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8/3/2019 M.tech.2008 Scheme & Syllabus (2)
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M.Tech. Programme
Electronics and Communication Applied Electronics and InstrumentationCurriculum and scheme of Examinations
SEMESTER I
Code No. Name of Subject
Credits
Hrs/
week
Exam
duration
Marks
ContinuousAssessment
UniversityExam Total
TAM 1001 Mathematical Methods forElectronics
3 3 3 50 100 150
TMC 1001 Advanced Digital Signal
Processing
3 3 3 50 100 150
TAC 1001 Advanced Optical
Instrumentation
3 3 3 50 100 150
TAC 1002 Non Linear Control Systems 3 3 3 50 100 150
TAC 1003 Adaptive Control Systems 3 3 3 50 100 150
TAC 1004 Advanced Digital SystemDesign
3 3 3 50 100 150
TAC 1101 Instrumentation & Control
System Lab
1 2 - 50 - 50
TAC 1102 Project Part I 1 - - 50 - 50
TAC 1103 Seminar 2 2 - 50 - 50
TOTAL 22 450 600 1050
SEMESTER II
Code No. Name of Subject
Credits
Hrs/week
Exam
duration
Marks
Continuous
Assessment
End
SemesterExam
Total
TAC 2001 Digital Image Processing 3 3 3 50 100 150
TAC 2002 Mixed Signal Circuit Design 3 3 3 50 100 150
** Stream Elective I 3 3 3 50 100 150
** Stream Elective II 3 3 3 50 100 150
** Department Elective 3 3 3 50 100 150
* Non- Dept. (Interdisciplinary)
Elective
3 3 3 50 100 150
TAC 2101 VLSI & Embedded Systems Lab 1 2 - 50 -- 50
TAC 2102 Project Part II 2 - - 100 - 100
TAC 2103 Seminar 2 2 - 50 - 50
TOTAL 23 --- 500 600 1100
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2* Students can select a subject from the subjects listed under non department (Interdisciplinary) electives for the second
semester as advised by the course coordinator.
** Students can select a subject from the subjects listed under stream/department electives for the second semester as
advised by the course coordinator.
STREAM ELECTIVES OFFERED IN APPLIED ELECTRONICS AND INSTRUMENTATION FOR SEMESTER
II
TAE 2001 Micro Electro Mechanical SystemsTAE 2002 Nano Electronics
TAE 2003 Neuro Fuzzy SystemsTAE 2004 Computer Vision
SEMESTER III
Code No. Name of Subject
Credits
Hrs/week
Exam
duration
MarksContinuousAssessment
EndSemester
ExamTotal
** Stream Elective III 3 3 3 50 100 150
** Stream Elective IV 3 3 3 50 100 150
TCC 3101 Research Methodology 1 - - 50 - 50
TCC 3102 Industrial Training 1 3 - 50 - 50
TAC 3101 Thesis - Preliminary 4 14 - 200 - 200
TOTAL 12 400 200 600
** Students can select a subject from the subjects listed under stream electives for the third semester as advised by thecourse coordinator.
STREAM ELECTIVES OFFERED IN APPLIED ELECTRONICS AND INSTRUMENTATION FOR
SEMESTER III
TAE 3001 Computer aided design of Control Systems
TAE 3002 PWM Schemes for Power Converters
TAE 3003 RF MEMS Circuit DesignTAE 3004 Current Topics in Instrumentation
SEMESTER IV
Code No Subject
Name Credits
Hrs/week
Marks
Continuous Assessment University ExamTotal
Guide Evaluation
Committee
Thesis
Eva.Viva
Voce
TMC 4101 Thesis 12 29 200 200 100 100 600
Total 12 29 200 200 100 100 600
Note : 6 to 10 hours per week is for department assistance
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M.Tech. Programme
Electronics and Communication Microwave and TV Engineering
Curriculum and scheme of ExaminationsSEMESTER I
Code No. Name of Subject
Cr
edits
Hr
s/
we
ek
Ex
am
du
ration
Marks
Continuous
Assessment
University
Exam Total
TMM 1001 Mathematical Methods forCommunication
3 3 3 50 100 150
TMC 1001 Advanced Digital Signal
Processing
3 3 3 50 100 150
TMC 1002 Advanced Digital
Communication
3 3 3 50 100 150
TMC 1003 Optical Communication Systems 3 3 3 50 100 150
TMC 1004 RF Circuits Design 3 3 3 50 100 150
TMC 1005 Antennas & Design 3 3 3 50 100 150
TMC 1101 Communication Systems &Optics Lab
1 2 - 50 - 50
TMC 1102 Project Part I 1 - - 50 - 50
TMC 1103 Seminar 2 2 - 50 - 50
TOTAL 22 450 600 1050
SEMESTER II
Code No. Name of Subject
Credits
Hrs/week
Exam
duration
Marks
ContinuousAssessment
EndSemester
Exam
Total
TMC2001 Wireless MicrowaveCommunication
3 3 3 50 100 150
TMC2002 Microwave Integrated Circuits 3 3 3 50 100 150
** Stream Elective I 3 3 3 50 100 150
** Stream Elective II 3 3 3 50 100 150
** Department Elective 3 3 3 50 100 150
* Non Dept.(Interdisciplinary)
Elective
3 3 3 50 100 150
TMC2101 RF Design & Measurements Lab 1 2 - 50 - 50
TMC2102 Project Part II 2 - - 100 - 100
TMC2103 Seminar 2 3 - 50 - 50
TOTAL 23 --- 500 600 1100
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4* Students can select a subject from the subjects listed under non department (Interdisciplinary) electives for the second
semester as advised by the course coordinator.
** Students can select a subject from the subjects listed under stream/department electives for the second semester as
advised by the course coordinator.
STREAM ELECTIVES OFFERED IN MICROWAVE AND TV ENGINEERING FOR SEMESTER II
TME 2001 Computational Methods for ElectromagneticsTME 2002 Secure Communication
TME 2003 Design of CDMA Systems
TME 2004 CMOS RF Circuit Design
SEMESTER III
Code No. Name of Subject
Credits
Hrs/week
Exam
duration
MarksContinuous
AssessmentEnd
Semester
ExamTotal
** Stream Elective III 3 3 3 50 100 150
** Stream Elective IV 3 3 3 50 100 150
TCC 3101 Research Methodology 1 - - 50 - 50
TCC 3102 Industrial Training 1 3 - 50 - 50
TMC3101 Thesis - Preliminary 4 14 - 200 - 200
TOTAL 12 400 200 600
** Students can select a subject from the subjects listed under stream electives for the third semester as advised by thecourse coordinator.
STREAM ELECTIVES OFFERED IN MICROWAVE AND TV ENGINEERING FOR SEMESTER III
TME 3001 Electromagnetic Interference and Compatibility
TME 3002 Simulation of Communication Systems & NetworksTME 3003 Advanced Coding Theory
TME 3004 Current Topics in Communication
SEMESTER IV
Code No SubjectName C
redits
Hrs/week
Marks
Continuous Assessment University ExamTotal
Guide Evaluation
Committee
ThesisEva.
VivaVoce
TMC 4101 Thesis 12 29 200 200 100 100 600
Total 12 29 200 200 100 100 600
Note : 6 to 10 hours per week is for department assistance
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M.Tech. Programme
Electronics and Communication Signal ProcessingCurriculum and scheme of Examinations
SEMESTER I
Code No. Name of Subject
Credits
Hrs/
week
Exam
duration
Marks
ContinuousAssessment
UniversityExam Total
TSM 1001 Linear Algebra for Signalprocessing
3 3 3 50 100 150
TSC 1001 Random Processes &
Applications
3 3 3 50 100 150
TMC 1002 Advanced Digital
Communication
3 3 3 50 100 150
TSC 1002 DSP Processor & Architecture 3 3 3 50 100 150
TSC 1003 Digital Filter Design &
Applications
3 3 3 50 100 150
TSC 1004 Speech Signal Processing 3 3 3 50 100 150
TSC 1101 DSP Systems Lab 1 2 - 50 - 50
TSC 1102 Project Part I 1 - - 50 - 50
TSC 1103 Seminar 2 2 - 50 - 50
TOTAL 22 450 600 1050
SEMESTER II
Code No. Name of Subject
Credits
Hrs/week
Exam
duration
Marks
ContinuousAssessment
EndSemester
Exam
Total
TAC 2001 Digital Image Processing 3 3 3 50 100 150
TSC 2001 Estimation and Detection Theory 3 3 3 50 100 150
** Stream Elective I 3 3 3 50 100 150
** Stream Elective II 3 3 3 50 100 150
** Department Elective 3 3 3 50100 150
* Non Dept. (Interdisciplinary)Elective
3 3 3 50 100 150
TSC 2101 VLSI & Embedded Systems Lab 1 2 - 50 - 50
TSC 2102 Project Part II 2 - - 100 - 100
TSC 2103 Seminar 2 2 - 50 - 50
TOTAL 23 --- 500 600 1100
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6* Students can select a subject from the subjects listed under non department (Interdisciplinary) electives for the second
semester as advised by the course coordinator.
** Students can select a subject from the subjects listed under stream/department electives for the second semester as
advised by the course coordinator.
