Department of Electrical and Electronic Engineering

 First Year  Semester I 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 101 Electrical Circuits I3 + 0 3.0 N/A

CSE 133 Structured Computer Programming3 + 0 3.0 N/A

CSE 134Structured Computer Programming Lab. 0 + 6 3.0 N/A

ENG 101 English Language I 2 + 0 2.0 N/AENG 102 English Language I Lab. 0 + 2 1.0 N/ACSE 108 Computer Aided Engineering Drawing 0 + 4 2.0 N/AMAT 101 Co-ordinate Geometry and Linear Algebra 3 + 0 3.0 N/APHY 103 Mechanics, Wave, Heat & Thermodynamics 3 + 0 3.0 N/APHY 104 Physics I Lab 0 + 3 1.5 N/A

Total 14 + 15 21.5   First Year  Semester II 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 123 Electrical Circuits II3 + 0

3.0EEE 101

EEE 124 Electrical Circuits   Lab .0 + 3

1.5EEE 101

EEE 126 Electrical Circuit Simulation Lab0 + 3

1.5EEE 101

PHY 207 Electromagnetism, Optics & Modern Physics 3 + 0 3.0 PHY 103PHY 204 Physics II Lab. 0 + 3 1.5 PHY 104

CHE 101 General Chemistry3 + 0

3.0N/A

CHE 102 General Chemistry Lab (Inorganic and Quantitative Analysis Lab) 0 + 3 1.5 N/A

ENG 103 English Language II 2 + 0 2.0 ENG 101ENG 104 English Language II Lab 0 + 2 1.0 ENG 102MAT 103 Differential and Integral Calculus 3 + 0 3.0 MAT 101

Total 14 + 14 21   Second Year  Semester I 

Course no. Course Title Hours/Week Credits Pre-requisite

Theory + LabEEE 221 Electronics I 3 + 0 3.0 EEE 101 & 123EEE 222 Electronic Circuit Simulation Lab. 0 + 3 1.5 EEE 124 & 126EEE 223 Electrical Machines I 3 + 0 3.0 EEE 101 & 123EEE 224 Electrical Machines I Lab. 0 + 3 1.5 EEE 124 & 126EEE 229 Electromagnetic Fields and Waves 3 + 0 3.0 MAT 102CSE 209 Numerical Analysis 2 + 0 2.0 CSE 135CSE 210 Numerical Analysis Lab. 0 + 2 1.0 CSE 136BAN 243 Cost and Management Accounting 3 + 0 3.0 N/A

MAT 221 Vector Analysis and Complex Variables 3 + 0 3.0 MAT 103Total 17 + 08 21  

 

Second Year  Semester II 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 225 Electrical Machines II3 + 0

3.0 EEE 223

EEE 226 Electrical Machines II Lab0 + 3

1.5 EEE 224

EEE 227 Electronics II3 + 0

3.0 EEE 221

EEE 228 Electronics   Lab 0 + 3

1.5 EEE 222

STA 202 Basic Statistics & Probability 4 + 0 4.0 N/AECO 103 Principles of Economics 4 + 0 4.0 N/AMAT 223 Ordinary and Partial Differential Equations 3 + 0 3.0 MAT 221

Total 17 + 06 20   Third Year  Semester I 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 321 Signals and Linear Systems3 + 0

3.0EEE 101 & 123

EEE 323 Digital Electronics3 + 0

3.0 EEE 221

EEE 324 Digital Electronics Lab0 + 3

1.5 EEE 222

EEE 325 Power System I3 + 0

3.0EEE 101 & 123

EEE 326 Power System I Lab0 + 3

1.5EEE 124 & 126

EEE 327 Electrical Properties of Materials3 + 0

3.0EEE 101 & 123

EEE 328 Electrical Services Design0 + 3

1.5EEE 101 & 123

IPE 301 Industrial & Business Management 3 + 0 3.0 N/ATotal 15 + 09 19.5  

 Third Year  Semester II 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 329 Digital Communication Engineering3 + 0

3.0MAT 204

EEE 330 Digital Communication Engineering Lab0 + 3

1.5MAT 204

EEE 331 Digital Signal Processing   I 3 + 0

3.0EEE 321

EEE 332 Digital Signal Processing   I     Lab 0 + 3

1.5EEE 321

EEE 333 Microprocessor & Assembly Language3 + 0

3.0 EEE 323

EEE 334 Microprocessor & Assembly Language Lab0 + 3

1.5 EEE 324

EEE 335 Control System I3 + 0

3.0 EEE 323

EEE 336 Control System   I   Lab 0 + 3

1.5 EEE 324

EEE 3** Option I3 + 0 3.0 Option list

Total 15 + 12 21   Fourth Year  Semester I 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 400 Project/Thesis (Initial work)0 + 4 2.0 Completion of

300 level courses

EEE 421 Solid State Devices3 + 0

3.0EEE 221

EEE 423 Computer Interfacing and Industrial Automation3 + 0

3.0EEE 333 & 335

EEE 424 Computer Interfacing and Industrial Automation Lab

0 + 3 1.5 EEE 334 & 336

EEE 4** Option II3 + 0

3.0Option list

EEE 4** Option III3 + 0

3.0Option list

EEE 4** Option III Lab0 + 3

1.5Option list

EEE 4** Option IV3 + 0

3.0Option list

Total 15 + 10 20   Fourth Year  Semester II 

Course no. Course Title Hours/WeekTheory + Lab

Credits Pre-requisite

EEE 408 Project/Thesis0 + 8 4.0 Completion of

300 level courses

EEE 4** Option V3 + 0

3.0Option list

EEE 4** Option V Lab0 + 3

1.5Option list

EEE 4** Option VI3 + 0

3.0Option list

EEE 4** Option VII3 + 0

3.0Option list

EEE 4** Option VIII3 + 0

3.0Option list

EEE 4** Option VIII Lab0 + 3

1.5Option list

Total 12 + 14 19  Total Credit: 160

 List of Options

Option I Courses 

Course Number Course Title Credit Hour Group

EEE 337 Power System II 3.0 Power

EEE 351 Analog Integrated Circuits 3.0 Electronics

EEE 371 Random Signals and Processes 3.0 Communication

 

Option II Courses  

Course Number Course Title Credit Hour Group

EEE 439 Electrical Machines III/ Energy Conversion III 3.0 Power

EEE 453 Processing and Fabrication Technology 3.0 Electronics

EEE 473 Digital Signal Processing II 3.0 Communication

CSE 411 PLC troubleshooting and programming 3.0 Computer

 Option III Courses 

Course Number Course Title Credit Hour Group

EEE 441EEE 442

Power ElectronicsPower Electronics Lab

3.01.5 Power

EEE 455EEE 456

VLSI   I VLSI   I   Lab

3.01.5

Electronics

(any one)EEE 457EEE 458

Microcontroller System DesignMicrocontroller System Design Lab

3.01.5

EEE 475EEE 476

RF and Microwave EngineeringRF and Microwave Engineering Lab

3.01.5 Communication

CSE 413CSE 414

Microprocessor System DesignMicroprocessor System Design Lab

3.01.5 Computer

 Option IV Courses 

Course Number Course Title Credit Hour Group

EEE 443 Power Plant Engineering3.0

Power

EEE 459 Compound Semiconductor and Hetero-Junction Devices 3.0

Electronics

EEE 477 Geographical Communication3.0

Communication

CSE 417 Real Time Computer System 3.0

Computer

 Option V Courses 

Course Number Course Title Credit Hour Group

EEE 445EEE 446

Power System ProtectionPower System Protection Lab

3.01.5

Power

(any one)EEE 447EEE 448

High Voltage EngineeringHigh Voltage Engineering Lab

3.01.5

EEE 461EEE 462

VLSI IIVLSI II Lab

3.01.5

Electronics

(any one)EEE 463EEE 464

Programmable ASIC DesignProgrammable ASIC Design Lab

3.01.5

EEE 481EEE 482

Optical Fiber CommunicationOptical Fiber Communication Lab

3.01.5

Communication

CSE 361 CSE 362 Computer Networking

Computer Networking Lab

3.01.5

Computer

 

