FACULTY OF ENGINEERING AND ARCHITECTURE

DEPARTMENT OF ELECTRONICS ENGINEERING

PROFESSORS:
Prof. Dr. Ali OKTAY

ASSOCIATE PROFESSORS:
Assoc. Prof. Arzu BABAEV
Assoc. Prof. Erdoğan DİLAVEROĞLU
Assoc. Prof. Tuncay ERTAŞ
Assoc. Prof. Eldar MUSAYEV

ASSISTANT PROFESSORS:
Asst. Prof. İsmail AVCIBAŞ
Asst. Prof. Figen ERTAŞ
Asst. Prof. Osman H. KOÇAL
Asst. Prof.Dr. Murat TÜRE
Asst. Prof. Dr. Halil YEŞİLÇİMEN

INSTRUCTORS:
Dr. Sevim KURTULDU
Dr. Erdem ÖZÜTÜRK

GENERAL INFORMATION:
Uludag University Department of Electronics Engineering founded in 1978 and from that on department's main purpose giving fundamental mathematical and engineering knowledge in areas of electronics and general engineering. Department gives to possibility to students design systems, make analyses and interpret experimental data in electronics engineering. We support to students easy and rapid communication with scientific and industrial foundations of electronics engineering.

PROGRAM MISSION STATEMENT
Department of Electronics Engineering;
In the field of fundamental engineering and electronics engineering give subjects to students for satisfying the industrial needs in order to;
" Educational formation
" Get information how and where
" Improve ability for produce, develop and design the information.
In additional for those properties and abilities, our department has had duty for bring up Ataturk's principle and reforms and patriot digest individuals.

OBJECTIVES

1) To educate students with fundamental mathematical and engineering knowledge in areas of electronics and general engineering.
2) To equip its graduates with additional and functional interdisciplinary engineering background apart from electronics engineering.
3) To equip its graduates with the ability of continuous learning which can be used throughout their lives after taking their diplomas?
4) To educate students with the ability of solving different problems and creating new knowledge by using their current knowledge.
5) To equip its graduates with the responsibility and ethical values of electronics engineering.

RESEARCH INTEREST AND FACILITIES

Department of Electronics Engineering has;
1) Electronics Lab,
2) Telecommunication Lab,
3) Microwave Lab,
4) Electrical machinery Lab,
5) Industrial Electronics Lab,
6) Control and Computer Lab.
All laboratories well-equipped and those equipments ensured to researches works.

UNDERGRADUATE CURRICULUM
I. Semester
Course Code and Name Credits
MAT1089 Differential and Integral Calculus I 5
FZK1073 General Physics I 4
KİM1071 Fundamental Chemistry 3
ELN101 Computer Programming I 4
G104 Ataturk's principle and revolution history 0
G105 Foreign Language 0
G106 Turkish 0
English Elective Course
II. Semester
Course Code and Name Credits
MAT1090 Differential and Integral Calculus II 5
FİZ1704 General Physics II 4
MAT11078 Linear Algebra 3
ELN202 Computer Programming II 4
G204 Ataturk's principle and revolution history 0
G205 Foreign Language 0
G206 Turkish 0
English Elective Course

III. Semester
Course Code and Name Credits
MAT2083 Differential Equations 4
ELN2011 Circuits Theory I 3
ELN2041 Electromagnetic I 3
ELN2051 Signals and Systems I 3
ELN2021 Electronics Circuit Elements 3
ELN2023 Electrical Circuits Lab. I 1,5
English Elective Course
IV. Semester
Course Code and Name Credits
ELN2002 Engineering Mathematics 4
ELN2022 Circuits Theory II 3
ELN2042 Electromagnetic II 3
ELN2052 Signals and Systems II 3
ELN2062 Logic Circuits 3
ELN2024 Electrical Circuits Lab II 1,5
English Elective Course

V. Semester
Course Code and Name Credits
ELN3021 Electronics Circuit I 3
ELN3023 Electronics Circuit Lab I 1,5
ELN3001 Engineering Probability 3
Technical Elective Course 3
Technical Elective Course 3
Non Technical Elective Course 3
English Elective Course
VI. Semester
Course Code and Name Credits
ELN3022 Electronic Circuits II 3
ELN3024 Electronic Circuits Lab II 1,5
ELN3043 Signal Processing 3
Technical Elective Course 3
Technical Elective Course 3
Non Technical Elective Course 3
English Elective Course

VII. Semester
Course Code and Name Credits
Technical Elective Course 3
Technical Elective Course 3
Technical Elective Course 3
Technical Elective Course 3
Technical Elective Course 3
Non Technical Elective Course 3
English Elective Course
VIII. Semester
Course Code and Name Credits
ELN4000 Graduation Project 1
Technical Elective Course 3
Technical Elective Course 3
Technical Elective Course 3
Technical Elective Course 3
Non Technical Elective Course l 3
English Elective Course

Elective Courses
Course Code and Name Credits
ELN3061 Microprocessors 3
ELN3041 Analogue Communication 3
ELN3071 Numerical Analysis 3
ELN3081 Electrical Measurement Techniques 3
ELN 3055 Microwave 3
Course Code and Name Credits
ELN3043 Digital Communication 3
ELN3072 Electrical Machineries 3
ELN3052 Automatic Control 3
ELN3082 Microwave Circuit Elements 3

VII. Semester
Course Code and Name Credits
ELN4081 Mobile Communication Systems 3
ELN4013 Communication Networks 3
ELN4015 Antennas and Propagation 3
ELN4042 Microwave Electronics 3
ELN4005Engineering Optimization Methods 3
ELN4011 Linear System Theory 3
ELN4023 Optoelectronics 3
ELN4033 Integrated Communication Systems 3
ELN4037 Signal Processing App. 3
ELN4021 High Frequency Electronics 3
ELN4049 Microwave Lab. 3
ELN4069 Digital Image Processing 3
ELN4052 Computer Aided Control Design 3
ELN4055 Industrial Automation 3
ELN4025 Digital Electronics Circuits 3
ELN4064 Advanced Programming 3
ELN4083 Operating Systems 3
VIII. Semester
Course Code and Name Credits()
ELN4047 Signal Processing in Comm. Sys. 3
ELN4014 Data Communication 3
ELN4034 Satellite Comm. Sys. 3
ELN4032 Optical Comm. Sys. 3
ELN4024 Analog Integrated Circuit Design 3
ELN4054 Industrial Electronics 3
ELN4084 Biomedical Signal Processing 3
ELN4012 Linear System App. 3
ELN4017 Microwave Systems 3
ELN4044 Microwave Heating Techniques 3
ELN4046 Electromagnetic Compability 3
ELN4052 Digital Control Systems 3
ELN4060 Information Eng. 3
ELN4075 Radar Tech. 3
ELN4066 Graphic in Computer 3
ELN4068 Data Structure 3
ELN4077 Industrial Electronics Lab 3
ELN4076 Telecommunication Lab. 3

DOUBLE MAJOR PROGRAMS

Electronics Engineering Credits Mechanical Eng.
Industrial Eng.

II. Semester
MAT1078 Linear Algebra 3 + +
FZK1074 General Physics II 4 + --

III. Semester
ELN2001 Electromagnetic I 3 + +
ELN2011 Circuits Theory I 3 + +
ELN2051 Signals and Systems I 3 + +
ELN2021 Electronics Circuits Elements 3 + +
ELN2023 Electrical Circuits Lab I 1,5 + +

IV. Semester
ELN2002 Engineering Mathematics 4 -- +
ELN2022 Circuits Theory II 3 + +
ELN2042 Electromagnetic II 3 + +
ELN2052 Signals and Systems II 3 + +
ELN2062 Logic Circuits 3 + +
ELN2024 Electrical Circuits Lab II 1,5

V.Semester
ELN3021 Electronics Circuit I 3 + +
ELN3023 Electronics Circuit Lab I 1.5 + +
ELN3001 Engineering Probability 3 + +

VI.Semester
ELN3022 Electronics Circuit II 3 + +
ELN3024 Electronics Circuit Lab II 1.5 + +
ELN3043 Signal Processing 3 + +

VII. Semester
Technical Elective Course 3 + +
Technical Elective Course 3 + +

VIII. Semester
Technical Elective Course 3 + +
Technical Elective Course 3 + +
ELN4000 Graduation Project 1 + +
TOTAL CREDITS 66 62 62

MINOR PROGRAMS

Electronics Engineering Credits Mechanical Eng. Industrial Eng.
II. Semester
MAT1078 Linear Algebra 3 + +
FIZ1074 General Physics II 4 + --
III. Semester
ELN2011 Circuits Theory I 3 + +
ELN2021 Electronic Circuit Elements 3 + +
ELN2051 Signals and Systems I 3 + +
ELN2041 Electromagnetic I
IV. Semester
ELN2002 Engineering Mathematics 4 -- +
ELN2022 Circuits Theory II 3 + +
ELN2052 Signals and Systems II 3 + +
ELN2042 Electromagnetic II 3 + +
ELN2062 Logic Circuits 3 + +
V.Semester
ELN3021 Electronic Circuits I 3 + +
ELN3001 Engineering Probability 3 + +
VI.Semester
ELN3022 Electronic Circuits II 3 + +
ELN3043 Signal Processing 3 + +
TOTAL CREDITS 44 40 40

DESCRIPTION OF UNDERGRADUATE COURSES

DIFFERENTIAL AND INTEGRAL CALCULATIONS I (4 2 0)
Real numbers and functions, limits, series, continuity and differentiation, uncertainty states and L'hospital rule, analyzing the changing of functions, polar coordinates, inverse functions and inverse trigonometric functions, exponential and logarithmic functions, indefinite and definite integral, basic theorems of integral calculations, area and volume calculations, length of a spring calculation, rotational surface's surface and volume calculations, area in polar coordinates.