STREAM ELECTIVES OFFERED IN SIGNAL PROCESSING FOR SEMESTER II
TSE 2001 Statistical Signal ProcessingTSE 2002 Optical Signal processing
TSE 2003 Multirate Systems & Wavelets
TSE 2004 Biomedical Signal Processing & Systems
SEMESTER III
Code No. Name of Subject
Credits
Hrs/week
Exam
duration
MarksContinuous
AssessmentEnd
SemesterExam
Total
** Stream Elective III 3 3 3 50 100 150
** Stream Elective IV 3 3 3 50 100 150
TCC 3101 Research Methodology 1 - - 50 -50
TCC 3102 Industrial Training 1 3 - 50 - 50
TSC 3101 Thesis- Preliminary 4 14 - 200 - 200
TOTAL 12 400 200 600
** Students can select a subject from the subjects listed under stream electives for the third semester as advised by the
course coordinator.
STREAM ELECTIVES OFFERED IN SIGNAL PROCESSING FOR SEMESTER III
TSE 3001 Spectral Analysis
TSE 3002 VLSI Structures for Digital Signal ProcessingTSE 3003 Array Signal Processing
TSE 3004 Current Topics in Signal Processing
SEMESTER IV
Code No Subject
Name Credits
Hrs/week
Marks
Continuous Assessment University ExamTotal
Guide Evaluation
Committee
ThesisEva.
VivaVoce
TMC 4101 Thesis 12 29 200 200 100 100 600
Total 12 29 200 200 100 100 600
Note : 6 to 10 hours per week is for department assistance
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List of Department Electives for II Semester (Common for all Streams)
TCD 2001 Design of VLSI Systems
TCD 2002 Design of Embedded SystemsTCD 2003 Optimization Techniques
TCD 2004 Information Hiding & Data Encryption
NON-DEPARTMENT (INTERDISCIPLINARY) ELECTIVES OFFERED II SEMESTER COMMON TO ALL
STREAMS IN ELECTRONICS & COMMUNICATION
1. CSI 2001 Finite Element Analysis
2. CSI 2002 Theory of Plates and Shells
3. CSI 2003 Advanced Mechanics of Materials
4. CSI 2004 Mechanics of Composites
5. CSI 2005 Random Vibration
6. CEI 2001 Philosophy of Technology
7. CEI 2002 Environmental Management8. CEI 2003 Environment and Pollution
9. CGI 2001 Geotechnical Engineering for Infrastructure Projects10. MII 2002 Financial Management
11. MII 2003 Organizational behavior
12. MII 2004 Operations Research13. MII 2005 Management Information Systems14. MDI 2001 Applied Finite Element Methods
15. MDI 2002 Acoustics and Noise Control for Engineers
16. MPI 2001 Computational Fluid Dynamics17. MTI 2001 Numerical Methods
18. EGI 2001 Navigation, Guidance And Control
19. EPI 2001 Energy Conservation and Management
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APPLIED ELECTRONICS AND
INSTRUMENTATION
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TAM 1001 MATHEMATICAL METHODS FOR ELECTRONICS 3-0-0-3
Algebraic structures. Sets-relations-Groups-subgroups-cosets and Lagranges TheoremRings Integral domain and Fields-Definition and examples.
Linear Algebra. Vector space-subspace-linear dependence-basis-dimension-Interpolation and
wronskian-Linear Transformation-change of bases-diagonalization.
Eigen values and eigen vectors-diagonalization of matrices--exponential matrices-of linear recurrence
relations.
Probability spaces: Random variables-distributions and densities-statistical independence-
expectations-moments and characteristic functions.
Sequence of random variables and its convergence-Chebychevs inequality-law of large numbers-
Central limit theorem.
Random processes: Definition and classification of random processes-stationarity(strict sense and
wide sense)-Autocorrelation function and its properties.-Ergodicity- ergodic theorems. spectral density
function and its properties.
Special Random Processes.Poisson process-properties-Markov process- Markov Chains-Transition
probability matrix-Chapman-Kolmogorov theorem.-Birth death process-weiner process.
References:
1. C.L.Liu,Elements of Discrete Mathematics, Tata McGraw Hill
2. Fraleigh,A first course in abstract algebra, Narosa3. Jin Ho Kwak and Sungpyo Hong,Linear Algebra-, 2/e, Springer.
4. Strang and Gilbert,Introduction to Linear Algebra , 3/e, Cambridge.
5. J.Medhi, Stochastic processes, New Age International, India
6. Stark Henry,Probability and random process with application to signal processing,3/e,Pearson
Education India.
7. Gray.R.M and Davisson.L.D,An introduction to statistical signal processing, Cambridge university
press.
8. T. Veerarajan, Probability, Statistics and Random processes, Tata- McGraw Hill
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks eachcovering entire syllabus out of which any five shall be answered. For the internal marks of 50, Two test
of 20 marks each and 10 marks for assignments (Minimum two)
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TMC 1001 ADVANCED DIGITAL SIGNAL PROCESSING 3-0-0-3
Basics of Multirate systems and its application, up sampling and Down - Sampling, Fractional
Sampling rate converter. Polyphase decomposition. Efficient realisation of Multirate systems.Uniformfilter banks and it's implementation using polyphase decomposition. Two channel Quadrature Mirror
Filter Banks, Perfect Reconstruction, M-channel PR QMFB.
Time Frequency Analysis, Heisenberg's uncertinity principle. Short time fourier transform - Gabortransform. Continous Wavelet Tranform and it's properties. Multi Resolution Analysis, Discrete
Wavelet Transform, Orthonormal Wavelet Analysis - Filterbank interpertation. Haar and Daubechise
wavelets, Bi-orthogonal wavelets and Filter bank interpretation. B -Spline wavelets, Wavelet
packets.2D wavelt transforms. Application of wavelet tranform for data compression, noise reduction.
Linear Prediction -Forward and Backward Prediction - Levinson-Durbin Algorithm, Schur Algorithm.
Power spectrum estimation of signals: Wide Sense Stationary Random Processes. Power spectral
density. Non parametric methods: periodogram,Backman-Tuckey method. Parametric method: ARMA,
AR processes, Yule-Walker method.
Reference
1) P. P. Vaidyanathan,Multirate Systems and Filterbanks, Prentice Hall
2) Wavelet Transforms - Bopadikar and Rao, Pearson Education3) Insight into wavelets, K. P. Soman, Prentice Hall India
4) Digital signal Processing, By John G. Proakis, Dimitris G. ManolakisPearson Education
Reading
1) L. Cohen, Time Frequency Analysis, Prentice Hall.
2) Wavelets and Filterbank, G Strang & T Nguyen , Wellesly-Cambridge3) Wavelets and subband coding, M Vetterli & J Kovacevic, Prentice Hall
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAC 1001 ADVANCED OPTICAL INSTRUMENTATION 3-0-0-3
Lasers for instrumentation:-Condition for laser oscillations-Coherence, He-Ne laser -frequencystabilization, semiconductor lasers, line width and frequency stability. Triangulation, types of laser
telemeters - Pulsed and sine wave telemeters -accuracy and ambiguity problem. LIDAR andapplications.
Laser for interferometry:- Basic optical interferometers -Performance parameters and limits of
performance. Laser vibrometry- white light interferometry. Speckle- pattern instruments-Speckleproperties-Speckle in single point interferometers-electronic speckle pattern inteferometry
Laser Doppler Velocimetry-Principle of operation and performance parameters. Doppler signal
processing.
Gyroscopes-The Sagnac effect-Basic Gyro configurations Fiber optic Gyroscopes (FOG)-Open loop
FOG-components and technology to implement FOGs.
Reference:-
Silvano Donati, Electro-Optical Instrumentation-Sensing and Measuring with Lasers, Pearson
Education, 2005 Edn.
Reading:
Vardeyen, Joseph, T-Laser Electronics, 2nd
Edn 1993, Prentice Hall of India Private Limited
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems & 50%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAC 1002 NON-LINEAR CONTROL SYSTEM 3-0-0-3
Non-linear systems
-Characteristics, Common non linearities.
Method of Analysis:-Linearization techniques
-Describing function analysis of non-linear systems. Dual input Describingfunction.(DIDF)
-Phase plane analysis of non-linear systems, existence of limit cycles
- Lyapunov stability theory for continuous and discrete time systems.
Construction of Lyapunov function.
Non linear control system design:
-Variable structure controller and sliding control.
- Implementation of switching control laws.
- Cascade design.
-Partial state feedback design.
References:1. Jean-Jacques E. Slotine&Weiping Li,Applied Nonlinear Control, Prentice-
Hall.,NJ,19912. Hassan K Khalil, Nonlinear Systems, Macmillan Publishibg Company,NJ
3. M Vidyasagar,Nonlinear Systems Analisis Prentice-Hall,India,19914. Shankar Sastry,Nonlinear System Analysis,Stability and Control, Springer,19995. Ashok D Belegundu,Tirupathi R Chandrupatla, Optimization concepts and Applications in
Engineering, Pearson Education,Delhi,20026. John E Gibson,Nonlinear Automatic Control, Mc Graw Hill,NewYork
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAC 1003 ADAPTIVE CONTROL SYSTEMS 3-0-0-3
Different adaptive control strategies - Gain scheduling, MRAS, STR, stochastic adaptive control - Lp
spaces - Norms, - stability of Dynamic system. Differential equations, stability definitions - Lyapunovstability Theory - Exponential stability theorems estimating parameters in dynamic systems with
least square methods .