Option VI Courses 

Course Number Course Title Credit Hour Group

EEE 449 Power System Reliability3.0

Power

EEE 465 Optoelectronics 3.0

Electronics

EEE 483 Telecommunication Engineering3.0

Communication

CSE 329 Computer Architecture 3.0

Computer

 Option VII Courses 

Course Number Course Title Credit Hour Group

EEE 451 Power System Operation and Control3.0

Power

EEE 467 Semiconductor Device Theory 3.0

Electronics

EEE 485 Cellular Mobile and Satellite Communication3.0

Communication

CSE 415 Multimedia Communications 3.0

Computer

 Option VIII (Interdisciplinary) Courses 

Course Number Course Title Credit Hour Group

EEE 487EEE 488

Control System IIControl System II Lab

3.01.5

Interdisciplinary

EEE 489EEE 490

Renewable Energy SystemsRenewable Energy Systems Lab

3.01.5

Interdisciplinary

EEE 491EEE 492

Biomedical InstrumentationBiomedical Instrumentation Lab

3.01.5

Interdisciplinary

EEE 493EEE 494

Measurement and InstrumentationMeasurement and Instrumentation Lab

3.01.5

Interdisciplinary

 

Detailed Syllabus 

Core Courses: 

EEE 101 ELECTRICAL CIRCUITS I3 hours/Week, 3 Credits 

Circuit variables and elements: Voltage, current, power, energy, independent and dependent sources, and resistance. Basic laws: Ohm’s law, Kirchoff’s current and voltage laws. Simple resistive circuits: Series and parallel circuits, voltage and current division, wye-delta transformation. Techniques of circuit analysis: Nodal and mesh analysis including super node and super mesh. Network theorems: Source transformation, Thevenin’s, Norton’s and superposition theorems with applications in circuits having independent and dependent sources, maximum power transfer condition and reciprocity theorem. Energy storage elements: Inductors and capacitors, series parallel combination of inductors and capacitors. Responses of RL and RC circuits: Natural and step responses.Magnetic quantities and variables: Flux, permeability and reluctance, magnetic field strength, magnetic potential, flux density, magnetization curve. Laws in magnetic circuits: Ohm’s law and Ampere’s circuital law. Magnetic circuits: series, parallel and series-parallel circuits.Pre-requisite: N/ATextbook: Introductory circuit analysis by BoylestadReference: Networks, lines and fields by J. D. Ryder EEE 103 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS 2 Hours/Week, 2 Credits 

Voltage and Current, Ohm’s law, Series circuits, Parallel circuits, Series-Parallel circuits, Capacitors, Inductors, R-L and R-L-C Circuits, Sinusoidal alternating wave forms, Square Waves and R-C response; Diode circuits, Transistor circuits, Op Amp. circuits, Popular ICs, Logic gates, Flip-Flops, and Counter. EEE 104 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS LAB2 Hours/Week, 2 Credits 

Laboratory works based on EEE 103 course  EEE 105 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS 3 Hours/Week, 3 Credits 

Voltage and Current, Ohm’s law, Series circuits, Parallel circuits, Series-Parallel circuits, Capacitors, Inductors, R-L and R-L-C Circuits, Sinusoidal alternating wave forms, Square Waves and R-C response; Diode circuits, Transistor circuits, Op Amp. circuits, Popular ICs, Logic gates, Flip-Flops, and Counter.Single phase transformer, Introduction to three phase transformer; DC machines: DC generator principle, types, characteristics and performances. AC machines: Single phase induction motor, three phase induction motor, introduction to synchronous machines; Oscilloscope; Transducers: Strain, temperature, pressure, speed and torque measurements. EEE 106 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS LAB3 Hours/Week, 1.5 Credits 

Laboratory works based on EEE 103/EEE 105. EEE 107 ELECTRICAL AND ELECTRONIC CIRCUIT ANALYSIS  4 Hours/Week, 4 Credits 

a. Circuit Models: Linear circuit elements, Ohm’s law, Voltage and Current sources, Kirchoff’s voltage and Current law, Voltage and Current Divider rules, Series Parallel Circuits, Circuit Theorem: Thevenin’s, Norton’s, Maximum power transfer, Superposition Reciprocity Theorem DC analysis: Source conversion,  Branch Current, Mesh analysis, Nodal Analysis, Bridge Network, Delta-Y conversion Transient and Time Domain Analysis: Transient in RC, RL and RLC circuits, Reactance, Average power AC theory and Frequency Domain Analysis: Phasors, Source conversion,  Series Parallel AC circuits, Mesh analysis, Nodal Analysis Resonance: Series, Parallel resonance circuit, Q valuesb. Semiconductors: Semiconductor materials, Energy levels, n, p type Semiconductor Devices: Diode, Transistor, FET, Optoelectronic devices and their uses in circuits Operational Amplifier: Basic operation and use in construction of analog circuits EEE 108 ELECTRICAL AND ELECTRONIC CIRCUIT ANALYSIS LAB6 Hours/Week, 3 Credits

 

1. Use of measuring Equipment: Multi-meter, Frequency meter and Oscilloscope2. Test of Ohm’s Law plot of  I-V, P-V curve3. I-V curve for Si, Ge and Zenor diodes4. Measurement of time constant in RC circuit5. Construction of a High pass and Low pass filter using RC circuit6. Measurement of Resonance frequency and Q value of a RLC circuit7. Making AND/OR gates using transistors8. FET as voltage controlled resistor9. Op amp as Inverting amplifier10. OP Amp as Differentiator and Integrator11. Optical data communication using LED and photodiode12. Electronic Project

 

EEE 123           ELECTRICAL CIRCUITS II              

3 hours/Week, 3 Credits 

Sinusoidal functions: Instantaneous current, voltage, power, effective current and voltage, average power, phasors and complex quantities, impedance, real and reactive power, power factor. Analysis of single phase AC circuits: Series and parallel RL, RC and RLC circuits, nodal and mesh analysis, application of network theorems in AC circuits, circuits with non-sinusoidal excitations, transients in AC circuits, passive filters. Resonance in AC circuits: Series and parallel resonance. Magnetically coupled circuits. Analysis of three phase circuits: Three phase supply, balanced and unbalanced circuits, and power calculation.Pre-requisite:  EEE 101       ELECTRICAL CIRCUITS ITextbook: Introductory circuit analysis by BoylestadReference: Networks, lines and fields by J. D. Ryder EEE 124           ELECTRICAL CIRCUITS   LAB 3 hours/Week, 1.5 Credits 

In this course students will perform experiments to verify practically the theories and concepts learned in EEE-101 and EEE 123.1. To familiar with the operation of different electrical instruments.2. To  verify the following  theorems:

i. KCL and KVL theorem,ii. Superposition theorem,

iii. Thevenin’s theorem, iv. Norton’s theorem and  v. Maximum power transfer theorem

 3. To design and construct of low pass and high pass filter and draw their characteristics curves.4. To investigate the voltage regulation of a simulated transmission network.    Study the characteristics of Star-Delta connection5. Study the frequency response of an RLC circuit and find its resonant frequency.6. To perform also other experiments relevant to this course.

Pre-requisite: EEE 101  ELECTRICAL CIRCUITS ITextbook: Introductory circuit analysis by BoylestadReference: Networks, lines and fields by J. D. Ryder EEE 126           ELECTRICAL CIRCUIT SIMULATION LAB      3 hours/Week, 1.5 Credits 

Simulation laboratory based on EEE-1011 and EEE-1113 theory courses. Students will verify the theories and concepts learned in EEE-1011 and EEE-1113 using simulation software like PSpice and Matlab. Students will also perform specific design of DC and AC circuits theoretically and by simulation.Pre-requisite: EEE 101  ELECTRICAL CIRCUITS ITextbook: Introductory circuit analysis by BoylestadReference: Networks, lines and fields by J. D. Ryder EEE 201 DIGITAL LOGIC DESIGN3 Hours/Week, 3 Credits 

Logic Families: TTL, CMOS, ECL, TristateLogic Gates: AND, OR, NAND, NOR, X-OR, X-NOR, Circuit Design              Flipflops: SR, JK, D, Master Slave, Application, SynchronizationLogic Circuits: Coder, Decoder, Mux, DmuxCounters: Synchronous, Asynchronous, Up/Down, Ripple, CascadingRegisters: Shift registersMemory Devices: ROM, RAM, Static, Dynamic, Memory OperationArithmatic Circuits: Adder, Carry, Look Ahead, ALUPAL: Microprogram Control, FPGA, HDLA EEE 202 DIGITAL LOGIC DESIGN LAB 4 Hours/Week, 2 Credits

 

1. Logic circuits using combination of gates2. Bounce-less switch using RS latch3. 0-9 second timer using 555, counters and 7-segment display4. Scrambler/De-scrambler circuit using latch for data communication5. Design of nano-computer6. Write, Read and Display contents of memory devices.7. Project with PAL/FPGA/Microcontroller

