Undergraduate Course Contents

EM 102 Introduction to Electrical and Electronics Engineering (1+0) 0 (ECTS:2)
General information about the main areas, historical development and contributing scinetists of Electrical and Electronics Engineering (EEE), Tools and methods used in the field. Interaction between EEE and other sciences and engineerings. Engineering ethics. Knowledge transfer from experienced engineers.

EM 110 Material Science (3+0)3- (ECTS:3)
Conductors and insulating materials. Transmission line conductors and underground cables. Resistance and resistivity, conductance and conductivity. Calculation of current carrying capacity of conductors and cables. Heating in cables. Fuses. Insulators. Insulated conductors and pipes used in internal installation. Internal circuits and their installation methods. Switches and applications. Lighting armatures. Electric meters. Security concept in electrical installations.

EM 200 Summer Practice I - (ECTS:2)
Minimum twenty five days of practical work in an organization with a sizable electrical or electronics operation. Special attention should be given to most but not necessarily all of the following subjects: production, operation, maintenance, management and safety. A formal report as described in the Summer Practice Guide is to be submitted.

EM204 Logic Design(3+0) 3 - (ECTS:4)
Binary systems. Codes. Boolean Algebra. Digital logic gates. Function simplification. Combinational logic. Sequential synchronous logic. Counters.

EM 205 C Programming Language (2+2) 3- (ECTS:4)
Objects, Functions, Operators, Control Statements, Loops, Arrays, Pointers, Dynamic Memory, Allocations, Structures
Prerequisite: ENF102

EM 212 Introduction to Electronics (4+2) 5 - (ECTS:5)
Basic semiconductor concepts. Physical electronics. Physics of P-N diodes. Bipolar junction transistors (BJTs). Field effect transistors (FETs). Transistor biasing and small signal models. Unijunction transistors (UJTs). P-N-P-N switching devices. Negative resistance microwave devices. Lasers. Introduction to electronic circuit analysis using SPICE.

EM 214 Low Voltage Power Systems (3+0) 3 - (ECTS:3)
Introduction to energy systems. Basic knowledge and electrical devices. Single phase and three phase power calculations. Power factor correction. Power system modeling. Distribution and transmission cables. Short circuit calculations. Fuses, conductors and circuit breakers in power systems. Measurement methods in low voltage systems. Earthing, concepts and methods. Introduction to touch and step voltages.

EM 221 Circuit Analysis I (4+2) 5 - (ECTS:7)
Fundamental concepts and definitions, mesh, loop, and nodal analysis, circuit theorems, energy and power concepts. Switching functions. Transient and steady state response of first and second order circuits. Dynamic response of multi-mesh and multi nodal circuits. State variables.
Prequisite: MAT 102

EM 222 Circuit Analysis II (4+2) 5 - (ECTS:7)
Sinusoidal alternating current. Phasors. Power and power- factor. Resonance. Bode plots. Topology. Non-sinusoidal waveforms. Mutual inductance and transformers. Four terminal networks. Complex frequency domain. Transfer function concept. Convolution. Fourier series and its application.
Prerequisite: EM 221

EM 223 Electromagnetic Field Theory I (3+0) 3 (ECTS:5)
Review of vector analysis. Electrostatic fields in vacuum and materials. Solution methods of electrostatic problems. Energy and forces in electrostatic fields. Electric current and conductors.

EM 226 Electromagnetic Field Theory II (3+0) 3 (ECTS:4)
Static magnetic field in vacuum and materials. Solution methods of magnetic field problems. Magnetic properties of materials. Slowly varying time dependent magnetic fields. Relationship between circuit and field theories. Introduction to Maxwell's equations.
Prerequisite: EM 223

EM 229 Probability and Statistic. (3+0) 3 - (ECTS:4)
Basic concepts of probability theory and statistics. Random variables. Distribution and density functions. Multiple random variables. Conditional distributions, correlation, application of statistics to engineering systems.

EM 300 Summer Practice II
Minimum twenty five days of practical work in an organization with a sizable electrical or electronics operation. Special attention should be given to most but not necessarily all of the following subjects: production planning, maintenance, management, quality control and design. A formal report as described in the Summer Practice Guide is to be submitted.