GENERAL PHYSICS (4 0 0)
Vectors, static, kinematics, dynamics, gravitation, work, power and energy, impulse and momentum, rotational motion, elasticity, harmonic motion, hydrostatic, hydrodynamic, surface tension, fluidity, heat, heat and calorimeter, heat transfer, ideal and real gases, molecular kinetic theory, thermodynamic rules, entropy.

BASIC CHEMISTRY (3 0 2)
Introduction to atom theory, chemistry formulas, chemistry equations, thermo chemistry, electronic structure of atoms, properties of atoms, ionic bond, covalent bond, gases, liquids and solids, solutions, electrochemistry, nonmetals, hydrogen and halogens, metals and metallurgy, complex compounds, organic chemistry.

COMPUTER PROGRAMMING I (3 0 2)
Introduction to computer, solving a problem by computer, build an algorithm, programming languages, introduction to C programming language, flow charts, produce Pseude code, functions and methods of producing arbitrary numbers, arrays, pointers, characters and character arrays, formatted input-output, file process, simple data structure, pre-processor.
LINEAR ALGEBRA (3 0 0)
Preparation for algebra, group, ring, object, vectors, calculations for vectors, definition of vector space, general properties of vector spaces, standard vector spaces IR?, sub vector spaces, properties of IR? vector space, dot products, linear independency, methods for making orthogonal, matrices and matrices calculations, calculation of determinants, linear equation systems and solving methods, finding solutions of linear equations systems by elementary operations, create and solve example problems related with linear equation systems.

GENERAL PHYSICS II (3 0 2)
Coulomb laws, electrical field and potential, capacitors, dielectrics, current and resistance, DC circuits, magnetic fields, electric measurement instruments, Ampere and Biot-Savart law, electromagnetic induction, transient currents, AC circuits, electromagnetic waves and photo reflection and diffraction, mirrors and prisms, scatter lenses and optic instruments, photometry, interference, diffraction and polarization.

COMPUTER PROGRAMMING II (3 0 2)
Introduction to data structure, stack, recursion, queue and lists, list process, trees, order, search, graph and applications, memory management.

DIFFERENTIAL AND INTEGRAL CALCULATIONS II (4 2 0)
Taylor formula, Binomial expansion, residue estimation, series, power series, vectors, vector valued functions, limit in multi-variable functions, continuity, partial differentiation, sided differentiation, Taylor expansions, maximum-minimum calculations, region transformations, multi integrals, curve integrals, surface integrals (Stoke's, Gauss and Green theorems).

DIFFERENTIAL EQUATIONS (3 2 0)
Classifications of differential equations and concept of solution, first order and first order differential equations, linear differential equations, Bernoulli, Riccati, Clairaut, Lagrange differential equations, rotations, high order differential equations, homogeneous constant coefficient differential equations, order reduce method, method of undetermined coefficients, method of variation of parameters, Cauchy-Euler differential equations, solution of differential equations by Laplace Transform, to solve linear differential equation systems by Laplace Transform, power series solutions, applications of differential equations in engineering and mathematics.

CIRCUIT THEORY I (3 0 0)
Electrical circuit's variables, circuit elements, circuit laws, resistance circuit solutions, nodal analysis, mesh analysis, superposition principle, source transformations, ?-Y transformations, dependent and independent sources, Thevenin and Norton equivalent circuits, maximum power transfer, capacitive and inductive circuits, natural and compulsory solutions of first order circuits, switching circuits.

ELECTROMAGNETICS (3 0 0)
Vectors and electromagnetic, electrostatic, magneto static field concepts, electromagnetic fields in different materials, Maxwell equations in form of integrals and differentiations for of time-varying fields, vector calculations and potentials functions, energy accumulation, static and semi-static fields, time domain analysis of waves, computer aided field calculations.

SIGNALS AND SISTEMS (3 0 0)
Continuous-time and Discrete-time signals, Linear time invariant systems, Fourier analysis of continuous time signals and discrete time signals, Fourier series, Fourier transformation, discrete Fourier transformation, frequency response of linear time invariant systems, convolution integral, convolution sum.

ELECTRONIC CIRCUIT ELEMENTS (3 0 0)
Structure of semiconductor diode, current voltage relation, important events in p-n junction and photodiode, LED kind of special diodes, structure of bipolar transistors, used for amplifier, transistors curves and models, transistor's small signal parameters and equivalent circuits, structure of MOS transistor, current-voltage relations, small signal parameters and equivalent circuits, p-n-p-n diode, thyristor, triac, etc switching circuit elements.

ELECTRICAL CIRCUIT LAB (0 0 3)
Circuit laws and simple electrical circuits, simple application of resistance circuits (Wheatstone bridge, ?-Y transformations), circuits' theorems (Thevenin, Norton, superposition), operational amplifiers and their applications, first order circuits (RL and RC circuits), second order circuits (RLC circuits) and term project.

ENGINEERING MATHEMATICS (4 0 0)
Complex variable functions, Cauchy-Riemann formulas, singular points, poles, Laurent series, residues, residue theorem, calculation of definite integrals, conformal mapping.

CIRCUIT THEORY II (3 0 0)
Circuit analysis in sinusoidal continuous state, phasor concept, impedance, frequency response, resonance circuits, common inductance, couplage circuits, transformators, filter types, circuit analysis by Laplace transform, power factor, active and reactive power, power compensation, 3 phases systems.

ELECTROMAGNETIC II (3 0 0)
Time varying fields and Maxwell equations, uniform plane waves, reflection and diffraction, theory of transmission lines, guided waves, optic waves and fiber optic, wave diffusion in ferrite medium, plasma, radiation and antennas.

SIGNALS AND SYSTEMS II (3 0 0)
Modulation, sampling of continuous-time signals, sampling theory, processing continuous-time signals in discrete-time, Laplace transformation, z-transformation, linear feedback systems.

LOGIC CIRCUITS (3 0 0)
Binary systems, Boole algebra, logic gates, simplification of function, combinational logic, PLD elements, synchronous consecutive logic, Asynchronous consecutive logic, displays, counters, memory elements, arithmetic operation circuits, ADC and DAC and term project.

ELECTRICAL CIRCUITS LAB. II (0 0 3)
Electrical permanent state analysis, 3 phase circuits, AC permanent state power, resonance circuits (series and parallel), filter circuits (Low-High-Band Pass and Band stop filters), and term project.

ELECTRONIC CIRCUITS I (3 0 0)
General concepts of amplifiers, and basic amplifier circuits, amplifier's behavior for big amplitude signals, square wave response of the capacitor connected multi staged amplifiers, directly connected stages amplifiers, difference amplifier, basic operational amplifier circuits, wide band amplifiers.

ELECTRONIC CIRCUITS LAB. I (0 0 3)
DC power suppliers, JFET amplifiers, amplifiers with transistors, logic circuits and multi vibrators, non-linear applications of operational amplifiers.

ENGINEERING PROBABILITY (3 0 0)
Probability, random variable, expectation, multi random variables, random functions, spectrum of random functions, random signal input linear systems.

ELECTRONIC CIRCUIT II (3 0 0)
Feedback and stability; kinds, circuits, positive and negative feedback, current and voltage feedbacks, in feedback amplifiers; current and voltage sourced circuits, affection of feedback on frequency characteristic, operational amplifiers and applications, power amplifiers, oscillators, supply circuits and analysis, circuits obtains high voltage from low voltage, switching supply circuits.
ELECTRONIC CIRCUIT LAB II (0 0 3)
Voltage amplifiers, feedback and stability in amplifiers with transistors, AF power amplifiers, linear impulse amplifier, sweep generators, electronic counters, piezoelectric crystals and crystal oscillators, PLL circuits, HF power amplifiers, wide band amplifiers.

SIGNAL PROCESSING (3 0 0)
Fast Fourier Transform, Continuous and discrete Wavelet transforms, digital filter design, FIR filters, IIR filters, continuous and discrete time stochastic signals, correlation function and coefficients, correlation matrices, power spectrum, non-linear systems and signals, Volterra filters.

