01_Engineering Faculty Introduction_08 Mart 08+

2007

2008

Fatih University

Engineering Faculty

Undergraduate Catalogue www.eng.fatih.edu.tr

INDEX

INDEX……………………………………………………………………………………………………………. 1

WELCOME MESSAFE FROM DEAN, Mazhar ÜNSAL, Professor 3

COMPUTER ENGINEERING DEPARTMENT 4

Welcome Message From Chairman, Bekir KARLIK, Professor…………………………………………….. 4

Teaching Staff……………………………………………………………………………………………………. 5

Laboratories of Department………………………………………………………………………………………. 7

Undergraduate Curriculum……………………………………………………………………………………….. 9

Table of Technical Electives……………………………………………………………………………………... 10

Prerequisite Table………………………………………………………………………………………………… 12

Equivalence Table………………………………………………………………………………………………... 13

Double Major…………………………………………………………………………………………………….. 14

Minor Program…………………………………………………………………………………………………… 15

Course Descriptions……………………………………………………………………………………………… 16

ELECTRICAL-ELECTRONICS ENGINEERING DEPARTMENT 23

Welcome Message From Chairman, Muhammet KÖKSAL, Professor…...…………………………….….. 23

Teaching Staff……………………………………………………………………………………………………. 24






Double Major…………………………………………………………………………………………………….. 43

Minor Program…………………………………………………………………………………………………… 43


ENVIRONMENTAL ENGINEERING DEPARTMENT 54

Welcome Message From Chairman, Sami GÖREN, Assoc.Professor……...……………………………….. 54

Teaching Staff……………………………………………………………………………………………………. 55






Double Major…………………………………………………………………………………………………….. 63

Minor Program…………………………………………………………………………………………………… 63


GENETICS and BIOENGINEERING DEPARTMENT 70

Welcome Message From Chairman, H.Rıdvan ÖZ, Professor…………......…………………………….….. 70

Teaching Staff……………………………………………………………………………………………………. 72





Double Major…………………………………………………………………………………………………….. 79

Minor Program…………………………………………………………………………………………………… 83


INDUSTRIAL ENGINEERING DEPARTMENT 94

Welcome Message From Chairman, Mazhar ÜNSAL, Professor…………......…………………………….. 94

Teaching Staff……………………………………………………………………………………………………. 95


1





Double Major…………………………………………………………………………………………………….. 101

Minor Program…………………………………………………………………………………………………… 102


2

WELCOME MESSAGE

Dean

Mazhar ÜNSAL, Professor

BS, Robert College, Mechanical Engineering, 1970; MS, Virginia Polytechnic Institute and State University, 1972;

MS, Virginia Polytechnic Institute and State University, 1975; PhD, Virginia Polytechnic Institute and State

University, 1975

Departments and Programs

The Faculty of Engineering consists of the Departments of Computer Engineering, Environmental Engineering,

Electrical and Electronics Engineering, Genetic and Bioengineering, and Industrial Engineering. The academic staff of the Faculty of Engineering at Fatih University spend extensive efforts in order to attain and maintain highest levels in education and research. Completion of the engineering laboratories of our Engineering Departments has been one of the outcomes of these endless effords.

Science and technology are advancing at a rapid pace, and information and technologies that are new today become outdated after short periods of time. The Faculty sets sights at teaching modern engineering techniques to students and providing them with a strong background to build on while trying to harmonize with the rapid pace of future technologies. The Faculty is also active with research and development at the graduate level besides instruction at the undergraduate level. The Engineering Faculty's most important feature is raising modern engineers equipped with advanced analytical and design skills capable of putting theory into practice in the best possible way.

The mission of our Faculty of Engineering is to raise engineers that will help improve the living standards of the people in our region and the citizens of our country, and also to conduct research and development activities. The vision of our Faculty of Engineering is to evolve into a distinguished Engineering Faculty raising qualified engineers that are capable of tackling challanging engineering problems at the national and international levels in our contemporary globalizing word economy.

3

DEPARTMENT OF COMPUTER ENGINEERING

Chairman

Cevdet MER İ Ç, Professor

BA , Ege University, 1978

MS , Ege University, 1979

PHD , Dokuz Eylül University, 1987

Undergraduate Program in Computer Engineering

Recently, Computers and Information Technologies are having a great impact on human life and on society. Our lives, starting in the second half of the twentieth century, have become computerized “at the speed of light.” We now live in times referred to as the computer age, the information age, or the Internet age. The Computer

Engineering Department offers a unique opportunity for bright young minds to excel themselves in the areas of computer science, computer software, and computer hardware.