EM 301 Signals and Systems (3+0) 3 - (ECTS:4)
Continuous and discrete-time signals and systems. Feedback, memory, stability, linearity, time-invariance, Linear and time-invariant systems described by differential or difference equations. Convolution. Fourier series and transformation. Modulation. Sampling. Z-transformation. Transfer functions.
Prerequisite: EM 222

EM 302 Digital Signal Processing (3+0) 3 - (ECTS:5)
Discrete time signals and systems. Sampling and reconstruction. Linear time-invariant systems. The Z transformation. Structures for discrete time systems. The discrete Fourier transform. Fourier analysis of signal using discrete Fourier transformation. Digital filter design techniques. Fast Fourier transformation methods. Optimal filtering and linear prediction.
Prerequisite: EM 301

EM 305 Electric Machinery (3+2) 4 - (ECTS:5)
Electromagnetic circuits. Electromechanical energy conversion. Single-phase and three-phase transformers. DC motors and generators: principles of operation, speed control. Rotating magnetic fields and three-phase windings. Asynchronous machines: principles of operation, equivalent circuit, speed control. Synchronous machines: equivalent circuit, state characteristics, synchronization. Special electrical machines.

EM308 Numerical Analysis (3+0) 3 - (ECTS:5)
Numerical error analysis. Roots of equations. System of linear algebraic equations. Curve fitting. Interpolation. Numerical differentiation and integration. Ordinary differential equations. Eigenvalue and eigenvectors.
Prerequisite : ENF 102

EM 309 Electromagnetic Waves (3+0) 3 - (ECTS:3)
Maxwell's equations in time and frequency domains. Electromagnetic energy and power. Wave equation. Uniform plain waves. Reflection and refraction. Introduction to transmission lines.

EM 314 Control Systems I (3+2) 4 - (ECTS:7)
Basic concepts. Models of physical systems: transfer function, block diagram, state equations. Time-domain and frequency-domain analysis of control systems. Stability analysis. Root-locus. Bode and Nyquist diagrams. Compensators.
Prerequisite: EM 301

EM 315 Analog Electronics (4+2) 5 - (ECTS:6)
Frequency response of single stage transistor amplifiers. Multistage amplifiers. Bode plots. DC, RC and transformer coupled amplifiers. Differential pair stages. Current mirrors. Operational amplifiers. Power amplifiers. Feedback in amplifiers. Power supply regulators. Noise in amplifiers
Prerequisite: EM 212

EM 316 Digital Electronics (3+2) 4 - (ECTS:6)
Large signal transistor models. TTL, MOS, and CMOS logic gates. Invertors, input and output circuits. AND, OR, NAND, NOR, and derivative gates (XOR, XNOR). Static and dynamic analysis. Regenerative circuits: Astable, monostable, bistable, multivibrators. Schmitt triggers. Timing circuits. Static and dynamic memories: RAM, ROM, EPROM,PLA etc. A/D and D/A converters. MUX, DEMUX and PLA devices.

EM 317 Analog and Digital Electronics (4+2) 5 - (ECTS:7)
Frequency response of single stage transistor amplifiers. Multistage amplifiers. Transformer coupled amplifiers. Differential pair stages. Operational amplifiers. Power amplifiers. Power supply regulators. Large signal transistor models. Invertors, input and output circuits. AND, OR, NAND, NOR, and derivative gates (XOR, XNOR). Regenerative circuits: Astable, monostable, bistable, multivibrators. Schmitt triggers. Timing circuits. Static and dynamic memories: RAM, ROM, EPROM,PLA etc. A/D and D/A converters. MUX, DEMUX and PLA devices.
Prerequisite: EM 212

EM 321 Electric Machinery I (3+2) 4 - (ECTS:7)
Electromagnetic circuits. Hysteresis and eddy-currents. Electromechanical energy conversion. Single-phase and three-phase transformers. DC motors and generators: principles of operation, speed control.

EM 322 Electric Machinery II (3+2) 4 - (ECTS:7)
Rotating magnetic fields and three-phase windings. Asynchronous machines: principles of operation, equivalent circuit, speed control. Synchronous machines: equivalent circuit, state characteristics, synchronization. Single-phase induction machines. Special electrical machines.
Prerequisite: EM 321

EM 330 Power Electronics I (3+2) 4 - (ECTS:6)
Power semiconductor switches and their characteristics. Power converter definitions and classification. VTA method. Midpoint and bridge rectifiers: non-ideal commutation, harmonics, input power factor, utility-factor, winding utilization and unbalances in rectifier transformers. Applications.
Prerequisite: EM 212

EM 334 Communication Systems I (3+2) 4 - (ECTS:7)
Mathematical representation of message signals. Amplitude and angle modulation techniques: Amplitude modulation, double sideband, single sideband, vestigial sideband modulation, frequency modulation. Super heterodyne receivers. Phase locked loops. Frequency division multiplexing. Noise in amplitude and frequency modulation systems.

