Curriculum

P. PHY 111:
Series and parallel circuits, Series-Parallel Networks; Methods of analysis: Mesh analysis, Node analysis and other methods of analysis; Kirchhoff’s laws, Y-delta transformation; Circuit theorems: Superposition Theorem, Norton’s Theorem, Thevenin’s Theorem, Millman’s Theorem Capacitors, Inductors, R-C and R-L circuits with DC excitation. Alternating current – AC quantities, Sinusoidal alternating wave forms, Phasors, AC circuit analysis – RC, RL, RLC series and parallel circuits.

P. EEE 183: Series-parallel ac networks, Network theorems, Dependent sources, Resonance and Q-factors, Power and power factors, Power Factor Improvement, Poly-phase systems – balanced and unbalanced, Problem solving Poly phase power measurement, Whitstone bridge measurement system, Coupled circuits, various passive filter circuits, Magnetic circuits.

Definition and scopes of Ethics, Different branches of Ethics, Social change and the emergence of new technologies, History and development of Engineering Ethics, Science and Technology- necessity and application, Study of Ethics in Engineering. Applied Ethics in engineering.

Human qualities of an engineer, Obligation of an engineer to the clients, Attitude of an engineer to other engineers, Measures to be taken in order to improve the quality of engineering profession.

Ethical Expectations: Employers and Employees; inter-professional relationship: Professional Organization- maintaining a commitment of Ethical standards. Desired characteristics of a professional code, Institutionalization of Ethical conduct

P. EEE 225: Transformer: Construction, Principle of operation, Ideal transformer- transformation ratio, no-load and load vector diagrams, equivalent circuit, Voltage regulation, Ratings, short circuit and open circuit tests, Introduction to 3-phase transformer. Three phase induction motor: Construction, Principle of operation, Rotating magnetic field, equivalent circuit, vector diagram, torque-speed characteristics, effect of changing rotor resistance and reactance on torque-speed curves, motor torque and developed rotor power, no-load test, blocked rotor test, starting and braking and speed control. Single phase induction motor: Theory of operation, equivalent circuit and starting.

P. PHY 121: Introduction to semiconductors, Intrinsic and extrinsic semiconductors, p-type and n-type semiconductors, Drift current and diffusion current in semiconductors. The p-n junction diode: The p-n junction, Formation of depletion layer and junction or Barrier potential in a p-n junction, p-n junctions under forward and reverse biases, Junction Breakdown-Zener and Avalanche breakdown, the p-n junction diode, The ideal diode and real diode, Load line analysis of diode circuits, graphical analysis of diode circuits, equivalent circuits and frequency response, diode applications –Ideal rectifier concept, half and full wave rectifier circuits, Voltage doublers, Clipping and clamping circuits, characteristics of different types of diodes – zener, tunnel, schottky and photo diodes, Zener diode voltage regulator, Zener diode voltage regulator, Bipolar Junction Transistors (BJT): Bipolar junction transistor-Construction and Operation, I-V characteristics, Amplifying action, Common-base (CB), Common-collector (CC) and Common-emitter (CE) configurations, Thermal runway and stability factor of a transistor, Input, output and current transfer characteristics of CB, CC and CE configuration of transistors, Different methods of transistor biasing, Darlington pair, Load Line (AC and DC), BJTs at low frequencies – hybrid model, h-parameters, small signal analysis of BJT amplifiers, high input impedance circuits.