MRAS adaptation law adaptation law based on stability criterion adaptation based on MIT rule Design of MRAS based on MIT rule Design of MRAS based on Lyapunov methods simulation ofMRAS systems.
Self Tuning Regulators Pole placement design Indirect STR continuous time STR Direct STR-
simulation of STR systems - stochastic self tuning regulators- linear quadrant STR adaptive
predictive control .
Reference:
Shankar Sastry & Mare Bodson,Adaptive Control, IEEE press
K.J Astrom & B.Wittenmark,Adaptive Control, Pearson Education
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAC 1004 ADVANCED DIGITAL SYSTEM DESIGN 3-0-0-3
Propagation Delay and Timing Defects in combinational Logic. Hazards static and dynamic.
Essential hazards. Static hazard free and dynamic hazard free combinational logic circuits design.Function hazards.
Synchronous State machine Design and analysis. Design of simple Synchronous State machineDesign with edge-triggered flip-flop. Analysis of simple State machine. Detection and elimination of
output race glitches. Detection and elimination of static hazards in the output logic. Asynchronousinputs: Rules and caveats. Clock skew. Clock sources and clock signal specifications. Initialization and
reset of the FSM: Sanity circuits. Design of complex state machines. Algorithmic state machine chartsand state tables. Array algebraic approach to logic design. State minimization. System-level design:
controller, data path and functional partition.
Asynchronous state machine design and analysis. Lumped path delay models for asynchronous
FSMs. Functional relationships and stability criteria. Excitation table for LPD model. State diagram, K-
maps and state table for asynchronous FSMs. Design of the basic cells by using the LPD model. Design
of the Rendezvous modules, , RET D flip-flop, RET JK flip-flop. Detection and elimination of timing
defects in asynchronous FSMs. Single-transition-time machines and Array algebraic approach.
Hazard-free design of fundamental mode FSMs. One-hot design of Asynchronous State Machines.
Design and Analysis of fundamental mode FSMs.
Design of state machines using Algorithmic State Machines (ASM) chart as a design tool. Introduction
to Field Programmable Gate Arrays (FPGA)- Types, Architecture of Xilinx Vertex II series,
Technology mapping, tools for technology mapping. Design examples, FPGA implementation of
adders, subtractors, multipliers, Booth I multiplier, carry save SRT 2 Dividers.
References:
1. Richard F. Tinder,Engineering Digital Design, Academic Press20012. Jean-Pierre Deschamps, Gery Jean Antoine Bioul, Gustavo D. Sutter Synthesis of Arithmetic
Circuits FPGA, ASIC & Embedded Systems, Wiley Interscience 2006
Reading
1. William I. Fletcher,An Engineering Approach to Digital Design, PHI, 1996.2. N.N. Biswas,Logic Design Theory, PHI, 1993.3. James E. Palmer, David E. Perlman,Introduction to Digital Systems, TMH, 1996.
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAC 1101 INSTRUMENTATION AND CONTROL SYSTEM LAB 0-0-2-1
1. Data Acquisition and control using Lab VIEW.2. Setting up of PROFIBUS Network.3. Distributed Control through PROFIBUS.4. Familiarisation of SCADA and application development using SCADA.5. Control of Robotic arm.6. PLC.7. Cascade control.8. Feed forward control.
Marks: Continuous Evaluation: 30
End Semester Exam & Viva-voce: 20
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TAC 1102 PROJECT PART I - - - 1
Project has 2 parts. The Project shall be hardware / hardware platform based.The student is expected to select and complete the design of the project work and submit the design
phase report and presentation. The design phase report shall be submitted for evaluation. This shall bein soft bonded form. This is the first volume of the Project report. The Second volume is the final
project report in the second semester.Marks: Project Design Report Evaluation : 25
Presentation & Viva-Voce : 25
TAC 1103 SEMINAR 0-0-2-2
The student is expected to present a seminar in one of the current topics in Electronics,
Communication, Instrumentation, Computers, Information Technology, Control systems and related
areas. The student will under take a detailed study based on current published papers, journals, books
on the chosen subject and submit seminar report at the end of the semester.
Marks: Seminar Report Evaluation : 25Seminar Presentation : 25
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TAC 2002 MIXED SIGNAL CIRCUIT DESIGN 3-0-0-3
Standard CMOS device models BSIM 3, BSIM 4. Differential Amplifiers, Cascode differentialamplifier, Wide Swing Differential Amplifier.
Design of CMOS Op Amps, Compensation, Low Noise Op Amps, Low voltage Op Amps.Design of two stage open loop comparator, High speed comparators.
Switched capacitor circuits First order switched capacitor circuits, capacitor filters.PLL, Sense amplifiers, DAC, ADC High speed ADC, Over sampling ADC.
Reference:
Phillip E. Allen, Douglas R. Holbery, CMOS Analog Circuit Design , Oxford, 2004
Reading:
1. Razavi B.,Design of Analog CMOS Integrated Circuits, Mc G Hill, 2001.2. Baker, Li, Boyce, CMOS: Circuits Design, Layout and Simulation, Prentice Hall India, 2000For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAC 2101 VLSI AND EMBEDDED SYSTEMS LAB 0-0-2-1
VLSI EXPERIMENNTS USING TANNER TOOLS:
CMOS analog circuits
CMOS digital circuitsCMOS implementation of Neural Networks
Reference voltage sources
Experiments using available kits, packages and tools.
EMBEDDED SYSTEMS EXPERIMENTS
1. Embedded Applications using C Programming and C++ programming2. Assembler level programming for ARM3. C programming to illustrate ARM/Thumb Networking
Marks: Continuous Evaluation: 30
End semester Exam and Viva-voce: 20
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TMC 2102 PROJECT PART II - - -2
Each student is expected to prepare a report on the project work done by him/her and present a paper
highlighting the work done by him/her in a seminar. The student is expected to complete the projectwork assigned to him/her and submit the project report by the end of semester. This report shall be of a
hard bound type and consist of design phase report as volume one and other part as volume two.
Marks: Project Design Report Evaluation : 50Presentation & Viva-Voce : 50
TCC 2103 SEMINAR 0-0-2-2
The student is expected to present a seminar in one of the current topics in Electronics,
Communication, Instrumentation, Computers, Information Technology, Control systems and related
areas. The student will under take a detailed study based on current published papers, journals, books
on the chosen subject and submit seminar report at the end of the semester.
Marks: Seminar Report Evaluation : 25
Seminar Presentation : 25
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TAE 2001 MICRO ELECTRO MECHANICAL SYSTEMS 3-0-0-3
Historical Background: Silicon Pressure sensors, Micromachining, MicroElectroMechanical Systems.
Microfabrication and Micromachining : Integrated Circuit Processes, Bulk Micromachining : IsotropicEtching and Anisotropic Etching, Wafer Bonding, High Aspect-Ratio Processes (LIGA)
Physical Microsensors : Classification of physical sensors, Integrated, Intelligent, or Smart sensors,Sensor Principles and Examples : Thermal sensors, Electrical Sensors, Mechanical Sensors, Chemical
and BiosensorsMicroactuators : Electromagnetic and Thermal microactuation, Mechanical design of microactuators,
Microactuator examples, microvalves, micropumps, micromotors-Microactuator systems : Success
Stories, Ink-Jet printer heads, Micro-mirror TV Projector.
Surface Micromachining: One or two sacrificial layer processes, Surface micromachining requirements,
Polysilicon surface micromachining, Other compatible materials, Silicon Dioxide, Silicon Nitride,
Piezoelectric materials, Surface Micromachined Systems : Success Stories, Micromotors, Gear trains,
Mechanisms
Optical MEMS: Micro opto electro mechanical sensors and systems, fiber optic sensors, Fiber bragg
grating, miniature sensors for temperature, pressure, fluid flow applications.
MEMS for automotive, communication and other applications, sensors, small structure.
Introduction to BioMEMS-materiels,sensors,fabrication,application.
References
1. Stephen D. Senturia, "Microsystem Design" by, Kluwer Academic Publishers, 2001.2. Marc Madou, Fundamentals of Microfabrication by, CRC Press, 1997.Gregory
3. Kovacs, Micromachined Transducers Sourcebook WCB McGraw-Hill, Boston,1998.
4. M.-H. Bao, Micromechanical Transducers: Pressure sensors, accelrometers, andgyroscopes by Elsevier, New York, 2000.
5. Gabriel M. Rebeiz,RF MEMS, Theory, Design, and Technology, Wiley Interscience,2003.
Reading:
1. Masood Tabib-Azar,Microactuators, Kluwer, 1998.2. Ljubisa Ristic, Editor, Sensor Technology and Devices, Artech House, 19943. Nadim Maluf, An Introduction toMicroelectromechanical Systems Engineering, Artech House,
2000.
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks eachcovering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
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TAE 2002 NANO ELECTRONICS 3-0-0-3
An atomistic view of electronic conduction, Schrodinger equation, Self-consistent field -Basis
functions, Band structure, Sub-bands - Capacitance, Level broadening Coherent transport - Atom totransistor and
new paradigms in nano electronics - Modeling and Analysis of single electron transistor (SET).