TECHNICAL ELECTIVE COURSES
V. SEMESTER
MICROPROCESSORS (3 0 0)
General architecture of microprocessors, memory system design, architecture of 8051 microcontroller family and pin functions, addressing modes, analyzing the command set, assembly language, interrupt process, timing and counting process, serial communication, developing card design, applications projects.

ANALOG COMMUNICATIONS (3 0 0)
Amplitude modulation and its types, phase modulation, frequency divided multipliers, super heterodyne receivers, random process, amplitude and phase modulation's noise analysis, sampling, analog impulse modulations.

NUMERICAL ANALYSIS (3 0 0)
Solution of linear equations by minimum error and inverse of matrix, iterative methods, non-linear equations solution methods, numerical differentiation and integral, differential equations numerical solutions.

MICROWAVE (3 0 0)
Current and voltage waves in transmission lines, frequency and time domain analysis, energy and power flow, impedance fitting, Smith chart, micro strip lines, impulse diffusion in line, wave guides, resonators, S-parameters.

ELECTRICAL MEASUREMENT TECHNIQUES (3 0 0)
Basic principles of measurement; effect, error, delay, sensors and transducers; heat, pressure and moisture transformers, transducer bridges and amplifiers, transducers modeling; linear regression models, error estimation, filtering the measurement signals, ADC and DAC principles.

VI. SEMESTER
DIGITAL COMMUNICATION (3 0 0)
Digital pulse modulation, link codes, base band pulse transmission, signal space, correlated and matched filter type demodulators, band pass modulations types, bit error analysis, information theory and introduction to error reduction codes.

ELECTRICAL MACHINERY (3 0 0)
Basic structure of transformators and equivalent models, electromechanical energy conversion, DC machines, synchronous and asynchronous machines, step motors and brushless DC machines.

AUTOMATIC CONTROL (3 0 0)
Models of physical systems, signal flow diagrams, state diagrams, state equivalents and transmission equivalents, controllable and observable, time response analysis, transient and steady state response and errors, stability and using methods for determine the stability; Routh-Hurwitz criterion, root-locus curve, Nyquist criterion and Bode diagrams.

MICROWAVE CIRCUITS ELEMENTS (3 0 0)
Basic properties of microwave passive elements, three or four gates microwave circuits, power dividers, directional couples, hybrids, attenuators, microwave filters, ferrite elements, semiconductor microwave elements, microwave tubes.

VII. SEMESTER
MOBILE COMMUNICATION SYSTEMS (3 0 0)
Principles of cellular communication, channel traffic, types of interference, way losses, Rayleigh, Log-normal, Rice type damps, damping channel, channel parameters and relation between them, types of damping, frequency selector and straight damping, dispertion in time and frequency, channel reach methods, channel allocation methods, diversite, diversite connect, cell planning, signal design, 2-G and 3-G cellular communication systems.

COMMUNICATION NETWORKS (3 0 0)
ISO-OSI model, media reaching bottom layer, ALOHA and local network protocols, IEEE 802.2 and Ethernet, data link layer, error detection and reduction, data link protocols, to direct, links between networks, transport layer, internet and internet tools.

ANTENNAS AND PROPAGATION (3 0 0)
Equivalent principle and radiation from aperture, far area calculation by two dimensional Fourier transformation, wire antennas and arrays, special wire antennas, self and mutual impedance, efficiency, radiation from transmission pipes, microstrip antennas and arrays, industrial and canonical horn antennas, parabolic reflector antennas, propagation; surface waves, troposphere waves, ionosphere waves.

MICROWAVE ELECTRONICS (3 0 0)
Microwave circuit theory, microwave diodes, PINN diode, Gunn and IMPATT, Schottky Barrier diodes, microwave transistors and MESFET, microwave amplifiers, mixers and oscillators, noise in amplifiers, power amplifiers, stripline and microstrips, microwave integrated circuits.
LINEAR SYSTEM THEORY (3 0 0)
State-space analysis digital control systems, state equations, canonic forms, similarity transformations, controllability and observability analysis, compensator, controller and observer design.

OPTOELECTRONICS (3 0 0)
Properties of light and parameters, LEDs, structures of lasers, working principles, characteristics and parameters, photo resistors, photodiodes, phototransistors, phototriacs, phototristors, characteristics, parameters, working principles and their structures, photo transmitter circuits and their analysis, photo receiver circuits and their analysis, optocouples, types of optocouples, optocouples with photo resistor, photodiode, phototransistor, phototriacs, phototristors, structures, working principles, characteristics and parameters, circuits with optocouplers and their circuit analysis, optic elements; lenses, reflectors, filters, fiber optic connections.

INTEGRATED COMMUNICATION NETWORKS (3 0 0)
Integrated communication networks with wide band; general information, LAN, MAN, WAN, SDH, ISDN, handshaking and signalization systems, transmission medias with wide band; copper conductor symmetric and coaxial cables, optic fiber cables, narrow band ISDN, wide band ISDN services; standards, protocols, asynchronous transfer mode (ATM), and synchronous digital hierarchy (SDH).

HIGH FREQUENCY ELECTRONICS (3 0 0)
Couple circuits, high frequency equivalent circuits of the transistors, amplitude modulated radio circuits, mixers, detectors, FM radio circuits, digital high frequency modulation and demodulation circuits, noise and interference in high frequency circuits.

SIGNAL PROCESSING APPLICATIONS (3 0 0)
Introduction to matlab, definition of matrices and vectors, visualize graphs, time domain signals and their applications, sampling applications, passing to frequency domain, FFT, STFT and WT applications.

OPTIMISATION METHODS IN ENGINEERING (3 0 0)
Definite basic mathematical principles about functions, convexity state and convex functions, no constrain minimization problems, Newton and half Newton, numeric algorithms like orthogonal projection method, constrain minimization problems, and Kuhn-Tucker theory, linear optimization and basics of single directional algorithms.

MICROWAVE LAB (2 0 2)
Determining Kylistron characteristics, microwave frequency and fixed wave measurements, impedance measurements, microwave power measurements, passive microwave elements characteristics, network analyzer measurements, Doppler radar, antenna measurements.

DIGITAL IMAGE PROCESSING (3 0 0)
Basics of two dimensional systems, sampling and quantization of images, multidimensional transformations; discrete Fourier, sinus, cosines, Hadamard, Walsh, KL. Image models, image correction, image filtering and repairing, image analysis and view in computer, image compression.

COMPUTER AIDED CONTROL DESIGN (2 0 2)
Definition of controller models, design of phase lead, phase lag, pole-zero erased and PID type controllers in time domain, frequency domain definitions and controllers frequency domain designs.

INDUSTRIAL AUTOMATION (3 0 0)
Basic PLC structure, PLC programming techniques, functions programming, timing and counting processes, program directing commands and structural programming, PLC interrupt process resources and their usages, mathematical processes, master slave communication, scada systems, projects and applications.

DIGITAL ELECTRONIC CIRCUITS (3 0 0)
Properties of digital circuits and signals, usage diodes by switching, bipolar transistors work in switching regime and usage as a switch, bipolar transitory digital circuits, MOS transistor switches and digital circuits, digital circuits, flip-flops, oscillators, memories, isolated digital circuits, auxiliary circuits.

ADVANCED PROGRAMMING (3 0 0)
Different script programming languages; Perl, java script, cgi…; object oriented programming systems, developing application in C++, and java programming languages, software systems, component -based software; COM, CORBA, .NET.

OPERATING SYSTEMS (3 0 0)
Process concept in computer, process management, synchronous process, memory management, interrupts, input-output and device management, file management, distributed operating systems, synchronous in distributed systems, distributed file systems, current operating systems (OS2,UNIX, LINUX, etc.)

VIII. SEMESTER
SIGNAL PROCESSING IN COMMUNICATION SYSTEMS (3 0 0)
Base band data transmission, source coding, channel equalization, carrier and symbol synchronous, prevent echo and noise, smart antennas, MIMO systems, space-time block coding, interference damping.

RADAR TECHNIQUES (3 0 0)
Properties of signals used in radars, radar and system properties, radar cross section, propagation, radar equation, continuous wave radars, moving target radars, following radars, virtual aperture radars and applications.

DATA COMMUNICATIONS (3 0 0 )
Basics of data communication, data transmission medias, base band and band pass data transmission, modems, data networks and architectures, internet and intranet, midlines and protocols, quality elements in data communication; security, handling, continuity.

SATTELITE COMMUNICATION SYSTEMS (3 0 0)
Basic structure of satellite communication systems, types of satellites and sub systems, transponder, analysis of satellite links, multiplexers, modulation and multi reachable techniques, design of earth stations, link radiation properties, design of fixed and moving satellite communication systems.

OPTICAL COMMUNICATION SYSTEMS (3 0 0)
Media and media's spectrum, optical elements, photo transmitters, analysis of photo transmitter circuits, photo receivers, analysis of photo receiver circuits, optical signals, noise, transmitter-receiver systems.