 EEE 221           ELECTRONICS I3 hours/Week, 3 Credits 

P-N junction as a circuit element: Intrinsic and extrinsic semiconductors, operational principle of p-n junction diode, contact potential, current-voltage characteristics of a diode, simplified DC and AC diode models, dynamic resistance and capacitance. Diode circuits: Half wave and full wave rectifiers, rectifiers with filter capacitor, characteristics of a Zener diode, Zener shunt regulator, clamping and clipping circuits. Bipolar Junction Transistor (BJT) as a circuit element: current components, BJT characteristics and regions of operation, BJT as an amplifier, biasing the BJT for discrete circuits, small signal equivalent circuit models, BJT as a switch. Single stage mid-band frequency BJT amplifier circuits: Voltage and current gain, input and output impedance of a common base, common emitter and common collector amplifier circuits. Metal Oxide Semiconductor Field Effect Transistor (MOSFET) as circuit element: structure and physical operation of an enhancement MOSFET, threshold voltage, Body effect, current-voltage characteristics of an enhancement MOSFET, biasing discrete and integrated MOS amplifier circuits, single-stage MOS amplifiers, MOSFET as a switch, CMOS inverter. Junction Field-Effect-Transistor (JFET): Structure and physical operation of JFET, transistor characteristics, pinch-off voltage. Differential and multistage amplifiers: Description of differential amplifiers, small-signal operation, differential and common mode gains, RC coupled mid-band frequency amplifier.Pre-requisite: EEE 101 Electrical Circuits I & EEE 123  Electrical Circuits IITextbook: Electronics Devices by R. L. BoylestadReference: Electronics Principles. By Malvino EEE 222           ELECTRONIC CIRCUIT SIMULATION LAB3 hours/Week, 1.5 Credits 

Simulation laboratory based on EEE-221 theory course. Students will verify the theories and concepts learned in EEE 221

using simulation software like PSpice and Matlab. Students will also perform specific design of electronics circuits theoretically and by simulation.

1. To familiar with electronics devices and Laboratory Equipments.2. To study of V-l Characteristics curve of P-N junction diode.3. To study of V-l Characteristics curve of a Zener diode. 4. To study of Half-Wave Rectification circuit.5. To study of Full-Wave Rectification circuit (Bridge & Cente- tap)6. To familiar with NPN and PNP Transistors.7. To study of Full-Wave filter circuit.

8. To study of Common Emitter (CE) Transistor Amplifier circuits. 9. To study of Clipping and clamping circuit.10. To study of output characteristics of an FET.11. To study of JFET as an amplifier.

To study of output characteristics of a JFET. Pre-requisite: EEE 124 Electrical Circuits  Lab & EEE  126  Electrical Circuit Simulation LabTextbook: Electronics Devices by R. L. BoylestadReference: Electronics Principles. By Malvino EEE 223           ELECTRICAL MACHINES I 3 hours/Week, 3 Credits 

Transformer: Ideal transformer- transformation ratio, no-load and load vector diagrams; actual transformer- equivalent circuit, regulation, short circuit and open circuit tests. Three phase induction motor: 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.Pre-requisite: EEE 101 Electrical Circuits I & EEE 123  Electrical Circuits IITextbook: Energy conversion by Kenneth C. WestonReference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher EEE 224           ELECTRICAL MACHINES I LAB3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 223. In the second part, students will design simple systems using the principles learned in EEE 223.Pre-requisite: EEE 124 Electrical Circuits  Lab & EEE  126  Electrical Circuit Simulation LabTextbook: Energy conversion by Kenneth C. WestonReference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher EEE 225           ELECTRICAL MACHINES II 3 hours/Week, 3 Credits 

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.             Pre-requisite: EEE 223  Electrical Machines ITextbook: Energy conversion by Kenneth C. WestonReference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher EEE 226           ELECTRICAL MACHINES II LAB3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 225. In the second part, students will design simple systems using the principles learned in EEE 225.Pre-requisite: EEE 224  Electrical Machines I LabTextbook: Energy conversion by Kenneth C. WestonReference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher EEE 227           ELECTRONICS II3 hours/Week, 3 Credits 

Frequency response of amplifiers: Poles, zeros and Bode plots, amplifier transfer function, techniques of determining 3 dB

frequencies of amplifier circuits, frequency response of single-stage and cascade amplifiers, frequency response of differential amplifiers. Operational amplifiers (Op-Amp): Properties of ideal Op-Amps, non-inverting and inverting amplifiers, inverting integrators, differentiator, weighted summer and other applications of Op-Amp circuits, effects of finite open loop gain and bandwidth on circuit performance, logic signal operation of Op-Amp, DC imperfections. General purpose Op-Amp: DC analysis, small-signal analysis of different stages, gain and frequency response of 741 Op-Amp. Negative feedback: properties, basic topologies, feedback amplifiers with different topologies, stability, frequency compensation. Active filters: Different types of filters

and specifications, transfer functions, realization of first and second order low, high and band pass filters using Op-Amps. 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.Pre-requisite: EEE 221  Electronics ITextbook: Electronics Devices by R. L. BoylestadReference: Electronics Principles. By Malvino EEE 228            ELECTRONICS   LAB 3 hours/Week,1.5 Credits

 

In this course students will perform experiments to verify practically the theories and concepts learned in EEE-221 & 227.1. Study of R-C coupling.2. Study of Transformer coupling.3. Study of Direct coupling.4. Study of R-C Phase shift Oscillator.5. Study of Transistor Tuned Oscillator.

Study of Negative feedback circuit.Pre-requisite: EEE 222  Electronic Circuit Simulation LabTextbook: Electronics Devices by R. L. BoylestadReference: Electronics Principles. By Malvino EEE 229           ELECTROMAGNETIC FIELDS AND WAVES3 hours/Week, 3 Credits 

Review of Vector Algebra and Co-ordinate System: Curvilinear Co-Ordinates, Rectangular Cylindrical and Spherical Co-Ordinates, Gradient, Divergence, Curl and Formulas involving Vector Operations,.Electrostatics: Coulombs law, Gauss’s theorem, Laplace’s and Poisson’s equations, Energy of an electrostatic system,Magneto static: Ampere’s law, Biot Savart law, Energy of magneto static system. Maxwell’s equations: Their derivations, Continuity of charges, Concept of displacement current, Electro-Magnetic Energy, Boundary conditions, The Wave Equations with Sources. Potentials used with varying charges and currents, Retarded potentials, Maxwell’s equation in different co-ordinate systems.Relation between circuit theory and field theory: Circuit concepts and the derivation from the field equations, high frequency circuit concepts, Circuit radiation resistance, Skin effect and circuit impedance, Concept of good and Perfect conductors and dielectrics, Propagation in good conductors, Reflection of uniform plane waves, standing wave ratio, Dispersion in dielectrics.Propagation of electromagnetic waves: Plane wave propagation, Polarization, Power flow and pointing theorem, Transmission line analogy, Display lines ion in dielectrics, Liquids and solids, Radio wave propagation: Different types of radio wave propagation Ionosphere, Vertical heights and critical frequencies of layers, Propagation of RW through Ionosphere, Reflection of RW, Skip distance and MUF, Fading, Static and noise, Two way communication.Pre-requisite: MAT 102   Matrices, Vector Analysis & GeometryTextbook: Field and Wave Electromagnetic by David K. ChengReference: Physics (Part-II) by Resnick & Haliday EEE 305A    BUILDING SERVICES III (ELECTRICAL)3 Hours/Week, 1.5 Credits EEE 321           SIGNALS AND LINEAR SYSTEMS3 hours/Week, 3 Credits 

Continuous-time signals and systems: Mathematical, frequency and time domain representation. Discrete-time signals and systems: Mathematical, frequency and time domain representation, Application in digital processing and communication systems.Linear Systems: Characteristics of a linear system, methods of transient and steady state solutions of differential and integro-differential equations, Network theorems, Analogous systems. Analysis by Fourier methods. Laplace transformation and its application to linear circuits. Impulse function, convolution integral and its application. Matrix with simple applications in circuits: network functions, poles and zeroes of a network. Introduction to topological concepts in electrical and magnetic circuit networks.Pre-requisite: EEE 101 Electrical Circuits I & EEE 123  Electrical Circuits IITextbook: Signals & Linear Systems by B.P. LathiReference: Signals and Systems  by Alan V. Oppenheim, Alan S. Willsky, S. Hamid, S. Hamid Nawab EEE 323           DIGITAL ELECTRONICS3 hours/Week, 3 Credits 

Introduction to number systems and codes. Analysis and synthesis of digital logic circuits: Basic logic functions, Boolean algebra, combinational logic design, minimization of combinational logic. Implementation of basic static logic gates in CMOS and BiCMOS: DC characteristics, noise margin and power dissipation. Power optimization of basic gates and

combinational logic circuits. Modular combinational circuit design: pass transistor, pass gates, multiplexer, demultiplexer and their implementation in CMOS, decoder, encoder, comparators, binary arithmetic elements and ALU design. Programmable logic devices: logic arrays, field programmable logic arrays and programmable read only memory. Sequential circuits: different types of latches, flip-flops and their design using ASM approach, timing analysis and power optimization of sequential circuits. Modular sequential logic circuit design: shift registers, counters and their applications.Pre-requisite: EEE 221  Electronics ITextbook: Digital Logic Design by M. Morris Mano                            Reference: Switching Theory by Dr. V. K. Jain EEE 324           DIGITAL ELECTRONICS LAB3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-323. In the second part, students will design simple systems using the principles learned in EEE-323.