Our mission is; •to develop research projects that will receive international recognition and •to engage our students in those projects that will enable them in finding jobs easily all over the world.

Our vision is; to educate our students with state-of-art computer engineering knowledge that emphasizes both theoretical and practical aspects, to provide our students the necessary computer engineering background that will enable them in finding jobs all over the world, to enrich our students with high moral and ethical values and to engage our students in social activities which will improve their leadership skills.

The faculty members in the Department believe that neither theory nor practice alone is enough in teaching computer science and engineering. Therefore, courses based on a balance of theory and practice is set up so that students gain a thorough understanding of the subjects in the Department. For the practice components, there are three Intel-based, networked computer laboratories, a Windows based lab, a Linux based lab, a Research lab, a

Wireless & Mobile Networks lab, and Evolutionary Computing lab available for undergraduate students.

Students use these labs extensively during their four years of study for their assignments, projects, and researches

Students begin with the introductory courses in procedural and object oriented programming and algorithm design that lay the foundations for the vital intermediate subjects such as data structures and algorithm analysis, operating systems, programming languages, databases, embedded and distributive system design, computer networks, computer security, and the Internet. Students also take courses in math, science, and engineering in order to prepare themselves for the more challenging course work and projects ahead. In their fourth year, students have the opportunity to take courses on specific and advanced subjects in the Computer Engineering

Department and in other engineering departments such as Electronics Engineering, Industrial Engineering, and

Bioengineering. In the fourth year, students also take the senior design project that give them the opportunity to take on a large challenging project similar to the projects they encounter in the real life environment.

To fulfill the requirements for a Bachelor of Science degree in Computer Engineering based on the current

ABET recommendations, students must take 62 credit hours of computer sciences and the other fundamental engineering courses, 25 credit hours of math and science courses, 24 credit hours of technical electives, 4 credit hours of design project and 23 credit hours of humanities, social sciences, and arts courses. The total number of credit hours required for graduation is 138. Students must also complete 60 workdays of on-the-job training in a computer related facility.

We will keep ourselves alerted to technological changes and innovations and update our programs according to required accreditations to stay always competitive in the university education

TEACHING STAFF

Chairman

Bekir KARLIK, Professor

B.S., Yıldız Technical University, 1988; M.S., Yıldız Technical University, 1991; Ph.D., Yıldız Technical

University, 1994

Haluk GÜMÜ Ş KAYA, Associate Professor

B.S., Middle East Technical University, 1986; M.S., Wisconsin-Madison University, 1989; Ph.D., Đ stanbul Technical

University, 1995

Atakan KURT, Assistant Professor

B.S., Hacettepe University, 1987; M.S., Case Western Reserve University, 1992; Ph.D., Case Western Reserve

University, 1997

Fatih CAMCI, Assistant Professor

B.S., Đ stanbul University, 1999; M.S., Fatih University, 2001; Ph.D., Wayne State University, 2005

Đ hsan Ömür BUCAK, Assistant Professor

B.S., Đ stanbul Technical University, 1985; M.S., Đ stanbul Technical University, 1992; Ph.D., Oakland University,

2000

Nahit EMANET, Assistant Professor

B.S., Bo ğ aziçi University, 1994; M.S., Bo ğ aziçi University, 1997; Ph.D., Bo ğ aziçi University, 2004

Tu ğ rul YANIK, Assistant Professor

B.S., Ege University, 1996; M.S., Oregon Graduate Institute of Science and Technology (OGI), 1999; Ph.D., Oregon

State University, 2001

Veli HAKKOYMAZ, Assistant Professor

B.S., Hacettepe University, 1992; M.S., Pittsburgh University, 1997; Ph.D., Case Western Reserve University, 1997

Zeynep ORHAN, Assistant Professor

B.S., Bilkent University, 1996; M.S., Bilkent University, 1998; Ph.D., Đ stanbul University, 2006

Ai ş e Zülal Ş EVKL Đ , Instructor

B.S., Đ stanbul University, 2000; M.S., Fatih University, 2003

Kadir TUFAN, Instructor.