DESIGN OF ANALOG INTEGRATED CIRCUIT (3 0 0)
Basics of analog integrated circuits design, working in linear regime JFET and MOS circuits, operational amplifiers, analysis of analog circuits, applications of analog circuits.

INDUSTRIAL ELECTRONICS (3 0 0)
Usage elements in industrial applications, structures, characteristics, parameters and applications, power sources, transformers, amplifiers, measurement devices, invertors, controlled bridge circuits, application examples of electronic circuits, sensors and link systems.

BIOMEDICAL SIGNAL PROCESSING (3 0 0)
Nonlinear dynamic time series, dynamic system series, phase space, attractor, Lyapunov exponentials, fractal dimension, Grassberger-Procaccia algorithm; modeling the biomedical signal and systems, nonlinear ARMA models, orthogonal minimum square method, singular value decomposition; modeling Cardiovascular system, nonlinear estimation and ECG signal processing, nonlinear estimation and EEG signal processing, nonlinear behaviors in blood pressure control.

LINEAR SYSTEM APPLICATIONS (3 0 0)
State space representations of digital control systems comparison with classical methods, stability analysis in linear systems, pole localization, observer types and design methods, parallel and cascade realizations, servo systems.

MICROWAVE SYSTEMS (3 0 0)
Microwave communication systems, cordless microwave systems, satellite systems, noise in microwave systems, antennas for cordless systems, radar and remote sensing systems, radiometer systems, microwave measurement systems, microwaves biological and industrial applications.

MICROWAVE HEATING TECHNIQUES (3 0 0)
Heat energy and heat transfer, heating principles with microwave, mathematical formulation of microwave heating, modeling of heat profile in microwave heating.

ELECTROMAGNETIC COMPABILITY (3 0 0)
EMC requirements of electronic systems, low frequency circuit models, high frequency and wideband interaction models, cover models, EMC system design, measuring EMI, EMC and EMI for electronic systems.

DIGITAL CONTOL SYSTEMS (3 0 0)
Time and frequency domain analysis in discrete time plane, designing controller in discrete time domain, noise analysis for realization of a controller which consist of from finite word length in electronically structure, designing a controller which minimizes affection of noise and corruptions.

INFORMATION ENGINEERING (3 0 0)
Representations of information, predicate logic productive systems, frames, semantic networks, rule based systems, uncertain information representations, used programming languages for representing information.

GRAPHICS IN COMPUTER (3 0 0)
Graphical hardware, 2D graphic plotting algorithms, 2D and 3D geometric transformations, 3D see and perspective, introduction to OpenGL; modeling layer, lighting, shadowing and color models.

DATA STRUCTURE (3 0 0)
Algorithm analysis, single directional and bidirectional list structure, stack and queue structure, tree structure and hash tables, graph structure, analyzing and realizing algorithms for ordering, searching, string process, geometric applications, graph process and matrix processes examples.

INDUSTRIAL ELECTRONICS LAB. (2 0 2)
Analyzing the optic sensors, capacitive sensors, inductive sensors. DC motor control circuit, bipolar step motor circuit, unipolar step motor circuit, circuits with tristor and triac, circuits with MOSFET and IGBT, driver circuits analysis.

TELECOMMUNICATION LAB (2 0 2)
Carrier double side band/ double side band/ single side band amplitude modulation/ demodulation, stereo/mono frequency modulation/demodulation, automatic efficiency control, automatic frequency control, sampling, time divided multiplexer, digital wave formats, digital modulation.

GRADUATE PROGRAMS
Master of Science
Philsophy of Doctorate

GRADUATE CURRICULUM

MSc PROGRAM

Code Course Credits Total Credit
T U L
Scientific Newness 1 0 0 0
Source Research and Presentation 1 0 0 0
ELE 901 Advanced Engineering Mathematics 3 0 0 3
ELE 923 Information Theory 3 0 0 3
ELE 941 Signal processing Techniques 3 0 0 3
MSc Preparation Seminar 2
MSc Thesis Seminar 4
MSc Special Topics 3 0 0 0
Elective Major Courses ( 3 Adet ) 3 0 0 3*3 = 9
Elective Minor Courses ( 2 adet ) 3 0 0 2*3 = 6
Thesis 30
TOTAL 60

PhD PROGRAM

Code Courses Credit Total Credit
T U L
Scientific Newness 1 0 0 0
Source Research and Presentation 1 0 0 0
Growth and Learn 3 0 0 0
Planning and Grading in Education 3 2 0 0
PhD Preparation Seminar 2
PhDThesis Seminar 4
PhD Special Topics 3 0 0 0
Elective Major Courses ( 6 Adet ) 3 0 0 3 * 6 = 18
Elective Minor Courses ( 2 adet ) 3 0 0 2 * 3 = 6
Thesis 30
TOTAL 60

Elective Courses

CODE CORSE NAME CREDITS
ELE911 Elctromagnetic Waves 3-0-0
ELE912 Microwave Techniques 3-0-0
ELE913 Microwave Circuits 3-0-0
ELE916 RF Circuits and Systems Analyses and Design 3-0-0
ELE917 Microwave System Engineering 3-0-0
ELE918 Radar Systems 3-0-0
ELE925 Electromagnetic Wave Guides 3-0-0
ELE926 Microwave Circuits Computer Aided Designs 3-0-0
ELE934 Numerical Methods in Electromagnetics 3-0-0
ELE964 Radiation in Electromagnetics 3-0-0
ELE965 Antenna Theory 3-0-0
ELE914 Optoelectronics Systems 3-0-0
ELE952 Artificial neural Networks 3-0-0
ELE953 Engineering Applications of Fuzzy and Neural Technologies 3-0-0
ELE954 Fuzzy Set and Systems 3-0-0
ELE955 Information Systems 3-0-0
ELE956 Genetic Algorithms 3-0-0
ELE961 System Identification Methods 3-0-0
ELE962 Adaptive Control 3-0-0
ELE963 Optimum Control 3-0-0
ELE968 Artificial Intelligence and Expert Systems 3-0-0
ELE970 Developed Microprocessors 3-0-0

DESCRIPTION OF GRADUATE COURSES

ELEKTROMAGNETİC WAVES (3 0 0)
Maxwell equations and constitutive relations, conservation theorem, boundary conditions, time harmonic fields, complex Poynting theorem, electrical properties of medium, wave equation and solution, wave propagation and polarization, reflection and transmission, wave solutions for different medium, electromagnetic theorems, guided waves, surface waves.

MİKROWAVE TECHNIQUES(3 0 0)
Transmission line theory, rectangular and circular waveguides, dielectric waveguides, resonators, planar microwave circuits, microwave network analysis, impedance and admittance parameters, scattering parameters, S parameters measurement and network analyzer, impedance matching, passive microwave circuit analysis and design dividers, directional structures, microwave filters, analysis of ferrite media and devices, microwave tubes.

MICROWAVE CIRCUITS (3 0 0)
General properties of linear and non linear microwave and milimeterwave devices and circuits, Schottky-Barrier diode, tunnel diode, Gunn diode, IMPATT diode, transferred electron devices, microwave bipolar junction transistor, heterojunction bipolar transistor, GaAs microwave field effect transistors, JFET, MESFET, HEMT, microwave amplicators, low noise microwave amplicators, wide band microwave amplicators, microwave oscillators, mixer and multiplier circuits, detectors, microwave integrated circuits.

ANALYSIS AND DESIGN OF RF CIRCUITS AND SYSTEMS (3 0 0)
Introduction to RF and wireless technologies, basic concepts in RF design, design with S parameters, transmitter-receiver structures, image reject receivers, direct conversion transmitters, two step transmitters, bipolar and CMOS low noise amplicators, bipolar and CMOS mixers, basic LC oscillators, voltage controlled oscillators, bipolar and CMOS LC oscillators, phase locked loop circuits, RF synthesizer architecture, frequency dividers, power amplicators.

MICROWAVE SYSTEM ENGINEERING (3 0 0)
RF and MW propagation principles, transmission media, RF and microwave antennas, channel modeling in microwave links, link analysis and design, general structure of microwave communication systems, noise and modulation methods transmitter and receiver structure, wireless communication, satellite communication, remote sensing, radar, electronic warfare, microwave measurement methods, microwave heating.

RADAR SYSTEMS
Analysis and design of radar systems, radar equation and system parameters, CW and FM radars, MTI and pulse Doppler radars, radar system components, radar cross section and target characteristics radar signal processing methods, signal detection from background, resolution, clutter rejection, pulse compression, SAR, target tracking and scanning radars, HF (OTH) radars.

COMPUTATIONAL METHODS IN ELECTROMAGNETICS (3 0 0)
Electromagnetic equations and medium properties, classification of electromagnetic problems and general solution methods, moment method, time domain finite difference method, scalar and vectoral finite elements method, time domain finite elements method, absorber boundary conditions, applications in different electromagnetic problems.