EM 345 Microprocessors (3+2) 4 - (ECTS:6)
Fundamentals of a microprocessors, assembly language. Hardware and registers. The internal block representation of well-known microprocessor, its instructions. Timing and control units. Design of arithmetic, logic and control units. Machine language of a selected microprocessor. Memory hardware, memory unit design. Microcomputer interfacing methods. Interrupts and direct memory access definitions and applications to selected microprocessors.
Prerequisite: EM 204

EM 362 Power System Analysis I (3+0) 3 - (ECTS:5)
Introduction to power systems. Line parameters; inductance and capacitance of transmission lines. Short, medium and long length lines; current and voltage relations. Electrical characteristics of transformers and generators. Per-unit quantities. System Modeling. Symmetrical three-phase faults. Selection of circuit breakers.

EM 418 Industrial Electronics (3+2) 4 - (ECTS:6)
Power converters: definitions and classifications. Power semiconductors and their characteristics. Basic characteristics and operation of a thyristor. Cooling. Derivation of the mean output voltage of a rectifier using VTA method. Rectifiers: midpoint and bridge connections, ideal and non-ideal commutations, overlap phenomenon, input current harmonics, output voltage harmonics, input power factor. Natural and forced commutations. DC-DC converters: buck and boost types; time-ratio control. Inverters: voltage fed and current fed inverters, PWM techniques. Applications.

EM 427 Microwave Techniques (3+2) 4 - (ECTS:8)
Review of electromagnetic wave theory. Frequency and time domain analysis of transmission lines. Rectangular and circular waveguides. Equivalent circuit analysis of microwave systems. Active and passive microwave devices. Impedance transformation and matching techniques. Stripline and microstripline techniques.

EM 428 Antennas (3+2) 4 - (ECTS:6)
Antenna parameters. Linear antennas. Radiation diagrams for simple antennas. Antenna arrays. Reflector antennas. Ground waves and introduction to propagation. Introduction to radar systems.

EM 431 Power Electronics II (3+2) 4 - (ECTS:6)
Introduction to forced commutated circuits, analysis and classification of techniques. Voltage-fed inverters: PWM techniques, voltage regulation, harmonics. Current-fed inverters. DC-DC switching converters: step-down and step-up converters. Time-ratio control, calculation of optimum values of circuit parameters. Protection, cooling and maximum operating ratings of switching devices. Series and parallel operation of switching elements.
Prerequisite: EM 330

EM 437 Communication Systems II (3+2) 4 - (ECTS:8)
Pulse modulation: Sampling theorem, pulse amplitude modulation, pulse code modulation, delta modulation. Time division multiplexing. Line codes. Digital communication systems: Amplitude shift keying, frequency shift keying, phase shift keying. Introduction to the theory of probability. Random variables. Statistical averages. The central limit theorem. Correlation.
Prerequisite: EM 334

EM 461 Power System Analysis II (3+0) 3 - (ECTS:5)
Symmetrical components. Positive, negative and zero-sequence networks. Unsymmetrical faults on power systems; single line to ground, double line to ground and line to line fault analysis. Matrix analysis of power systems and solutions. Load-flow solutions. Stability of power systems.
Prerequisite: EM 362

EM 475 Energy Distribution I (3+2) 4- (ECTS:5)
Properties of electrical energy and energy distribution systems. Line constants and calculation methods. Effect of abnormal voltages on apparatus and machines. Fundamentals of line conductor cross-section determinations. Lines loaded from a point. Energy distribution networks. Lines loaded with point loads and their cross-section calculations. Distributed loads and power densities. Cross-section calculations on compact and distributed load lines. Determination of transformation locations, and calculations of powers. Towers, calculation of side-wing forces and determination of tower types. Preparation fundamentals of low voltage energy distribution network projects.

EM 480 High Voltage Techniques (3+2) 4 - (ECTS:7)
Current-voltage relationship in gases. Electron emission. Ionization and deionization. Townsend and Streamer breakdown mechanisms. Breakdown mechanisms in Electronegative gases. Lightning discharges. Corona discharges and corona loss. Breakdown mechanisms in Liquid and Solid dielectrics. Generation and measurement of A.C, D.C and Impulse voltages.

