Course Description
EEN101 Orientation to Electrical and Electronics Eng. (2-2)3
Overview of electrical and electronics engineering, basic electrical quantities, components, and circuits, Kirchhoff’s laws, resistive circuits, node and mesh analysis, Thevenin and Norton equivalent circuits, inductance and capacitance, practical instructions to use instruments such as voltmeter, ammeter, and oscilloscope, transients and sinusoidal steady state, phasors, impedances, logic gates and basic combinatorial circuits, diodes, transistors, operational amplifiers, magnetic circuits and transformers, DC machines, and AC machines.
MTH111 Linear Algebra (with MATLAB) (2-2)3
Introduction to Vectors, Vectors and Linear Equations, Elimination, Inverse Matrices and A=LU Factorization, Solving Ax=0, Complete solution Ax=b, Orthogonality, Least Square Method, Gram-Schmidt Method, Determinants, Permutations and Cofactors, Cramer Rule, Inverses, and Volumes, Eigenvalues and Eigenvectors, Diagonalizing, Symmetric Matrices, Positive Definite Matrices, Similar Matrices, Singular value Decomposition (SVD). Examples for each subject of this course are performed in Matlab.
CEN103 Introduction to Information Technologies (2-2)3
Overview of Computer Hardware/ Overview of operating systems and Microsoft Windows/ Microsoft Word/ Microsoft Excel/ Microsoft Powerpoint/ Adobe Flash/ Adobe Flash Actionscript/ Adobe Dreamweaver/ Adobe Photoshop
MTH101 Calculus I (3-2)4
Functions; Graph of Functions, Linear function, Slope, Tangent, Finite difference, Factorial, Binom theorem/ Series; Power Series (Maclaurin, Taylor) / Limit; Limit of a function, (Left, right) limit, Limit sequence, Intermediate form, (e, δ)-definition form/ Derivatives; Derv. of Polynomials, Derv. rules for products and quotient rules, Chain rule, (Maximum, minimum, mean value) problems, Implicit differentiations, Derv. of Trigonometric functions, L’Hospital rule, Differentials. / Integrals; Integration methods (by parts, by trigonometric transformations, by perfect square form), Indefinite integrals, Definite integrals, Improper Integrals, The fundamental theorem of calculus.
MTH107 Physics-I (3-2)4
Physics and Measurement/ Vectors/ Motion in One Dimension/ Motion in Two Dimension/ The Laws of Motion/ Circular Motion and Other Application of Newton’s Laws/ Work and Energy/ Potential Energy and Conservation of Energy/ Linear Momentum and Collisions/ Rotation of Rigid Body about a Fixed Axis/ Rolling Motion , Angular Momentum and Torque/ Oscillatory Motion/ The Laws of Universal Gravitation
ENG105 Communication Skills And Academic Reporting – I (2-2)3
Introductions, Communication Model, Feasibility Thinking / Communication Principles
Exploring the Communication Process, Review of basic newswriting concepts, Roadmap of advanced academic writing projects / Communication Competence,Characteristics of Self Concept, The layers of reporting, Research Techniques / The Process of Perception, Role of Culture & Society in Perception, Documentation Styles, Document Design / Role of Emotion in Communication, Managing Impressions/ Language Principles,Oral Presentations/ Characteristics of Nonverbal Communication, Elements of the Listening Process / Intimacy and Distance in Relationships, Methods of Conflict Resolutions, Oral Presentations
EEN102 Material Science for EEN (3-0)3
Introduction, Atoms, molecules, Bonds between atoms, Crystals, Lattices, x rays, Conducting materials, Energy bands, Semiconductors, Semiconducting devices, Magnetic and dielectric materials, Optical materials, Engineering materials and applications, General outline and project, General outline and laboratory
EEN104 Circuit Theory-I (2-2)3