ELECTROMAGNETIC WAVEGUIDES (3 0 0)
Green function formulations, conducted cross sectioned uniform waveguides, open waveguides, non uniform waveguides, dispersive and nonlinear factors, discontinuity modeling in waveguides, numerical solution methods and examples to distributed parameter circuit equivalent coupled waveguides, periodical structures in waveguides, optical waveguides.

COMPUTER AIDED DESIGN OF MICROWAVE CIRCUITS
Noise, linear and nonlinear characteristics of active microwave devices, equivalent circuit models, physical models, computer aided design, principles of microwave circuits, matrix representation of microwave circuits, computer aided design and optimization techniques of amplificators, oscillators and mixers in microwave frequencies

HIGH SPEED OPTICAL FIBER COMMUNICATION SYSTEMS (3 0 0)
Optical fiber LANs (FFOL, Gigabit Ethernet etc.), longdistance communication systems-International, undersea, and intercontinental systems, WDM and DWDM systems, coherent systems, factors negatively effecting data transmission speed in high speed communication systems-chromatic dispersion, polarization mode dispersion.
OPTICAL FIBER COMMUNICATION SYSTEMS (3 0 0)
Optical fiber wave guides-total internal reflection, numerical aperture, reflective index, electromagnetic waves, single mode and multimode fibers, transmission properties of optical fibers-transmission losses, material losses, linear and nonlinear scattering losses, material and intermodal dispersion, mode field diameter and cut off wavelength, modal noise and polarization, optical fiber materials and production technologies-halogen glass, crystals and plastics, MCVD, OVD, VAD production techniques, transmission parameters measurement and evaluation, optical transmitter and receivers, optical fiber communication systems architectures.
ADVANCED ENGINEERING MATHEMATICS (3 0 0)
Introduction to Linear Algebra and matrix applications, solution method of linear and algebraic systems, introduction to complex variables contour integral and residue theorem, Fourier and Laplace Transforms.

ADVANCED DIGITAL SIGNAL PROCESSING (3 0 0)
Analysis of linear time invariant system characteristics with impulse response, transfer functions difference equations, z transform and Fourier Analysis, discrete Fourier Transform and fast algorithms, finite and infinite impulse response filter design, frequency transform, analysis of filters based on least squares method.

RANDOM SIGNAL ANALYSIS (3 0 0)
Review of probability theory, convergence and probability boundaries, multi-variable normal theory, sequences of random variables and random processes, Bernoulli and Poisson processes, wide sense stationary processes, correlation function and power spectrum, random input linear systems, Gauss-Markov processes, first and second degree properties of ARMA processes and Markov Chains.

NEURAL NETWORKS (3 0 0)
Principles of Graph theory, Petry networks, Petry network applications, training algorithms of neural networks, back propagation algorithm, fuzzy neural networks, application areas of neural networks.

APPLICATIONS OF FUZZY AND NEURAL TECHNOLOGIES IN ENGINEERING
Basic concepts of fuzzy sets theory, neural networks, fuzzy rule base systems, neural fuzzy systems, applications of neural fuzzy systems in classification, applications of fuzzy neural systems in classification, max-min neural networks and applications.
FUZZY SETS AND SYSTEMS
Basic concepts of fuzzy set theory, fuzzy binary relations and fuzzy numbers, fuzzy rule base, fuzzy controllers, fuzzy classification, fuzzy data base management systems,
dynamic and linear programming in fuzzy medium.

ARTIFICIAL INTELLIGENT AND EXPERT SYSTEMS
Information engineering fundamentals, predicates logic, if-then fuzzy informations, semantic networks, design and applications of expert systems.

OPTOELECTRONIC SYSTEMS (3 0 0)
Light, spectrum and wavelength concepts; devices forming optoelectronic systems; light emitters and photodetectors; structure, working principles and characteristics of light emitters and photodetectors, optic devices; light modulation and demodulation; optoelectronic systems types: optoelectronic systems including passive and active light emitters; single wave, double wave and multiple wave optoelectronic systems; single light emitter-single photodetector optoelectronic systems, single light emitter-multiple photodetector optoelectronic systems, multiple light emitter-single photodetector optoelectronic systems, multiple light emitter-multiple photodetectors optoelectronic systems, optoelectronic system analysis.

INFORMATION BASED SYSTEMS (3 0 0)
General problem solving techniques, information based system structure, logical and automatic result derivation, rule based systems, Rete algorithm, network frame and express the information in terms of objects, blackboard architecture, constraint satisfaction, model base qualitative, case-based reasoning.

ADVANCED MICROPROCESSORS (3 0 0)
Architectures of Intel processors (8086, ...., Pentium), analysis of command structures, micro assembler usage and programming, analysis of interrupt operations, protected mode structure, paging, cache memory access methods, computer architecture, analysis of bus structures and access to peripherals.

SIGNAL PROCESSING TECHNIQUES (3 0 0)
Orthogonal vector and signal spaces, orthogonal transform techniques, matrix form, transfıorm and inverse transform matrices of discrete Fourier Transform, fast Fourier Transform, fast Fourier Transform algorithm, wavelet transform, matrix form transform and inverse transform, matrices of wavelet transform, stationary stochastic process, AR, MA, ARMA stochastic signals, Wiener filter theory, linear prediction, gradient vector estimation and adaptive filters, LMS algorithm, Kalman filter theory, RLS algorithm, nonlinear adaptive filtering methods, Volterra filters.

PATTERN RECOGNITION (3 0 0)
Bayes decision theory, supervised learning and parameter estimation, maximum likelihood estimation, Bayed classifier, Bayes learning rule, geometrical classification rules, unsupervised learning, unsupervised learning rule, applications, classification and recognition of handwriting characters, fingerprint classification and recognition of speech classification and recognition.

ADVANCED TOPICS IN COMMUNICATION (3 0 0)
Channel equalization, continuous phase modulation, multiple carrier modulation methods, spread spectrum technique and interference cancellation, statistical representation of fading channels, transmitter and receiver diversity techniques, space time coding methods and interference cancellation, turbo and space time turbo coding, adaptive antennas.

DIGITAL COMMUNICATION THEORY (3 0 0)
Random processes, band-pass signal representation, binary and M-ary modulation techniques, PSK, PAM, FSK orthogonal signals, biorthogonal signals and their performances under AWGN channel noise, hard-decision and soft decision decoding for coded signals, performances of coded signals under AWG channel noise.
INFORMATION THEORY (3 0 0)
Information measurement, entropy, conditional entropy, mutul information, prefix, Huffmann and Lempel-Ziv codes, discrete memoryless source and channels, capacity, definition and computation channel coding theorem and its importance, diferential entropy, discrete time Gauss channels and capacity, channel capacity under white and colored noise, error correcting codes, black codes, convolution codes, Trellis codes, ML and MAP decoding.

MOBILE COMMUNICATION SYSTEMS (3 0 0)
Mobile radio medium and definition, channel types, system functions, WSSUS channels, mobile radio signal representations, fading reasons and types, short and long term fading, diversity techniques, interference types, coherence bandwidth, frequency planning and channel access, FDMA, TDMA, CDMA, modulation methods, base and mobile stations des,gn parameters, cell planning, MIMO systems, GSM, WCDMA,UMTS.

SYNTHESIS AND ANALYSIS OF SPEECH SIGNALS (3 0 0)
Numerical models for speech signals, acoustic phonetics, short trem Fourier Analysis, cepstrum analysis, format and pitch estimation, LPC analysis, speaker verification and identification methods, speech recognition methods.

STATE SPACE AND LINEAR SYSTEM THEORY
State space definition, methods used to obtain state equations, matric theory, matrix analysis, solution of linear state equations, controllability, observability, conanical forms of state equations, stability of linear systems.

GENETIC ALGORITHMS (3 0 0)
Operation of genetic algorithms, mathematical fundamentals, development of basic techniques in genetic algorithms, alternative selection schemes, scaling mechanisms, computer applications.

SYSTEM IDENTIFICATION METHODS (3 0 0)
Classical methods; step response method, frequency response method, correlation method and convolution method, modern methods; least squares method, instrumental variables method, maximum likelihood method, online and offline applications of these methods, identification of continuous time models.

ADAPTIVE CONTROL (3 0 0)
Lyapunov stability analysis, model reference adaptive control; MIT rule, Lypunov (stability) based adaptive control, passivity theorem and passivity based adaptive control. Self tuning control; implicit and explicit methods.

OPTIMUM CONTROL
Representation of systems as operators between input-output Hilbert spaces, Adjoint operator, definition of quadratic cost function and obtaining the optimum input, matrix Riccati and Wiener Hopf solutions, optimum controller design in time and frequency domain..

DATA COMPRESSION
Introduction to information theory, lossless coding, arithmetical coding, dictionary methods, LZ77, LZ78 lossy coding, scalar quantization, vectoral quantization, predictive coding, transform based coding, sub band coding, introduction to video coding.

