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View srcinal Menu ⓘ Optimized by Google just now http://www.ee.iitm.ac.in/list-of-ee-courses/ ee.iitm.ac.in Department Of ElectricalEngineering Indian Institute of Technology Madras You are here: Home » List of EE courses List of EE courses B.Tech students must get consent of teacher (COT) before registering for graduate coursesS.NoCourseNoCourse Name / SyllabusCreditL -T-P -E -O -TH 1BT1020Material and Energy Balances Course No : BT1020 Course Title : Material and Energy Balances Pre Requisite : Extended Tutorial: 1 Outside Class Hours : 6 Total Hours PerWeek : Description : To understand the bioprocesses described in words and convert them to flow chartsand mathematical expressions. To understand basic material and energy balancesand their applications in bioprocess industries by using examples primarily based onbioprocess operations and other biological systems. To develop an ability to performmaterial and energy balances simultaneously for biological systems in steady stateand transient state Course Content : Units and dimensions; significant figures; process variables and stoichiometry. Systemand surrounding; steady and unsteady state; problem solving strategy; choosing abasis; general material balance equation; balances on single and multiple unitswithout reactions; balances on processes involving reactions; recycle; bypass andpurge; balances involving cell growth and product formation. First law ofthermodynamics; balances on closed and open systems; calculation of enthalpychanges; general energy balance equation; balances on non-reactive and reactiveprocesses; heat of reaction for processes with biomass production; thermodynamicsof microbial growth; balances on cell culture. Unsteady state material and energybalances; simultaneous unsteady state balances; solving unsteady state balances Text Books : 113 -1 -0 -1 -6 - 1. David M. Himmelblau, James B. Riggs, Basic Principles and Calculations inChemical Engineering, 7th Edition, 2004, Prentice Hall India 2. Richard M. Felder,Ronald W. Rousseau, Elementary Principles of Chemical Processes, 3rd Edition, 2000,John Wiley & Sons Reference Books : 1. Pauline M. Doran, Bioprocess Engineering Principles, 1995, Academic Press 2EC5410Fibre Optic Communication Technology Course No : EC5410 Course Title : Fibre Optic Communication Technology Pre Requisite : Extended Tutorial: 0 Outside Class Hours : 8 Total Hours PerWeek : 12 Description : Fiber Optic Communication Technology is intended as a graduate level course, whichis structured such that there is a seamless transition from Physical Layer issues toData Link Layer issues in optical communication systems and networks. Course Content : Introduction: Motivation for optical networks, Link requirements, throughputs,distance-bandwidth product Simple Link Design: Modes in optical fibers, losses andattenuation. LED/LD/DFB-based transmitters, modulation, extinction ratio, PIN/PIN-TIA receivers, noise sources, bandwidth vs sensitivity, simple link design. Multi-hopLink Design: Inline amplifiers, EDFA basic model, noise analysis, Raman Amplifier. Pre-amplifed receiver, OSNR, APD-based receiver, Chromatic Dispersion, effect on signal,mitigation, Power penalty approach to link design, multihop link design, WDMcomponents, nonlinearity, PMD, PDL, crosstalk Networking Basics: Computer Network,definition and scope, layering concepts, a simple network architecture and itsfunctions, ISO/OSI 7 layer reference model, functionality of first three layers, withemphasis on Data Link layer. Framing, error control, MAC layer functions, CSMA/CD,circuit, packet and message switching. Digital Transmission Basics: A simplesynchronous TDM, timing inaccuracies, timing issues in practical digital links, master-slave and independent timing architectures, slips, elastic stores and asynchronousmultiplexing. Basic Optical Networks: Plesiochronous Digital Heirarchy (PDH), E1, DS1lines. DS2 frame structure and asynchronous multiplexing. Disadvantages of PDH andintroduction to SDH networks, elements of SDH infrastructure, AU-4 justification andUPSR. Text Books : 1. Rajiv Ramaswamy, Kumar N. Sivarajan and Galen Sasaki, �Optical Networks - APractical Perspective�, Morgan and Kaufmann, NY. 3 e, 2008. Reference Books : 1. L. L. Peterson and B S Davie, �Computer Networks. A system approach�, 2e,Margan and Kaufmann, 2000. 2. Bellamy, �Digital Telephony�, PHI, 2000. 3.Mynbaev and Scheiner, �Fiber Optic Communication Technology�, Pearson, 3rdIndian Reprint, 2003. 4. Bertsekas and Gallager, �Data Networks�. PHI. 5. BiswanathMukherjee, �Optical WDM Networks� Springer, 2006. 124 -0 -0 -0 -8 -12Introduction to Electrical Engineering Course No : EE1000 Course Title : Introduction to Electrical Engineering Pre Requisite : Extended Tutorial: Outside Class Hours : Total Hours PerWeek : 3EE1000 --- Course Content : Electrical Power and Energy � dc and ac power � polyphase systems, ElectricalMachines. Semiconductor devices and their applications - Analog and digital systems� Methods of electrical communication � telephony � radio � television �computers and communications. Working Principles of some simple electricalgadgets such as radio � television, computer, mixie, mobile phone, etc. Text Books : 1. Vicent Del Toro, Electrical Engineering fundamentals, Prentice Hall India. 