1. To construct and study the following logic gates: AND, OR, NOT. NAND, NOR, EXOR2. Verify the Demorgan’s Law : Law(I) and Law(II)3. To Verify different kind of applications of Boolean algebra.4. To construct an AND gate by diode resistors and observe its characteristics.5. To verify the characteristics of Exclusive OR and Exclusive NOR using basic logic gate.6.    Verification of De-Morgan’s Theorem for 2 input Variable.6. To simplify the given Boolean function by using K-map and implement it with logic Diagram.7. ABCD to 7 Segment Decoder8. Study of 4-bit BCD adder.9. Study of Asynchronous & Synchronous R-S Flip-Flop.10. Study of J-K Flip-Flop.11. Study of 4-bit binary Ripple Counter. 

Pre-requisite: EEE 222  Electronic Circuit Simulation LabTextbook: Digital Logic Design by M. Morris Mano                            Reference: Switching Theory by Dr. V. K. Jain EEE 325           POWER SYSTEM I3 hours/Week, 3 Credits 

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. Typical layout of a substation. Load curves: Demand factor, diversity factor, load duration curves, energy load curve, load factor, capacity factor and plant factorPre-requisite: EEE 101 Electrical Circuits I & EEE 123  Electrical Circuits IITextbook: Communication and Control in Electric Power Systems: Applications of Parallel and Distributed by Mohammad ShahidehpourReference: Transient Phenomena in Electrical Power Systems by Valentin Andreevich Venikov EEE 326           POWER SYSTEM I LAB3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-325. In the second part, students will design simple systems using the principles learned in EEE-325.Pre-requisite: EEE 124 Electrical Circuits  Lab & EEE  126  Electrical Circuit Simulation LabTextbook: Communication and Control in Electric Power Systems: Applications of Parallel and Distributed by Mohammad ShahidehpourReference: Transient Phenomena in Electrical Power Systems by Valentin Andreevich Venikov EEE 327           ELECTRICAL PROPERTIES OF MATERIALS3 hours/Week, 3 Credits 

Wiring system design, drafting, and 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.Pre-requisite: EEE 101 Electrical Circuits I & EEE 123  Electrical Circuits IITextbook: Electronics Properties of Materials by Rolf E. Hummerl

Reference: Properties Of Materials: Anisotropy, Symmetry, Structure by Robert Everest Newnham EEE 328           ELECTRICAL SERVICES DESIGN3 hours/Week, 1.5 Credits 

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. Introduction to quantum mechanics: Wave nature of electrons, Schrodinger’s equation, one-dimensional quantum problems- infinite quantum well, potential step and potential barrier; Heisenbergs’s uncertainty principle and quantum box. 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- electronics, 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.Pre-requisite: EEE 101 Electrical Circuits I & EEE 123  Electrical Circuits IITextbook: Electronics Properties of Materials by Rolf E. HummerlReference: Properties Of Materials: Anisotropy, Symmetry, Structure by Robert Everest Newnham EEE 329            DIGITAL COMMUNICATION ENGINEERING3 hours/Week, 3 Credits 

Introduction: Basic constituents of communication system. Need for using high carrier frequency, Classification of RF spectrum. Communication channels, mathematical model and characteristics. Probability and stochastic processes. Source coding: Mathematical models of information, entropy, Huffman code and linear predictive coding. Digital transmission system: Base band digital transmission, inter-symbol interference, bandwidth, power efficiency, modulation and coding trade-off. Receiver for AWGN channels: Correlation demodulator, matched filter demodulator and maximum likelihood receiver. Channel capacity and coding: Channel models and capacities and random selection of codes. Block codes and conventional codes: Linear block codes, convolution codes and coded modulation. Spread spectrum signals and system.Pre-requisite: MAT 221  Ordinary and Partial Differential Equations and                         EEE 323   Digital ElectronicsTextbook: Digital Communications by John G. ProakisReference: Communication System by Simon Haykin EEE 330    DIGITAL COMMUNICATION ENGINEERING LAB3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-329. In the second part, students will design simple systems using the principles learned in EEE-329Pre-requisite: MAT 221  Ordinary and Partial Differential Equations                         EEE 324   Digital Electronics  Textbook: Communication Theory: Epistemological Foundations by James Arthur AndersonReference: Modern Digital and Analog Communication System by B.P. Lathi EEE 331    DIGITAL SIGNAL PROCESSING   I 3 hours/Week, 3 Credits 

Introduction to digital signal processing (DSP): Discrete-time signals and systems, analog to digital conversion, impulse response, finite impulse response (FIR) and infinite impulse response (IIR) of discrete-time systems, difference equation, convolution, transient and steady state response. Discrete transformations: Discrete Fourier series, discrete-time Fourier series, discrete Fourier transform (DFT) and properties, fast Fourier transform (FFT), inverse fast Fourier transform, z-transformation - properties, transfer function, poles and zeros and inverse z-transform. Correlation: circular convolution, auto-correlation and cross correlation. Digital Filters: FIR filters- linear phase filters, specifications, design using window, optimal and frequency sampling methods; IIR filters- specifications, design using impulse invariant, bi-linear z- transformation, least-square methods and finite precision effects.Pre-requisite: EEE 321  Signals and Linear SystemsTextbook: Digital Signal Processing by John G. ProakisReference: Introduction to Digital Signal Processing by Johnny R. Johnson EEE 332           DIGITAL SIGNAL PROCESSING   I     LAB 3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 331. In the second part, students will design simple systems using the principles learned in EEE 331. 

1. Time Domain Characterization of LTI system.2. DFT and IDFT computation.3. Rational Z-transform and inverse of it.4. Schur-Cohn Stability test.5. IIR digital filter design.6. FIR digital filter design.7. Design of linear phase FIR filters based on windowed Fourier Series Approach.8. Application of FFT and IFFT functions.

Pre-requisite: EEE 321  Signals and Linear SystemsTextbook: Digital Signal Processing by John G. ProakisReference: Introduction to Digital Signal Processing by Johnny R. Johnson EEE 333 MICROPROCESSOR & ASSEMBLY LANGUAGE3 hours/Week, 3 Credits 

Microprocessor: Introduction to different types of microprocessors. Microprocessor architecture, instruction set, interfacing, I/O operation, Interrupt structure, DMA. Microprocessor interface ICs. Advanced microprocessors; parallelism in microprocessors. Concepts of Microprocessor based systems design.Assembly LanguageIntroduction: Machine & assembly languages, Necessity and applications, Elements of assembly languages, Expression and operators, Statements, Format, Machine instructions and mnemonics, Register, Flags and stack.Instruction sets and implementation: Data definition and transfer, Arithmetic instructions, Character representation instructions, Addressing modes, Instructions and data in memory.Subroutine: Calling, Parameter passing, and Recursion.Macros: Calling macros, Macro operators, Advance macros usage.Files: DOS file functions, Text file, Bit file, and File manipulation.I/O programming: Procedure, Software interrupts, DOS functions call.Machine and assembly language programming (macro and large system)Advanced programming techniques in assembly language, interfacing with high level programmingPre-requisite: EEE 323  Digital ElectronicsTextbook: Microprocessor & Microprocessor Based System Design by Dr. M. RafiquzzamanReference: Microprocessor Architecture, Programming & Applications by R.S. Gaonker EEE 334  MICROPROCESSOR & ASSEMBLY LANGUAGE LAB3 hours/Week, 1.5 Credits

 

1. Registers, JMP, LOOP, CMP instructions, and Conditional jump instruction.2. Implementation of different types of instructions (rotating, shifting etc)3. Instructions (MUL, IMUL, DIV, IDIV, CBW, CWD, arrays, XLAT).4. String instructions, macro handling.5. Bios Interrupt, Dos Interrupt6. The IN, OUT, INS and OUTS instructions,

   7.    To perform also other experiments relevant to this course.Pre-requisite: EEE 324  Digital Electronics LabTextbook: Microprocessor & Microprocessor Based System Design by Dr. M. RafiquzzamanReference: Microprocessor Architecture, Programming & Applications by R.S. Gaonker EEE 335  CONTROL SYSTEM I3 hours/Week, 3 Credits 