ANTENNA THEORY (3 0 0)
Maxwell equations, equivalency and reciprocity principles, vector potentials and Hertz vectors, plain wave approximation and local plain waves, integral solution of Helmholtz equation and radiation condition, current distribution method, aperture method, solution of vectoral Helmholtz equation with Fourier Transform, radiation from wired antenna arrays, radiation from aperture antennas, radiation from micro strip antennas.

ELECTROMAGNETIC SCATTERING (3 0 0)
Maxwell equations, vector potentials and Hertz vector, Green functions, reciprocity principle, high and low frequency approximations, asymptotical methods; geometrical optics, physical optics, model expansions, integral equations, geometrical theory of diffraction, physical theory of diffraction scattering from conductors, radar equation and radar cross section area, inverse scattering problem.

DEPARTMENT OF ENVIRONMENTAL ENGINEERING
" PROFESSORS
" ASSOCIATE PROFESSORS
" ASSISTANT PROFESSORS
" INSTRUCTORS
" GENERAL INFORMATION
" VISSION AND MISSION OF THE DEPARTMENT
" PROGRAM OBJECTIVES
" RESEARCH INTERESTS AND FACILITIES
- UNIT OPERATIONS LABORATORY
- ENVIRONMENTALCHEMISTRY AND STUDENT EXPERIMENT LABORATORY
- ENVIRONMENTAL MICROBIOLOGY LABORATORY
- AIR POLLUTION CONTROL LABORATORY
- INSTRUMENTAL ANALYSIS-SOIL POLLUTION-SOLID WASTE LABORATORY
- BIOTECHNOLOGY LABORATORY
" UNDERGRADUATE CURRICULUM
" DOUBLE MAJOR PROGRAM IN ENVIRONMENTAL ENGINEERING
" MINOR PROGRAM IN ENVIRONMENTAL ENGINEERING
" GRADUATE PROGRAMS AT THE DEPARTMENT OF ENVIRONMENTAL ENGINEERING
" GRADUATE CURRICULUM
- M.S. in Environmental Engineering
- Ph.D. in Environmental Engineering
" GRADUATE COURSES
" DESCRIPTION OF GRADUATE COURSES
PROFESSORS:
BAŞKAYA, Hüseyin : B.S., A.U.; Ph.D., University of Georg-August.
PINARLI,Vedat : B.S.,İTÜ ; M.S., University of Newcastle ; Ph.D., University of Brunel.
KESTİOĞLU,Kadir : B.S., İ.U.; M.S., Ph.D., University of 9 September.
ASSOCIATE PROFESSORS:
TAŞDEMİR, Yücel : B.S., University of 9 September ; M.S., Ph.D., Illinois Institute of Technology.
ALKAN, Ufuk : B.S., University of 19 May; M.S.,Ph.D, University of Newcastle.
ASSISTANT PROFESSORS :
KARAER, Feza : B.S., METU ; MPA, Ph.D., University of Uludağ.
ELMACI, Ayşe : B.S., M.S., Ph.D., University of Ankara.
SOLMAZ, Seval : B.S., M.S., Ph.D., University of İTÜ.

INSTRUCTORS :
UÇAROĞLU, Selnur : B.S., M.s., University of 9 September; Ph.D., University of İTÜ.
ESEN, Fatma : B.S., University of 9 September; M.S., Ph.D., University of Uludağ.

GENERAL INFORMATION :
The increasing and multi-dimensional interest both in inland and abroad gave rise to the department of Environmental Engineering to be founded in the year 1991, within the body of Engineering and Architectural Faculty, to meet the environmental problems of Bursa. The laboratory building of our department, having 800 square meters field, provided education at the beginning of the 1994-1999 academic teaching year. In this building 7 laboratories are located with the aim of both educational activities and research. The department consists of two major chairs : Environmental Sciences and Environmental Technology. The undergraduate program in our curriculum is carried out by our permanent staff and some other part time staff from the other faculties, totally 3 professors, 4 associate professors, 5 assistant professors, 6 lecturers, 7 instructors and 3 other teaching personal. Now, in our department, 3 permanent professor, 2 permanent associate professor, 3 permanent assistant professors, 2 instructors and 16 research assistants are in change of the academic purpose. And from the other teaching staff of our department, 13 of them are environmental engineers or the ones having masters degree in environmental engineering; and 1 is a biologist, 1 is a chemist and another one is an expert in the soil chemistry. The undergraduate students of our department are totally 130. Since the spring term of the 1998-99 academic year, totally 78 students have graduated. In our department, post graduate study program was started in the 1994-95 academic year. At the moment, we have got 34 post graduate students and 14 student in the doctoral studies.
The Vision and Mission of the Department

VISION OF THE DEPARTMENT
The vision of environmental engineering department is to be a model department focusing on development of environmental quality, meeting the need of community and industries with education, research and serves at international levels.

MISSION OF THE DEPARTMENT
The environmental engineering department has a duty of research on specific topics about environmental subjects, educating with sustainable development, training the graduate persons who can understand and solve the problems, connected with ethic merits, renewable mind, working with group, being leadership and serving in environmental subjects.
PROGRAM OBJECTIVES :

Environmental Engineering Department Educational Aims
1) To obtain knowledge and comprehension about profession, to provide the combining of preceding and new knowledge and to obtain environment conscious
2) To obtain research capability about profession
3) To define the characteristics of receiving environments and pollutants, to know probable effects to environment, to research the studies done in world, in country and in the city
4) To evaluate the engineering practices due to environmental effects and to obtain a sense about working with group as systematic and multidisciplinary
5) To give knowledge about national and international environmental law
6) To determine and formulise the environmental engineering problems and to obtain engineering formation
7) To gain knowledge and practice of basic analysis about environmental engineering laboratory studies and related models.
8) To arrange and interpret the data collected from environmental projects, to research project criteria and alternatives, to calculate the project cost, to select applicable processes
9) To practice and evaluate the theoretical knowledge with technical tours and internships, to see, fix and propose solving alternatives about the problems caused by construction and operation
10) To obtain synthesis capability at every problems related environment

Knowledge and skills
on environmental area that should be gained by a student (quality/output)
1) To obtain minimum knowledge and comprehension on environmental engineering
2) To know the basic knowledge sources and use when needed
3) To have knowledge about basic subjects such as water, air and soil
4) To seize the engineering education and developing and currency of environmental engineering
5) To have experience on laboratory studies about environmental engineering
6) To have ability to develop himself and to follow the technological newness
7) To have information about basic concepts, discussion areas and problems of related science branches
8) To take into consideration the differences and multidisciplinary properties of environmental engineering area
9) To use theoretical knowledge in practical education and solving problems
10) To have sufficient rigging about environmental engineering and communication, to arrange the data and interpret
11) To use computer software effectively
12) To have knowledge on areas related environmental engineering such as Physics, Chemistry, Mathematics, Biology, civil engineering, mechanical engineering
13) To approach objectively to different concepts and thinking
14) To gain a concept devoted to understand and solve different problems
15) To order the knowledge according to significance level
16) To see the whole situation beside details in information and ideas
17) To take new knowledge and connect with preceding
18) To show an ability on proper selections due to scientific and technological principles
19) To make projects and engineering design on environmental areas
20) To comment the modern developments according to Ataturk Principles and Revolutions
21) To response and take duty in civil and official associations
22) To make special organisations about environmental engineering
23) To have personality in professional and social areas, to be devoted to merits and peace
24) To have opinions and ideas related to ethical properties based on basic and true knowledge in profession

RESEARCH INTERESTS AND FACILITIES :
The Environmental Engineering Department, which has been established in the constitution of Engineering and Architecture Faculty in 1991 with 26 teaching staff, carries on undergraduate and graduate education to solve the environmental problems of Bursa city with increasing national and international interest in environmental issues.

Department Laboratory:

The environmental engineering department has a laboratory of 800 m2 area with full rigging in Turkey scale. The research focusing on environment, tests and studies in the scope of revolving capital are done in the laboratory.

