Course Descriptions

Objects and classes, constructors, static variables, constants and methods, visibility modifiers, passing objects and object arrays to methods, immutability, variable scopes, class abstraction and encapsulation, super and subclass concepts, inheritance, polymorphism, overriding, overloading, abstract classes, object-oriented design.

To develop the skills required to analyze electrical properties, such as voltage, current, power and energy, in circuits driven by time varying sources; using mathematical transformations. To develop the ability of using mathematical transformations to model engineering systems.

Circuit simulation and design by SPICE software. Measurements using voltmeters, ammeters, oscilloscopes and other instruments. Application of circuit principles introduced in EE 221 and EE 222: Resistive circuits, circuit analysis, frequency response tests with RL and RC networks. Two-port circuit parameters. Passive and active filters. Design, simulation and measurement of electrical circuits.

Conduction mechanism in metals and semi-conductors, doping in semi-conductors, p-n junction. Diode characteristics and applications. Bipolar Junction. Transistor operation, transistor characteristics, transistor biasing, small-signal modeling and analysis. JFET operation and biasing, MOSFET operation and biasing. FET small-signal modeling and analysis. BJT and JFET amplifiers' frequency response.

Number systems. Boolean algebra, logic networks and their simplification. Logic design with gates. MSI and LSI technologies. Combinatorial circuits, sequential circuits. Counters, shift registers, arithmetic logic, memory and control units.

Experiments with logic gates and combinational circuits, digital arithmetic circuits, multiplexers, flip-flops, counters, shift registers.

Electrostatic fields. Dielectric properties of materials. Stationary electric currents and static magnetic fields. Time-varying electromagnetic fields. Faraday's induction. Maxwell's equations. Time-harmonic electromagnetic waves. Uniform plane waves.

Types of energy, energy conversion principles, electromechanical energy conversion. DC machines: equivalent circuits, operating characteristics, voltage and velocity regulations. Transformers: equivalent circuits, operating characteristics and transformer testing. Induction motors and generators, stepping motors. AC synchronous machines.

Matlab environment. Vector, matrix and array operations. Matlab commands. Plotting and graphics. Symbolic math. Matlab programming. Search and sort algorithms. Simulink and modeling. Graphical user interfaces. Circuit analysis. Signal processing and applications.

Diode characteristics and applications. Transistor biasing. Measurement of transistor parameters. Single and multistage transistor amplifiers. Amplifier frequency response. DC power supplies and regulator circuits. Design and simulation of differential amplifiers, active filters, oscillator circuits and power amplifiers.

Time and frequency domain analysis of signals and systems. Periodic signals. Convolution integral. Transmission of information by orthogonal functions. Fourier transforms. Filters. Modulation theory. Analysis of discrete time signals and systems. Discrete time Fourier transform (DFT). Computer applications.

Linear time invariant systems, stability and causality. Discrete Time Fourier Transform. Z-Transform. Sampling and quantization schemes. Sampling Theorem. A/D, D/A conversion. Transform analysis of LTI systems. Finite Impulse Response (FIR) and Infinite Impulse Response (IIR) systems, and their realizations. Digital filter design techniques. Discrete Fourier Transform (DFT) and its computation: Fast Fourier transform techniques. Computer applications.

Introduction to microwave engineering. Transmission lines. Impedance transformation and matching. Smith Chart. Microwave network analysis, matrix representations, generalized scattering parameters. Power dividers and directional couplers. Microwave filters. Microwave amplifiers. Introduction to antennas and microwave propagation.

To establish an introductory level understanding of widely used analog and digital communication techniques in communication systems.

Design and development of a project for an electronics, signal processing or communication engineering problem under the supervision of an academic advisor; submission of the results in the form of a project report and oral presentation.

Departmental Elective-I

Departmental Elective-II

Departmental Elective-III

Departmental Elective-IV

Lumped circuit elements. Kirchoff’s laws.Reference directions, power and energy, Introduction to time-invariant circuits. Techniques of circuit analysis. General resistive circuits. OPAMPs. Capacitors, inductors and magnetic coupling, Analysis of first-order and second-order circuits.