Introduction to control systems. Linear system models: transfer function, block diagram and signal flow graph (SFG). State variables: SFG to state variables, transfer function to state variable and state variable to transfer function. Feedback control system: Closed loop systems, parameter sensitivity, transient characteristics of control systems, effect of additional pole and zero on the system response and system types and steady state error. Routh stability criterion. Analysis of feedback control system: Root locus method and frequency response method. Design of feedback control system: Controllability and observability, root locus, frequency response and state variable methods. Digital control systems: introduction, sampled data systems, stability analysis in Z-domain.Pre-requisite: EEE 323  Digital ElectronicsTextbook: Control Systems Engineering by Norman S. NiseReference: Modern Control Engineering (4th Edition) by Katsuhiko Ogata EEE 336   CONTROL SYSTEM   I   LAB 3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-335. In the second part, students will design simple systems using the principles learned in EEE-335. Pre-requisite: EEE 324  Digital Electronics LabTextbook: MATLAB 6.1 Supplement to accompany Control Systems Engineering by Norman S. NiseReference: Control Systems Engineering by Norman S. Nise EEE 400     PROJECT/THESIS (INITIAL WORK)2 hours/Week, 2 Credits 

Project work based on all major coursesPre-requisite: Completion of 300 level coursesTextbook: N/AReference: N/A EEE 421    SOLID STATE DEVICES3 hours/Week, 3 Credits 

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.Pre-requisite: EEE 221  EEE 221  Electronics ITextbook: Solid State Electronics Devices (6th Edition) by Ben Streetman and Sanjay BanerjeeReference: Modular Series on Solid State Devices by Robert F. Pierret, Gerold Neudeck EEE 423    COMPUTER INTERFACING AND INDUSTRIAL AUTOMATION3 hours/Week, 3 Credits 

Introductory Concept: I/O interface, memory interface, interfacing components and their characteristics. Interfacing components: 8284A Programmable timer, Bus architecture, Bus Timing, Bus Controller, analog and digital interface.Interrupt: Interrupt sources, types of interrupt, 8259A priority interrupt controller, Daisy chainSerial Interface: Characteristics of memory and I/O interface, Synchronous and asynchronous communication,   Serial I/O interface, 8251A communication interface, RS-232 interfaceParallel Interface: 8155A Programmable peripheral Interface, Parallel adapter, parallel portI/O Controller: 8237A DMA Controller, Floppy and Hard disk ControllerPeripheral Components: Barcode Reader, Sound card, Stepper motor and opto-isolation, MIDI  interface, power circuits.Industrial Automation: Part A: General concepts of the industrial production. Concepts of production systems and production processes. Automation production systems and their classification. Production equipment. Process and manufacturing productions automation. Flexibility of the manufacturing systems: general elements. Principal performance indexes. Part B: Modeling and control of Discrete Events Systems (DES). Discrete Events Systems (DES) concepts review; their use in modeling productive processes. Importance of DES for engineers and relevant features of control of such systems. Preliminary elements on the Petri Nets as DES modeling formalisms. Fundamental properties of the Petri nets. Place and Transition-invariant. Modeling of typical elements of the manufacturing systems. Examples of production systems models. Analysis of cyclic production systems. Supervisory Control of DES using Petri Nets. Elements of SFC language.Pre-requisite: EEE 333 Microprocessor & Assembly Language & EEE 335  Control System ITextbook: Microprocessor and Interface by Douglas V. Hall and                   Process Control Instrumentation Technology  by C. D. JohnsonReference: Microprocessor and Interfacing by Mohamed Rafiquzzaman EEE 424    COMPUTER INTERFACING AND INDUSTRIAL AUTOMATION LAB3 hours/Week, 1.5 Credits 

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-423. In the second part, students will design simple systems using the principles learned in EEE-423.

Some of the experiments are: Registers, JMP, LOOP, CMP instructions, and Conditional jump instruction. Implementation of different types of instructions (rotating, shifting etc) Instructions (MUL, IMUL, DIV, IDIV, CBW, CWD, arrays, XLAT).

  String instructions, macro handling. Bios Interrupt, Dos Interrupt The IN, OUT, INS and OUTS instructions, Computer Interfacing Details about parallel port ( pin description, port address and commands) LED interface through parallel port. Interfacing 7-segment Display High power load interface Stepping motor interface and to control it both in clockwise and anti-clockwise direction Inputting data through parallel port Serial port programming Interfacing a robot manipulator arm and writing a program to control it Parallel port programming using Visual Basic Voice Interface

List of the Project:1. Traffic Control system2. Interfacing a joystick using parallel port3. 3-DOF robot manipulator arm control4. Room Automation5. Electronics voting machine6. Interfacing a 2x8 character LCD display

To perform also other experiments relevant to this coursePre-requisite: EEE 334 Microprocessor & Assembly Language Lab & EEE 336  Control System   I   Lab Textbook: Microprocessor and Microcomputer Based System  Design by Microprocessor Data handbookReference: Microprocessor and Interface by Douglas V. Hall EEE 408    PROJECT/THESIS (Finalization and Submission)8 hours/Week, 4 Credits 

Project work based on all major coursesPre-requisite: Completion of 300 level coursesTextbook: N/AReference: N/A 

EEE OptionsPOWER OPTIONS EEE 337   POWER SYSTEM II3 hours/Week, 3  Credits 

Transmission lines cables: overhead and underground. Stability: swing equation, power angle equation, equal area criterion, multi-machine system, step by step solution of swing equation. Factors affecting stability. Reactive power compensation. Flexible AC transmission system (FACTS). High voltage DC transmission system. Power quality: harmonics, sag and swell.Pre-requisite: EEE 325  Power System ITextbook: Communication and Control in Electric Power Systems: Applications of Parallel and Distributed by Mohammad ShahidehpourReference: Economic Operation of Power Systems by Leon Kenneth Kirchmayer EEE 439   ELECTRICAL MACHINES III 3 hours/Week, 3  Credits 

Special machines: series universal motor, permanent magnet DC motor, unipolar and bipolar brush less DC motors, stepper motor and control circuits. Reluctance and hysteresis motors with drive circuits, switched reluctance motor, electro static motor, repulsion motor, synchros and control transformers. Permanent magnet synchronous motors. Acyclic machines: Generators, conduction pump and induction pump. Magneto hydrodynamic generators. Fuel Cells, thermoelectric generators, flywheels. Vector control, linear motors and traction. Photovoltaic systems: stand alone and grid interfaced. Wind turbine generators: induction generator, AC-DC-AC conversion.Pre-requisite: EEE 225  Electrical Machines IITextbook: Energy conversion by Kenneth C. Weston

Reference: Energy conversion: systems, flow physics and engineering by Professor Reiner decher EEE 441   POWER ELECTRONICS3 hours/Week, 3  Credits EEE 442   POWER ELECTRONICS LAB3 hours/Week, 1.5  Credits 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, buckboost, boost and Cuk regulators. AC voltage controllers: single and three phase. Choppers. DC motor control. Single phase cycloconverter. 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.Lab work: This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-441. In the second part, students will design simple systems using the principles learned in EEE-441.Pre-requisite: EEE 227  Electronics II , EEE 325  Power System I and their LabsTextbook: An Introduction to Power Electronics by Bird, B. M., K. G. King, and D. A. G. Ped derReference: Power electronics systems: theory and design by Agrawal, Jai P. EEE 443   POWER PLANT ENGINEERING3 hours/Week, 3  Credits 

Power plants: general layout and principles, steam turbine, gas turbine, combined cycle gas turbine, hydro and nuclear. Power plant instrumentation. Selection of location: Technical, economical and environmental factors. Load forecasting. Generation scheduling: deterministic and probabilistic. Electricity tariff: formulation and types.Pre-requisite: EEE 337  Power System IITextbook: Power Plant Engineering by Larry Drbal, Kayla Westra, Pat BostonReference: Power Generation Handbook : Selection, App by Philip Kiameh EEE 445  POWER SYSTEM PROTECTION3 hours/Week, 3  Credits

EEE 446  POWER SYSTEM PROTECTION LAB3 hours/Week, 1.5  Credits 

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, electronics 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.Lab work: This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-445. In the second part, students will design simple systems using the principles learned in EEE-445.Pre-requisite: EEE 337  Power System II Textbook: Power System Protection by Paul M. AndersonReference: Practical Power System Protection by Leslie Hewitson EEE 447           HIGH VOLTAGE ENGINEERING3 hours/Week, 3  Credits 