¢ Unit Operations laboratory
¢ Instrumental analysis-Soil pollution-Solid waste laboratory
¢ Air pollution control laboratory
¢ Environmental microbiology laboratory
¢ Environmental chemistry and Student experiment laboratory
¢ Biotechnology laboratory

Research and Study Areas

A) Research Projects

¢ TUBITAK (The Scientific and Technical Research Council of Turkey) Projects
¢ University research projects
¢ Graduate research projects
¢ Industry projects

B) Practical Research Studies outside the University

¢ Water and wastewater analysis
¢ Air pollution and control measurements and report studies
¢ Solid and hazardous waste analysis
¢ Continuous or batch flow measurements, and composite sampling
¢ Soil pollution analysis
¢ Environmental microbiology analysis
¢ Domestic wastewater treatment projects
¢ Industrial wastewater treatment projects
¢ Feasibility studies of wastewater treatment plants
¢ Water pollution control projects
¢ Marine outfalls projects
¢ Air pollution control projects
¢ Treatment and disposal projects of activated sludge
¢ Optimisation of treatment plants projects
¢ Solid waste landfill projects
¢ Sewerage projects
¢ Environmental impact assessment projects

Undergraduate Course

The new course that was gradual applied since 2001 from the programme before 2000 in the department. The 1. and 2. class students have been educated according to the new course plan, 3. and 4. class students the old plan. The both plans were presented below:

UNIT OPERATIONS LABORATORY:
Making characterization of wastewater, showing base processes by applications which is using for wastewater treatment, making the studies of wastewater treability, settling down the pilot models of wastewater teratment foundation and operating. ÇEV 3001 Making characterization of wastewater, showing base processes by applications which is using for wastewater treatment, making the studies of wastewater treability, settling down the pilot models of wastewater teratment foundation and operating. ÇEV 3002
ENVIRONMENTALCHEMISTRY AND STUDENT EXPERIMENT LABORATORY:
Determining the important chemical and physiological parametres in drinking water and wastewater samples in environmental engineering, ÇEV 2017,ÇEV 2018
MICROBIOLOGY LABORATORY:
Continuining the laboratory of Environmental Engineering Microbiology lesson, making the microbiological analysis of water and treatment sludges, supporting the project concerning biologic treatment and drinking water.
AIR POLLUTION CONTROL LABORATORY:
Making the analysis of the samples which taking comprise Air Pollution, determining of pollutate consantration, ÇEV 4007, ÇEV 4024, ÇEV 4032
INSTRUMENTAL ANALYSIS-SOIL POLLUTION-SOLID WASTE LABORATORY: Supporting post-graudate lessons that Instramental Analysis and Water Chemistry, Soil Pollution and continuening projects cocerning solidwaste subjects.
BIOTECHNOLOGY LABORATORY:Continuining graduate and post-grautade studies and project studies concerning biological treatment of wastewater, treatment sludges and drinking water
UNDERGRADUATE CURRICULUM

TABLE: Undergraduate Courses Given by the Department
( The first number of the code designates the year of the program )
Course How Many Times a Year is the Course Given Number of Groups Average Number of Students Kind of the Course
Code Name Teoretic Lab. Practical Other*
MAT 1071 Calculus I 1 1 50 4 0 0 -
FZK 1081 Physics I 1 1 50 3 0 0 -
CEV 1031 Int. to Env. Engineering 1 1 50 2 0 0 -
CEV 1023 Technical Draving 1 1 50 1 3 0 -
CEV 1033 General Chemistry 1 1 50 2 1 0 -
CEV 1029 Env. Polution and Ecology 1 1 50 2 0 0 -
CEV 1011 Engineering Geology 1 1 45 2 0 0 -
AIT 101 Ataturk's Principler and the History of Turkish Revolution 1 1 45 2 0 0 -
TUD 101 Turkish 1 1 45 2 0 0 -
YAD 101 Foreign Language 1 1 45 2 0 0 -
YAD 111 Foreign Language (English) 1 1 - 2 0 0 -
YAD 121 Foreign Language (German) 1 1 - 2 0 0 -
MAT 1072 Calculus II 1 1 50 4 0 0 -
FZK 1082 Physics II 1 1 50 3 0 0 -
CEV 1024 Statics and Strength 1 1 45 2 1 0 -
CEV 1026 Computer -Programming 1 1 50 1 3 0 -
CEV 1030 Env. Quantitative Analyse 1 1 50 2 0 2 -
CEV 1014* Technical Drawing II 1 1 50 2 0 2 -
CEV 1010* Statics 1 1 45 3 0 0 -
AIT 102 Ataturk's Principler and the History of Turkish Revolution 1 1 45 2 0 0 -
TUD 102 Turkish 1 1 45 2 0 0 -
YAD 102 Foreign Language 1 1 45 2 0 0 -
YAD 112 Foreign Language (English) 1 1 - 2 0 0 -
YAD 122 Foreign Language (German) 1 1 - 2 0 0 -

CEV 1022 Biology of Freshwater Pollution 1 1 10 3 0 0 -
MAT 2071 Calculus III 1 1 40 4 0 0 -
CEV 2003 Materials Science 1 1 40 2 0 0 -
CEV 2005 Strength 1 1 40 3 0 0 -
CEV 2007 Fluid Mechanics 1 1 40 2 2 0 -
CEV 2009 Ecology 1 1 40 2 1 0 -
CEV 2011 Hydrology 1 1 40 2 0 0 -
CEV 2017 Environmental Chemistry I 1 1 40 2 1 2 -
CEV 2015 Microbiology for Env. and Public Health Eng. 1 1 10 3 0 0 -
MAT 2072 Calculus IV 1 1 35 4 0 0 -
CEV 2004 Hyrolics 1 1 45 4 2 0 -
CEV 2006 Dynamics 1 1 35 2 0 0 -
CEV 2008 Env. Eng. Microbiology 1 1 35 2 0 2 -
CEV 2010 Surveying Knowledge 1 1 40 2 0 1 -
CEV 2010 U Appl. of Surveying Knowledge 1 1 40 0 0 0 2 weeks*
CEV 2018 Environmental Chemistry II 1 1 40 2 1 2 -
CEV 2016 Environmental Toxicology and Chemistry 1 1 10 3 0 0 -
CEV 3001 Unit Operations and Processes I 1 1 35 2 2 0 -
CEV 3003 Water Pollution Control 1 1 30 3 0 0 -
CEV 3005 Structure Technology I 1 1 35 4 0 0 -
CEV 3007 Water Supply 1 1 40 4 2 0 -
CEV 3009 Env. Eng. Biochemical Processes 1 1 35 2 2 0 -
CEV 3011 Environmental Economics 1 1 40 1 2 0 -
CEV 3017 Principles of Water Quality Control 1 1 10 3 0 0 -
*2 weeks field study
TABLE-Continue: Undergraduate Courses Given by the Department

Course How Many Times a Year is the Course Given Number of Groups Average Number of Students Kind of the Course
Code Name Teoretic Lab. Practical Other*
CEV 3002 Unit Operations and Processes II 1 1 30 2 2 0 -
CEV 3004 Sea Outfalls 1 1 30 2 2 0 -
CEV 3006 Drink,ng Water Treatment 1 1 35 2 2 0 -
CEV 3008 Environemental Thermodynamics 1 1 35 2 2 0 -
CEV 3010 Structure Technology II 1 1 40 3 0 0 -
CEV 3012 Sewerage Systems 1 1 40 2 3 0 -
CEV 3014 Base and Foundation in the Infrastructure 1 1 35 2 1 0 -
CEV 3018 Water Supply and Wastewater Disposal 1 1 10 3 0 0 -
CEV 4001 Waste Water Treatment I 1 1 30 4 2 0 -
CEV 4003 Solid Wastes 1 1 30 3 1 0 -
CEV 4005 Environmental Modelling 1 1 30 2 0 0 -
CEV 4007 Air Pollution 1 1 30 3 1 0 -
CEV 4009 Environmental Impact Assesement 1 1 30 2 0 0 -
CEV 4017 Air Pollution Science 1 1 10 3 0 0 -
CEV 4013 Measurement and Automatic Control 1 1 30 2 0 0 -
CEV 4015 Sludge Treatment and Disposal 1 1 30 2 0 0 -
CEV 4002 Waste Water Treatment II 1 1 30 3 1 0 -
CEV 4004 Management and Operation of Water Works 1 1 30 2 1 0 -
CEV 4008 Environmental-Soil Relation 1 1 30 2 2 0 -
CEV 4006 Graduation Project 1 1 20 0 4 0 -
CEV 4034 Air Pollution Design 1 1 10 3 0 0 -
CEV 4016 Anaerobşc Treatment 1 1 10 2 0 0 -
CEV 4018 Treatment Plant Design 1 1 10 2 0 0 -
CEV 4020 Environmental Law 1 1 10 2 0 0 -

CEV 4022 Statistics 1 1 10 2 0 0 -
CEV 4024 Control technşcs of Air Pollution 1 1 10 2 0 0 -
CEV 4032 Measurement Technics of Air Pollutants 1 1 10 2 0 0 -

DOUBLE MAJOR PROGRAM IN ENVIRONMENTAL ENGINEERING :
The quotas for the double major program in Environmental Engineering
in 2003-2004 Academic Year

Faculty : Faculty of Engineering and Architecture
Department : Environmental Engineering
Program : Double Major Program
The semester of the program : 2003-2004 Academic Year Autumn and Spring Semester
Quotas : 3

The provisions of request and acceptance for the double Major Program
in Environmental Engineering

1.) The students of Uludag University Faculty of Engineering and Architecture Department of Mechanical Engineering, Textile Engineering and Industrial Engineering can apply for the double major program in Environmental Engineering.

2.) The apply for the double major program is accepted in registration time for the credit system undergraduate courses in every semester.