Basic topics in probability, probability axioms, sample space, conditional probability, counting methods, discrete random variables, probability mass function, families of discrete random variables, expectations, function of a random variable, variance and standard deviation, continuous random variables, distribution function, probability density function, expected values, families of continuous random variables, the normal distribution, pairs of random variables, joint distribution function, marginals, joint probability function, functions of two random variables, variance, covariance and correlation concepts.

Why Teach Chemistry to Engineers? Matter-Its Properties and Measurement, Uncertainty and Significant Figures, Dimensional Analysis. Atoms and Atomic Theory, Atomic Mass and Mole Concept. Chemical Compounds, Molecular and Ionic Compounds, Composition, Oxidation States. Chemical Reactions, Stoichiometry, Reactions in Solutions, Limiting Reactant. Introduction to Reactions in Aqueous Solutions, Precipitation, Acid-Base, and Oxidation-Reduction Reactions, Titrations. Gases, Gas Laws, Ideal Gas Equation, Gases in Reactions, Mixtures of Gases, Kinetic Molecular Theory. Electrons in Atoms, Electromagnetic Radiation, Atomic Spectra, Quantum Theory, Electron Configurations. The Periodic Table and Some Atomic Properties.

English Speaking Skills

The origins of ethical thought; ethical principles and basic theories; personal, academic and professional ethics for engineers; environmental ethics; ethical implications of technology, computer ethics; ethics in research and experimentation.

Introduction to Computing

Functions, graphs, limits and continuity. Derivatives, derivative rules, chain rule, implicit differentiation. Applications of derivatives. Indefinite integrals. Definite integrals. Applications of integrals. Transcendental functions.

Standards and units; vectors and coordinate systems; kinematics, dynamics; work and energy; dynamics of system of particles; conservation of energy and momentum, collisions; rotational kinematics and dynamics; equilibrium of rigid bodies; oscillations.

Experiments on: work and energy; dynamics of system of particles; conservation of energy and momentum, collisions; rotational kinematics and dynamics; equilibrium of rigid bodies; oscillations.

Academic writing and speaking skills with a focus on organizing a research project involving a proposal, preliminary and ongoing research, annotations, thesis proposal, works cited and an interview to demonstrate the results of their work. Critical thinking, reasoning, logical argumentation, and presentation skills.

Integration techniques; improper integrals. Infinite series, positive and alternating series, power series, Taylor and Maclaurin series. Polar coordinates. Vectors and motion in space, vector valued functions.

Matrices, matrix addition, matrix and scalar multiplication, algebraic properties of matrix operations, special types of matrices, solving linear systems, elementary row and column operations, echelon form of a matrix, Gauss and Gauss-Jordan method, elementary matrices and finding the inverse of a matrix by using elementary operations, real vector spaces, definition, subspaces, span and linear independence, basis and dimensions, homogeneous systems, rank of a matrix, linear spaces with inner product, definition of the inner product, Gram-Schmidt process, orthogonal complements, linear transformation and their matrix representations, kernel and range of a linear transformation, matrix of a linear transformation, determinants, definition and properties of determinants, cofactor expansion, finding inverses by using cofactors, eigenvalues and eigenvectors, characteristic polynomial and equation of a matrix, eigenvalues and eigenvectors, diagonalization of symmetric matrices.

Charge and matter, electric field and Gauss' law, electric potential, capacitors, DC circuits, magnetic field, Ampere's law, Faraday's law, inductance, magnetic properties of matter, Maxwell's equations.

Experiments on: capacitors; DC circuits; magnetic field; Ampere's law; Faraday's law; inductance; magnetic properties of matter.

Basic definitions, first order differential equations, second order linear differential equations with constant coefficients. Systems of first order linear differential equations with constant coefficients, Laplace transforms and its applications to linear differential systems. Linear differential equations with variable coefficients, series solutions of second-order linear differential equations.

Explanation of communication, explanation of language and its relationship with the thinking proces, culture, society and literature; written and oral communication; main characterisrics of the Turkish language; phrases and types of narration; expressional failure.

Definitions of microeconomics and macroeconomics. Essentials of microeconomics. Operations of markets. Scarcity and resource allocation. Demand and supply analysis and elasticities. Market efficiency and welfare. Consumer and producer surplus. Cost analysis of firms. Perfect competition and imperfect competition. Monopoly, oligopoly and monopolistic competition. Externalities and internalities. Economics of factor markets.