P. MAT 237: Static electric field: Postulates of electrostatics, Gauss’s law and its application, electric potential due to charge distribution, conductors and dielectrics in static electric field, flux density- boundary conditions; capacitance- electrostatic energy and forces, energy in terms of field equations, capacitance calculation of different geometries; boundary value problems- Poisson’s and Laplace’s equations in different co-ordinate systems. Steady electric current: Ohm’s law, continuity equation, Joule’s law, resistance calculation. Biot-Savart’s law, Ampere’s law and applications. Boundary conditions for magnetic field, magnetic energy, magnetic forces, torque and inductance of different geometries. Time varying fields and Maxwell’s equations: Faraday’s law of electromagnetic induction, Maxwell’s equations – differential and integral forms, boundary conditions, potential functions; time harmonic fields and Poynting theorem. Plane electromagnetic wave: plane wave in loss less media- Doppler effect, transverse electromagnetic wave, polarization of plane wave; plane wave in lossy media- low-loss dielectrics, good conductors; group velocity, instantaneous and average power densities, normal and oblique incidence of plane waves at plane boundaries for different polarization.

P. EEE 257: Synchronous Generator: excitation systems, equivalent circuit, vector diagrams at different loads, factors affecting voltage regulation, synchronous impedance, synchronous impedance method of predicting voltage regulation and its limitations. Parallel operation: Necessary conditions, synchronizing, circulating current and vector diagram. Synchronous motor: Operation, effect of loading under different excitation condition, effect of changing excitation, V-curves and starting. DC generator: Types, no-load voltage characteristics, build-up of a self excited shunt generator, critical field resistance, load-voltage characteristic, effect of speed on no-load and load characteristics and voltage regulation. DC motor: Torque, counter emf, speed, torque-speed characteristics, starting and speed regulation. Introduction to wind turbine generators Construction and basic characteristics of solar cells.

P EEE 225 & MAT 219: Characteristics of linear systems, Differences between linear and nonlinear electrical circuits, Methods of transient and steady state solutions of differential and integro-differential equations, Frequency response of LTI systems, Analysis by Fourier Transformation, Laplace Transformation and its applications to linear circuits, Taylor series application to electrical circuits, Analogous systems, Unit step function, Impulse function, convolutions integral and their applications, Introduction to discrete signal processing−Z transform, Z- transform analysis of LTI systems.

P. EEE 265: Field effect transistors (FET): Types of FET, Construction, principles of operation, characteristic curve, Channel conductivity, Channel ohmic and pinch-off region, characteristic parameter of the FET, MOSFET- depletion and enhancement type, n- and p- channels, Biasing arrangements, Basic FET amplifiers. Use of FET as voltage controlled switches and resistors, feedback amplifiers with different topologies, stability, frequency compensation, Oscillators, Multi-vibrators, Introduction to IC technology.
Difference amplifier, Signal generators: Basic principle of sinusoidal oscillation, Op-Amp RC oscillators, LC and crystal oscillators. Power Amplifiers: Classification of output stages, class A, B and AB output stages, Ideal OP-AMP, Practical OP-AMP, Frequency response and noise of an OP-AMP, Bandwidth and other practical limitation of OPAMP, Inverting and Non-inverting amplifier, Linear applications of OP-AMP, The Comparator, Differentiator, Integrator, Instrumentation amplifier, CMMR, Active Filters, Low pass, High pass and Band pass Filters using op-amps, positive and negative feedback, Feedback amplifiers, Different kinds of Oscillators, Timer-555,VCO-566, Binary counter.

P. EEE 315: Number System, Digital logic: Boolean algebra, De Morgan’s Theorems, logic gates and their truth tables, canonical forms, combinational logic circuits, minimization techniques; Arithmetic and data handling logic circuits, decoders and encoders, multiplexers and demultiplexers; Combinational circuit design; Flip-flops, race around problems; Counters: asynchronous counters, synchronous counters and their applications; Memory and Programmable Logic design; Synchronous and asynchronous logic design; State diagram, Mealy and Moore machines; State minimizations and assignments; Pulse mode logic; Fundamental mode design, PLC.