Reversible Computation - Reversible Turing machine- Entropy of Logic gates - Energy andInformation Loss - Reversible Logic Gates- requirements - NOT, k-CONT, TOFFOLI gates -
Reversible Logic synthesis - Elimination of Garbage - Reversible Lattice structures - ModifiedReconstructability Analysis (MRA), Reversible Decision Diagrams, Quantum computation and
Quantum Logic gates
Reference
1. S. Data, Quantum Transport: Atom to Transistor, Cambridge UniversityPress, 2005
2. David K. Ferry, Shunt Oda, Silicon Nanoelectronics, CRC Press, 2005
3. A N Al-Rabadi, Reversible Logic synthesis from Fundamental to Quantumcomputing, Springer 2004
Reading
1. CH Bennet,Logical Reversibility of Computation, IBM Jl. of Res.
Develp., 17:525-532, 1973
2. CH Bennet, The thermodynamics of computation - a review, Int. J. oftheoret. Phys., 21(1982) 905-940
3. R Lanunder,Irreversibility and heat generation in the computingprocess, IBM Jl. of Res. Develp., 5:183-191, 1961
4. Vivek V Shende, Aditya K Prasad etc, Synthesis of Reversible Logiccircuits, IEEE Tran. on Comp. aided Design of Integrated Circuits and
Systems, Vol 22, No 6, 710-722, June 2003
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAE 2003 NEURO FUZZY SYSTEMS 3-0-0-3
Learning processes-Single layer and Multi layer Perceptrons-Principal Component Analysis-Independent Component Analysis-Stochastic Machines.
Introduction to Neurodynamics and Neuroprogramming.Fuzzy systems-Crisp sets and fuzzy sets operation on fuzzy sets fuzzy relations fuzzy control
systems Case studies. Neural networks and fuzzy systems Models-Case studies.
Genetic Algorithms and Fuzzy Logic- Basics-Design issues-Convergence rate-Genetic Algorithm
methods-Case studies.
References :
1. Simon Haykin,Neural Networks, a comprehensive foundation, 2/e, Pearson Education.2. Timothy J Ross, Fuzzy logic with Engineering Applications 2/e, McGraw Hill3. John Yen, Reza Langari, Fuzzy Logic-Intelligence, Control and Instrumentation, Pearson
Education, 2002
Reading
1. Yegna Narayana B,Artificial Neural Networks PHI2. Ahamad M.Ibrahim,Introduction to Applied Fuzzy Electronics, PHI3. S.Rajasekharan,G.A Vijayalakshmi Pai ,Neural Networks,Fuzzy Logic and Genetic Algorithams,
PHI
4. Martin T.Hagan, Howard B.Demuth, Mark BealeNeural Network Design, Vikas ThomsonLearning.
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks eachcovering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TAE 2004 COMPUTER VISION 3-0-0-3
Introduction: The Marr paradigm and scene reconstruction, Other paradigms for image analysis.
Image Formation: Image Geometry, Radiometry, DigitizationBinary Image Analysis and Segmentation: Properties, Digital geometry, Segmentation
Image Processing for Feature Detection and Image Synthesis: Edge detection, corner detection,Line and curve detection, SIFT operator, Image-based modeling and rendering, Mosaics, snakes.
Shape from X : Shape from shading, Photometric stereo, Texture, Occluding contour detection.
Motion Analysis: Motion detection and optical flow, Structure from motion
Photogrammetry and Stereo.
Object Recognition: Model-based methods, Appearance-based methods
Invariants.
References:D. A. Forsyth and J. Ponce, Computer Vision: A Modern Approach , Prentice Hall, 2003.
Reading:
1. B. K. P. Horn Robot Vision, MIT Press, 1986.
2. Linda Shapiro and George Stockman, Computer Vision, Prentice Hall, 20013. R. Jain, R. Kasturi and B. Schunk,Machine Vision, McGraw Hill, 1995
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TCC 3101 RESEARCH METHODOLOGY 0-0-0-1
Introduction Meaning of research Objectives of research Motivation in research Types of
research Research approaches Significance of research Research methods vs Methodology Criteria of good research.
Defining Research Problem What is a research problem Selecting the problem Necessity of
defining the problem Literature review Importance of literature review in defining a problem
Critical literature review Identifying gap areas from literature review
Research design Meaning of research design Need Features of good design Important concepts
relating to research design Different types Developing a research plan
Method of data collection Collection of data- observation method Interview method Questionnaire
method Processing and analysis of data Processing options Types of analysis Interpretation of
results
Report writing Types of report Research Report, Research proposal ,Technical paper Significance Different steps in the preparation Layout, structure and Language of typical reports Simple
exercises Oral presentation Planning Preparation Practice Making presentation Answeringquestions - Use of visual aids Quality & Proper usage Importance of effective communication -
Illustration
References
1. Coley S M and Scheinberg C A, 1990, "Proposal Writing", Newbury SagePublications.
2. Leedy P D, "Practical Research : Planning and Design", 4th Edition, N
W MacMillan Publishing Co.
3. Day R A, "How to Write and Publish a Scientific Paper", Cambridge
University Press, 1989.
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TCC 3102 INDUSTRIAL TRAINING 3-0-0-1
There shall be 15 days training in Industrial / Research organization by each student during the Second
Semester vacation and present a Seminar and report during the Third Semester. The report shall beapproved by the organization / industry where the student have undergone the training.
Marks:Evaluation of reports : 25
Seminar Presentation : 25
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TAE 3001 COMPUTER AIDED DESIGN OF CONTROL SYSTEMS 3-0-0-3
Introduction The design process Quantitative behavior and stability theory Liapunov stability
theorems Root locus analysis construction design concepts .
Case study: A light source tracking system, control of a flexible space craft Root locus design cascade P plus I compensator cascade lead compensator cascade lag lead compensator.Case study control of a flexible space craft State space analysis state space representation state
transformation and diagonalisation stability controllability observability state space design
State feed back and pole placement case study: A magnetic levitation system.
Control system design using MATLAB & SIMULINK Part-I. Introduction the design process
simulating simple systems with SIMULINK mathematical modes of systems state variable models
feed back control system characteristics performance of feedback control systems.
Control system design using MATLAB & SIMULINK Part-II. Stability of linear feedback systems
Root locus method Design of feedback control systems Design of state variable feedback systems
Robust control systems.
References :1. Robert H Bishop,Modern Control Systems Analysis & Design using MATLAB &
SIMULINK, Addison Wesley.
2. Raymond T Stefani etal,Design of feedback control system, 3rd
edn., Saunders College Publishing3. Bernard Friedland,Advanced Control System Design, PHI
Reading:
1. John J DAzoo, Constantine H Houpis,Linear Control System Analysis & Design, 4th Edn., Mc.
Graw Hill
2. Edward W Kamen, Bonnies S Heek, Fundamentals of Signals and Systems using
MATLAB.
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%Theory. For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments
(Minimum two) /Term Project.
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TAE 3002 PWM SCHEMES FOR POWER CONVERTERS 3-0-0-3
Three phase Voltage Source Inverters (VSI) - Fundamental Concepts of PWM schemes, Sine-TrianglePWM, - Space Vector PWM - Comparison of Sine-Triangle PWM and Space Vector PWM - Zero
vectors and importance of their placement in PWM -Harmonic Distortion- Harmonic Distortion factors
for 3 phase inverters, Harmonic loses in PWM.
Multilevel Inverters- Fundamental Concepts, Modulation schemes- Sine triangle PWM and Space
vector PWM 3-level inverters, Extension of the schemes to higher level inverters. Optimum switching
in space vector PWM- Over modulation of a Voltage Source Inverter- Space Vector approach to Over
modulation - Implementation of PWM controllers- Overview, DSP based implementation.
Current hysterisis control of a Voltage Source Inverter - Introduction to Random PWM strategy .
Reference
1. G.Holmes & T.A. Lipo, Pulse width Modulation for Power Converters, Principle and
practice, IEEE Press, 2003
2. M.P.Kazmierkowski ,Control of Power Converters : Selected Problems, AcademicPress, 2003
3. Current Literature
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory. For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments
(Minimum two) /Term Project.
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TAE 3003 RF MEMS CIRCUIT DESIGN 3-0-0-3
Physical and practical aspects of RF circuit design. Impedance mismatch effects in RF MEMS.
RF/Microwave substrate properties. Micro machined- enhanced elements. MEM switches. Resonators.MEMS modeling.
Reconfigurable circuit elements. Resonator MEMS switch Tunable CPW resonator. MEMS
microswitch arrays. Reconfigurable antenna.
MEMS phase shifters. Types of phase shifters. Switched delay line phase shifters. Distributed MEMS
phase shifters.
RF MEMS filters. Modeling of mechanical filters and resonators. SAW filters. Micromachined filters
for millimeter wave applications.