EM 492 Electrical and Electronics Engineering Design (SE) (1+2) 2 (ECTS:5)
This course provides guidelines for developing an organized method of doing an engineering design project from start to finish.

EM 495 Undergraduate Research Project (SE) (2+4)4 - (ECTS:7)
Theoretical and practical research for undergraduate students to acquire designing skills in various branches of electrical and electronics engineering.
Prerequisite : To be taken by the students who will graduate at the and of two consecutive terms.

EM 496 Final Year Project (SE) (0+2)1 - (ECTS:4)
A project which is carried out under the supervision of one of the academic staff approved by the department according to the intent of the student and which is subject to special judgment.
Prerequisite: EM 495

TECHNICAL ELECTIVE COURSES FOR ELECTRICAL BRANCH

EM 403 Lighting Techniques (3+2) 4 - (ECTS:5)
Light theories. Eye, sensitivity and vision types. Light reflection, absorption and transmission phenomenon. Definition of lighting terms. Lighting methods. Internal lighting systems and calculations. Pre-project preparation fundamentals. Feeder, column and main-column line formation. Fundamentals of practical application project preparations. Low power-factor correction methods in internal installations. Voltage-drop calculation for lighting systems. External lighting calculations.

EM 404 Road Lighting Techniques (3+0) 3 - (ECTS:5)
Basic fundamentals of road lighting. Lighting apparatus and armatures used in road lighting. Measures taken for the quality of road lighting. Preparation fundamentals of road lighting projects. Computational methods for road lighting. Feeder lines for road lighting networks. Tunnel lighting and examples.

EM 410 Energy Transmission Line Engineering (3+0) 3 - (ECTS:5)
Selection of conductors for transmission lines. Calculations of transmission line apparatus in terms of mechanical strength and over voltages. Computation of protection angle and chain curve for high voltage transmission lines. Calculation of sagging and methods for proper conductor sagging. Line tow and span calculations, and additional loads on power transmission lines. Distances between towers and related calculations. Economical and critical distance computations. Design and construction of towers. Steel and concrete towers and computations. Earthing resistance on transmission lines. Introduction to transmission system stability.

EM 421 Design of Electrical Machines (3+0) 3 - (ECTS:5)
Induction machine design: design principles, determination of dimensions, selection of slot numbers, windings, calculation of parameters. Synchronous machine design: determination of dimensions, windings, calculations of parameters. Optimum design of induction and synchronous machines.

EM 423 Dynamics of Electrical Machines (3+0) 3 - (ECTS:5)
Introduction. Dynamical behavior of DC machines: mathematical and circuit models, transfer functions and block diagrams, dynamical solutions. Synchronous machines: mathematical models in (d-q-0) axes, per unit dimensions, numerical simulation. Induction machines: mathematical models in different reference axes, per unit dimensions, numerical simulation.

EM 425 Control Systems II (3+2) 4 - (ECTS:5)
Compensation in frequency-domain. State-space representation. Eigenvalues and eigenvectors. Linear transformation. Solution techniques. Controllability and observability. Liaponov's method. Phase plane analysis. Pole assignment. Observer design. Introduction to optimal control. Analysis and design of discrete-time systems. Application examples.
Prerequisite: EM 314

EM 434 Electric Drive Systems (3+2) 4 - (ECTS:5)
Speed control methods of dc motors and applications. Four-quadrant operation. Speed control methods of induction motors and their applications: speed control by voltage adjustment, frequency speed control, flux constant speed control, speed control by rotor resistance. Inverters and PWM techniques. Operation principles of step motors. Operation principles of reluctance motors.
Prerequisite: EM 322

EM 462 Introduction to Insulation Coordination of Power Systems (3+0) 3 - (ECTS:5)
Introduction and general philosophies. Generation of over voltages; lightning surges and switching surges. Propagation of surges; reflaxion and refraction. Bewley Lattice analysis of traveling surges. Protection against over voltages and protective devices

EM 476 Energy Distribution II (3+0) 3 - (ECTS:5)
Medium-voltage lines and networks. Norms for voltage levels and determination of economic operation voltages. Determination of line conductor cross-section with respect to mechanical strength and thermic properties in medium voltage lines. Calculation of voltage drop in terms of length and width. Energy loss calculations. Economical line conductor cross-section calculation methods. Line failures and line conductor calculation from short-circuit currents. Dual supplied medium-voltage networks and cross-section computation. Further details of distribution system project preparations.
Prerequisite: EM 475

EM 479 Power Systems Protection - (ECTS:5)
Faults and abnormal conditions. Introduction and general philosophies. Introduction to protection systems. Current and voltage transformers. Over current, differential and distance protection: Protection of generators and transformers. Line protection.