P EEE 315: Crystal structures: Types of crystals, lattice, and basis, Bravais lattice and Miller indices. Classical theory of electrical and thermal conduction: Scattering, mobility and resistivity, temperature dependence of metal resistivity, Mathiessen’s rule, Hall Effect and thermal conductivity. Band theory of solids: Band theory from molecular orbital, Bloch theorem, Kronig-Penny model, effective mass, density-of-states. Carrier statistics: Maxwell-Boltzmann and Fermi-Dirac distributions, Fermi energy. Modern theory of metals: Determination of Fermi energy and average energy of electrons, classical and quantum mechanical calculation of specific heat. Dielectric properties of materials: Dielectric constant, polarization- electronic, ionic and orientational; internal field, Clausius-Mosotti equation, spontaneous polarization, frequency dependence of dielectric constant, dielectric loss and piezoelectricity. Magnetic properties of materials: Magnetic moment, magnetization and relative permitivity, different types of magnetic materials, origin of ferromagnetism and magnetic domains. Introduction to superconductivity: Zero resistance and Meissner effect, Type I and Type II superconductors and critical current density.

P EEE 225 & CEN 120: Wiring system design, drafting, estimation. Design for illumination and lighting. Electrical installations system design: substation, BBT and protection, air-conditioning, heating and lifts. Design for intercom, public address systems, telephone system and LAN. Design of security systems including CCTV, fire alarm, smoke detector, burglar alarm, and sprinkler system. A design problem on a multi-storied building.

P. EEE 225: The course deals with various elements of power transmission and distribution. Aspects dealt with include inductance of single & 3 phase lines, capacitance of two wires & 3 phase lines, transmission lines, transformers, line alternative, line protection and all the related design, development and maintenance issues.

The topics include: classification of transmission and distribution voltage levels and consumers. Transmission line – conductor types, insulators and potential distribution, sag and loading, lightning and ground wire, corona and its redaction. Transmission line resistance (DC and effective), calculation of inductance and capacitance – composite, bundled conductors and parallel circuit line, effect of earth in capacitance calculation. Equivalent circuits of short, medium and long line, SIL and Ferranti effect. Maximum receiving end power. Power, voltage and power factor control: tap changing transformers, phase shifting. Booster and regulating transformers, shunt capacitor, synchronous condenser, static VAR compensators (SVC). Insulated cables: comparison with overhead line, solid dielectric, crossed polyethylene (XPLE), oil and gas filled. Distribution systems: radial, ring mains and interconnected. Layout of a typical substations and familiarization with its protective devices. Introduction to harmonic generating utility and consumer devices, effects, total harmonic distortion (THD), harmonic reduction. High voltage DC transmission. FACT and STATCOM

P. EEE 329:.Introduction to 8-bit, 16-bit, and 32-bit microprocessor – architecture, addressing modes, instruction set, interrupts, multi-tasking and virtual memory – memory interface, bus interface, arithmetic co-processor, Microcontrollers, integrating microprocessors with interfacing chips.

P. EEE 303: Classical concepts of feedback system analysis and associated compensation techniques are presented. In particular, the root locus, Bode diagram, and Nyquist criterion are used as determinants of stability. P, I, D, P+I, P+D, PID control. Digital control, Use of concepts and techniques in real life systems, in particular, electrical and mechanical engineering systems. Design digital controllers.

P. EEE 303: Introduction to digital signals and digital signal processing, A/D conversion, sampling theorem, Illustration of aliasing, analysis of Discrete-Time Linear-Tme-Invariant (LTI) systems, Resolution of Discrete-Time signals into impulse, Convolution and correlation, Z-transform, Concept of Pole and Zero, Frequency domain representation of discrete-time systems and signals, Discrete Fourier series and discrete Fourier transform (DFT), computation of the DFT, Fast Fourier Transform (FFT), Discrete Cosine Transform (DCT), Signal flow graph representation of digital networks. Filter structure for IIR and FIR filters, Introduction to speech and Image processing.