Reference
1. H.J.D.Santos,RF MEMS Circuit Design for Wireless Communications,Artech House , 2002.
2. G.M.Rebeiz , RF MEMS Theory , Design and Technology, wiley , 2003.
3. V.K.Varadan etal,RF MEMS and their Applications, Wiley,2003
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems & 50%
Theory.For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
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TAE 3004 CURRENT TOPICS IN INSTRUMENTATION 3-0-0-3
The syllabus shall contain current area of research in Instrumentation (45 hrs). The syllabusshall be approved by the Academic committee of the college before the semester starts.
TAC 3101 THESIS PRELIMINARY 0-0-14-4
This shall comprise of two seminars and submission of an interim thesis report. This report shall be
evaluated by the evaluation committee. The fourth semester Thesis-Final shall be an extension of this
work in the same area. The first seminar would highlight the topic, objectives, methodology and
expected results. The first seminar shall be conducted in the first half of this semester. The second
seminar is presentation of the interim thesis report of the work completed and scope of the work which
is to be accomplished in the fourth semester.
Weightages for the 4 credits allotted for the Thesis-Preliminary
Evaluation of the Thesis-Preliminary work by the guide - 100 Marks
Evaluation of the ThesisPreliminary by the Evaluation Committee - 100 Marks
TMC 4101 THESIS FINAL 0-0-29-12
Towards the end of the semester there shall be a pre submission seminar to assess the quality
and quantum of the work by the evaluation committee. This shall consist of a brief presentation of
Third semester interim thesis report and the work done during the fourth semester. At least one
technical paper is to be prepared for possible publication in journals / conferences. The final evaluation
of the thesis shall be an external evaluation. The 12 credits allotted for the Thesis-Final may be
proportionally distributed between external and internal evaluation as follows.
Weightages for the 12 credits allotted for the Thesis
Internal Evaluation of the Thesis work by the guide - 200 Marks
Internal Evaluation of the Thesis by the Evaluation Committee - 200 Marks
Final Evaluation of the Thesis work by the Internal and External Examiners:-
(Evaluation of Thesis + Viva Voce) - 100+100Marks
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MICROWAVE AND TV
ENGINEERING
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TMM 1001 MATHEMATICAL METHODS FOR COMMUNICATION 3-0-0-3
Metric Spaces:Definition-Examples-Open and closed sets-continuity-convergence-Cauchy sequenceand completeness-contraction mapping Theorem.
Hilbert Spaces; Normed linear spaces-linear operators on normed linear spaces-linear functionals-
inner product spaces-Hilbert space-orthogonality-direct sum-projetion theorem-orthonormal sets andsequences-eigen function expansions-separable Hilbert spaces-Riesz representation Adjoint operator-
spectral theory in finite dimensional normed spaces.
Random processes: Sequence of random variables and its convergence-Chebychevs inequality-law
of large numbers-Central limit theorem.
Definition and classification of random processes-stationarity(strict sense and wide sense).
Autocorrelation function and its properties.-Ergodicity- ergodic theorems. spectral density function and
its properties.
Special Random Processes.Poisson process-properties-Markov process- Markov Chains-Transition
probability matrix-Chapman-Kolmogorov theorem.-Birth death process-weiner process
Lebesgue measure and integration:.Measure spaces-measurable functions-Lebesgue integration
Fatous lemma- Monotone convergence Theorem-Lebesgue convergence Theorem- pL spaces-Radon
Nikodym Theorem(statement only)
References:-
1. Erwin Kreizig,Introduction to Functional analysis with applications, John wiley & sons2. L.Debnath and P.Mikusinski,Introduction to Hilbert spaces with applications, 3/e,Academic
press3 . T. Veerarajan, Probability, Statistics and Random processes, Tata- McGraw Hill
4. J.Medhi, Stochastic processes, New Age International, India5. Stark Henry,Probability and random process with application to signal processing,3/e,PearsonEducation India.
6. Gray.R.M and Davisson.L.D,An introduction to statistical signal processing, Cambridgeuniversity press
7. H.L Royden,Real Analysis, Prentice Hall
8. Gupta, Malik and Mittal,Measure Theory, Kedarnath, India
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. For the internal marks of 50, Two test
of 20 marks each and 10 marks for assignments (Minimum two)
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TMC 1001 ADVANCED DIGITAL SIGNAL PROCESSING 3-0-0-3
Basics of Multirate systems and its application, up sampling and Down - Sampling, Fractional
Sampling rate converter. Polyphase decomposition. Efficient realisation of Multirate systems.Uniform
filter banks and it's implementation using polyphase decomposition. Two channel Quadrature Mirror
Filter Banks, Perfect Reconstruction, M-channel PR QMFB.
Time Frequency Analysis, Heisenberg's uncertinity principle. Short time fourier transform - Gabor
transform. Continous Wavelet Tranform and it's properties. Multi Resolution Analysis, Discrete
Wavelet Transform, Orthonormal Wavelet Analysis - Filterbank interpertation. Haar and Daubechise
wavelets, Bi-orthogonal wavelets and Filter bank interpretation. B -Spline wavelets, Wavelet
packets.2D wavelt transforms. Application of wavelet tranform for data compression, noise reduction.
Linear Prediction -Forward and Backward Prediction - Levinson-Durbin Algorithm, Schur Algorithm.
Power spectrum estimation of signals: Wide Sense Stationary Random Processes. Power spectraldensity. Non parametric methods: periodogram,Backman-Tuckey method. Parametric method: ARMA,
AR processes, Yule-Walker method.
Reference
1) P. P. Vaidyanathan,Multirate Systems and Filterbanks, Prentice Hall
2) Wavelet Transforms - Bopadikar and Rao, Pearson Education
3) Insight into wavelets, K. P. Soman, Prentice Hall India4) Digital signal Processing, By John G. Proakis, Dimitris G. Manolakis
Pearson Education
Reading1) L. Cohen, Time Frequency Analysis, Prentice Hall.
2) Wavelets and Filterbank, G Strang & T Nguyen , Wellesly-Cambridge3) Wavelets and subband coding, M Vetterli & J Kovacevic, Prentice Hall
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
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TMC 1004 RF CIRCUITS DESIGN 3-0-0-3
Review of transmission lines Binomial and Chebyshev transformer. Return loss and Insertion loss.Smith Chart - Impedance Matching Using smith Chart. ABCD parameters of simple Two -Port
Networks - Impedance Element, T networks , Transmission line section (Analysis - Notrequired).Scattering Parameters - Chain Scattering Matrix , Signal Flow analysis using S- Parameters.
RF filter design - First order low pass, high pass and band pass filter circuits. Frequency transformation
and impedance transformation. Higher order filter design Concepts. Review of BJT and MESFET. V-I
characteristics and high frequency equivalent circuit. High Frequency Equivalent circuits of Tunnel
diode, Gunn Diode, Varactor diode.PIN diode as an attenuator, Computation of transducer loss.
Design of simple matching and biasing networks .Power Relations for RF transistor and MESFET
amplifiers, Stabilisation Methods. Simple BJT and MESFET amplifier design examples.
Microwave oscillators - High frequecy oscillator configuration, Design of MESFET based oscillator.
Dielectric resonator Oscillator, gunn Oscillator, YIG Oscillator. Mixers - Design of simple RF mixer
circuits based on BJT and MESFET.
Reference
Reinhold Ludwig, Pavel Bretchko, RF Circuit Design-Theory and Application, - Pearson Education.
Reading:
1. Matthew M. Radmanesh, Radio Frequency and Microwave electronics, Pearson Education.Asia 2001
2. Collins, Foundation for Microwave Engineering, 2ndEd. McGraw Hill, Inc.3. David M.Pozar , Microwave Engineering , 2ndEd.Wiley
Equations for K , , Power gain e , radius and centre of gain and noise figure circles, willbe provided along with the Question paper for design purpose.
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems & 50%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)/Term Project
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TMC 1005 ANTENNAS AND DESIGN 3-0-0-3
Review of antenna parameters, Reciprocity and reaction Theorems - Analysis of loop antennas - smallcircular loop of constant current, Circular loop with non-uniform current. Biconical antenna, cylindrical
dipole, folded dipole, discone and conical skirt monopole, sleeve dipole. Matching techniques - Submatching quarter - wavelength transformer, T-match, gamma match, omega match, baluns and
transformers.
Antenna arrays Linear and planar array, array pattern synthesis, Phased arrays. Yagi-Uda arrays
analysis and design, Frequency dependent antennas Equiangular spiral, Log periodic antennas -
design. Analysis of aperture antennas - field equivalence principle, radiation equations, directivity,
Rectangular apertures, Circular aperture, horn, dish, Microstrip antennas characteristics, feeding
methods, Rectangular patch, circular patch, Lens antennas, smart antennas.