B.S., Middle East Technical University, 1995; M.S., Bo ğ aziçi University, 2003

Mine MERCAN, Instructor

B.S., Đ stanbul Technical University, 1989; M.S., Fatih University, 2004

Tara SAL Đ H, Instructor

B.S., Al-Isra University, 2000; M.S., Fatih University, 2003

Murat GEZER, Expert

B.S., Ege University, 1997, M.S., Đ stanbul University, 2007

Ahmet Volkan GÜREL, Research Asisstant

B.S., Fatih University, 2004

Melek OKTAY, Research Asisstant

B.S., Fatih University, 2004; M.S., Fatih University, 2007

5

Mustafa SARIÖZ, Research Asisstant

B.S., Kocaeli University, 2005

Nazife Özen, Research Asisstant

B.S., Fatih University, 2007;

Pınar ÖNDER, Research Asisstant

B.S., Ege University, 2006

Taner ÇEV Đ K, Research Asisstant

B.S., Đ stanbul Technical University, 2001

6

LABORATORIES of DEPARTMENT

Teaching Laboratory (Senior Students)

This laboratory is used for courses and research by senior and master students of Computer Engineering Department.

Senior and Masters students use this computer laboratory for their software requirements on their thesis. This laboratory use for, research and education. Our department has 2 laboratories, like this one. These laboratories equipments upgrades every year according to technical developments. And finally every laboratories built up about

60 m

2

Computer Networks Laboratory

The Computer Networks Lab is the first hardware lab in the Department of Computer Engineering at Fatih

University. The lab is a miniature version of the Internet. The available equipment is sufficient to emulate many traffic scenarios found on the real Internet and to teach TCP/IP protocols and data communication to students, and to give them hands-on experience on networking.

The lab has modular Internet rack equipment. Each rack has 4 Cisco 2811 Integrated Services Routers, a 3Com (or

CISCO) switch, 4 Linux PCs as internet hosts, 4 switches, 1 KVM switch and its set (LCD monitor, keyboard, and mouse), cables and connectors. One set of rack equipment is used by 4 students in lab experiments. Currently there are 6 racks in the lab (4 racks in E-106 and 2 racks in E-108) which can be used by 24 students simultaneously.

The Computer Networks Lab is mainly for undergraduate students but it is also used for some advanced network research by graduate students and researchers. This is the first university network lab in its class in Turkey

7

Wireless Network Laboratory

The Wireless Networks Lab was founded as a part of the Computer Networks Lab. Additional to the same essential facilities that exist in the Computer Networks Lab, this lab includes indoor and outdoor access points and antennas, notebooks, mobile devices like Pocket PCs (Asus MyPal 636N and IPAQs like hw6515, hw6915, h6340, and hx2790), smart mobile phones (like SonyEricsson P990), GSM/GPRS/GPS/802.11/Bluetooth devices and modems, wireless development kits, Sensors Networks Teaching Lab Equipment (Crossbow Mote Sensor Kits), Dallas

DS80C400 (DSTINIm400) Networked Microcontroller Evaluation Kits, ...

This lab also has two racks each of which has 4 Cisco 2811 Integrated Services Routers, a 3Com (or CISCO) switch,

4 Linux PCs as internet hosts, 4 switches, 1 KVM switch and its set (LCD monitor, keyboard, and mouse), cables and connectors. These racks are shared by the Computer Networks Lab.

TheWireless Networks Lab is mainly for undergraduate students but it is also used for some advanced network research by graduate students and researchers. This is the first university network lab in its class in Turkey.

Teaching Laboratory (Masters Students)

This laboratory is used for courses and research by senior and master students of Computer Engineering Department.

Senior and Masters students use this computer laboratory for their software requirements on their thesis. This laboratory use for, research and education. Our department has 2 laboratories, like this one. These laboratories equipments upgrades every year according to technical developments. And finally every laboratories built up about