P. EEE 345 Introduction: Principle, evolution, networks, exchange and international regulatory bodies. Telephone apparatus: Microphone, speakers, ringer, pulse and tone dialing mechanism, side-tone mechanism, local and central batteries and advanced features. Switching system: Introduction to analog system, digital switching systems – space division switching, blocking probability and multistage switching, time division switching and two dimensional switching. Traffic analysis: Traffic characterization, grades of service, network blocking probabilities, delay system and queuing. Modern telephone services and network: Internet telephony, facsimile, integrated services digital network, asynchronous transfer mode and intelligent networks. Introduction to cellular telephony and satellite communication.

P. EEE 361: Power Network representation: Single line and reactance diagram of power system and per unit. Line representation: equivalent circuit of short, medium and long lines. Load flow: Gauss- Siedel and Newton Raphson Methods. Power flow control: Tap changing transformer, phase shifting, booster and regulating transformer and shunt capacitor. Fault analysis: Short circuit current and reactance of a synchronous machine. Symmetrical fault calculation methods: symmetrical components, sequence networks and unsymmetrical fault calculation. Protection: Introduction to relays, differential protection and distance protection. Introduction to circuit breakers,

P. EEE 453: Various Power plants general layout and principles, steam turbine: construction & operation, gas turbine: construction and operation, combined cycle gas turbine. Technical, economical and environmental factors. Load forecasting, Load factor calculation. Hydro based power plant, Nuclear Plant: principle of nuclear plant, components of a nuclear plant and operation. Future scopes of generating Electrical power, Power plant instrumentation. Deterministic and probabilistic. Electricity tariff: formulation and types. Introduction to renewable energy.

P. MAT 147 & EEE 215:. Analysis of engineering proposals, utilizing time value of money and relevant factors. Alternative proposals. Cost elements involved in engineering products and projects; cost control. Project costing, feasibility criteria, cash flow, payback period, EUAC, present value criterion, future value criterion, internal rate of return, benefit-cost ratio; replacement studies. After-tax project evaluation.
Principles of management; project planning, scheduling and controlling, PERT, CPM, Resource scheduling; materials management. Psychology in administration.

Application of planning and management principles to fire protection and electrical engineering projects. Introduction to industry and construction management.

Introduction to optimization techniques used in managing mechanical and electrical engineering projects.
5s management, Time management, TPM management, Six Sigma Philosophy, LEAN Tools, How to conduct internal Audit, Production Planning, Fire and Safety Management, Industrial Wastage Management, How to ensure product quality in your manufacturing industries and Cost control technique

P EEE 347: Power semiconductor switches and triggering devices: BJT, MOSFET, SCR, IGBT, GTO, TRIAC, UJT and DIAC. Rectifiers: Uncontrolled and controlled single phase and three phase. Regulated power supplies: Linear-series and shunt, switching buck, buck boost, boost and Cuk regulators. AC voltage controllers: single and three phase. Choppers. DC motor control. Single phase cyclo converter. Inverters: Single phase and three phase voltage and current source. AC motor control. Stepper motor control. Resonance inverters. Pulse width modulation control of static converters.

P EEE 453: Purpose of power system protection. Criteria for detecting faults: over current, differential current, difference of phase angles, over and under voltages, power direction, symmetrical components of current and voltages, impedance, frequency and temperature. Instrument transformers: CT and PT. Electromechanical, electronic and digital Relays: basic modules, over current, differential, distance and directional. Trip circuits. Unit protection schemes: Generator, transformer, motor, bus bar, transmission and distribution lines. Miniature circuit breakers and fuses. Circuit breakers: Principle of arc extinction, selection criteria and ratings of circuit breakers, types – air, oil, SF6 and vacuum.