Overview of Electrical and Electronics Engineering, Electrical Elements and Circuits, Circuit Variables, Power and Energy, Circuit Elements and Simple Resistive Circuits, Inductance, Capacitance and Mutual Inductance, Techniques of Circuit Analysis, Node Voltage and Mesh Current Methods, Techniques of Circuit Analysis, Circuit Theorems, Complex Numbers, Complex Impedance and Phasors, Sinusoidal Steady State Analysis, Sinusoidal Steady State Power Calculations, Phasor Diagrams, Balanced Three-Phase Circuits, Power Calculations in Balanced Three-Phase Circuits
CEN102 Algorithms and Programming (3-0)3
Introduction. Definition of the Algorithm. Necessary Properties of the Algorithm. Flowcharts. Introduction to C programming, simple i/o, memory concepts, arithmetic operators, precedence. Algorithms, if, if/else, while structures, assignment operators, increment & decrement operators, Essentials of repetition, counter controlled repetition, For repetition, switch multiple selection. Do/While repetition, break & continue, logical operators, equality and assignment operators. Program modules in C, math library functions, functions, function definitions, function prototypes, header files. Calling functions, random number generation, storage classes, scope rules, recursion, recursion vs. iteration. Arrays, declaring arrays, passing arrays to functions, sorting arrays, searching arrays. Pointer variable declaration & initialization, pointer operators, calling functions by reference. Pointer expression & pointer arithmetic, relationship between pointers and arrays, arrays of pointers, pointers to functions. Fundamentals of strings and characters, character handling library. standard I/O, string manipulation, comparison. Structure definitions, initializing structures, accessing members of structures. Using structures with functions, typedef, unions, bitwise operators, bit fields, enumeration constants. Using Disk Files, Project Presentations
MTH102 Calculus II (3-2)4
Sequences, Series: The comparison tests, Series: Absolute convergence and the ratio and root tests, Series: Power series, Maclaurin and Taylor series, applications of Taylor series, Differentiation: A comprehensive review of techniques and applications, Integration: A comprehensive review of techniques, Integration: A comprehensive review of applications, Multivariable Calculus, Partial derivatives, Implicit partial derivatives, higher-order partial derivatives, chain rule, Optima for functions of two variables, Lagrange multipliers, Further applications of (partial) derivatives, Multiple integrals, Further applications of (multiple) integration, Parametric equations and polar coordinates
MTH108 Physics II (3-2)4
Introduction, Review of physical quantities & gravity, Electric charge & coulomb’s law & electric field, Electric fields & gauss’s law, Electric potential (cont.) & equipotentials, Capacitance & dielectrics, Current, resistance & dc circuits, Magnetic fields & magnetic forces, Ampere’s law, Biot-savart law, Electromagnetic induction & faraday’s law, Inductance & magnetic energy, Maxwell’s equations, Modern physics: relativity & quantum mechanics
TRL101 Turkish Language-I (2-0) 2
TRL102 Turkish Language-II (2-0) 2
AHR101 Principles of Atatürk and History of Reforms-I (2-0) 2
Türk Devrimi’nin Temel Kavramları, Türk Devrimi’ nin özellikleri, Avrupa Modernleşme Tarihi ( XIX. ve XX. Yüzyıl), Osmanlı Devleti’nde Tanzimat ve Islahat Hareketleri-Lale Devri, III. Selim- II. Mahmut Islahatları, İttihat ve Terakki Cemiyeti ve I.Meşrutiyet, İlk Anayasa, II. Meşrutiyet-Fikir Hareketleri, Trablusgarp, I-II. Balkan Harpleri ve Sonuçları,
İlk İşgaller, Yerel Direnme Örgütleri ve Kuva-i Milliye, Mondros Ateşkes Antlaşması ve Gizli Antlaşmalar, Amasya Genelgesi-Erzurum Kongresi ve Sonuçları, Sivas Kongresi -Amasya Görüşmeleri ve Sonuçları, Temsili Heyet’in Ankara’ya Gelmesi, İlk TBMM’nin Toplanması ve Alınan Kararlar, İç İsyanlar neden ve Sonuçları, Sevr Antlaşması, I.İnönü Zaferi-Düzenli Orduya Geçiş, Sakarya Meydan Muharebesi-Büyük Taarruz ve Zafer, Mudanya Ateşkes Antlaşması
