality, Orthogonality (4) Section – II 5. The arithmetic of Finite Fields finite fields based on the integrator ring and polynomial ring; primitive elements. Structure of finite fields. Linear block codes matrix description of linear block codes; standard arrays; hamming codes and Reed -Muller codes. (5) 6. Cyclic codes polynomial description of cyclic codes; minimal polynomials and conjugates; matrix description of cyclic codes; circuits for implementation of cyclic codes BCH codes definition of the codes. (5) 7. The Peterson decoder, fast decoding of BCH codes; Reed-Solomon codes. Code based on the spectral techniques Fourier transforms in a Galois field; Reed-Solomon codes. Code based on the spectral techniques Fourier transform in a Galois field. Conjugacy constraints and idempotent; spectral description of cyclic codes; extended Reed – Solomon codes and extended BCH codes; decoding algorithms based on spectral techniques. (7) 8. Convolutional codes; encoding of convoluional codes, structural properties of convolutional codes, distance properties of convolutional codes, maximum likelihood decoding of convolutional codes and majority logical decoding of convoluional codes. (5) Reference Books: 1. Linear Algebra – David c. Lay (Pearson Education.) 2. Linear Algebra – Krushanamurty, V.P. Mainra, J,L. Arora 3. Linear Algebra- Haufmann K & Kunze R, (Pearson Education, 1972) 4. An Introduction to Error Correcting Codes- Lin (PHI 1992). 5. Error Correcting Codes- W.W. Paterson & E.J. Weldon Jr, (Addison Wisley-1994.) 6. Theory & Practice of Error Control Code- R.E. Salhut , (Addison Wesley-1995.) 7. Text books on Error Control Codes - Williams (Springer Press.) 8. Digital Communication with Matlab - Proakis (TMH) M.E. (Electronics & Telecommunication) Sem.- I 3. ADVANCED NETWORK SYSTEMS Lectures:- 3 Hrs/week Theory:- 100 marks Practical:- 2 Hrs/week Term Work:- 25 marks. 1. Internet Technology: Internet address, ARP, RARP, Routing IP, Datagram, ICMP, UDP, TCP, DHCP and Mobile IP, Internet Routing Protocols, multicast Routing, IP V6. (6) 2. DNS Techniques: Names for machines, Flat Namespace, Hierarchical Names, Delegation of Authority for names, Subset Authority, TCP/IP Internet domain names, official and unofficial Internet, Domain names, items named and syntax of names, mapping domain, names to addresses, domain names resolution, efficient translation caching. The key to efficiency, Domain mapping message format, compressed name format, abbreviation of domain names, inverse mappings, pointer queries, object types and resource record contents, obtaining authority for a sub domain. (5) 3. FTP: File access and transfer, online shared access, sharing by file transfer, the major view of FTP, An example of anonymous FTP session, TFTP, NFS, NFS Implementation, Remote procedure call (RPC). (2) 4. Electronic Mail: Electronic Mail, Mailbox names and Aliases, Alias expansion and mail, Forwarding the the relationship of internetworking and mail, TCP/IP standards for electronic mail service, Electronic mail addresses, Pseudo domain addresses, simple mail transfer protocol (SMTP), The MIME extension for Non-ASCII Data, MIME multipart messages. (4) 5. Internet Security and firewall Design: Protection resources, the need for and information policy, communication, cooperation, and mutual mistrust, mechanisms for internet security, firewalls and Internet access, multiple connections and weakest links, firewall implementation and High-speed hardware, packet-level filters, security and packet filter specifications, the consequence of restricted access for clients, Accessing services through A firewall, the details of firewall architecture, Types of fire walls, stub network, An alternative Firewall implementation, monitoring and logging. (6) 6. ATM Networks: Need of ATM, BISDN model, ATM layer, ATM Adaptation Layer, ATM signaling, PNNI Routing. (8) 7. Advanced Network Architecture: IP forwarding Architecture, Overlay model MPLS, Integrated Services in the internet, RSVP, Differentiated Services (6) 8. Giga Bit Ethernet: Architecture and overview of Giga Ethernet, MAC, Physical layer, IEEE 802.32 Standard. (6) Practicals: Minimum eight experiments based on above syllabus. Reference Books: 1. Internet working with TCP/IP D.E. Comer, (for chapter 1& 2) 2. Communication Networks: Fundamental & concepts and Key Architectures by Leon-Garcia, widjaja (for cheaper 3 & 4) (Tata McGraw-Hill) 3. ATM – Rich Seifert (for chapter 5) 4. Unix Network Programming by W. Richard Stevens 5. Gigabit Ethernet: Technology and Applications for High Speed LANs, (Addison Wesley). 6. Gigabit Ethernet Networking, David Cunningham, William G. Lane, Bill Lane.(Pearson Higher Education ) 7. Data Communication & Networking- Behrmz Foruzan (TMH) M.E. (Electronics & Telecommunication) Semester.- I 4. RANDOM PROCESSES Lectures:- 3 Hrs/week Theory:- 100 marks Practical:- 2 Hrs/week Term Work:- 25 marks. 