EEE 448           HIGH VOLTAGE ENGINEERING LAB3 hours/Week, 1.5  Credits 

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.Pre-requisite: EEE 337  Power System IITextbook: High Voltage Engineering by M.S. NaiduReference: Dielectric Phenomena In High Voltage Engineering by F. W. Peek 

EEE 449           POWER SYSTEM RELIABILITY3 hours/Week, 3  Credits 

Review of probability concepts. Probability distribution: Binomial, Poisson, and Normal. Reliability concepts: Failure rate, outage, mean time to failure, series and parallel systems and redundancy. Markov process. Probabilistic generation and load models. Reliability indices: Loss of load probability and loss of energy probability. Frequency and duration. Reliability evaluation techniques of single area system.Pre-requisite: EEE 337  Power System IITextbook: Power System Reliability Evaluation by R. BillintonReference: Reliability Assessment of Electrical Power Systems Using Monte Carlo Methods by Billinton  EEE 451           POWER SYSTEM OPERATION AND CONTROL3 hours/Week, 3  Credits 

Principles of power system operation: SCADA, conventional and competitive environment. Unit commitment, static security analysis, state estimation, optimal power flow, automatic generation control and dynamic security analysis.Pre-requisite: EEE 337  Power System II and EEE 335  Control System ITextbook: Power System Operation by Robert H. Miller, James H. MalinowskReference: Electric Utility Systems and Practices by Homer M. Rustebakke ELECTRONICS OPTIONSEEE 351           ANALOG INTEGRATED CIRCUITS3 hours/Week, 3  Credits 

Review of FET amplifiers: Passive and active loads and frequency limitation. Current mirror: Basic, cascode and active current mirror. Differential Amplifier: Introduction, large and small signal analysis, common mode analysis and differential amplifier with active load. Noise: Introduction to noise, types, representation in circuits, noise in single stage and differential amplifiers and bandwidth. Band-gap references: Supply voltage independent biasing, temperature independent biasing, proportional to absolute temperature current generation and constant transconductance biasing. Switch capacitor circuits: Sampling switches, switched capacitor circuits including unity gain buffer, amplifier and integrator. Phase Locked Loop (PLL): Introduction, basic PLL and charge pumped PLL.Pre-requisite: EEE 227  Electronics IITextbook: Analysis and Design of Analog Integrated Circuits                    by Paul R. Gray, Paul J. Hurst, Stephen H. Lewis, Robert G. Meyer Reference: CMOS Analog Circuit Design by Phillip E. Allen EEE 453           PROCESSING AND FABRICATION TECHNOLOGY3 hours/Week, 3  Credits 

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 metalization. Discrete device fabrication: Diode, transistor, resistor and capacitor. Integrated circuit fabrication: Isolation - pn junction isolation, mesa isolation and oxide isolation. BJT based microcircuits, p-channel and n-channel MOSFETs, complimentary MOSFETs and silicon on insulator devices. Testing, bonding and packaging.Pre-requisite: EEE 227  Electronics IITextbook: Semiconductor Technology: Processing and Novel Fabrication Techniques                    by Michael E. Levinshtein, Michael S. ShurReference: Photomask Fabrication Technology by Benjamin G. Eynon, Banqiu Wu EEE 455           VLSI   I 3 hours/Week, 3  Credits

EEE 456           VLSI   I   LAB 3 hours/Week, 1.5  Credits 

VLSI technology: Top down design approach, technology trends and design styles. Review of MOS transistor theory: Threshold voltage, body effect, I-V equations and characteristics, latch-up problems, NMOS inverter, CMOS inverter, pass-transistor and transmission gates. CMOS circuit characteristics and performance estimation: Resistance, capacitance, rise and fall times, delay, gate transistor sizing and power consumption. CMOS circuit and logic design: Layout design rules and physical design of simple logic gates. CMOS subsystem design: Adders, multiplier and memory system, arithmetic logic unit. Programmable logic arrays. I/O systems. VLSI testing.Lab work:

This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-455. In the second part, students will design simple systems using the principles learned in EEE-455Pre-requisite: EEE 323  Digital Electronics and EEE 324  Digital Electronics LabTextbook: CMOS  Circuit design, Layout and Simulation, Modern VLSI  Design : Systems on Silicon                    by R.Jacob Baker, Harry W .Li, David E.BoyceReference: Design of VLSI Systems : A practical Introduction, by Linda E.M. Brackendury   EEE 457           MICROCONTROLLER SYSTEM DESIGN3 hours/Week, 3  Credits 

EEE 458           MICROCONTROLLER SYSTEM DESIGN LAB3 hours/Week, 1.5  Credits 

The internal structure and operation of microcontrollers will be studied. The design methodology for software and hardware applications will be developed through the labs and design projects The objective of this course is to teach students design and interfacing of microcontroller-based embedded systems. High-level languages are used to interface the microcontrollers to various applications. There are extensive hands-on labs/projects. Embedded system for sensor applications will be introduced. GUI using C# Lab work: (1) PIC microcontrollers: introduction and features, (2) CCS C Compiler and PIC18F Development System, (3) PIC Architecture & Programming, (4) PIC I/O Port Programming, (5) PIC Programming in C (6) PIC18 Hardware Connection and ROM loaders, (7) PIC18 Timers Programming, (8) PIC18 Serial Port Programming, (9) Interrupt Programming, (10) LCD and Keypad Interface, (11) External EEPROM and I2C, (12) USB and HID Class, (13) ADC and DAC, (14) Sensor and other Applications, (15) CCP and ECCP Programming, (16) Capture Mode Programming and Pulse Width Measurement, (17) C# RS232 Interface Programming, (18) C# GUI Plot Program, (19) Digital Oscilloscope, spectral Analyzer, and multi-meter, (20) Impact of engineering solutions in a global, economic, environmental, and societal context, (21) Knowledge of contemporary issues, (22) Final ProjectPre-requisite: EEE 323  Digital Electronics and EEE 324  Digital Electronics LabTextbook: The PIC Microcontroller and Embedded systems – Using Assembly and C for PIC18                     by Muhammad Ali Mazidi, Rolin D. McKinlay, and Danny CauseyReference: Embedded System Design with the Atmel Avr Microcontroller By Steven Barrett EEE 459            COMPOUND SEMICONDUCTOR AND HETERO-JUNCTION DEVICES3 hours/Week, 3  Credits 

Compound semiconductor: Zinc-blend crystal structures, growth techniques, alloys, band gap, density of carriers in intrinsic and doped compound semiconductors. Hetero-Junctions: Band alignment, band offset, Anderson’s rule, single and double sided hetero-junctions, quantum wells and quantization effects, lattice mismatch and strain and common hetero-structure material systems. Hetero-Junction diode: Band banding, carrier transport and I-V characteristics. Hetero-junction field effect transistor: Structure and principle, band structure, carrier transport and I-V characteristics. Hetero-structure bipolar transistor (HBT): Structure and operating principle, quasi-static analysis, extended Gummel-Poon model, Ebers-Moll model, secondary effects and band diagram of a graded alloy base HBT.Pre-requisite: EEE 421  Solid State DevicesTextbook: Compound semiconductor electronics: the age of maturity, by M shurReference: Sige heterojunction bipolar transistors by Peter ashburn EEE 461           VLSI II3 hours/Week, 3  Credits

EEE 462           VLSI II LAB3 hours/Week, 1.5  Credits 

VLSI MOS system design: Layout extraction and verification, full and semi-full custom design styles and logical and physical positioning. Design entry tools: Schematic capture and HDL. Logic and switch level simulation. Static timing. Concepts and tools of analysis, solution techniques for floor planning, placement, global routing and detailed routing. Application specific integrated circuit design including FPGA.Lab work: This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-461. In the second part, students will design simple systems using the principles learned in EEE-461Pre-requisite: EEE 455  VLSI   I and EEE 456  VLSI   I   Lab Textbook: Digital Integrated Circuits by Jan M. RabaeyReference: Silicon VLSI Technology: Fundamentals, Practice and Modeling                     by James D. Plummer, Michael D. Deal and Peter B. Griffin EEE 463           PROGRAMMABLE ASIC DESIGN3 hours/Week, 3  Credits