AHR102 Principles of Atatürk and History of Reforms-II (2-0) 2
EEN201 Probability and Random Variables (2-2)3
Probability Models in Electrical Engineering, Random Experiments, The axioms of Probability, Conditional Probability, Independence of Events, Sequential Experiments,
Discrete Random Variables, Probability Mass Functions, Expected Value, and Moments,
Conditional Probability Mass Func., Important Disc. Rand. Var., Continuous Rand. Var. Cumulative Dist. Func., Prob. Density Func., Expected Value of X, Important Cont. Rand. Var., Functions of Rand. Var., Markov and Chebyshev Inequalities, Transform Method, Entropy, Two Random Variables, joint cdf and pdf of two Cont. Rand. Var., Independence of two rand. var., Joint moments and expected values, Conditional probability, functions of two rand. var. , Jointly Gaussian rand. var. , Vector rand. var., Functions of several rand. var., expected values of vector rand. var., Jointly Gaussian rand. var. , Sum of Rand. var., Sample mean and the law of large numbers, The central limit theorem.
EEN203 Electronic Devices and Circuits (3-2)4
Introduction to Semiconductor Basics, N-and P-type Materials, Semiconductor Diodes, Diode Biasing, Diode Equivalent Circuits, Zener Diodes, Light Emitting Diodes, Load Line Analysis, Diode Applications-Rectifiers (Half-wave & Full-wave), Diode Applications-Clippers/Clampers, Bipolar Junction Transistors, Bipolar Junction Transistor Limits of Operation, Operating Point, Bipolar Junction Transistor Operating Point, DC Biasing, Load Line Analysis, Field Effect Transistors, Field Effect Transistors Characteristics, Biasing, MOSFET Operation and Biasing, Operational Amplifiers
EEN205 Circuit Theory II (2-2)3
The Operational Amplifier, Response of First-Order RL and RC Circuits, Natural and Step Responses of RLC Circuits, Introduction to Laplace Transform, Laplace Transform, Poles and Zeros, Bode Diagrams, The Laplace Transform in Circuit Analysis, Transfer Function, Impulse Function, Introduction to Frequency Selective Circuits, Low-Pass Filters, High-Pass Filters, Band-Pass Filters, Active Filter Circuits, Op. Amp Bandpass and Bandreject Filters, Fourier Series, The Fourier Transform, Two Port Circuits
EEN207 Electric Circuits Laboratory (0-4)2
Enrollment and registration into groups, Introduction, Laboratory rules, Ohm’s Law, Kirchhoff’s Laws, Types of Resistors/ Series Circuits, Parallel Circuits, Wheatstone Bridge/ Node Voltage Method, Mesh Current Method, Delta Wye Conversion/ Source Transformations, Thevenin Equivalents, Norton Equivalents/ Capacitance, Capacitor Charging and Discharging, Capacitors in Parallel and Series, Inductance, Current Buildup Transients, Inductances in Series and Parallel/ Series connection of R and L, Parallel connection of R and L/ Series connection of R and C, Parallel connection of R and C/ Series connection of R,L and C, Parallel connection of R, L and C, Voltage Resonance/ Current Resonance/ Transformer without Load, Short circuited and loaded transformers, No load and short circuit losses.
EEN202 Electromagnetic Field Theory (3-0)3
Description of the course and introduction, basic postulates. Coulomb force, electrostatic field and elecetric field lines. Electric scalar potential and potential energy. Gauss and Poisson equations. Distributions, Dirac distribution. Surface charge, line charge. Electrostatic field in a dielectric, boundary relations. Electric energy density, capacitors and capacitance. Logarithmic potential. Lorentz Force, Biot-Savart law. Vector potential, magnetic field in magnetic material, boundary relations, Ampere law. Ampere formula. Magnetic circuits, magnetic energy density.