60 m

2

8

UNDERGRADUATE CURRICULUM

First Semester

CENG 100 Computer Eng. Orientation

CENG 101 Introduction to Programming

ENG 101 Advanced English I

MATH 113 Single-Variable Calculus

PHYS 103 General Physics I

Theo. Prac. Credits ECTS Workload

0 2 1 5 7

3

3

4

3

2

0

0

2

4

3

4

4

16

7

4

7

7

30

8

6

10

10

41

Second Semester

CENG 102 Algorithms and Programming

ENG 102 Advanced English II

MATH 110 Discrete Mathematics

MATH 114 Multi-Variable Calculus

PHYS 104 General Physics II


3 2 4 7 8

3

3

4

3

0

0

0

2

3

3

4

4

18

4

5

7

7

30

6

7

10

10

41

Third Semester

CENG 201 Data Structures

CENG 217 Object Oriented Programming

CENG 203 Digital Systems

MATH 220 Linear Algebra

TURK 101 Turkish Language I

MATH 348 Intro. to Prob. & Statistics

Fourth Semester

CENG 204 Programming Languages

CENG 252 Computer Organization

MATH 329 Numerical Analysis I

EEE 292 Electronic Circuits & Devices

TURK 102 Turkish Language II

XXX xxx Non-Technical Elective I

+

Fifth Semester

APHR 101 Atatürk's Principles and History of

Turkish Rev.I

CENG 309 Signal Processing for Computer

Engineering

CENG 299 Industrial Training I

CENG 341 Operating Systems

CENG 351 Database Management Systems

CENG 303 Microprocessors and

Microcomputing

XXX xxx Non-Technical Elective II

+


3

2

2

2

4

3

7

6

9

8

3

3

2

3

3

2

3

3

3

3

2

0

0

0

Theo. Prac. Credits ECTS

0

0

0

2

0

0

4

3

2

3

19

3

3

3

4

2

3

18

5

5

2

5

30

6

6

5

5

3

5

30

7

7

4

7

42

Workload

8

7

7

7

4

7

40


2 0 2 2 4

3

-

3

3

2

3

0

-

2

0

2

0

3

NC

4

3

3

3

18

5

-

7

6

5

5

30

6

-

9

8

6

7

40

9

Sixth Semester

APHR 102 Atatürk's Principles and History of

Turkish Rev.II

CENG 304 Automata Th. & Formal Lang.

CENG 310 Web Programming

CENG 362 Computer Networks

CENG 305 Analysis of Algorithms

XXX xxx Non-Technical Elective III

+


2 0 2 2 4

3

3

3

3

3

0

0

2

0

0

3

3

4

3

3

18

5

6

7

5

5

30

7

8

9

7

7

42

Seventh Semester

CENG 399 Industrial Training II

CENG 401 Software Engineering

CENG 497 Senior Design Project I

CENG 4xx Technical Elective I

*

CENG 4xx Technical Elective II

*

CENG 4xx Technical Elective III

*

XXX xxx Technical Elective IV

*


-

3

-

0

NC

3

-

6

-

8

3

3

0

3

3

2

0

0

0

0

1

3

3

3

3

3

5

5

5

5

6

7

7

7

7

16 29 42

Eighth Semester

CENG 498 Senior Design Project II

CENG 4xx Technical Elective V

*

CENG 4xx Technical Elective VI

*

CENG 4xx Technical Elective VII

*

XXX xxx Technical Elective VIII

*


0

3

3

3

3

6

0

0

0

0

3

3

3

3

3

15

11

5

5

5

5

31

14

7

7

7

7

42

Total Credits Required in Degree Program: 138

Total ECTS Credits: 240

TABLE of TECHNICAL ELECTIVES

Course Code Course Name

CENG 404 Combinatorics & Graph Theory

CENG 410 Intro. to Design Patterns &

Frameworks

CENG 411 Intro to Web Engineering

CENG 421 Intro. to Logic Programming

CENG 431 Intro. to Programming Lang. Design

CENG 432 User Interface Design

CENG 433 Human-Computer Interaction

CENG 451 Intro. to MIS

CENG 452 Intro. to Data Mining

CENG 453 Intro. to E-Bus./E-Commerce

CENG 454 XML and Web Services

CENG 455 Special Topics in Database Systems

CENG 456 Multimedia Systems

CENG 457 Digital Image Processing


3 0 3 6 8

3 0 3 5 7

0

0

0

0

0

0

0

0

0

0

0

0

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

5

5

5

5

5

5

5

5

5

5

5

5

*

Students must select courses from the technical electives’ list shown above, excluding the courses of the specialization option