Laboratory experiments based on EEE 463

P EEE 361: Importance of renewable energy, sources; Statistics regarding solar radiation and wind speed; Insulation; geographical distribution, atmospheric factors, measurements; Solar cell; principle of operation, spectral response, factors affecting conversion efficiency, I_V characteristics, maximum power output; PV modules and arrays; stationary and tracking; PV systems; stand alone, battery storage, inverter interfaces with grid; Wind turbine generators; types; operational characteristics; cut-in and cut-out speed, control, grid interfacings, AC-DC -AC link

P EEE 361: High voltage DC: Rectifier circuits, voltage multipliers, Van-de-Graaf and electrostatic generators. High voltage AC: Cascaded transformers and Tesla coils. Impulse voltage: Shapes, mathematical analysis, codes and standards, single and multi-stage impulse generators, tripping and control of impulse generators, Breakdown in gas, liquid and solid dielectric materials, Corona, High voltage measurements and testing, Over-voltage phenomenon and insulation coordination. Lightning and switching surges, basic insulation level, surge diverters and arresters.

P EEE 288: Brushless DC Machines: Construction and working principle, Equivalent magnetic analysis, EMF and torque equations, Types of converter and speed control, Comparison between the axial and radial Permanent magnet motors, applications , Permanent magnet DC and AC motors, Applications, Stepper Motors: Constructional features – Principle of operation – Variable reluctance motor –Hybrid motor – Single and multi stack configurations – Theory of torque predictions – Linear and non-linear analysis – Characteristics – Drive circuits, Switched Reluctance Motor: Construction details and classification, Working principle, Equivalent circuit, Motor speed-torque characteristics and modification with advance angle and dwell angle variation, Position sensing, Converter topologies, Speed Control, Applications, Wind Mill Generator: Characteristics of wind power. Wind power parameters, Classification of wind mill generators, Configuration of variable slip wind turbine generator and Doubly Fed induction Generator, Other Special Machines: Principle of operation and characteristics of Hysteresis motor – AC series motors – Linear induction motor Applications

P EEE 225: Measuring instrument: PMMC, Ammeters & Voltmeters. Current & Potential transformers, Extension of instrument range. Measurement of resistance: Wheatstone bridge, Kelvin Bridge, Voltmeter Ammeter method .Mega ohm meter. Measurement of capacitance and inductance, Localization of cable faults: Murray and varley loop test, capacitance test method, blavier’s test. Transducers: Potentiometer, strain gauge, thermistor, thermocouple, resistive transducer, capacitive, inductive, linear variable differential transformer, piezoelectric, Selection of transducer, application of transducers for measuring temperature, pressure flow, level and strain. Signal conditioning: block diagram of DC and AC signal conditioning systems, data acquisition and conversion system, Instrumentation amplifier, Introduction to telemetering system. Electronic measuring instrument: DVM, CRO, frequency and phase measurement

P EEE 275: VHF, UHF and microwave frequency ranges. Transmission line, Smith chart, impedance transformation and matching. Waveguides: parallel plane, rectangular, co-axial, Waveguide components, cavities and resonators. Microwave tubes: transit time and velocity modulation, Klystron, multi cavity klystron, reflex klystron, oscillator, Magnetron, TWT, Backward wave oscillators (BWO).Introduction to solid state microwave devices. Radiation: Dipole and its analysis, radiation pattern, description of different types of antennas. Introduction to antenna arrays and their design.

P EEE 329: VLSI technology: terminologies and trends, MOS transistor characteristics and equations, MOS fabrication process, nMOS & CMOS inverters: dc & transient characteristics, pass transistor & pass gates, Derivation of drain-to source current (Ids), Ids VS Vds, Pull-up to pull down ratio, CMOS & nMOS design Style, Stick Diagrams, CMOS layout and design rules: λ-based design rule. Complex CMOS gates: NAND, NOR, EXclusive OR, Resistance & Capacitance estimation and Modeling, raise time and fall time calculation of gate capacitance, Scaling & scaling factor of different parameters. Signal propagation delay, noise margin and power consumption, Interconnect, BiCMOS circuits. CMOS building blocks: adders, counters, multipliers and barrel shifters, Parity generator, Data paths, memory structures: Dynamic RAM cells, PLAs and FPGAs, VLSI testing: objectives & strategies.