Illustration of “narration” and its types; writing and communication modes; exemplified by masterspieces chosen from Turkish and world literature; exercises in effective writing and public speech.

Complementary Elective-I

This course aims to discuss political, social, cultural and economic transformations in the 19th century in their relation with the formation of the Republican Turkey and focuses on the modernization process in the early republican period until 1945.

Complementary Elective-II

Free Elective-I

HSS Elective-I

Political, social and cultural development of Turkey since WWII. Transition to multi-party system, social transformation in 1960s and 1970s, as well as the demographical change, industrialization and new social movements. The coup d'état of 1980 and its aftermath, political and social polarization in 2000s.

Free Elective-II

HSS Elective-II

HSS Elective-III

Science Elective-I

Introduction to computers, computer programs and the Java language, identifiers, variables, assignment statements, constants, data types, casting, selections, loops, methods, arrays, strings and characters.

Multivariable functions, partial derivatives, directional derivatives. Lagrange multipliers. Double integrals, triple integrals, line integrals. Green's theorem. Surface integrals, Stokes' theorem. Gauss theorem (Divergence Theorem). First order differential equations. Second and higher order linear equations with constant coefficients. Reduction of order. Nonhomogeneous equations. The Laplace transform, initial value problems. Systems of first order linear equations with constant coefficients.

Multistage amplifiers, coupling techniques and frequency response, differential amplifiers. High-frequency modeling of transistors. Feedback and broad banding techniques. Analog integrated circuits. OPAMPs. Power amplifiers, filters and oscillators, regulated power supplies.

Departmental Elective-V

Content is missing.

Analysis of linear control systems by differential equations and transfer function methods. Transient response of first and second order systems. Stability of closed loop systems. Routh-Hurwitz criterion, root-locus diagrams. System analysis in frequency domain. Bode and polar plots. Nyquist stability criterion. Introduction to the design of linear control systems, compensation techniques.

Introduction to Java, Objects and classes, constructor, static variable, constants, methods, visibility modifiers, passing objects to methods, immutable objects, data field encapsulation, class abstraction, inheritance.

Number systems. Boolean algebra. Logic circuits and simplification of the circuit. Logic design with gates. MSI and LSI technologies. Combinatorial circuits. Sequential circuits. Counters. Arithmetic logic, memory and control units.

Verification of logic gates. Introduction to combinational circuits. Introduction to VHDL. Binary adder circuit. Binary adder-subtractor circuit. Combinational circuit design. Multiplexers. Flip-flops. Counters.

Magnetic circuits. Relation of current in a coil with the produced magnetic flux and magnetic flux density. Ideal transformers and practical transformers and their equivalent circuit parameters. Electromechanical energy conversion process. Mechanical force in the electromagnetic system. Electromagnetic conversion. DC machines, DC generators and DC motors. Asynchronous machines. Synchronous machines.

Review of Fourier transform and LTI systems; Baseband and passband signal and system representations. Linear and angular modulation. Modulators and demodulators; Frequency translation and FDM; Review of probability and introduction to random processes; Noise analysis of communication systems; Pulse modulation, PCM and TDM; Matched filtering and intersymbol interference.

Design and development of a system component or process for an electrical and elctronics engineering problem to meet desired needs. Submission of the results in the form of a project report and oral presentation.

Minimum 20 working days of summer practice in the system development and integration, design, manufacturing, assembly and testing departments of an industrial corporation related with the electrical and electronics engineering fields. Delivering a report on the accumulated knowledge.

Area Elective-IV

Area Elective-V

Area Elective-VI

Area Elective-VII

Circuit variables. Circuit elements. Ohm's law, Kirchoff's laws and Thevenin's/Norton's, and superposition theorems. Circuit analysis methods. Natural and step responses of first and second order circuits. Sinusoidal steady state analysis of electrical circuits. Power and energy.

Area Elective-I

Data description. Text analysis. Summary and paraphrase of simplified research articles and data charts. IMRAD Summary. Critical thinking and logical argumentation skills to express an informed opinion. Presentation of information to an audience in an academic setting.