Reference:
1. Consrantive A Balanis -Antenna Theory - Analysis and Design 2/e John Wiley & Sons.2. John D. Krans, Ronald J. Marhefka : Antennas for all Applications , 3/e, TMH.3. Sopholes J. Orfanidis Electromagnetic waves and antennas. Available at:
www.ece.rutgers.edu/~orfanidi/ewa
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project
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TMC 1101 COMMUNICATION SYSTEMS & OPTICS LAB 0-0-2-1
COMMUNICATION EXPERIMENTS:(1) Simulation Of a RADAR System
(2)Simulation Of Mobile Network using MATLABFIBER OPTICS EXPERIMENTS:
(1)Study Of Optical Spectrum Analyser(2)Design and setting up a WDM system(3)Measurement Of Fiber Length & Core index measurement using OTDR(4)Link Analysis Using OTDR
NETWORKING EXPERIMENTS:
Configuring Mail, DNS, HTTP, SAMBA, NFS & YP Servers for Corporate Networks
MICROWAVE EXPERIMENTS:
(1) Calibration & Trouble shooting Of Microwave measurement set up(2) Crystal Index measurement(3) Parameter measurements of H plane , E-plane & Magic T.(4) Measurement Of Dielectric Constant
Marks: Continuous Evaluation: 30End semester Exam and Viva-voce: 20
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TMC 1102 PROJECT PART I - - -1
Project has 2 parts. The Project shall be hardware / hardware platform based.
The student is expected to select and complete the design of the project work and submit the designphase report and presentation. The design phase report shall be submitted for evaluation. This shall be
in soft bonded form. This is the first volume of the Project report. The Second volume is the finalproject report in the second semester.
Marks: Project Design Report Evaluation : 25
Presentation & Viva-Voce : 25
TMC 1103 SEMINAR 0-0-2-2
The student is expected to present a seminar in one of the current topics in Electronics,
Communication, Instrumentation, Computers, Information Technology, Control systems and related
areas. The student will under take a detailed study based on current published papers, journals, books
on the chosen subject and submit seminar report at the end of the semester.
Marks: Seminar Report Evaluation : 25Seminar Presentation : 25
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TMC 2001 WIRELESS MICROWAVE COMMUNICATION 3-0-0-3
Line of sight communication, over the horizon systems FM microwave radio stations,Repeaters, microwave antennas .Radio wave propagation, Free space propagation models. Three basic
propagation mechanisms. Reflection-ground reflection two ray model. Diffraction-Frensel zonegeometry, knife edge diffraction model. Scattering. Long distance path loss model, Log normal
shadowing. Determination of percentage of coverage area. Cellular concept ,Interference, Trunking andgrade of service, Improving coverage and capacity in cellular systems.
Small scale multipath propagation. Impulse response model of multipath channels. Parameters
of Mobile multipath channels Types of small scale fading. Jakes channel model. Digital modulation for
mobile radio analysis under fading channels. Diversity techniques, RAKE receiver. Capacity of cellular
systems-cellular CDMA, cellular FDMA ,TDMA and SDMA.CDMA Digital cellular standards,
Forward CDMA channel, Reverse CDMA channel. Wireless networking ISDN evolution, ISDN
layers, services, Frame relay, B- ISDN, Asynchronous Transfer Mode (ATM),wireless ATM
Reference
1. W.Jakes,Microwave Mobile Communication, IEEE Press.2. Achille Pattavina, Switching Theory: Architectures and performance in Broadband ATM
Networks, John Wiley & Sons Ltd., New York.1998
3. T.S. Rappaport, Wireless Communications: Principles and Practice, Prentice-Hall, 19964. William C Y Lee :Mobile Cellular Telecommunications, 2 edn. Mc. Graw Hill.
Reading :1. J.G. Proakis,Digital Communications, McGraw Hill, 1995
2. Wayne Tomasi:Advanced Electronics Communication Systems PHI, 4TH Edn. (Chap. 8th & 9th) 5
thEd, Pearson Education, 2001.
3. Dr.Kamilo Feher ,Wireless digital communication4.
Jochen. H. schiller, Mobile communication
For the End semester exam ( 100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems &50%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project
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TMC 2002 MICROWAVE INTEGRATED CIRCUITS 3-0-0-3
Planar Transmission line methods of analysis. Microstrip line, coupled striplines, microstrip
coupled lines, Distributed and lumped elements of integrated circuits capacitors, inductors, resistors,terminations, attenuators, resonators and discontinuities.
Filters LPF, BPF, Diode control devices switches, attenuators, limiters, phase shifters
diode phase shifter, ferrite and differential phase shifters, circulators and isolators.
Microwave integrated subassemblies L band multifunctional Transmit/Receive module,
Electrically tunable L band pre selector balanced amplifier, C band multichannel receiver.
Design and fabrication RF/Microwave packages, 3 dimensional design, fabrication aspects.
Reference:
1. Leo Maloratsky: Passive RF and Microwave Integrated Circuits, Elsevier, 20062. Bharathi Bhat and Shiban K. Koul: Stripline-like Transmission Lines for MIC, New Age
International (P) Ltd, 1989
Reading:
1. Yoshihiro Konishi:Microwave Integrated Circuits, CRC Press 19912. Ivan Kneppo: Microwave Integrated Circuits, Springer, 1994
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems & 50%
Theory.For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project
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TMC 2101 RF DESIGN AND MEASURMENT LAB 0-0-2-1
1) Study of S parameters of active and passive microwave devices using Network Analyzer.2) Study of spectrum analyzer.3) Design and simulation of RF amplifier, Oscillator, attenuators , and Filters using
Microwave Office.
4) Simulation of Antennas using Antenna Design and simulation software.5) MiniProject: A MiniProject has to be implemented in the field of RF circuit design
Or antennas and a final report should be submitted .
Marks: Continuous Evaluation: 30
End semester Exam and Viva-voce: 20
TMC 2102 PROJECT PART II - - -2
Each student is expected to prepare a report on the project work done by him/her and present a paper
highlighting the work done by him/her in a seminar. The student is expected to complete the project
work assigned to him/her and submit the project report by the end of semester. This report shall be of ahard bound type and consist of design phase report as volume one and other part as volume two.
Marks: Project work and Report Evaluation :50Presentation & Viva-Voce : 50
TMC 2103 SEMINAR 0-0-3-2
The student is expected to present a seminar in one of the current topics in Electronics,
Communication, Instrumentation, Computers, Information Technology, Control systems and related
areas. The student will under take a detailed study based on current published papers, journals, books
on the chosen subject and submit seminar report at the end of the semester.
Marks: Seminar Report Evaluation : 25
Seminar Presentation : 25
.
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TME 2001 COMPUTATIONAL METHODS FOR ELECTROMAGNETICS 3-0-0-3
Introduction to Numerical Methods for solution of partial differential equation, Richardsons
extrapolation formula. Green's Function and it's Numerical Integration and use of Richardson'sextrapolation.Finite Difference Method. Solution of one dimensional two dimensional differential
equations with simple example. Application to waveguides.
Finite Difference Time Domain (FDTD) method -Yee 's Algorithm - Solution of Maxwell's Equationin 1 ,2 and 3 dimension .Method of Moments - Application of Method of Moments to waveguides and
Microstrip transmission lines.
Application of Method of moments for analysis of antenna characteristics - Radiation Pattern , Antenna
Impedance, Mutual Coupling and antenna arrays. Spectral Analysis of Microstrip circuits.
Reference
1) Richard C . Booton , Computational Methods for Electro Magnetics and Microwaves. Wiley Series
in Microwave and Optical Engineering.
Reading:
1. R.F Harrington, Time Harmonic Electromagnetic Fields, McGraw Hill, Newyork 19612. Andrew F. Peterson, Computational Methods for Electromagnetics, IEEE press.
3. Anders Bondeson , Thomas Rylander ,Computational Electromagnetics, Par ngelstrm Springer2005, 1/e
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project
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TME 2002 SECURE COMMUNICATION 3-0-0-3
Review of Algorithm analysis and Complexity, Number Theory, Review of Algebraic
structures, Mathematical Theory of Secrecy Systems, Finite Fields, Polynomial Rings over Finite
Fields, Discrete logarithm, Pseudo Random Number Generation and Randomness Tests.
Symmetric Key and Asymmetric Key cryptosystems, cryptographic hash functions, RSA, DSA,
Deffiehel man Key Exchange, Digital Signature Schemes, Zero Knowledge Proofs, Elliptic Curve
Cryptosystems, DES. AES, Stream and Block Ciphers.Cryptanalysis methods of stream ciphers, symmetric key systems and asymmetric key systems.
Modeling and Analysis of Cryptographic Protocols. Case studies using AVISPA package.
Reference:1. N. Koeblitz, A course in Number theory and Cryptography, Springer Verlag2. Niven, Zuckerman : The theory of Numbers, John Wiley
3. Alfred J. Menezes, Paul C. van Oorschot, Scott A. Vanstone,Handbook of Applied
Cryptography, CRC Press
4. Henk CA,An Introduction to Cryptography, Kluwer Academic Pub
5. J A Buchman,Introduction to cryptography, Springer Verlag, 2001
6. JOHN TALBOT, DOMINIC WELSH, Complexity and Cryptography An Introduction,
Cambridge University Press, 20067. AVISPA package homepage ,http:/ www.avispaproject.org/
8. Peter Ryan,Steve Schneider,Michael Goldsmith,Gavin Lowe, Bil Roscoe: TheModeling and Analysis of Security Protocols: The CSP Approach, Addison Wesley
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)/Term Project
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TME 2003 DESIGN OF CDMA SYSTEMS 3-0-0-3
Direct Sequence and Frequency Hopped Spread Spectrum, Spreading sequences and their correlation
functions, Acquisition and tracking of spread spectrum signals, Error probability of DS-CDMA on
AWGN channels, DS-CDMA on frequency selective fading channels,
Performance analysis of cellular DS-CDMA, Capacity Estimation, Power Control, Effect of imperfect
power control on DS-CDMA performance, soft handoffs, Spreading/Coding tradeoffs, Multicarrier
CDMA. Wideband CDMA.
