Elektrik ve Elektronik Mühendisliği (İngilizce) Bölümü - Ders İçeriği

Physics-I 22G1001

Vectors. One-dimensional movement. Movement in two dimensions. Newton's laws of motion and their applications. Newton's law of universal gravitation. Work and energy. Conservation of energy. Momentum and motion of systems. Static equilibrium of solid bodies. Rotation and angular momentum.

 

Physics-II 22B1002

Columb's law and electric field, Gauss's law, electrical potential, capacitance, electrical energy and properties of insulators, current and resistance, energy and current in DC circuits, magnetic field and magnetic field sources, Faraday's law, inductance, magnetic field in materials, electromagnetic vibrations and AC circuits.

 

Numerical Analysis 22B2002

Numerical solution methods of algebraic equations. Bisection method, fixed point method. Newton's method. Numerical derivative. Numerical integral. Divided differences. Euler method. midpoint method. Runge-Kutta method. Forward method

 

Scientific Research and Ethics 22G1003

Basic concepts and information about science, the structure of scientific research, scientific methods and different views on these methods, problem, research model, universe and sample, data collection and data collection methods (quantitative and qualitative data collection techniques), data recording, analysis, interpretation and reporting.

 

Linear Algebra 22G2001

Algebraic Structures, Operations on Matrices, Systems of Determinant Linear Equations, Gaussian Method, Vector spaces, Linear independence, base, dimension, linear transformations, rank, characteristic values, characteristic and minimum polynomials of an operator, eigenvalues, diagonalization, inner product spaces

 

Career Planning 2075B1004

Courses will be organized for first year university students in the fall semester, for 14 weeks, with one class hour per week. The courses, in accordance with the topics and course contents; It should be processed by university lecturers, industry professionals and guest educators who will be invited from other universities and non-governmental organizations. The supporting activities to be included in the course should be designed to inform students about the methods and tools used in professional applications and to gain the ability to use them in the most effective way, and should be supported by practical assignments. Career centers should support the course in practice with activities that provide experience opportunities that will support students to develop their skills.

 

Materials' Science 2213B2002

Classification and general structures of materials, atomic structure. Types of materials and their properties; mechanical and thermal properties; Atomic electronic structure, interatomic bonding-properties relation. Metallic, ionic, covalent and weak bonding, polarization. Metals, ceramics, polymers and composites. Mechanical, electrochemical, electrical, magnetic, electromagnetic and optical properties of engineering materials. Conduction mechanisms in conductors, insulators and semiconductors; dielectric, ferroelectric, piezoelectric and pyroelectric materials. Magnetic properties of materials, paramagnetic, diamagnetic and ferromagnetic materials; superconductors. Corrosion, degradation, durability, sustainability.

Basic circuit materials, Basic electronic materials, High voltage HV transmission materials, low voltage LV and HV cables / Illumination materials, Basic electrical hardware.

 

Circuit Theory II 2213B2004

current and voltage measurements and modeling in physical circuits, Kirchhoff's laws, ideal circuit elements and circuit analysis methods.

 

Electronic Circuits 2213B2006

Structure of Diodes, Rectifier Circuits, Filters, Clippers and Clamps, Voltage Doublers, Zener Diodes and Circuits, Other Diode Types and Characteristics, Structure of Transistors, Common Emitter Transistors, H and R Parameters, Common Base and Common Collector Circuits, DC Transistor Amplifiers.

 

Electromagnetic Theory 2213B2008

Basic assumptions, electric charge, Coulomb's law, electrostatic event in empty space, electrostatic energy, surface charges and Dirac distribution, dipoles, electrostatic event in non-empty space, body equations and boundary conditions, Lorentz force and magnetostatic phenomenon in empty space, magnetic energy density, magnetic dipoles and permanent magnets. Maxwell equations and electromagnetic fields. Self and mutual inductance.

 

Signals and Systems 2213B2010

Introduction to basic concepts; Signals and Systems; Linear and Time Invariant Systems; Time Domain Analysis of Continuous Time Systems; Time Domain Analysis of Discrete-Time Systems; Continuous Time Fourier Series; Discrete Fourier Transform; Continuous Time Fourier Transform; Fourier Transforms of Some Functions; Sampling and Reconstruction; Laplace Transform; z-Transform.