EEN204 Electronic Devices and Circuits Laboratory (0-4)2
Enrollment and registration into groups. Introduction, Laboratory rules. Electronic characteristics of diodes and LED’s. Characteristics of Zener diodes and voltage regulation. Input and output characteristics of transistors. Transistors with common emitters. Feedback in amplifiers. Transistors with common base and collector. Transistor as a switch. FET characteristics. Operational amplifiers.
EEN206 Digital Design I and Laboratory (2-2)3
Introduction & Numbers Used In Digital Electronics. Binary Codes & Binary Logic. Fundamentals of Boolean Algebra. Basic Logic Gates. Other Logic Gates. Gate Level Minimization. Combinational Logic Circuits (adders, subtractors). Combinational Logic Circuits (decoder,encoder). Sequential Logic Circuits. Flip-flops. Multivibrators. Counters.
EEN208 Signals and Systems (2-2)3
Introduction, classification of signals, basic operations on signals. Elementary signals, properties of systems, noise. Time Domain Representation of LTI Systems, Convolution. Impulse response, step response, differential and difference equation representation of LTI systems. Block diagram representation and State-variable description of LTI Systems. Fourier representation. Complex sinusoids and frequency response of LTI systems, Discrete time periodic signals, Continuous time periodic signals. Discrete time nonperiodic signals, Continuous time nonperiodic signals, Properties of Fourier representation. Inverse Fourier transform using partial fraction expansions, Parseval relation, Time-bandwidth product, Duality. App. of Fourier representations to mixed signal Class. FT of periodic signals. Convolution and multiplication with mixtures of periodic and non periodic signals, sampling and reconstruction. Discrete time processing of continuous time signals, Fourier series representation of finite duration nonperiodic signals, DTFS approximation to the FT, Efficient algorithms for DTFS. Laplace Transform, Unilateral Laplace Transform, solving differential equations, Bilateral Laplace Transform, Inverse of LT. Region of convergence, causality and stability, z-transform, region of convergence. Inverse of z-transform, causality and stability.
EEN210 Numerical Methods for EEN (3-0)3
Mathematical modeling and engineering problem solving. Progromming and software. Approximations and round-off errors. Truncation errors and the Taylor Series. Bracketing methods. Open methods. Roots of polynomials. One-dimesional unconstrained optimization. Least-squares regression. Numerical differentiation. Numerical integration. Runga-Kutta methods. Finite-element method.
EAR 101 History of Civilization (2-0)2
EEN301 Electromechanical Energy Conversion (3-0)3
Energy technology and resources: Fossil fuels, nuclear, solar, and other types of energy. Three phase systems and magnetic circuits. Transformers: Ideal and physical models and equivalent circuit, and transformer testing. Electromechanical energy conversion. Efficiency and process performance. Sensors and actuators: Relays, stepper and positioning systems, switched reluctance machines, synchronous reluctance machines, direct current (DC) machines. Symmetrical alternating current (AC) synchronous machines. Symmetrical AC induction machines.
EEN303 Electromagnetic Waves Theory (3-0)3
Maxwell's equations in time and frequency domains. Electromagnetic energy and power. Wave equation. Uniform plane electromagnetic waves; reflection and refraction. Introduction to transmission lines, waveguides, antennas and radiation.
EEN305 Microprocessors and Laboratory (3-2)4
An introduction to microprocessor hardware and software. Assembly language instructions and programming, troubleshooting, and input/output techniques.