 EEE 464           PROGRAMMABLE ASIC DESIGN LAB3 hours/Week, 1.5  Credits 

The goal of the course is to introduce digital design techniques using field programmable gate arrays (FPGAs). We will discuss FPGA architecture, digital design flow using FPGAs, and other technologies associated with field programmable gate arrays. The course study will involve extensive lab projects to give students hands-on experience on designing digital systems on FPGA platforms.Topics include:1. Introduction to ASICs and FPGAs, 2. Fundamentals in digital IC design, 3. FPGA & CPLD Architectures, 4. FPGA Programming Technologies, 5. FPGA Logic Cell Structures, 6. FPGA Programmable Interconnect and I/O Ports, 7. FPGA Implementation of Combinational Circuits, 8. FPGA Sequential Circuits, 9. Timing Issues in FPGA Synchronous Circuits, 10. Introduction to Verilog HDL and FPGA Design flow with using Verilog HDL, 11. FPGA Arithmetic Circuits, 12. FPGAs in DSP Applications, 13. FPGA Implementation of Direct Digital Frequency Synthesizer, 14. FPGA Microprocessor design, 15. Design Case Study: Design of SDRAM Controller, 16. Design Case Study: Design of Halftone Pixel Converter, 17. FPGA High-level Design Techniques, 18. Programming FPGAs in Electronic Systems, 19. Dynamically Reconfigurable Systems, 20. Latest Trends in Programmable ASIC and System Design.Lab work: 1. Implement an encoding circuit with using user constraint file 2. Implement an 8-bit signed multiplier with using user constraint file. Study how user constraint files can be used to improve circuit performance 3. Design and implement an multiplier and accumulator (MAC) unit using distributed arithmetic circuits 4. Project: Implementing a fixed-point 2nd-order low-pass filter  Pre-requisite: EEE 457  Microcontroller System Design, EEE 458  Microcontroller System Design LabTextbook: FPGA-Based System Design by Wayne WolfReference: Advanced FPGA Design by Steve Kilts  EEE 465           OPTOELECTRONICS3 hours/Week, 3  Credits 

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.Pre-requisite: EEE 227  Electronics II Textbook: Electrochromism and Electrochromic Devices                    by Paul Monk, R. J. Mortimer, D. R. RosseinskyReference: Optical System Design by Robert Fischer, Paul R. Yoder, Biljana Tadic-Galeb EEE 467     SEMICONDUCTOR DEVICE THEORY3 hours/Week, 3  Credits 

Lattice vibration: Simple harmonic model, dispersion relation, acoustic and optical phonons. Band structure: Isotropic and anisotropic crystals, band diagrams and effective masses of different semiconductors and alloys. Scattering theory: Review of classical theory, Fermi-Golden rule, scattering rates of different processes, scattering mechanisms in different semiconductors, mobility. Different carrier transport models: Drift-diffusion theory, ambipolar transport, hydrodynamic model, Boltzman transport equations, quantum mechanical model, simple applications.Pre-requisite: EEE 421  Solid State DevicesTextbook: Power Semiconductor Devices: Theory and Applications                    by Vítezslav Benda, Duncan A. Grant, John Gowar.Reference: Physics of Semiconductor Devices by Simon M. Sze COMMUNICATION OPTIONSEEE 371           RANDOM SIGNALS AND PROCESSES3 hours/Week, 3  Credits 

Probability and random variables. Distribution and density functions and conditional probability. Expectation: moments and characteristic functions. Transformation of a random variable. Vector random variables. Joint distribution and density. Independence. Sums of random variables. Random Processes. Correlation functions. Process measurements. Gaussian and Poisson random processes.

Noise models. Stationarity and Ergodicity. Spectral Estimation. Correlation and power spectrum. Cross spectral densities. Response of linear systems to random inputs. Introduction to discrete time processes, Mean-square error estimation, Detection and linear filtering.Pre-requisite: EEE 321  Signals and Linear SystemsTextbook: Introduction to Random Signals and Processes by Michael HaagReference:  An Introduction to the Theory of Random Signals and Noise by Wilbur B., Jr. Davenport, William L. Root EEE 473           DIGITAL SIGNAL PROCESSING II3 hours/Week, 3  Credits 

Spectral estimation: Nonparametric methods – discrete random processes, autocorrelation sequence, periodogram; parametric method–autoregressive modeling, forward/backward linear prediction, Levinson-Durbin algorithm, minimum variance method and Eigen-structure method I and II. Adaptive signal processing: Application, equalization, interference suppression, noise cancellation, FIR filters, minimum mean-square error criterion, least mean-square algorithm and recursive least square algorithm. Multi-rate DSP: Interpolation and decimation, poly-phase representation and multistage implementation. Perfect reconstruction filter banks: Power symmetric, alias-free multi-channel and tree structured filter banks. Wavelets: Short time Fourier transform, wavelet transform, discrete time orthogonal wavelets and continuous time wavelet basis.Pre-requisite: EEE 331  Digital Signal Processing   I Textbook: Digital Signal Processing by John G. ProakisReference: Digital Signal Processing by Alan V. Oppenheim and R. W. Schafer 

EEE 475    RF AND MICROWAVE ENGINEERING3 hours/Week, 3  Credits

EEE 476    RF AND MICROWAVE ENGINEERING LAB3 hours/Week, 1.5  Credits Electromagnetic Engineering Antenna Theory and Practice Analytical and Computational Techniques in Electromagnetics, RF and Microwave Circuits and Antenna . RF and Microwave Integrated Circuits. Tuned small-signal amplifiers, mixers and active filters, oscillators; receivers; amplitude modulation; single side-band modulation; angle modulation; digital communications; transmission lines and cables; radio wave propagation; antennae. Spectral analysis; phase locked loops; noise; antennae; cellular radio; meteor burst communications; spread spectrum techniques.Transmission lines: Voltage and current in ideal transmission lines, reflection, transmission, standing wave, impedance transformation, Smith chart, impedance matching and lossy transmission lines. Waveguides: general formulation, modes of propagation and losses in parallel plate, rectangular and circular waveguides. Microstrips: Structures and characteristics. Rectangular resonant cavities: Energy storage, losses and Q. Radiation: Small current element, radiation resistance, radiation pattern and properties, Hertzian and half wave dipoles. Antennas: Mono pole, horn, rhombic and parabolic reflector, array, and Yagi-Uda antenna.Lab work: This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-475. In the second part, students will design simple systems using the principles learned in EEE-475.Pre-requisite: EEE 321  Signals and Linear Systems Textbook: Microwave devices and Circuits by Samuel Y. LiasReference: Microwave Engineering by P.A. Rizzi EEE 477           GEOGRAPHICAL COMMUNICATION3 hours/Week, 3  Credits 

By the end of the course students will…1. Understand how communication both structures and is structured by geography. 2. Understand the uneven geographical development of the Internet and other communication technologies. 3. Recognize the significance of the location of physical telecommunications infrastructure in the construction of cyberspaces. 4. Understand the ways that communications technologies may be undermining or enhancing the creation of community. 5. Critically analyze the content of online communications. 6. Apply principles of good web design (including principles of accessibility for people with disabilities) to become a

content creator as well as a content consumer. 7. Be able to identify the ways that online and offline worlds interconnect. 8. Understand the interrelationships among the disciplines of communication and geography. 9. Understand how their own relationships with others are affected by telecommunications technologies. 10. Understand how technological skills may be used to benefit their own and other's communities. 11. Develop skills in managing complex projects and in working as a part of a team. be able to identify both printed and online

sources of information that they can use in the future to understand the changing geography of communication. 12. Develop web design skills that may be useful for gaining employment upon graduation.

Pre-requisite: EEE 329  Basic Communication EngineeringTextbook: The Cybercities Reader by Stephen Graham. Reference: Mapping Cyberspace by Martin Dodge and Rob Kitchin

 EEE 481           OPTICAL FIBER COMMUNICATION3 hours/Week, 3  Credits

EEE 482           OPTICAL FIBER COMMUNICATION LAB3 hours/Week, 1.5  Credits 

Optical fiber as wave-guides: Ray theory, Modes, SMF, MMF, Step Index and graded Index Fiber, Transmission Characteristic: Attenuation, Dispersion, Polarization, Fabrication: Liquid phase, Vapor phase, Fiber Cables, Connectors and Couplers: Alignment and joint loss, Splices, GRIN rod lens, Connectors, Couplers, Optical Source: LASER, semiconductor injection LASER, LASER characteristic, modulation Optical Detectors: Photodiode construction, characteristic, P-N, P-I-N, APD, Direct Detection: Noise, Eye diagram, Receiver design, Fiber Amplifier: Construction, characteristic, use, Digital Transmission System: Point to point link, power budget, Noise, Advanced Systems and  Techniques: WDM, Photonic switching, All optical network. Lab work: 1. Study of Optical Fibers, 2. Multimode behavior of a optical fiber, 3. Measurement of Bend Loss, 4. Study of an optical attenuator, 5. L-I curve of a LASER, 6. Construction of a power meter, 7. Fiber optic data communication, 8. BER plot of fiber optic system, 9. Project on fiber optic system.Pre-requisite: EEE 329  Basic Communication Engineering,                          EEE 330  Basic Communication Engineering LabTextbook: Optical Fiber Communication by John M. SeniorReference: Fiber Optic Communication Technique by D.K Mynbaev EEE 483           TELECOMMUNICATION ENGINEERING3 hours/Week, 3  Credits 