EM 482 High Voltage Circuit Breakers (3+0) 3 - (ECTS:5)
Introduction to power circuit switching and circuit breakers. Network switching analysis. Physics of Circuit breaker arcs. Methods of breaking. Circuit breaker types and construction. Circuit breaker testing

TECHNICAL ELECTIVE COURSES FOR ELECTRONICS AND COMMUNICATION BRANCH

EM 405 Introduction to VLSI Design (3+0) 3 - (ECTS:5)
Design techniques for rapid implementations of very large-scaled integration (VLSI) circuits. MOS technology and logic. Structure design. Design rules, layout procedures. Circuit simulation. Project to develop and layout circuits

EM 415 Introduction to Biomedical Engineering (3+2) 4 - (ECTS:5)
Basic principles of biomedical instrumentation. Basic transducer and principles. The origin of biopotential electrodes. Physiology and measurement of neural, circulatory and respiratory systems. biopotential amplifiers. Patient care and monitoring systems. Therapeutic and prosthetic devices.

EM 416 Medical Imaging Systems (3+0) 3 - (ECTS:5)
Generation and detection of X-rays, X-ray image characteristics, Biological effects of ionizing radiation, The principles of conventional X-ray systems, digital subtraction angiography and computerized tomography. Fundamentals of acoustic propagation, ultrasonic diagnostic methods. Fundamentals of radionuclide imaging, generation of detection of nuclear emission, the principles of gamma camera. Fundamentals of magnetic resonance imaging, generation and detection of MR signal, imaging methods.

EM 425 Control Systems II (3+2) 4 - (ECTS:5)
Compensation in frequency-domain. State-space representation. Eigenvalues and eigenvectors. Linear transformation. Solution techniques. Controllability and observability. Liaponov's method. Phase plane analysis. Pole assignment. Observer design. Introduction to optimal control. Analysis and design of discrete-time systems. Application examples.
Prerequisite: EM 314

EM 430 Microwave Circuit Elements (3+0) 3
Passive reciprocal and nonreciprocal devices. Electromagnetic resonators. Periodic structures and microwave filters. Microstripline structures and coupled lines. Solid state microwave devices.
Prerequisite: EM 427

EM 433 Communication Electronics (3+0) 3 - (ECTS:5)
Active and Passive filters. RF Amplifier analysis and synthesis using Y-parameters. LC and crystal oscillators. PLLs and frequency synthesizers. Linear and exponential modulator and demodulator design.

EM 438 Digital Communications (3+0) 3 - (ECTS:5)
Random processes. The power spectral density of a random process. Multiple random processes. Transmission of random processes through linear systems. Bandpass random processes. Optimum threshold detection. M-ary communication. Introduction to information theory. Error correcting codes.

EM 439 Electromagnetic Modelling (3+0) 3 (ECTS:5)
Finite-difference time-domain method. Yee cell. Absorbing boundary conditions. Simulation of wave propagation. Finite element method. High frequency methods. Method of moments. Application of numerical and high frequency methods to antenna and microwave problems.

EM 440 Optics (3+0) 3 (ECTS:5)
Introduction to optical theory, Waves, Wave propagation, Electromagnetic theory, Fotons, Light, Light propagation, Reflection and refraction of light, Geometrical optics, Diffraction, Interference, Polarization, Introduction to Fourier Optics.

EM 447 Technology of Semiconductor Devices - (ECTS:5)
Preparation of semiconductor slices. Insulating film on semiconductors. Photolithography. Dopant impuritien and diffusion of dopant impurities. Metallization, interconnection and packaging. Integrated circuits components and their fabrications. Integration of commercial circuits. Future developments in semiconductor micro technology.

SERVICE COURSES OFFERED BY OTHER DEPARTMENTS

ENF 101 Introduction to Computers and Information Systems (1+2) 0, ECTS:2
Basic information about computer systems, introduction to computer hardware and software, DOS and WINDOWS operation systems, word processing, database use, preparation of presentation, charting and graphic applications, internet, email and WWW information network use, HTML and JAVA programming.