EEN381 Summer Training-I
EEN302 Computational System Programming (MATLAB) (2-2)3
Vector spaces, subspaces. Linear dependence/independence, span, basis. Linear transformations, eigenstructure analysis. Diagonalization, matrix representations of linear transformations, change of coordinates. Fourier transformations and applications, Laplace transformation and applications, z-transformation and applications. All applications are executed on MATLAB
EEN304 Feedback Control Systems (3-2)4
Analysis of linear control systems by differential equations and transfer function methods using Laplace transforms. Stability of closed loop systems. Routh-Hurwitz criterion, root-locus diagrams. System analysis in frequency domain. Bode, polar plots and Nichols charts. Nyquist stability criterion. Introduction to design and optimization of linear control systems, compensation techniques.
BUS112 History & Philosophy of Science (3-0)3
Science and Technology before Scientists: through 599 BCE, Science and Technology in Antiquity: 600 BCE through 529 CE, Medieval Science and Technology: 530 through 1452, The Renaissance and the Scientific Revolution: 1453 through 1659, Scientific Method: Measurement and Communication: 1660 through 1734, The Enlightenment and the Industrial Revolution: 1735 through 1819 , Science and Technology in the 19th Century: 1820 through 1894, Rise of Modern Science and Technology: 1895 through 1945, Big Science and the Post-Industrial Society: 1946 through 1972, The Information Age: 1973 through 2003
EEN 491 Graduate Design Project (1-4)3
EEN481 Summer Training-II
EEN492 Graduate Project (1-4)3
EEN321 Electronic Circuits I (2-2)3
DC and AC analysis of Bipolar Junction Transistors and Field Effect Transistors. Amplifier Circuits and Frequency Analysis
EEN323 Analog Communications (3-0)3
The objective of the Analog Communications Course is to familiarize students with the functions of oscillators, filters, amplifiers, LC networks, modulators, limiters, mixers, and detectors in AM, FM, PM, SSB, and PLL circuits. The course provides comprehensive, hands-on instruction in the terminology, principles, and applications of the analog communication circuits
EEN322 Electronic Circuits II (2-2)3
Operational Amplifiers, Power Amplifiers, Differential Amplifiers. Feedback Amplifiers, DTL, RTL, TTL, and MOS logic circuits.
EEN324 Digital Communications (3-0)3
Introduction to the basic principles of the design and analysis of modern digital communication systems. Topics include source coding, channel coding, baseband and passband modulation techniques, receiver design, and channel equalization. Applications to the design of digital of digital telephone modems, compact disks, and digital wireless communication systems. Concepts illustrated by a sequence of MATLAB exercises.
EEN326 Electronic Circuits I Laboratory (0-4)2
Operational amplifier circuits, High frequency techniques, power amplifier circuits, Field Effect Transistors and frequency responses, oscillator circuits, active filters.
EEN328 Communication Laboratory (0-4)2
Design and testing of analog and digital communications circuits, such as: Amplitude modulation (AM) using discrete multiplier circuits and fully integrated implementations. Frequency Modulation (FM) based on discrete and integrated modulator circuits such as voltage-controlled oscillators (VCOs). Phase-Lock Loop (PLL) techniques, characterization of key parameters and their applications in demodulation.
EEN421 Analog Integrated Circuit Design (3-0)3
Analysis, design, and applications of modern analog circuits using integrated bipolar and field effect transistor technologies. Introduce the principles of analog circuits and apply the techniques for the design of analog integrated circuit (Analog IC’s). Apply the methods learned in the class to design and implement practical projects.
EEN423 Radio and TV Engineering (3-0)3
Principles of picture transmission. Color fundamentals. Camera tubes. Color television systems. Video signal. Carrier transmission of the video signal. Video recording. Television studio equipment. Transmitters and receivers.
EEN425 Digital Design II and Lab. (2-2)3
Analysis and design of combinational circuits and clocked synchronous sequential circuits. Random access memory (RAM) and programmable logic devices. Register transfer level (RTL) representation of digital systems. Analysis and design of asynchronous sequential circuits. Integrated circuit digital logic families.