P EEE 315: Semiconductors in equilibrium: Energy bands, intrinsic and extrinsic semiconductors, Fermi levels, electron and hole concentrations, temperature dependence of carrier concentrations and invariance of Fermi level. Carrier transport processes and excess carriers: Drift and diffusion, generation and recombination of excess carriers, built-in-field, Einstein relations, continuity and diffusion equations for holes and electrons and quasi-Fermi level. PN junction: Basic structure, equilibrium conditions, contact potential, equilibrium Fermi level, space charge, non-equilibrium condition, forward and reverse bias, carrier injection, minority and majority carrier currents, transient and AC conditions, time variation of stored charge, reverse recovery transient and capacitance. Bipolar Junction Transistor: Basic principle of pnp and npn transistors, emitter efficiency, base transport factor and current gain, diffusion equation in the base, terminal currents, coupled-diode model and charge control analysis, Ebers-Moll equations and circuit synthesis. Metal-semiconductor junction: Energy band diagram of metal semiconductor junctions, rectifying and ohmic contacts. MOS structure: MOS capacitor, energy band diagrams and flat band voltage, threshold voltage and control of threshold voltage, static C-V characteristics, qualitative theory of MOSFET operation, body effect and current-voltage relationship of a MOSFET. Junction Field-Effect-Transistor: Introduction, qualitative theory of operation, pinch-off voltage and current-voltage relationship. Substrate materials: Crystal growth and wafer preparation, epitaxial growth technique, molecular beam epitaxy, chemical vapor phase epitaxy and chemical vapor deposition (CVD). Doping techniques: Diffusion and ion implantation. Growth and deposition of dielectric layers: Thermal oxidation, CVD, plasma CVD, sputtering and silicon-nitride growth. Etching: Wet chemical etching, silicon and GaAs etching, anisotropic etching, selective etching, dry physical etching, ion beam etching, sputtering etching and reactive ion etching. Cleaning: Surface cleaning, organic cleaning and RCA cleaning. Lithography: Photo-reactive materials, pattern generation, pattern transfer and metallization.

P EEE 431: Introduction to Wireless Communication, Basic Wireless Theory, Components of a Radio System, Design of a Radio System, Understanding Standards and its necessity, Radio Frequency Spectrum, Infrared Networking Structures, Infrared WLAN, IrDA, Bluetooth, Low Speed WLAN, High Speed WLAN, WLAN Security, WiFi and WiMax. Introduction to communication using satellite, GEO, MEO and LEO satellites, Kepler’s law and orbital mechanics, satellite launching, Frequency spectra and band, Satellite subsystems, Satellite transponder, earth stations, earth station antenna, satellite link analysis, VSAT network, Satellite communication for Internet, Mobile satellite communications, Multiple Access Techniques: TDMA, FDMA and CDMA, Introduction to ISDN, B-ISDN.

P EEE 315: Fundamental of Optical physics, Optical properties in semiconductor: Direct and indirect band-gap materials, radiative and non-radiative recombination, optical absorption, photo-generated excess carriers, minority carrier life time, luminescence and quantum efficiency in radiation. Properties of light: Particle and wave nature of light, polarization, interference, diffraction and blackbody radiation. Light emitting diode (LED): Principles, materials for visible and infrared LED, internal and external efficiency, loss mechanism, structure and coupling to optical fibers. Stimulated emission and light amplification: Spontaneous and stimulated emission, Einstein relations, population inversion, absorption of radiation, optical feedback and threshold conditions. Semiconductor Lasers: Population inversion in degenerate semiconductors, laser cavity, operating wavelength, threshold current density, power output, hetero-junction lasers, optical and electrical confinement. Introduction to quantum well lasers. Photo-detectors: Photoconductors, junction photo-detectors, PIN detectors, avalanche photodiodes and phototransistors. Solar cells: Solar energy and spectrum, silicon and Schottkey solar cells. Modulation of light: Phase and amplitude modulation, electro-optic effect, acousto-optic effect and magneto-optic devices, Introduction to integrated optics, Introduction to optical fiber.