ENF 102E Basic Computer Science and C/C++ Programming (2+2) 3, ECTS:4
Problem solving, developing Algorithms and Flowcharts, Basic Programming principles, History and basic contents of C++ lnguage; lexical elements (keywords, constants), Operators and statements, Visual programming tools, object oriented programming environments, Pointers, Control statements, Object oriented programming basics.

FIZ 103 Physics I (4+0) 4, ECTS:6
Physics and Measurement, One Dimensional Motion, Two Dimensional Motion, Laws of Motion, Circular Motion and Other Applications of Laws of Newton, Work and Kinetic Energy, Potential Energy and Energy Conservation, Linear Momentum and Collisions, Rotation of Solid Bodies About A Fixed Axis, Rolling Motion and Angular Momentum, Static Equilibrium and Elasticity, Vibraiton, The Law of Gravity, Fluid Mechanics, Temperature, Heat and First Law of Thermodynamics, The Kinetic Theory of Gases, Heat Machines, Entrophy and Second Law of Thermodynamics.

FIZ 104 Physics II (4+0) 4, ECTS:6
Electric Fields, Gauss's Law, Electrical Potential, Capacitance and Dielectrics, Electric Current and Resistance, Direct Current, Magnetic Fields, Magnetic Fields Sources, Faraday's Law, Inductance, Alternating Current Circuit, Electromagnetic Waves, The Nature of Light and Laws of Geometric Optic, Interference, Diffraction and Polarization of Light Waves

FIZ 156 Physics Laboratory (0+2) 1, ECTS:1
Velocity and Acceleration, Two Dimensional Motion, Newton's Laws of Motion: Motion in Oblique Plane, Elastic and Inelastic Collisions, Simple Harmonic Motion

KIM 103 Chemistry (4+0) 4, ECTS:5
Chemical Calculations. Structure of Atom. Periodic System. Chemical Bonds. Gases, liquids, solids and solutions. Chemical Kinetic and Equilibrium. Acids and Bases. Reactions in Aqueous Solutions and Ion Equilibrium. Electrochemistery. Thermodynamics.

KIM 151 Chemistry Laboratory (0+2) 1, ECTS:1
Identification of Matter with Chemical and Physical Properties, Purification Methods in Chemistry, Crystallization, Diffusion, Stoichiometry, Determination of Ideal Gas Constant, Effect of Temperature on Reaction Rate, Indicators and Determination of pKa, Acid-Base Titration, Chemical Equilibrium

MAT 101 Mathematics I (4+0) 4, ECTS:6
Number Sentences. Absolute value, inequalities involving absolute value function, induction. Coordinates. Complex numbers. Functions. Function composition. Trigonometric functions. Limit of functions. Continuity. Properties of continuous functions. Differentiation. Derivative, mean value theorem and its applications. Determination of maximum, minimum and their applications. The graphs of functions, differential and its applications. Integral, fundamental theorem. Functions identified integrals. Integration formulas, methods of integration. Calculations of area, volume and length of an arc.

MAT 102 Mathematics II (4+0) 4, ECTS:6
Sequences, series, power series. Polar coordinates, vectors in R3, curves, lines and planes. Limit and continuity of multivaraible functions, partial differentiation, gradient, tangential plane, directional derivatives, unconditional and conditional maximum/minimum,Lagrange multipliers. Multiple integrals, line integrals and path independence, surface integral.

MAT 116 Linear Algebra (3+0) 3 - (ECTS:4)
Matrices, determinants and systems of linear equations. Vector spaces, the Euclidian space, linear transformations. Eigenvalues, diagonalization. Lines and planes in 3-space. Basic surfaces in space, cylinders, surface of revolutions, quadratic surfaces. Cylindrical and spherical coordinates.

MAT 213 Differential Equations (2+2) 3 - (ECTS:5)
First order differential Equations: Exact differential equations, integral multiplier, linear differential equations, electric circuits, curve families, approximate solutions, existence and uniqueness. Linear differential equations: Homogeneous linear equations, constant coefficiency method, The Mean Value theorem, differential operators, free oscillation, inhomogeneous equations, indefinite coefficiency method, electric circuits, variation of parameters. Differential equation systems. Series solutions: Legendre and Bessel equations. The Laplace transform. Introduction to Fourier series. Introduction to partial differential equations and separation of variables.