 

Digital Electronics 2213B3002

Number Systems, Conversion between Number Systems, Logic Gates, Boolean Algebra, Design with Logic Circuits, Karnaugh Diagrams, Karnough Map, Encoders, Decoders, Data Selectors (Multiplexer), Data Distributors (Demultiplexer), Adders, Extractors.

Digital Electronics Lab 2213B3004

Basic Logic Gates, Boolean Algebra, Karnough Map, Adder Circuits, Subtractor Circuits, Comparator Circuits, Data Selector (Mux) - Data Distributor (Demux) Circuits, Decoder - Encoder Circuits, Code Converter Circuits, Flip Flop Circuits, Square Wave Generator Circuits, Counters

 

Electrical Machines I 2213B3006

Basic Magnetic Theory, Magnetic Laws and Magnetic Circuits, Electromechanics Energy Conversion, Introduction to Machinery Principles, Transformer on No-Load and Ideal Transformer, Real Transformer and Equivalent Circuit, Transformer Losses, Transformer Testing, DC Machinery Fundamentals, Commutation and Armature Constructıon in Motor Direct Generators and Reducing Voltage Machines Characteristics of DC Generator, Characteristics of DC Motor.

 

Electromechanical Energy Conversion 2213B3008

Magnetic circuits and flux, properties of magnetic materials and losses, skin and proximity effect, types and properties of permanent magnets, analysis of magnetic circuits containing magnets, basic laws about magnetic fields, transformers, phasor diagrams, equivalent circuit parameters, force in a current carrying conductor in a magnetic field and induced voltage in a moving conductor, linear direct current machine, energy conservation and energy balance equation, relations between magnetic field and rotating magnetic field, relations between magnetic field and rotating magnetic field (MM) voltage induction and torque generation in AC and DC machines.

 

Engineering Systems Reliability Evaluation 2213B3010

Reliability definitions and concepts, basic probability theory, practical engineering concepts, network modeling and evaluation of simple and complex systems, discrete Markov chains, continuous Markov processes.

 

Power Systems Reliability Evaluation (Part I) 2213G3013

Power system reliability principles, System capability and safety, State space diagrams and Markov modelling, A recursive algorithm for capacity modeling, Loss of Load Expectation (LOLE) method, Capacity expansion planning generation.

 

Introduction to Robotics 2213B4002

Introduction of Robot Systems, Kinematics of Robot Joints, Robot Dynamics, Independent Joint Control, Actuator Dynamics and Control, Pd, Pid Type Controllers to Robot Systems, Examples of Matlab Robotic Toolbox, Status Feedback and Observers in Robot Control, Feedback and Forward Feed Control (Calculated Moment) Method), Multivariate Control in Robot Arms, Inverse Dynamic Method; Stability Problem in Robots

 

Power Generation Plants 2213B4006

Definition of Energy and Power; Principles of Electricity Generation; Types of Power Plants; Hydroelectric Power Plants; Steam Power Plants; Gas Plants; Combined Cycle Gas Plants; Site Selection in Power Plants; Determination of Installed Power and Number of Units; Basic Concepts of Electrical Energy Economics; Optimum Operation of Units in Thermal Power Plants; Daily Load Curve; Adjusted Annual Load Curve; Calculation of Fuel and Energy Cost (TL/kWh) by Power Plant Type.

 

Electrical Facilities 2213B4008

Generation, transmission and distribution facilities. General structure of a manufacturing facility. Electrical calculation of transmission lines, nominal and equivalent circuits. Conductors. Insulators. Potential distribution in insulators. Poles and their selection. Separators, cutters. Short-circuit current and its properties. Calculation and selection of breaker according to short circuit current. Busbars and busbar systems. Measurement transformers. Ground.

 

Introduction to Avionic Systems 2213B4010

Avionics Systems in accordance with the Aeronautical-ATA Chapter configuration

 

Power Systems Protection 2213B4010

Introduction to the protection of electrical power systems. Basic protection methods and applications. Signal conditioning for digital relays. Digital Relay hardware. Signal processing for digital protection. Digital protection and fault location algorithms. Digital protection systems software. Digital data for protection communication. Protection signaling. Pilot protection. Integrated protection and control systems.

 

Sensors and Converters 2213B4012

Servo potentiometers, Linear potentiometers, Temperature sensors, Light sensors, Phototransistors and photodiodes, Inductive and capacitive sensors, Inertial sensors, Displacement sensors, Airflow sensors, Speed sensors, Pressure and tension sensors, Humidity sensors, Optical sensors, Sensor technologies.