P EEE 449: Introduction to optical properties of light, Light propagation through optical fiber: Ray optics theory and mode theory. Optical fibers: Types and characteristics, modes of propagation, transmission characteristics, fiber joints and fiber couplers, waveguide analysis. Optical sources: Light Emitting Diode (LED) and semiconductor laser diode (SLD), Operational principles, characteristic curves, optical transmitter design using LED/SLD, Transmission limitations: Chromatic dispersion, nonlinear refraction, four wave mixing and laser phase noises, Optical Amplifiers: laser and fiber amplifiers, applications and limitation, Photo-detectors: P-i-N and avalanche photo detectors, Optical Modulation and detection schemes, direct and coherent detection receiver, Multi-channel optical system: Frequency division multiplexing, wavelength division multiplexing and co-channel interference, Optical data transmission in LAN, design of fiber-optic systems, optical networks.

P EEE 407: Spatial Descriptions, Direct Kinematics- the arm equation, Inverse Kinematics-solving the arm equation, Jacobian’s Dynamics, Motion Planning and Trajectory Generation, Position and Force Control, Manipulator Design, task planning.

P EEE 403: The human body: an overview, forms of mammalian cells, bioelectricity, Electroconduction system of the heart, bioelectric amplifiers: carrier amplifiers, optically coupled amplifiers, current loading type isolation amplifiers, chopper amplifiers, differential chopper amplifiers. Electrocardiograph (ECG): waveform, ECG preamplifiers, defibrillator. Blood pressure measurements and electronic manometry Pressure transducers, pressure amplifiers, Systolic, diastolic and mean detector circuits, practical problem in pressure monitoring, Blood flow measurements: plethysmography, electromagnetic flow meter, Phonocardiography, vector cardiography, cardioverter and pacemakers. Measurement of human brain parameters: cerebral angiography, cronical X-ray, brain scans. Tomography & Ultrasonogram, Electro-encephalography (EEG): electrode, frequency bands, EEG patterns and EEG preamplifiers, ICU/CCU central monitoring system.

P EEE 403: Embedded systems have become the next inevitable wave of technology, finding application in diverse fields of engineering. Microprocessors, together with sensors and actuators, have become embeddable in almost everything. The purpose of the course is to provide the students with the basic information about embedded systems which can be defined as a control system or computer system designed to perform a specific task. The course consists of two parts being closely interconnected. The aim of the course, in its first half, is to introduce students to the theory and practice of control system engineering. The second part is devoted to the basis of microcontroller’s architecture and programming of embedded systems.

P EEE 403: Brain Science; Brain & Behavior; Neuro Linguistic Programming (NLP); Attitude Theory; Cognitive Neuroscience; Brain Waves and Signals, Memory system. Neuromorphic Computing, Brain inspired computing; System design with Neuromorphic chip; Methods for Neuroimaging; Bio-Crime etc; Brain Computer Interface like CBI, BMI, Bio-net, Bio-Money etc. Neural Networks; Biological Intelligence (BI); Brain facts on AI, Robotics, Deep Learning; Deep BrainStimulation; IOT with Brain Interface, Data Science; Neuroscience; Bioinformatics; Bio-Commerce; Bio-Marketing; Bio-Business; Bio-Education; Collective Intelligence in Biomedical Applications; Disease like Alzheimer’s; Future trend and focused possibilities.

Study of problems in the field of Electrical and Electronic Engineering. A student needs to select a suitable topic of his/her interest or supervisors may display a list of Thesis. This course will be taken at the 10th semester or after 120 credit-hours completion.

This is designed for real life experience through internship for a semester in a relevant organization for BSEEE students. An internship project report is required. The report is examined and graded. There is also a comprehensive oral examination.