Multiuser Detection: MF detector, Decorrelating detector, MMSE detector. Successive Interference
Canceller, Parallel Interference Canceller, performance analysis of multiuser detectors and interference
cancellers.
Reference
1. Kamil Sh. Zigangirov, Theory of Code Division Multiple Access Communication, IEEE Press, 2004
2. Don Torrieri, PRINCIPLES OF SPREAD-SPECTRUM COMMUNICATION SYSTEMS, Springer,
2005
3. Sergio Verdu,Multiuser Detection , Cambridge University Press, 1998
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems & 50%
Theory.
For the Internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project.
.
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TME 2004 CMOS RF CIRCUITS DESIGN 3-0-0-3
System Design Considerations - Basic concepts and system architectures- Noise figure.- Dynamic
Range Sensitivity - CMOS RF Components & Devices - Characteristics of MOSFET at high-frequency.
LNA and Mixers :General considerations for RF CMOS LNA. Input matching- LNA topologies -
Power match versus noise match -General considerations for mixers- nonlinear systems as mixers -Configurations and operation of CMOS mixers multiplier based mixers subsampling mixers
PLL, Oscillator and synthesizers : Linearised PLL models phase detectors sequential phase
detectors loop filters- charge pumps PLL design examples frequency synthesis with PLL
prescaling and heterodyne - down conversion techniques
Reference :
1. Thomas H. Lee - The Design of CMOS Radio-Frequency Integrated Circuits, Cambridge,20042. Razavi B., -RF microelectronics, Prentice Hall3. Reinhold Ludwig, Pavel Bretchko,RF Circuit Design, Prentice-Hall, 2000.
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
/Term Project
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TCC 3101 RESEARCH METHODOLOGY 0-0-0-1
Introduction Meaning of research Objectives of research Motivation in research Types ofresearch Research approaches Significance of research Research methods vs Methodology
Criteria of good research.
Defining Research Problem What is a research problem Selecting the problem Necessity ofdefining the problem Literature review Importance of literature review in defining a problem
Critical literature review Identifying gap areas from literature review
Research design Meaning of research design Need Features of good design Important concepts
relating to research design Different types Developing a research plan
Method of data collection Collection of data- observation method Interview method Questionnaire
method Processing and analysis of data Processing options Types of analysis Interpretation of
results
Report writing Types of report Research Report, Research proposal ,Technical paper Significance
Different steps in the preparation Layout, structure and Language of typical reports Simple
exercises Oral presentation Planning Preparation Practice Making presentation Answering
questions - Use of visual aids Quality & Proper usage Importance of effective communication -Illustration
References
1. Coley S M and Scheinberg C A, 1990, "Proposal Writing", Newbury SagePublications.
2. Leedy P D, "Practical Research : Planning and Design", 4th Edition, N
W MacMillan Publishing Co.3. Day R A, "How to Write and Publish a Scientific Paper", Cambridge
University Press, 1989.
TCC 3102 INDUSTRIAL TRAINING 3-0-0-1
There shall be 15 days training in Industrial / Research organization by each student during the Second
Semester vacation and present a Seminar and report during the Third Semester. The report shall be
approved by the organization / industry where the student have undergone the training.
Marks:
Evaluation of reports : 25Seminar Presentation : 25
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TME 3002 3-0-0-3
SIMULATION OF COMMUNICATION SYSTEMS AND NETWORKS
Simulation and Modeling Methodology, Review of Random Process :Univariate and multivariatemodels, Transformation of random variables, Bounds and approximation, Random process models -
Markov and ARMA Sequences, Sampling rate for simulation.
Random Number Generation, Testing Random Number Generators.
Modeling of Transmitter and Receiver subsystems: Information sources, Radio frequency and
optical modulation. Demodulation and detection, Multiplexing.
Communication channels and models: Fading and multipath channels, The Almost Freespace
channel, Conducting and Guided wave media, Finite state channel models.
Estimation of parameters in simulation: Quality of an estimator, Estimating the average level of
waveform, Estimating the power spectral density of a process.
Estimation of performance measures from simulation : Estimation of SNR, Estimating
Performance measures for digital systems :The Monte Carlo Method , Importance sampling method,
Review of Queuing models, Burke's theorem, Queuing Networks, Operational Laws, Mean valueanalysis , Hierarchical decomposition of Large Queuing networks: Queuing network model with a load
dependent server.
Analysis of simulation Results: Model Verification Techniques, Model Validation Techniques,Transient Removal, Terminating Simulations , Stopping Criteria, Variance Reduction
References:1. M.C.Jeruchim, Philip Balaban and K.Sam Shanmugam, "Simulation of communication systems",
Plenum Press, New York,1992
2. Raj Jain, The Art of Computer Systems Performance Analysis, John Wiley and Sons 1991
3. Jerry Banks and John S.Carson, "Discrete-event system Simulation, Prentice Hall, Inc., New
Jersey,1984
4. A.M.Law and W.David Kelton, "Simulation Modeling and analysis", Mc Graw Hill Inc., New York,
1991
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
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TME 3003 ADVANCED CODING THEORY 3-0-0
Review of modern algebra. Galois fields. Linear block codes; encoding and decoding. Cyclic codes.Non-binary codes.
Convolutional codes. Generator sequences. Structural properties. ML decoding. Viterbi decoding.
Sequential decoding. Practical applications of convolutional codes.
Modulation codes. Trellis coded modulation. Lattice type Trellis codes. Geometrically uniform trelliscodes. Decoding of modulation codes.
Turbo codes. Turbo decoder. Interleaver. Turbo decoder. MAP and log MAP decoders. Iterative turbo
decoding. Optimum decoding of turbo codes.
Space-time codes. MIMO systems. Space-time block codes (STBC) decoding of STBC.
Reference:
1. S.Lin & D.J.Costello,Error Control Coding (2/e), Pearson, 2005.
2. B.Vucentic & J.Yuan, Turbo codes, Kluwer, 2000
3. C.B.Schlegel & L.C.Perez, Trellis and Turbo Coding Wiley.
Reading
1. Stephen B.Wicker,Error Control System for Digital Communication & Storage, PHI
2. David Joyner (Ed), Coding Theory & Cryptogrphy, Springer
3. Aazhang B. Digital Communication Systems
[Connexions Web site]. January 22, 2004.available at: http://cnx.rice.edu/content/col10134/1.3/
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory.
For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
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SIGNAL PROCESSING
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TSM 1001 LINEAR ALGEBRA FOR SIGNAL PROCESSING 3-0-0-3
Algebraic Structures: - Sets functions operators- Group homomorphism of groups - Ring Field
Vector Space Subspaces direct sum - metric space inner product space Lp space BanachSpace - Hilbert Space.
Linear independence basis dimension orthonormal basis finite dimensional vector spaces
isomorphic vector spaces - Examples of finite and infinite dimensional vector spaces RN, C
N,
signal space .
Linear Transformations :- Linear Transformations four fundamental subspaces of linear
transformation inverse transformation - rank nullity theorem - Matrix representation of linear
transformation square matrices unitary matrices - Inverse of a square matrix - Change of basis
coordinate transformation - system of liner equations existence and uniqueness of solutions-
projection least square solution pseudo inverse.
Transforms :- Eigen values, Eigen vectors and spectrum - Diagonalizability orthogonaldiagonilization - Properties of Eigen values and Eigen vectors of Hermitian matrices - Diagonalization
of LTI operator Fourier basis - DFT as a linear transformation Translation invariant lineartransformation wavelet basis wavelet transforms.
Reference
1. G.F.Simmons, Topology and Modern Analysis , McGraw Hill2. Frazier, Michael W.An Introduction to Wavelets Through Linear Algebra, Springer Publications.3. Hoffman Kenneth and Kunze Ray,Linear Algebra, Prentice Hall of India.
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory. For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments
(Minimum two) /Term Project.
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TSC 1002 DSP PROCESSOR AND ARCHITECTURE 3-0-0-3
Review of Pipelined RISC Architecture and Instruction Set Design.Performance and Benchmarks- SPEC CPU 2000, EEMBC DSP benchmarks.
Basic Pipeline: Implementation Details- Pipeline Hazards (based on MIPS 4000 arch).
Instruction Level Parallelism (ILP): Concepts, Dynamic Scheduling Tomasulos algorithm- Reducing
Data hazards. Dynamic Hardware Prediction - Reducing Branch Hazards. Multiple Issue- Hardware-
based Speculation. Limitations of ILP.
Review of Memory Hierarchy - Cache design, Cache Performance Issues & Improving Techniques.