MAT 216 Complex Calculus (3+0) 3 - (ECTS:5)
Algebra of complex numbers. Polar representation. Derivatives of complex functions, analytical functions, Cauchy-Riemann equations. Power series. Elementary functions. Mapping by elementary functions. Linear fractional transformations. Line integral Cauchy integral theorem. Cauchy integral formula. Series, singular points, Taylor's Series. Laurent series. Residues, Residue theorem. Improper integrals.

MM 103E Computer Aided Technical Drawing I (2+1) 3, ECTS:5
Introduction to computer aided technical drawing. Geometrical constructions. Principles of orthographic projection; projection of principal views from three dimensional models. Drawing techniques for basic manufacturing processes and standard features. Projection of third principal view from two given principal views; free hand drawing techniques. Three dimensional drawing techniques; simple shapes, inclined surfaces, skew surfaces. Principles of dimensioning. Principles of sectioning; full and half sections. Further work on sectioning, conventional practices. Introduction to the solid modeling.

TAR 101 History of Turkish Republic I (2+0) 0, ECTS:2
Reform movements of the Ottoman Empire in the late of 19. Century and general status of the Ottoman Empire in the beginning of 20 century. I. And II. Monarchy periods, Tripoli and Balkan Wars, I. World War (especially Canakkale battles) general view of I. World War, Ottoman Empire in the war. Mondros Cease-Fire Agreement and the effects on the Ottoman Empire and results. Important facts from Mondros Cease- Fire Agreement to 19 May 1999. Early Life, Circumference, Personality of Mustafa Kemal, Initial Organization of the Turkish War of Independence. Landing of Mustafa Kemal in Samsun. Erzurum Congress. Sivas Congress. Establishment of The Turkish Grand National Assembly, Establishment of The Turkish Grand National Government . Civil Riots of 1920.

TAR 102 History of Turkish Republic II (2+0) 0, ECTS:2
Ideas about sharing Ottoman Empire. Paris Conference. Military occupation of Izmir. Minorities. Cerkez Ethem Event. First and second Inonu Battles. Eskisehir and Kutahya Battles. Sakarya Warand its results. Kars and Ankara Treaties. Mudanya Cease-fire Treaty and its importance. Lousanne Conference and its importance. Turkish Revolutions. Politicial, juridical, social, cultural, educational revolutions. Economical growth of Turkey Turkish foreign policiy. Armenian problem. Second World War and Turkey. Principles of Ataturk.

ING 103 English (3+0) 3, ECTS:3
ING 103 aims to develop reading comprehension and writing skills by enlarging the academic vocabulary of the students. Developing analytical and critical thinking skills through the selected texts, students will be able to evaluate, synthesize and respond to the ideas in the texts. In addition, students are equipped with basic principles and mechanics of writing.

ING 104 English (3+0) 3, ECTS:3
In the same fashion as ING 103, ING 104 aims to develop reading comprehension and writing skills by enlarging the academic vocabulary of the students. Developing analytical and critical thinking skills through the selected texts, students will be able to evaluate, synthesize and respond to the ideas in the texts. In addition, students are equipped with basic principles and mechanics of writing a paragraph.

ING 203 English (3+0) 3, ECTS:3
ING 203 aims to equip the students with the skills they need to succeed in their future academic and professional careers and to teach extensive and intensive reading skills as well as vocabulary, grammar, and writing skills. Students will gain a deeper knowledge of the material they are presented with, both in and out of the classroom. They will be able to apply the skills they have learned to new situations with materials they have never seen before.

ING 204 English (3+0) 3, ECTS:3
ING 204 aims to equip the students with the skills they need to succeed in their future academic and professional careers and to teach extensive and intensive reading skills as well as vocabulary, grammar, and writing skills. Students will gain a deeper knowledge of the material they are presented with, both in and out of the classroom. They will be able to apply the skills they have learned to new situations with materials they have never seen before.

TUR 101 Turkish I (2+0) 0
What is language? Importance of language for national life. Relationship between culture and language. Place of Turkish language in the world languages and its distribution area. Classification, properties and rules of Turkish Phonetics. Syllables. Spelling and punctuation rules and their applications.

TUR 102 Turkish II (2+0) 0
Turkish affixes and their applications. Composition writing rules. Planning of composition writing and its applications. Turkish nouns and verbs. Composition expression and its applications. Turkish adverbs and prepositions.