Critical thinking and logical argumentation. Academic research. Annotations, citations, quotations. Identification of arguments, reasoning, logical cohesion. Debates. Evaluative summary. Interview.

Introduction to basic IT theory and terminology. Basic skills in a word processor programs, such as MS Word to create documents, format text, apply styles. Basic skills in a spreadsheet program, such as MS Excel, to create and format spreadsheets, including the use of mathematical formulas and to summarize given data in the form of graphics.

Resources and scarcity; supply and demand; the mixed economy; market structure; national income, business cycles, unemployment and inflation; economic growth and productivity; money, banking and monetary policy; international trade and finance

Voltage and current, ideal basic circuit elements. Reference directions, power and energy. Ohm’s law and Kirchoff 's laws. Time-invariant resistive circuits with dependent/independent sources. Equivalent resistance calculations, Delta-to-Wye equivalent circuits. Node-voltage and mesh-current methods, source transformation, superposition. Thevenin and Norton equivalent circuits. The operational amplifier. Inductance, capacitance and mutual inductance. Natural and step response of first and second-order circuits.

Phasor transform and sinusoidal steady state analysis of circuits. Ideal transformers. Power calculations for circuits with sinusoidal sources, complex power. Impedance matching for maximum power transfer. Laplace transform. Transient and steady state analysis of time invariant circuits using Laplace transform. Transfer function and impulse response. Convolution integral in circuit analysis. Frequency response and frequency selective circuits. Passive and active filter circuits. Two-port circuit characterization and analysis of terminated two-port circuits.

Introduction to laboratory equipment and measurements. Introduction to circuit simulation tools. Two-terminal passive elements. Experimental applications of the fundamental circuit principles and theorems: Ohm’s and Kirchoff’s laws, Thevenin, Norton and Superposition theorems. Usage of oscilloscope and signal generator. Capacitor. Inductor. Response of RC, RL, RLC circuits

Electrostatic fields. Dielectric properties of materials. Stationary electric currents and static magnetic fields. Time-varying electromagnetic fields. Faraday's induction. Maxwell's equations. Time-harmonic electromagnetic waves. Uniform plane waves.

Analysis of linear control systems by differential equations and transfer function methods. Determination of transient and steady-state response of first order and second order systems. Solution of control systems using state-space methods. Stability of closed loop systems. Routh-Hurwitz stability criterion. Root-locus diagrams. System analysis in frequency domain. Bode and polar plots. Introduction to the design of linear control systems. Compensation techniques.

Minimum 20 working days of summer practice on the general engineering applications at an industrial corporation related with the electrical and electronics engineering fields. Delivering a report on the accumulated knowledge.

General Elective-I

Basic topics in parametric statistics; estimation, confidence intervals, and hypothesis testing; analysis of variance, regression and correlation analysis; goodness of fit tests. Elementary design of experiments and data collection; computer implementations using available up-to-date statistical software.

Diode characteristics and applications. Transistor biasing. Measurement of transistor parameters. Single and multistage transistor amplifiers. Amplifier frequency response. Design and simulation of differential amplifiers. Design and realization of active filters, oscillator circuits, power amplifiers.

General Elective-II

Area Elective-II

Area Elective-III

General Elective-III

General Elective-IV

Engineering project and risk management, feasibility analysis. Preparing project proposals. Interdiciplinary teamwork. Examples of social, environmental, ethical, legal aspects of engineering solutions for contemporary real life problems. Examples of entrepreneurship and innovation practices. Widely used engineering standards.

The basic theories in Ethics (the Philosophy of Morality). The practical implications of these theories in particular professions and areas such as engineering, medicine, pharmacology, genetics, technological innovation, artificial intelligence and robotology, management, marketing, international relations, public services, media and law. The meaning and significance of virtue and values. Moral principles within particular professions and their foundation in Ethics.

History of occupational health and safety. Work law. Occupational health and safety law. National and international conventions. Occupational diseases. Introduction to the concept of hazard and risk

General Elective-V

Hazard and risk concept. Chemical risk factors. Physical risk factors. Biological risk factors. Psychological risk factors. Ergonomic risk factors. Risk analysis and types. Industrial applications