EEN427 Digital Integrated Circuit Design (3-0)3
Processors, ASICs, FPGAs. ASIC design methodology. Review of digital design basics. CMOS implementation of gates. Verilog review. Timing analysis. Computer arithmetic. High Level Synthesis based design. Using Block RAMs in FPGAs. Using Digital Clock Managers in FPGAs. Using Tri-state Pins in FPGAs. Metastability.
EEN429 Industrial Electronics and Automation (3-0)3
Industrial Electronics Engineering offers the opportunity for professional careers in the production and operation areas in various industries especially the manufacturing sector. The curriculum and structure of this course is comparable to any international engineering degree program. Preparation of the curriculum, selection of the faculty, planning of the infrastructure facilities such as dedicated building, classrooms, labs and other resources is designed to fulfill the PEC requirements.
EEN431 Digital Signal Processing and Lab. (2-2)3
Sampling and quantization schemes. Linear shift invariant systems, stability and causality. Two-dimensional systems and sequences. Flow graphs, digital filter design techniques, FIR and IIR filters. Computation of DFT, FFT techniques. Effects of finite register length. Estimation of power spectra. Homomorphic filtering, discrete time random signals and systems.
EEN433 Digital Control Systems (3-0)3
Fundamentals of sampled linear systems from a control perspective, encompassing both frequency-domain and time-domain control strategies. Topics covered include analysis of difference equations, the z-transform, sampling, stability, minimality, discrete approximation, and stabilization techniques.
EEN422 Measurement and Instrumentation (3-0)3
Units and principles of measurement. Error of measurement. Probability of error. Electronic measurements and electronic measuring instruments: Instrument amplifiers, signal sources, oscilloscopes, digital frequency meters, digital voltmeters. High frequency and microwave measurement techniques.
EEN424 Embedded Systems (3-0)3
Design of embedded systems (hardware & software). Advanced topics including interrupt, multitasking, Programming 68HC12 microcontroller in Assembly language, C. and Forth. An open ended embedded system design project which requires consideration of alternatives, economic and aesthetic constraints, and detailed system description is compulsory.
EEN426 RF Electronics (3-0)
Small-signal amplifiers. Network noise and intermodulation distortion, sensitivity. Frequency-selective networks and transformers. Impedance matching and harmonic filtering. High frequency amplifiers. Oscillators, amplitude and phase stability. Phase-locked loops and applications.
EEN428 Introduction to VLSI Design (3-0)3
Design techniques for rapid implementations of very large-scale integrated (VLSI) circuits, MOS technology and logic. Structured design. Design rules, layout procedures. Design aids: layout, design rule checking, logic, and circuit simulation. Timing. Testability. Projects to develop and lay out circuits.
EEN430 App. of Industrial Electronics and Laboratory (2-2)3
Students will have enough knowledge about the main components of typical industrial electronic systems and will be able to design controller systems for industrial processes. Extensive laboratory work will allow students to gain hands on experience with the operation of such systems.
EEN341 Power Systems (3-0)3
Steady-state AC circuit analysis, instantaneous power, complex power, network equations, power in balanced three-phase circuits, symmetrical components. Per-unit system, power transformers, transmission lines, synchronous machine control models. Power-flow equation, numerical solution methods, computer analysis of power flow. Symmetrical faults, series R-L circuit transients, three-phase short circuit. Transient stability, swing equation, the equal-area criterion.
EEN343 Illumination Techniques (3-0)3
This course covers light and vision. Photometric quantities and laws. Fundamentals of physiological and optical concepts. Light generation. Light sources, Lamps types, Lighting terminology Lighting calculations, Installation of wiring systems, Selection of conductor cross-sectional area, Preparation of reports.
EEN342 Electric Machines I (3-0)3
Magnetic principles, magnetic equivalent circuits, structure of transformers, equivalent circuits of transformers, 3-phase transformer connections, efficiency, autotransformer, constructions for DC machines, energy convergence, field winding connections, characteristics of CD machines, motor and generator operations, speed control, various applications.