 

Internet of Things and Smart System Applications 2213B4014

Internet of Things (IoT) Overview, IoT Physical Devices (Arduino, Raspberry), Sensors to be used in Application Application development with IoT Physical Servers and Cloud computing, MQTT from IoT Communication Protocols, IoT Communication Technologies: GSM

 

 

 

Microwave Circuits and Antenna Design 2213B4016

Microwave Power Measurement, Detector Characteristics, Impedance Measurement and Microwave Tuner, Obtaining Heating Properties of Antenna, Using Router Coupler in Power Transmission and Reflection Measurements, Antenna pattern measurement techniques, reflection coefficient of RF elements and standing wave measurement technique, use of various RF circuit structures and examination of their functionality.

 

Circuit Theory I 2213G1004

DC Circuits: Basic Concepts-Unit System, Load, Current, Voltage, Power and Energy, Circuit Elements; Basic Laws-Ohm's Law, Kirchhoff's Laws, Series and Parallel Resistors, Division of Current and Voltage, Star-Delta transformations; Circuit Analysis Methods-Node Analysis, Environmental Analysis, Comparison of Node Analysis and Environmental Analysis; Circuit Theorems-Linearity, Superposition, Source Transformation, Thevenin and Norton Theorems, Maximum Power Transfer; Operational Amplifiers (Operational Amplifiers-Op-Amps) and Applications; Capacitor and Inductance elements.

 

Algorithm and Programming 2213G1005

Structure of Diodes, Rectifier Circuits, Filters, Clippers and Clamps, Voltage Doublers, Zener Diodes and Circuits, Other Diode Types and Characteristics, Structure of Transistors, Common Emitter Transistors, H and R Parameters, Common Base and Common Collector Circuits, DC Transistor Amplifiers

 

Algorithm and MATLAB Programming 2213G1005

Computer programming fundamentals, Matlab programming environment fundamentals, manipulating and visualizing data, programming parts, data structures, simple input and output, using multimedia content, timing and recording, development and debugging techniques, functions and modular programming, reading and processing records.

 

Mathematics I (Calculus I) 2213G1007

Function. Limit, continuity, derivative. Applications of the derivative, Max. Min, Optimization. linearization

 

Mathematics II (Calculus II) 2213G1008

Integral (continued) Bivariate Function. Limit, continuity, derivative. Applications of the derivative. Series. Convergence. tests. Max. Min, Integral finding saddle points. Double integrals. Integration techniques. Applications

 

 

 

Introduction to Electrical and Electronics Engineering 2213G1009

Basic units used in Electrical and Electronics Engineering, introduction of circuit elements used in electrical systems, Ohm's Law, Maximum Power Transfer Theorem, Kirchoff's Current and Voltages law, introduction to semiconductor devices, introduction of computer systems and number systems.

 

Probability and Random Variables 2213G2001

Permutation, combination, Introduction to probability, Axiomatic probability and its properties, conditional probability, Bayes' theorem, independent events, discrete and continuous variables, discrete probability distributions, Bernoulli, Binomial, Geometric, Poisson Distributions, Continuous Distributions Normal distribution and its applications, Exponential Distribution, Moment Concept, Moment generating function, hypothesis-generating chain of variables, tests of centrality measures, hypotheses, centrality tests,

 

Engineering Mathematics 2213G2003

Area, volume, moment. Applications of double integral. Line integral and its applications. Work. Flow, Flux. Potential function and applications. Conservative field. Green's theorem and its applications. Stoks theorem and its applications

 

Introduction to Differential Equations (2213G2005)

Ordinary differential equations. 1 and 2 order DD. Existence and uniqueness of the solution. Linear equations, separable equations. Linear homogeneous equations Inhomogeneous equations. Uncertain coefficients method and variation of constant decrementation. Two-order equations with constant coefficients. Serial solutions. system of equations. Laplace transform. Numerical solution techniques.

 

Electronic Circuits 2213G2007

Structure of Diodes, Rectifier Circuits, Filters, Clippers and Clamps, Voltage Doublers, Zener Diodes and Circuits, Other Diode Types and Characteristics, Structure of Transistors, Common Emitter Transistors, H and R Parameters, Common Base and Common Collector Circuits, DC Transistor Amplifiers.