1. Concepts of Probability: Conditional probability and Baye’s theorem, Independence of events, Bernoulli trails. (5) 2. Random variables: Cumulative distribution, Joint probability density function, Statistical properties, Jointly distributed Gaussian random variables, Conditional probability density, properties of sum of random variables, Central limit theorem, Estimate of population means, expected value and variance and covariance, Computer generation of random variables. (6) 3. Multiple Random Variables: joint cumulative distribution function, Joint probability density function statistical properties, Jointly distributed Gaussian random variables, Conditional probability density, properties of sum of random variables, Central limit theorem, Estimate of population means, Expected value and variance and covariance, Computer generation of random variables. (7) 4. Markov Chains: Chapman Kolmogorov equation, Classification of states, Limiting probabilities, Stability of Markov system, Reducible chains, Markov chains with continuous state space. (6) 5. Queuing Theory: Introduction, Cost equation, steady state probabilities, Models of single server exponential queuing system with no limit and with finite buffer capacity (M/M/I, M/M/N). Queuing system with bulk service, Network of queues with open system and closed system. The M/G/I system and application of work to M/G/I. (5) 6. Random Processes: Properties, Auto correlation and cross correlation function, Estimate of auto correlation function. (5) 7. Spectral Density: Definition, Properties, white noise, Estimation of auto-correlation function using frequency domain technique, Estimate of spectral density, cross spectral density and its estimation, coherence. (5) Practicals: Minimum eight experiments based on above syllabus. Reference Books: 1. Introduction to probability Models,(Third edition) - Sheldon M. Ross. 2. Probability and Random Processes for Electrical Engg.-Alberto Lean-Garcia (Pearson Education.) 3. Stochastic Processes – J. Medhi , (New Age International.) 4. Probability random variables & Stochastic process- Athanasios Papoulis (MGH) 5. Introduction to Probability and Random Processes. By Jorge I. Aunin, V. Chandrashekar. 6. Probability & Statistics- Murrary R. Spiegel – (MGH.) M.E. (Electronics & Telecommunication) Semester - II 5. RF & MICROWAVE CIRCUIT DESIGN Lectures: - 3 Hrs/week Theory: - 100 marks Practical: - 2 Hr/week Term Work:- 25 marks. 1. Review of EM Theory : Maxwell’s equations, Plane waves in dielectric & conducting media, Energy & Power, Transmission lines, Solid state devices. (7) 2. Monolithic Microwave Integrated Circuits & Technology : History of Monolithic Microwave Integrated Circuits, Monolithic circuit components planner, Transmission Lines, Lumped and Distributed, Passive Elements, GaAs MESFET, Other active devices. Metal Semi-conductor Functions, and their characterization, Physical characteristics, modeling of GaAs MESFET & HEMT. Material and fabrication techniques of GaAs MESFET. Properties of GsAs. Electron Beam and X-ray lithography, Plasma assisted deposition, Molecular beam epitaxy & MOCVD, Ion milling, S-Parameter measurements and their use in GaAs MESFET, S-Parameter measurements : General concept, measurements, utilization of S-Parameters in circuit design, Amplifiers (Narrow band/Broad band), Oscillators, Mixers, Active & Passive Phase shifters, Monolithic Microwave Integrated circuit Process, Optical Control of MMIC’s. (16) 3. RF And Microwave Circuit Design: Single & multi port network, Basic definitions, interconnecting networks, network properties, & applications, scattering parameters. RF filter design, filter configurations, special filter realizations, filter implementation, coupled filter, Active components : Semiconductor basics, RF diodes, bipolar junction transistor, RF field effect transistors, High electron mobility transistors. Active RF components modeling : Diodes models, transistor models, measurement of active devices, scattering parametric device characterization. Matching & biasing network: Impedance matching using discrete components, micro strip line matching networks, amplifier class of operation, biasing networks. RF transistor amplifier design, amplifier power relations, stability considerations, constant gain, noise figure circles, constant VSWR circles, broadband, high power & multistage amplifiers, Oscillators & Mixer: basic oscillator model, High Frequency oscillator configuration, basic characteristics of mixers. (16) Practicals: Minimum eight experiments based on above syllabus. Reference Books 1. RF circuit design, theory & applications- Reinhold Ludwig, Pavel Bretchko, (Pearson Education – LPE) 2. Microwave Engineering-David M. Pozar (John Wiley & Sons) 3. Microwave Amplifier Design- Samuel Y. Liao, (PHI) 4. Microwave Engineering- Sisodiya and Raghuvanshi, (PHI) 5. Microwave Devices & Circuit Design”-Gupta & Shrivastava(PHI) 6 M.E. (Electronics & Telecommunication) Semester.- II 6. WIRELESS For detailed syllabus , here is the attachment |