7

7

7

7

7

7

7

7

7

7

7

7

10

IE

IE

IE

IE

IE

IE

IE

IE

IE

IE

IE

IE

IE

IE

IE

MATH

MATH

CENG 458 Computer Vision

CENG 459 Machine Learning

CENG 460 Intro. to Natural Lang. Processing

CENG 463 Network Programming

CENG 464 Distributed Systems

CENG 465 Mobile and Wireless Networking

CENG 481 Intro. to Computer Graphics

CENG 482 Network Security

CENG 483 Computer Architecture

CENG 484 Embedded Systems

CENG 485 Introduction to Cryptography

CENG 490 Intro. to Art. Intelligence

CENG 491 Intro. to Neural Networks

CENG 492 Intro. to Pattern Recognition

CENG 493 Intro. to Evolutionary Computing

CENG 494 Digital Data Communication

BIOL 419 Bioinformatics

EEE

EEE

415 Intro. to Mod. and Coding

417 Error-Correcting Codes

EEE 424 Digital Integ. Circuit Design

EEE 425 Introduction to VLSI Design

EEE

EEE

431

435

Discrete Time Control Systems

Robot Dynamics & Control

EEE 436 Mechatronics

EEE 437 Intelligent Control Systems

EEE

EEE

EEE

458 Computer Vision

464 Fund. of Biomedical Eng.

465 Medical Imaging Systems

EEE

IE

IE

475 Microcontroller Based Sys. Des.

216 Operation Research I

305 Work Methods and Measurement

MATH

MATH

MATH

MATH

MATH

315 Operation Research II

320 Production Planning & Control I

345 Simulation

411 Reliability and Maintainability

413 Human Factors Engineering I

416 Activity Net. and Project Man.

420 Human Factors Engineering II

430 Total Quality Management

435 Quality Control

445 Comp. Integrated Man. Systems

448 System Design

452 Quality by Design

455 Optimization

470 Des & Operation of Supply-Chain

473 Enterprise Resource Planning System

330 Numerical Analysis II

414 General Topology

420 Real Analysis

425 Abstract Algebra I

428 Abstract Algebra II

429 Group Theory

450 Game Theory

3

3

3

3

2

3

3

2

3

3

2

2

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

2

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

0

0

0

0

0

2

2

0

2

2

0

0

1

0

1

0

0

0

0

0

0

0

0

0

0

0

0

0

1

2

0

0

2

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

4

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

5

5

5

5

5

6

5

5

5

5

5

5

6

5

6

5

5

5

5

5

7

5

5

5

5

5

5

5

6

6

5

5

6

5

5

7

5

5

6

5

5

5

6

5

5

5

5

5

5

5

5

5

5

7

7

7

7

7

7

7

7

7

7

7

7

8

7

7

7

7

7

7

7

8

7

7

7

7

7

7

7

8

7

7

7

9

7

7

9

7

7

8

7

7

7

8

7

7

7

7

7

7

7

7

7

7

11

CENG 341

CENG 351

CENG 362

CENG 399

CENG 401

CENG 404

CENG 410

CENG 411

CENG 421

CENG 431

CENG 432

CENG 433

CENG 452

CENG 454

CENG 455

CENG 457

CENG 459

CENG 458

CENG 460

CENG 463

CENG 464

CENG 465

CENG 481

CENG 482

CENG 483

CENG 484

CENG 485

CENG 490

Course Code

CENG 102

CENG 104

CENG 201

CENG 204

CENG 217

CENG 219

CENG 252

CENG 299

CENG 303

CENG 304

CENG 305

CENG 309

CENG 310

Course Name

PREREQUISITE TABLE

Algorithms and Programming

Fund. of Computer Programming II

Data Structures

Programming Languages

Object Oriented Programming

C++ Programming

Computer Organization

Industrial Training I

Microprocessors and Microcomputing

Automata Theory & Formal Languages

Analysis of Algorithms

Signal Processing for Computer Engineering

Web Programming

Operating Systems

Database Management Systems

Computer Networks

Industrial Training II

Software Engineering

Combinatorics & Graph Theory

Intro. to Design Patterns & Frameworks

Intro to Web Engineering

Intro. to Logic Programming

Intro. to Programming Lang. Design

User Interface Design

Human-Computer Interaction

Intro . to Data Mining

XML and Web Services

Special Topics in Database Systems

Digital Image Processing

Machine Learning

Computer Vision

Intro. to Natural Language Processing

Network Programming

Distributed Systems