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.Pre-requisite: EEE 329  Basic Communication Engineering,                          EEE 330  Basic Communication Engineering LabTextbook: Telecommunications by Warren HiokiReference: Reference manual for telecom engineering 2d e by Freemann EEE 485           CELLULAR MOBILE AND SATELLITE COMMUNICATION3 hours/Week, 3  Credits 

Cellular & Mobile Communication: Introduction to code divisions Multiple Access (CDMA), Basic concepts, Spread spectrum, DS (Direct sequence) spread spectrum, Reverse link DSCDMA, forward link DS-CDMA, Cellular systems, GSM, AMPS, Cellular digital packet data. CDMA Air links: Pilot channel, Synchronous channel, Paging channel, Traffic channel, Free space propagation, Propagation model, Multi path propagation, Propagation environment, Marine environment.Historical developments of Mobile Telephony, Trunking efficiency, Propagation criteria, mobile ratio environment, Elements of cellular radio system design, Specifications, Channel capacity, Cell coverage for signal and traffic, Mobile propagation models and fading models, Interference effects, Power control, Mobile switching and traffic, Mobile switching system and its subsystems, Mobile communication protocols. Satellite Communication: Introduction, Types of Satellites, Orbits, Station keeping, Satellite altitude, Transmission path, Path losses, Noise considerations, Satellite systems, Saturation flux density, Effective isotropic radiated power, Multiple access methods.Pre-requisite: EEE 483  Telecommunication EngineeringTextbook: Cellular Mobile Systems Engineering by Saleh Faruque and                   Wireless Communication by Theoder S. RappaportReference: Cellular mobile communication by William Schneder INTERDISCIPLINERY OPTIONSEEE 487           CONTROL SYSTEM II3 hours/Week, 3  Credits 

EEE 488           CONTROL SYSTEM II LAB3 hours/Week, 1.5  Credits 

Compensation using pole placement technique. State equations of digital systems with sample and hold, state equation of digital

systems, digital simulation and approximation. Solution of discrete state equations: by z-transform, state equation and transfer function, state diagrams, state plane analysis. Stability of digital control systems. Digital simulation and digital redesign. Time domain analysis. Frequency domain analysis. Controllability and observability. Optimal linear digital regulator design. Digital state observer. Microprocessor control. Introduction to neural network and fuzzy control, adaptive control. HµControl, nonlinear control.Pre-requisite: EEE 335  Control System I and EEE 336  Control System I LabTextbook: Control Systems Engineering by Norman S. NiseReference: Modern Control Engineering (4th Edition) by Katsuhiko Ogata EEE 489    RENEWABLE ENERGY SYSTEMS3 hours/Week, 3  Credits 

EEE 490    RENEWABLE ENERGY SYSTEMS LAB3 hours/Week, 1.5  Credits 

Modern society relies on stable, readily available energy supplies. Renewable energy is an increasingly important component of the new energy mix. The course covers energy conversion, utilization and storage for renewable technologies such as wind, solar, biomass, fuel cells and hybrid systems. Thermodynamics concepts (including the first and second law) will form the basis for modeling the renewable energy systems. The course also touches upon the environmental consequences of energy conversion and how renewable energy can reduce air pollution and global climate change. Course Objectives of the course:I. Understand and analyze energy conversion, utilization and storage for renewable technologies such as wind, solar, biomass, fuel cells and hybrid systems and for more conventional fossil fuel-based technologies.II. Use the First and Second Laws of Thermodynamics and introductory transport phenomena to form the basis of modeling renewable energy systems.III. Understand the environmental consequences of energy conversion and how renewable energy can reduce air pollution and global climate changeTopics include: Introduction to Renewable Energy, Review of Thermodynamics, Second Law Analysis, Availability, Exergy, Free Energy, Solar Radiation, Solar Thermal, Biomass, Wind Energy, Fuel Cells, Hydrogen Production, Hydrogen Storage, Thermionics, Wave, Pre-requisite: EEE 223  Electrical Machines I, EEE 224  Electrical Machines I Lab, EEE 225  Electrical                          Machines II, EEE 225  Electrical Machines II Lab, EEE 439  Electrical Machines IIITextbook: Fundamentals of Renewable Energy Processes by Aldo Da Rosa Reference: Fundamentals of Thermodynamics by                     Sonntag, Borgnakke, Van Wylen John Wiley and Sons 

EEE 491           BIOMEDICAL INSTRUMENTATION3 hours/Week, 3  Credits

EEE 492           BIOMEDICAL INSTRUMENTATION LAB3 hours/Week, 1.5  Credits 

DescriptionIntroduction to engineering aspects of the detection, acquisition, processing, and display of signals from living systems; biomedical sensors for measurements of bio-potentials, ions and gases in aqueous solution, force, displacement, blood pressure, blood flow, heart sounds, respiration, and temperature; therapeutic and prosthetic devices; medical imaging instrumentation.

Course Objectives Understand the limitations of instrumentation in terms of accuracy, resolution, precision, and reliability. Analyze and design operational amplifier and instrumentation amplifier circuits to amplify bio-signals. Analyze and design filter circuits to filter unwanted signals from bio-signals  Understand the origin of cardiac and muscle bio-signals and how they are acquired using ECG and electro-

myogram electrodes Understand electrode circuit models and how they effect signal acquisition  Understand they physical modes of operation of various biosensors (amperometric, enzymatic, optical, resistive, capacitive) . Describe and compare methods and instrumentation needed to measure pressure and flow in the body. Determine and characterize the factors that limit medical imaging methods in biological tissue. Describe the requirements and limitations of bioinstrumentation in the clinical environment. Function and interact cooperatively and efficiently as a team member in completing a project. Present work in both written and oral reports.

Lab work: DescriptionThe goal of the course is to provide students with laboratory experience to test the principles, design, and applications of medical instrumentation. This course also provides exposure to clinical applications of medical instrumentation. Course Objectives

Analyze, design, and construct operational amplifier and instrumentation amplifier circuits to amplify bio-signals.

Analyze, design, and construct filter circuits to filter unwanted signals from bio-signals. Acquire electrical and biological signals by implementing virtual instruments with Agilent VEE, LabView, or

amplifiers coupled to a computer with other software. Understand biosensor and electrode design and apply them for signal acquisition. Understand the limitations of instrumentation in terms of accuracy, resolution, precision, and reliability. Understand the origin of cardiac and muscle bio-signals and acquire data using ECG and electromyogram

electrodes. Determine and characterize the factors that limit ultrasound and other imaging methods in biological tissue. Describe the requirements and limitations of bioinstrumentation in the clinical environment. Function and interact cooperatively and efficiently as a team member in completing laboratory projects. Present laboratory data in a written format.

Pre-requisite: EEE 223  Electrical Machines I, EEE 224  Electrical Machines I Lab, EEE 225  Electrical                          Machines II, EEE 225  Electrical Machines II Lab, EEE 439  Electrical Machines IIITextbook: Medical Instrumentation: Application and Design, Fourth Edition by John WebsterReference: Design and Development of Medical Electronics Instrumentation: A Practical Perspective of the Design, Construction, and Test of Medical Devices by David Prutchi EEE 493           MEASUREMENT AND INSTRUMENTATION3 hours/Week, 3  Credits

EEE 494           MEASUREMENT AND INSTRUMENTATION LAB3 hours/Week, 1.5  Credits 

Introduction: Applications, functional elements of a measurement system and classification of instruments. Measurement of electrical quantities: Current and voltage, power and energy measurement. Current and potential transformer. Transducers: mechanical, electrical and optical. Measurement of non-electrical quantities: Temperature, pressure, flow, level, strain, force and torque. Basic elements of DC and AC signal conditioning: Instrumentation amplifier, noise and source of noise, noise elimination compensation, function generation and linearization, A/D and D/A converters, sample and hold circuits. Data Transmission and Telemetry: Methods of data transmission, DC/AC telemetry system and digital data transmission. Recording and display devices. Data acquisition system and microprocessor applications in instrumentation.Lab work: This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE-493. In the second part, students will design simple systems using the principles learned in EEE-493.Pre-requisite: EEE 223  Electrical Machines I, EEE 224  Electrical Machines I Lab, EEE 225  Electrical                          Machines II, EEE 225  Electrical Machines II Lab, EEE 439  Electrical Machines IIITextbook: Measurement and Instrumentation Principles, Third Edition by Alan S MorrisReference: Instrumentation for Process Measurement and Control, Third Editon by Norman A. Anderson