2. Zbar,Paul B Malvin, Albert Paul and Miller Michael. Basic electronics, Tata McGraw Hill. Reference Books : 1. Paul Horowitz, The art of electronics, Cambridge University Press 2- - -- -4EE1100Basic Electrical Engineering Course No : EE1100 Course Title : Basic Electrical Engineering Pre Requisite : Extended Tutorial: 0 Outside Class Hours : 6 Total Hours PerWeek : 10 Description : This course provides a comprehensive understanding and applications of DC and ACcircuits used in electrical and electronic devices, parameters of electrical circuits,single phase, three phase circuits, diodes and operational amplifiers circuits,transformers, induction and DC machines. Course Content : 1. Properties of resistance, Ohms law, KVL, KCL, mesh and nodal analysis, Networktheorems: Superposition, Thevenin, Norton and maximum power transfer. 2.Properties of inductance and capacitance, DC transients: Series RL, RC, RLC andparallel RLC. 3. Single phase AC, voltage and current phasors, impedance, networktheorems application to AC, frequency response of ac circuits, resonance, filters,active power, reactive power, apparent power, power factor. 4. Balanced Three phaseAC, three phase power, star and delta connection. 5. Single phase transformer:Principle of operation, equivalent circuit, OC and SC test, voltage regulation, efficiency.6. Three phase Induction motor: Construction, rotating magnetic field, principle ofoperation, slip, torque, equivalent circuit, efficiency. 7. DC machines: Principle ofoperation, excitation, equivalent circuit, emf, speed and torque characteristics. 8.Diodes and applications: Diode characteristics, voltage and current relationship, diodecircuits-rectifiers, peak and envelop detectors, solar cell. 9. Operational amplifiers:Description of amplifiers as a black box and definition of gain, effect of feedback ongain, Operational amplifier circuits: Non-inverting, inverting, summing, differential,integrators, differentiators, buffers. Text Books : Electrical Engineering Fundamentals, Vincent Del Toro, Prentice Hall, 2006. Reference Books : [1] Electrical Circuit Theory and Technology, John Bird, Elsevier, 2011. [2] Essentials ofElectrical and Computer Engineering, Kerns & Irwin, Pearson, 2004 [3] ElectricalEngineering Concepts and Applications, Carlson and Gisser, Addison Wesley, 1990. 103 -1 -0 -0 -6 -10Signals and Systems Course No : EE1101 5EE1101 Pre Requisite : Extended Tutorial: 0 Outside Class Hours : 6 Total Hours PerWeek : 10 Description : At the end of this course, the student should be able to: 1. Understand and apply theconcepts about linear time-invariant (LTI) systems 2. understand and apply FourierSeries representation of periodic continuous-time signals 3. understand and applyFourier Transform representation of periodic and aperiodic continuous-time signals 4.Apply Laplace transforms to analyze LTI Systems Course Content : 1. Signals (continuous-time): Signal classification (analog-digital, energy-power, even-odd, periodic-aperiodic, deterministic-random etc.), standard signals (unit step, unitimpulse, ramp, exponential, sinusoids), transformations of the independent variable (4classes) 2. Systems (continuous-time): System classification (memory, causal, stable,linear, time-invariant, invertible etc.), Impulse response of an LTI system, convolutionintegral, graphical convolution, system properties from impulse response, complexexponential as eigenfunction of LTI systems, interconnection of LTI systems (6classes) 3. Discrete-time signals and systems: Emphasize similarities and differenceswith continuous-time counterpart (3 classes) 4. Continuous-time Fourier series:Periodic signals and their properties, exponential and trigonometric FS representationof periodic signals, convergence, FS of standard periodic signals, salient properties ofFourier series, FS and LTI systems, some applications of FS (eg. filtering) (6 classes)5. Continuous-time Fourier transform: Development of Fourier representation ofaperiodic signals, convergence, FT of standard signals, FT of periodic signals,properties of FT, some applications of FT (eg. modulation) (6 classes) 6. LaplaceTransform: Bilateral Laplace transform, region of convergence, properties of Laplacetransform, standard Laplace transform pairs, transfer function of LTI system,characterising LTI system properties from transfer function, algebra of transferfunctions and block diagram representations, Unilateral Laplace transform � briefintroduction and application to simple initial value problems (8 classes) 7. Sampling(Bridge continuous and discrete): Sampling theorem and signal reconstruction, notionof aliasing with examples, Sampling in frequency domain (5 classes) Text Books : Signals and Systems: Oppenheim, Willsky and Nawab (2nd Edn). Reference Books : Principles of Linear Systems and Signals: B.P. Lathi (2nd Edn) 103 -1 -0 -0 -6 -106EE1102Introduction to Programming Course No : EE1102 Course Title : Introduction to Programming Pre Requisite : Extended Tutorial: 0 Outside Class Hours : 6 Total Hours PerWeek : 12 Description : EE1102 is currently a course on Introduction to programming using C language. Theobjective is to provide a basic introduction to programming through C language. Course Content : Course Contents: 1. Introduction to Computers, programming language a. C languagehistory 2. Variables constants and declarations 3. Arithmetic, relational and logicaloperators. a. Precedence order 4. Control flow statements a. For loop b. While loop c.123 -0 -3 -0 -6 -12