Computer arithmetic- Signed Digit Numbers(SD) - Multiplier Adder Graph - Logarithmic and
Residue Number System(LNS, RNS) - Index Multiplier Architecture for Pipelined Adder, Modulo
Adder & Distributed Arithmetic(DA), CORDIC Algorithm and architecture
Case studies: Introduction to TMS 320 C 6X Processor Architecture Functional units _ pipelining
Registers Linear and Circular addressing modes Types of instructions sample program, Overview
of BlackFin processor
Reference
1. JL Hennesy, D.A. Patterson, Computer Architecture A Quantitative Approach; 3 Edition, ElsivierIndia
Chapter 1, Appendix A, Chapter 3, Chapter 5 (5.1 - 5.8)2. Digital Signal Processing with FPGAs, Uwe Mayer-BAeses, Springer, 2001
Chapter 2
3. Digital signal Processing and Applications with the C6713 and C6416 DSK RulphChassaing, Wiley Interscience
Reading
1. Blackfin Processor Hardware Reference, Analog Devices, Version 3.0, 2004
(Section 2.3-2.53, 4.7-4.15, 6.1 -6.53)
2. Digital Signal Processor, Architecture Programming and Applications, D Venkat Remani, M
Bhaskar, Tata Mc GrawHill, 2002
3. DSP Processor fundamentals : Architecture and Features. Phil Lapsley, J Bier, Amit Sohan,Edward A Lee; Wiley IEEE Press.
4. Digital Signal Processors. Sen M. Kuo, Woon-seng S. Gan, Prentice Hall.5. Processor Manuals.
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 50% problems & 50%Theory. For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments
(Minimum two) /Term Project.
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TSC 1003 DIGITAL FILTER DESIGN AND APPLICATIONS 3-0-0-3
LTI Systems & Transform
LTI systems as frequency selective filters. Invertibility of LTI systems. Minimum phase, maximumphase and mixed phase systems. All-pass filters. Design of digital filters by placement of poles and
zeros. DFT as a linear transformation. Linear filtering methods based on DFT. Frequency analysis of
signals using DFT. Discrete cosine transform.Design of FIR filtersIntroduction-Specifications-Coefficient calculation methods-Window, Optimal and Frequency
sampling methods- Comparison of different methods-Realization structures-Finite word length effects-
Implementation techniques-Application examples. FIR filter design with Matlab or Octave.
Implementation of FIR filtering in general purpose digital signal processors.
Design of IIR filter
Introduction-Specifications. Coefficient calculation methods-Pole zero placement, Impulse invariant,
Matched Z transform and Bilinear Z transform(BZT) .Design using BZT and classical analog filters.
IIR filter coefficients by mapping S plane poles and zeros. Realization structures-Finite word length
effects-Implementation techniques. Application examples. IIR filter design with Matlab or Octave.
Implementation of IIR filtering in general purpose digital signal processors.
Adaptive Digital FiltersConcepts -Wiener filter-LMS adaptive algorithm-Recursive least squares algorithm-Lattice Ladderfilters. Application of Adaptive filters.
Power Spectrum EstimationEstimation of spectra from finite-duration signals. Nonparametric and Parametric methods for Power
Spectrum Estimation.
Reference:
1. Emmanuel C Ifeachor, Barrie W.Jervis,Digital Signal Processing, A practical
Approach, 2/e, Pearson Education.2. Proakis, Manolakis, Digital Signal Processing: Principles, Algorithms, and Applications, 4/e,
Pearson Education.3. Johnny R. Johnson,Introduction to Digital Signal Processing,PHI,1992
4. Ashok Ambardar,Digital Signal Processing: A Modern Introduction, Thomson,IE,2007Reading:
1. Douglas F. Elliott, Handbook of Digital Signal Processing- Engineering Application , AcademicPress.
2. Robert J.Schilling, Sandra L.Harris, Fundamentals of Digital Signal Processing usingMATLAB,Thomson,2005
3. Ingle, Proakis,Digital Signal Processing Using MATLAB, Thomson, 1/e4. Jones D. Digital Filter Design [Connexions Web site]. June 9, 2005. Available at:
http://cnx.rice.edu/content/col10285/1.1/
For the final exam (100 marks), the question paper shall have six questions of 20 marks each covering
entire syllabus out of which any five shall be answered. It shall have 75% problems & 25% Theory. For
the internal marks of 50, Two test of 20 marks each and 10 marks for assignments (Minimum two)
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TSC 1004 SPEECH SIGNAL PROCESSING 3-0-0-3
Speech Production :- Acoustic theory of speech production (Excitation, Vocal tract model for
speech analysis, Formant structure, Pitch). Articulatory Phonetic (Articulation, Voicing, Articulatorymodel). Acoustic Phonetics ( Basic speech units and their classification).
Speech Analysis :- Short-Time Speech Analysis, Time domain analysis (Short time
energy, short time zero crossing Rate, ACF ). Frequency domain analysis (Filter Banks, STFT,Spectrogram, Formant Estimation &Analysis). Cepstral Analysis
Parametric representation of speech :- AR Model, ARMA model. LPC Analysis ( LPC model, Auto
correlation method, Covariance method, Levinson-Durbin Algorithm, Lattice form).LSF, LAR, MFCC,
Sinusoidal Model, GMM, HMM
Speech coding :- Phase Vocoder, LPC, Sub-band coding, Adaptive Transform Coding , Harmonic
Coding, Vector Quantization based Coders, CELP
Speech processing :- Fundamentals of Speech recognition, Speech segmentation. Text-to-speech
conversion, speech enhancement, Speaker Verification, Language Identification, Issues of Voice
transmission over Internet.
Reference
1. Douglas O'Shaughnessy, Speech Communications : Human & Machine, IEEEPress, Hardcover 2nd edition, 1999; ISBN: 0780334493.
2. Nelson Morgan and Ben Gold, Speech and Audio Signal Processing : Processing and PerceptionSpeech and Music, July 1999, John Wiley & Sons, ISBN: 0471351547
3. Rabiner and Schafer,Digital Processing of Speech Signals, Prentice Hall, 1978.4. Rabiner and Juang, Fundamentals of Speech Recognition, Prentice Hall, 1994.5. Thomas F. Quatieri, Discrete-Time Speech Signal Processing: Principles and Practice, Prentice
Hall; ISBN: 013242942X; 1st edition
6. Donald G. Childers, Speech Processing and Synthesis Toolboxes, John Wiley & Sons, September1999; ISBN: 0471349593
For the End semester exam (100 marks), the question paper shall have six questions of 20 marks each
covering entire syllabus out of which any five shall be answered. It shall have 75% problems & 25%
Theory. For the internal marks of 50, Two test of 20 marks each and 10 marks for assignments
(Minimum two) /Term Project.
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TSC 1101 DSP SYSTEMS LAB 0-0 2-1
Development Environment
Familiarization to DSP project development stages. Study of the features of the processor used.
Development environment.
High Level Language Project Development
Developing projects in a high level language and cross-compiling. Familiarization with the debugging
facilities of the IDE. Profiling. Optimizations in C.
Assembly Optimizations
Assembly coding. Function calling conventions. Calling assembly functions from C. Optimization by
coding core modules in assembly.
Memory Map
Understand the memory map of the processor. Optimizations by using internal memory.
Real Time Processing.
Using the ADC and DAC for signal acquisition and play back. Real time filtering.
Mini Project (Compulsory)The student should do a Mini project based on the above area, and a report should be submitted along
with the lab record. A vivavoce will be conducted at the end of semester.
Reference
1. Jones D. DSP Laboratory with TI TMS320C54x [Connexions Web site]. January 22, 2004.Available at: http://cnx.rice.edu/content/col10078/1.2/
2. The manuals of the IDE and Processor being used.Marks : Continuous Evaluation: 30
Mini Project, End Semester Exam: 20
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TSC 1102 PROJECT PART I - - -1
Project has 2 parts. The Project shall be hardware / hardware platform based.The student is expected to select and complete the design of the project work and submit the design
phase report and presentation. The design phase report shall be submitted for evaluation. This shall bein soft bonded form. This is the first volume of the Project report. The Second volume is the final
project report in the second semester.
Marks: Project Design Report Evaluation : 25Presentation & Viva-Voce : 25
TSC 1103 SEMINAR 0-0-2-2
The student is expected to present a seminar in one of the current topics in Electronics,
Communication, Instrumentation, Computers, Information Technology, Control systems and related
areas with application of Signal Processing. The student will under take a detailed study based on
current published papers, journals, books on the chosen subject and submit seminar report at the end of
the semester.
Marks: Seminar Report Evaluation: 25
Seminar Presentation: 25
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TAC 2001 DIGITAL IMAGE PROCESSING 3-0-0-3
Image representation - Gray scale and colour Images, image sampling and quantization.
Two dimensional orthogonal transforms - DFT, FFT, WHT, Haar transform, KLT, DCT.Image enhancement - filters in spatial and frequency domains, histogram-based processing,
homomorphic filtering.Edge detection - non parametric and model based approaches, LOG filters, localization problem.
Image Restoration - PSF, circulant and block - circulant matrices, deconvolution, restoration usinginverse filtering, Wiener filtering and maximum entropy-based methods.
Mathematical morphology - binary morphology, dilation, erosion, opening and closing, duality
relations, gray scale morphology, applications such as hit-and-miss transform, thinning and shape
decomposition.
Image and Video Compression Standards: Lossy and lossless compression schemes: Transform
Based, Sub-band Decomposition, Entropy Encoding, JPEG, JPEG2000, MPEG
Computer tomography - parallel beam projection, Radon transform, and its inverse, Back-
projection operator, Fourier-slice theor