 

Electrical Circuit Lab. 2213G2009

In this course, current and voltage measurement and modeling in physical circuits, Ohm's Law, Kirchhoff's laws, RC Circuits, ideal circuit elements and circuit solution methods are taught.

 

Summer Internship 1 2213G3001

Internship entails four weeks (20 working days) of field experience in any workplace (public or private sector). Students must follow the procedure in the IESU Internship Directive to successfully complete their internship.

 

Computer Architecture and Organization 2213G3003

Basic Components of Computer System: Basic Concepts, System Path, Clock and Timing Signals, Structure of Microprocessors, Processor main Function Cycle (Fetch – Execute), I/O System Bus, CPU – Central Processing Unit, Pentium. Microprocessor Architecture: Numerical Design, Instruction Processing Techniques, Control Unit, Arithmetic - Logic Unit, Data Bus, Pipeline. Memory: Main Memory, Ram, Rom, Segmentation, Dominant, Memory Hierarchy, Cache. Memory Addressing and Mapping: CPU Segment Addressing, Finding Physical Addresses of Variables, Memory Cell Selection via Address Bus, Memory Mapping, Addressing Circuit, Memory Organization, Assembly Addressing Modes: Addressing modes for register and instant values, Memory Access Address Modes, Memory Access Applications.

 

Analog Electronics 2213G3005

Structure of Diodes, Rectifier Circuits, Filters, Clippers and Clamps, Voltage Doublers, Zener Diodes and Circuits, Other Diode Types and Characteristics, Structure of Transistors, Common Emitter Transistors, H and R Parameters, Common Base and Common Collector Circuits, DC Transistor Amplifiers

 

Feedback Systems 2213G3007

Introduction, History of control systems, Feedback concept, Mathematical Foundation (Laplace), Mathematical modeling of physical systems, Transfer functions, Block diagrams, Signal flow diagrams, Time Responce(Time domain analysis of control systems), Steady State Error, Stability concept, Routh Hurwitz Criterion, Roots locus technique, Frequency domain analysis, PID Control.

 

Feedback Systems 2213G3007

Introduction, History of control systems, Feedback concept, Mathematical Foundations (Laplace), Mathematical model of physical systems, Transfer function, Block diagram, Signal flow diagram, Time plane analysis, Steady state error, Stability concept, Root-locus technique, Routh Hurwitz method, Frequency plane analysis, PID control.

 

Analog Electronics Lab 2213G3009

Multimeter and oscilloscope usage, PN junction diode, Half wave rectifier, Full wave rectifier, Zener diode, Transistor characteristic, Transistor amplifier, Bias voltage balancing, Common collector and common emitter amplifiers, Two-stage amplifiers, Transistor switching, JFET characteristic, JFET amplifier.

 

Digital Signal Processing 2213G3011

Continuous and Discrete Signals, Sine-Shaped Signals, Spectrum Representation, Sampling, FIR filters, IIR filters, Frequency Response, Continuous Time Fourier Transform, Z-transform.

 

Power Systems Reliability Evaluation (Part I) 2213G3013

Power system reliability principles, System capability and safety, State space diagrams and Markov modelling, A recursive algorithm for capacity modeling, Loss of Load Expectation (LOLE) method, Capacity expansion planning generation.

 

Introduction to Communication 2213G3015

Analysis of signals and systems in the time and frequency domain; periodic (periodic) signals; convolutional integration; information transmission with orthogonal functions; Fourier transforms; filters; modulation theory; analysis of discrete-time signals and systems; discrete time Fourier transform (DFT), technical applications of the theories taught.

 

Power System Analysis 2213G3017

- Identification of transients occurring in power systems, - Study of the effect of transients, - Determination of system behavior during transients, - Effects of transients on stability, - Fault analysis and protection systems

 

Summer Internship 2 2213G4001

Internship entails four weeks (20 working days) of field experience in any workplace (public or private sector). Students must follow the procedure in the IESU Internship Directive in order to successfully complete their internship.

 

Graduation Project 1 2213G4003

Each student, together with his/her advisor, will make a final work on a topic he/she has determined and defend his/her report in front of the jury.

 

Graduation Project 2 2213G4004

Each student, together with his/her advisor, will make a final work on a topic he/she has determined and defend his/her report in front of the jury.

 

Power Transmission 2213G4005

Power transmission principles, short, medium and long transmission line modelling, energy losses and corona effect, ABCD constants of transmission lines, different transmission line compensations, static var compensations.