EEN344 High Voltage Techniques (3-0)3
This course covers, Field analysis: experimental methods and applications. Electrical breakdown in gases, Electrical break-down of liquids, Electrical breakdown of solid, insulating oils and solid dielectrics. Generation and measurement of high AC, DC, and impulse voltages and impulse currents: AC to DC conversion and electrostatic generators. Operation, design and construction of impulse generators.
EEN346 Power Plant and Generation Engineering (3-0)3
This course covers engineering economics, thermodynamics and power plant cycle analysis, fossil fuels, coal and limestone handling, combustion processes, steam generators, circulation water systems, cycle performance impacts, power plant atmospheric emissions control, electrical systems, plant control systems, gas turbine, fluidized bed combustion, nuclear power, hydroelectric power, power plant planning and design.
EEN348 Power Transmission and Distribution (3-0)3
Power transmission, substations, transmission equipments, transmission lines, HVDC transmission. Power distribution, distribution lines, distribution substations, distribution metering and efficient energy management.
EEN441 Power Electronics (3-0)3
Power switches and their characteristics. Power converter definitions, classification. VTA method. Rectifiers: Non-ideal commutation, harmonics, input power factor, utility-factor, winding utilization and unbalances in rectifier transformers. Forced commutated circuits. Inverters. DC and AC choppers.
EEN443 Electric Machines II (3-0)3
Principles of AC machines, structures of induction machines, equivalent circuits, power, efficiency, torque, T-s diagrams, 3-phase and single-phase induction machines, start and speed control techniques, structures of synchronous machines, equivalent circuits, power, efficiency, and torque equations, stability, characteristics of synchronous machines, operation properties.
EEN445 Protection of Power Systems (3-0)3
Current and voltage transformers. Overcurrent protection. Comparators and static relay circuits. Differential protection and its application to generators, transformers and bus bars. Motor protection. Pilot wire protection of feeders. Introduction to distance and other protection systems.
EEN447 Power Engineering Laboratory (1-4)3
Power Generation: Synchronous generator, synchronization circuit, automatic synchronization circuit, generator cos phi control, automatic generator active power control. Power transmission/distribution: three-phase transformers, transmission line model 380kV, generator fed transmission system with RLC loads, parallel and serial circuits of transmission lines, three-phase bus bar system, electronic switch. Protection of Power Engineering Systems: Current and voltage transformers, protective relays, protection of a power transmission line, protection of parallel power transmission lines. Energy Utilization: Reactive power compensation of an inductive load, power consumption measurement and peak load monitoring.
EEN449 Electric Drives (3-0)3
DC Drives: Single-phase drives, three-phase drives, power control, regenerative brake control, rheostatic brake control, combined regenerative and rheostatic brake control, choppers drives. AC Drives: Induction motor drives, synchronous motor drives.
EEN442 Power Electronics Laboratory (1-4)3
Power supplies, UJT characteristics, UJT oscillator and timer circuits, PUT characteristics, PUT oscillator and timer circuits, ramp and step function generators, SCR and RC phase control, SCS characteristics, SCS trigger circuits, UJT-SCR phase control, PUT-SCR power control, two-way DC machine control with SCR, diac and triac characteristics, automatic lamb brightness control circuits, machine start and speed control, temperature control, photocoupler and touching alarm systems, Overvoltage and low-voltage breakers, AC flasher control circuit, liquid level control, IC timer circuit, digital signal drive, zero voltage switch, SCR inverter, SCR rectifier, FET/MOSFET characteristics, speed control with MOSFET, IGBT characteristics.
EEN444 Electric Machines Laboratory (1-4)3
Laboratories of single-phase and 3-phase transformers, DC machines, induction machines and synchronous machines to find their parameters and characteristics.