3.) The student wanted to join the double major program applies to Student labours unit with her/his transcript and application document within the stated dates.

4.) In order to apply the double major program, the average general grade of the student should be 3.00.

5.) The student can apply the double major program between III. Semester (the earliest time) and the V. Semester (the latest time) of undergraduate program which she/he had registered.

6.) If the number of the students who applied the double major program is over the stated quotas, the acceptance of the student will be done according to the average general grades of the students in major undergraduate program. If there is an indefiniteness again, an election examination will be carried out.

7.) The student who applied the double mojor program must take the courses which are arrenged according to major undergraduate program that the student had registered and which are defined in curriculum of double major program.

8.) The student who applied the double mojor program must accept the principles of Uludag University Double Major Program Directive.

CURRICULUM FOR THE DOUBLE MAJOR PROGRAM

Environmental Engineering Credit Mechanic.
Eng. Textile Eng. Indust.
Eng.
II. Semester
CEV 1030 Environ. Quan. Analysis 3 -- + +

III. Semester
CEV 2025 Environmental Eng. Chemistry I 3 -- + +
CEV 2033 Fluid Mechanics 2,5 -- -- +

IV. Semester
CEV 2024 Hydraulics 3 -- -- +
CEV 2026 Environmental Eng. Chemistry II 3 -- + +
CEV 2030 Microbiology of Environ. Eng. 3 -- + --

V. Semester
CEV 3001 Unit Operations and Processes I 3 -- + +
CEV 3003 Water Pollution Control 3 + + +
CEV 3007 Water Supply 5 + -- --
CEV 3011 Environmental Economics 2 + + +
CEV 3009 Env. Eng. Biochem. Processes 3 + + --

VI.Semester
CEV 3002 Unit Operations and Processes II 3 + + +
CEV 3006 Drinking Water Treatment 3 + -- --
CEV 3004 Marine Outfall Systems 3 -- -- --
CEV 3012 Sewerage Systems 4,5 + -- --

VII. Semester
CEV 4001 Wastewater Treatment I 5 + + --
CEV 4003 Solid Wastes 3,5 + + +
CEV 4007 Air Pollution 3,5 + -- +
CEV 4009 Env. Impact Assesment 2 + + +
CEV 4005 Environmental Modelling 2 + + +

VIII. Semester
CEV 4002 Wastewater Treatment I 3,5 + + +
CEV 4004 Op. and Econ. Of WW Treat. Plants 2,5 + + +
CEV 4006 Graduation Project 2 + + +

TOTAL CREDITS 47,5 46,5 44,5

MINOR PROGRAM IN ENVIRONMENTAL ENGINEERING
The quotas for the Minor Program in Environmental Engineering
in 2003-2004 Academic Year

Faculty : Faculty of Engineering and Architecture
Department : Environmental Engineering
Program : Double Major Program
The semester of the program : 2003-2004 Academic Year Autumn and Spring Semester
Quotas : 5

The provisions of request and acceptance for the Minor Program
in Environmental Engineering

1.) The students of Uludag University Faculty of Engineering and Architecture can apply for the minor program in Environmental Engineering.

2.) The apply for the minor program is accepted within registration time for the credit system undergraduate courses in every semester.

3.) The student wanted to join the minor program applies to Student labours unit with her/his transcript and application document within the stated dates.

4.) In order to apply the minor program, the average general grade of the student should be at least 2.50.

5.) The student can apply the minor program between III. Semester (the earliest time) and the V. Semester (the latest time) of undergraduate program which she/he had registered.

6.) If the number of the students who applied the minor program is over the stated quotas, the acceptance of the student will be done according to the average general grades of the students in major undergraduate program. If there is an indefiniteness again, an election examination will be carried out.

7.) The student who applied the minor program must take the courses which are arrenged according to major undergraduate program that the student had registered and which are defined in curriculum of minor program.

8.) The student who applied the minor program must accept the principles of Uludag University Minor Program Directive.

CURRICULUM FOR THE MINOR PROGRAM

Environmental Eng. Credit Mechanic.
Eng. Textile Eng. Indust.
Eng.
II. Semester
CEV 1030 Environ. Quan. Analysis 3 -- + +

III. Semester
CEV 2025 Environmental Eng. Chem. I 3 -- + +

IV. Semester
CEV 2026 Environmental Eng. Chem. II 3 -- + +

V. Semester
CEV 3003 Water Pollution Control 3 + + +

VI.Semester
CEV 3002 Unit Operations and ProcessesII 3 + + +
CEV 3006 Drinking Water Treatment 3 + -- --

VII. Semester
CEV 4001 Wasrewater treatment I 5 + -- --
CEV 4003 Solid Wastes 3,5 -- -- +
CEV 4007 Air Pollution 3,5 + -- +
CEV 4009 Environ. Impact Assesment 2 -- -- +
CEV 4005 Environ. Modelling 2 + -- +

VIII. Semester
CEV 4002 Wasrewater treatment II 3,5 + + +

TOTAL CREDITS 23 18,5 29,5

DESCRIPTION OF UNDERGRADUATE COURSES :
I.YEAR (1.SEMESTR )

MAT 1071 DIFFERENTIAL CALCULUS
The set of reel numbers, inequalities,limits,continuity and methods of derivative, trigonometric functions, some theorems on derivation, indeterminates and L'Hospital rule, maximum, minimum and curve scetching, polar coordinates, inverse functions and inverse trigonometric function, exponential function and logarithm.

FZK 1081 PHYSICS -I
Motion in one dimension. Motion in two dimension. Newton's laws of motion. Applications of Newton's laws of motion. Newton's law of universal gravitation. Work and Energy. Conservation of energy. Momentum and the motion of systems. Rotation-I. Rotation-II. Oscillations. Solids and fluids. Temperature and heat transfer

CEV 1031 INTRODUCTION TO ENVIRONMENTAL ENGINEERING
The effects and reasons of environmental pollution, the cycles in nature, global environmental problems, the physical properties of water, water quality, eutrophication, air and its physical composition,basic principles of air quality control, soil pollution, the effects of wastes on soil, noise pollution, radioactive pollution, economical and institutional factors about the quality of environment

CEV1023 TECHNICAL DRAWING
STANDART WRITING
Drawing from 3 sight of an object.Giving dimensions of an object.Drawing cross section of an object.Drawing 3D of an object

CEV 1033 GENERAL CHEMISTRY
1.Introduction to general chemistry 2. The Atomic Hypotesis,3.Chemical Bonds,4. Molecular Geometry,5. Chemical Equilibruim,6. Gases,7.Liquids and Solids,8. Oxygen and Hydrogen,9. Solutions, 10. Electro chemistry,11. Ph Calculation, 12. Ametal

ÇEV - 1029 ENVIRONMENTAL POLLUTION AND ECOLOGY
Introduction to ecology, The chronological change of the earth and their effects on species existence, the basic theories and principles in ecology, Abiotic factors and their effects on organisms, Biotic factors, Population and its structural characteristics, Population dynamics, community and its characteristics, ecosystem and its characteristics, The major ecosystems of the world and their distributions, The ecological problems of humanity, The protection of nature, Environmental protection and the new concepts in the organization

I.YEAR (2.SEMESTR)

MAT 1072 INTEGRAL CALCULUS
Definite integral, fundemental theorems of integral, indefinite integral and its properties, techniques of integration, improper integrals,applications of definite integral, area and volume calculus,length of curves, surface of revolution, area in polarcoordinates, Taylor's Formula, The binomial expansion, squence, series, power series

FZK 1082 PHYSICS - II
Coulomb's law and the electric field. Gauss's law. Electric potential. Capacitance, electric energy, and properties of insulators. Current and resistance. Energy and current in DC circuits. The magnetic field. Sources of the magnetic field. Faraday's law. Inductance. Magnetic fields in matter. Electromagnetic oscillations and AC circuits

CEV 1024 STATICS- STRENGTH OF MATERIALS
Basic definitions and concepts, equilibrium of a rigid body, structural analysis, center of gravity, moments of inertia, shearing force and bending moment diagrams, friction, substances on strength of materials, subjected forces to materials, some principals on strength of metarials (principal of become hard, principal of separate, principal of saint-venant, principal of first degree, principal of superposition), stress and types of stress, the tensile tests and Hooke's Law, stress of safety and factor of safety, effect of weight on stress and strain, bars of equal stress, systems of hiperstatics on tensile and pressure, temperature stresses, general Hooke's Law, rate of strain volume, Hooke's Law at simple shearing and shear mudulus, relationship between modulus of elasticity (E), shearing modulus (G) and poisson's ratio ( ), thin cylinders, mohr's circle of stress, bending. Slope and deflection of beams (definition of problem, differantial equation for deflection of elastic beams, direct integration method, moment-area method, conjugate bar method, superposition method), buckling (failure criteria, higher buckling loads), thick columns, torsion.

CEV 1026 COMPUTER -PROGRAMMING