 

Electrical Machines II 2213G4007

General Structures, Working Principles of Synchronous Machines, Extraction of Electrical Equivalent Circuits of Single-Phase and Three-Phase Synchronous Machines / Investigation of the Excitation Field in a Cylindrical Rotor Synchronous Machine with Polarization in a Synchronous Machine / Investigation of Stator Windings in a Synchronous Machine / Induced Voltage Diagrams in Synchronous Machines / Extraction of Induced Voltage Diagrams in Synchronous Machines Analysis of Power and Torque Relations in a Cylindrical Rotor Synchronous Machine / Investigation of Active and Reactive Power Adjustment in a Cylindrical Rotor Synchronous Machine

 

Power Distribution 2213G4009

Principles of power distribution, calculation of system demand, demand, load, diversity and loss factors, design of 11 KV overhead distribution systems, optimum cable sizing (Kelvin's law), optimal design of distribution networks, economics of capacitor installation, power quality.

 

  High Voltage Engineering 2213G4011

Definition, production and measurement of high voltage. Investigation of systems where High Voltage is applied. Multilayer systems. Discharge events at High Voltage, corona. Dielectric loss and measurement of insulating materials.

 

Embedded System Design 2213G4011

The course covers the following main topics: Embedded system components and their presentation, embedded hardware elements, programming of embedded systems, interaction and interfacing of embedded systems with the real world, evaluation, selection and integration of embedded system elements and architectures. Simulation, implementation and research assignments based on design and analysis are given to reinforce the techniques and knowledge taught. Students are expected to prepare and present term projects.

 

Antennas And Propagation 2213G4013

Technological and Historical Development of Antennas, Delayed Electric-Magnetic Scalar, Finding Fields with the Help of Vector Potential Functions, Important Theorems and Concepts in Electromagnetic Theorem (Energy Theorems, Duality, Stability)/ Modeling Principles in Electromagnetic Theory, Harmonically Oscillating Electric and Magnetic Dipole with Time, Calculation of Far and Near Field Dipole, Antenna Dipole ma Diagram, Radiation Efficiency, Luminous Gain, Luminous Power, Half Power Beam Width (HPBW), Effective Beam Power, Effective Surface, Effective Length, Communication Equations (Friis Equations), Fine Wire Antennas, Half Wave Dipole Antennas, Antenna Arrays, Frequency Independent Antennas (Helical, Log-Periodical Antennas), Patch Antennas Lens Antennas, Yagi-Uda Antenna, Horn Antennas, Factors Affecting Propagation of EM Waves, Radiolink Antennas, Radar Antennas, Array Antenna Theory, Electronic Beam Scanning and Beam Zeroing (Null) Technique.

 

Power Electronics 2213G4015

Power Electronics General Topics, Diode-Thyristor, BJT – MOSFET, Other Power Circuit Elements, Problems with Power Circuit Elements, AC-DC Converters, Problems with AC-DC Converters, Midterm Exam, DC-DC Converters, DC-DC Converters-Problems, DC-AC Converters-DC Converters-DC Converters-DC Converters-DC Converters-2 Inverters-Problems, Losses in Power Elements and Heating

 

Radar Technologies 2213G4017

History of electronic warfare, Basic concept representation, Radio Frequency (RF) propagation, Antennas, Transmitters, Receivers, Sensors, Tactical communication systems, Information warfare, Electronic attack and protection, Electronic listening and directional determination (DF), Electronic support measures (EDT), Electronic countermeasures (ECT), Electronic countermeasures (EKKT), High power RF energy weapons, Radar jammer and RF jammer systems (Radar RF technology, Decaf) equation, Radar antennas, Microwave and millimeter wave radars, Beyond horizon high frequency radar, Subsurface imaging radar (GPR), Passive radar, Weapon and guided missile systems, Artificial Aperture Radar (YAR), Scanning and tracking radar, Infrared (IR) sensors, Acoustic submarine radar (SONAR).

 

Control System Design 2213G4019

Root locus, Computer aided drawing of root locus, Controller design in time domain, Root locus and PI, PD and PID controller design, PID parameters setting methods, Implementation of designed controllers, Analysis in frequency domain, Bode and nyquist diagrams and drawing techniques of these diagrams, Drawing bode and nyquist diagrams under Matlab, drawing synthesis diagrams, phase margin and gain domain, phase margin and gain domain.

Bu içerik 08/09/2024 tarihinde güncellenmiştir.

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