Mobile and Wireless Networking

Intro. to Computer Graphics

Network Security

Computer Architecture

Embedded Systems

Intro. to Cryptography

Intro. to Artificial Intelligence

Prerequisite

CENG 101, or Chairman’s Consent









CENG 204, MATH 110, or

Chairman’s Consent


MATH 114, or Chairman’s

Consent

CENG 217, CENG 351, or




















MATH 113, CENG 201, or



CENG 204, or Chairman’s

Consent









MATH 110, MATH 348, or



12

CENG 491

CENG 492

CENG 493

CENG 494

CENG 497

CENG 498

EE 377

Intro. to Neural Networks

Intro. to Pattern Recognition

Intro. to Evolutionary Computing

Digital Data Communication

Senior Design Project I

Senior Design Project II

EQUIVALENCE TABLE

Old Old

Course Course Name



EE 201 Circuit Theory I

EE 201

EE 273

EE 273

EE 391

Circuit Theory I

Fundamentals Of Logic Design I

Fundamentals Of Logic Design I

EE 391

EE 391

EE 392

EE 393

EE 393

Intro. To Electrical Circuits And

Electronics


Electronics


Electronics

Intro. To Electronic Circuits

Introduction To Circuit Theory


IE 417 Human-Computer Interaction

MATH 129 Introduction To Probability And

Statistics


Statistics

EE 271

EE 273

Digital Logic Design

Digital Logic Design I

EE 292

EE 391

Electronic Circuits & Devices

Intro. To Electrical Circuits

EE 391 Intro. To Electrical Circuits

CENG 101 Computer Programming I

CENG 102 Computer Programming Ii

CENG 201 Data Structures And Algorithms-I

EE 271 Digital Logic Design

MATH 348 Intro. To Prob. & Statistics

CENG 252 Computer Organization

Introduction To Microprocessors

CENG 351 Database Management Systems I

CENG 310 Internet Programming

CENG 310 Introduction To Xml

CENG 202 Data Structures And Algorithms-Ii

New New

Course Course Name



EE 391 Intro. To Electrical Circuits

EE 393

EE 271

EE 273

EE 201




Circuit Theory I

EE 393

EE 391

EE 292

EE 201

EE 391






Senior Standing, or Chairman’s

Consent




Electronic Circuits & Devices

Circuit Theory I


CENG 433 Human-Computer Interaction


Statistics


Statistics

EE 273

EE 271



EE 392

EE 201

Intro. To Electronic Circuits

Circuit Theory I

EE 393 Introduction To Circuit Theory

CENG 101 Introduction To Programming

CENG 102 Algorithms And Programming


CENG 203 Digital Design

CENG 348 Intro. To Prob. & Statistics

CENG 252 Computer Organization And

Architecture

CENG 303 Microprocessors And

Microcomputing

CENG 351 Database Management Systems

CENG 310 Web Programming

CENG 310 Xml & Web Services

CENG 305 Analysis Of Algorithms

13

DOUBLE MAJOR PROGRAM

FOR DEPARTMENT of ELECTRICAL-ELECTRONICS STUDENTS

First Semester Contact/Credit Hours Second Semester Contact/Credit Hours

Third Semester

CENG 201 Data Structures and Algorithms I

Contact/Credit Hours Fourth Semester

(3+0) 3 CENG

Contact/Credit Hours

202 Data Structures and Algorithms II (3+0) 3

CENG 217 Object Oriented Programming (3+0) 3

(6+0) 6

CENG 204 Programming Languages (3+0) 3

(6+0) 6

Fifth Semester



Contact/Credit Hours Sixth Semester

CENG 304 Automata. Th. & Formal Lang.


(3+0) 3

(3+0) 3

(3+2) 4

CENG

CENG

310 Đ nternet Programming

362 Computer Networks

(3+0) 3

(3+2) 4

(6+2) 7 (9+2) 10



CENG xxx Technical Elective I

CENG xxx Technical Elective II

*

*

Contact/Credit Hours Eighth Semester

(3+0) 3

(3+0) 3

(3+0) 3

CENG xxx Technical Elective V

*

CENG xxx Technical Elective VI

*

(9+0) 9


(3+0) 3

(3+0) 3

(6+0) 6

NOTES:

Total credits required in Double Major Program: 44 .

The mınımum cumulative GPA requirement is 3.50

.

If the prerequisite(s) of a course above is not present in the Double Major Program, it will not be required .

CENG 103 is accepted as equivalent to CENG 101 and CENG 104 is accepted as equivalent to CENG 102 in the double major programs .

FOR DEPARTMENTS of INDUSTRIAL ENGINEERING, PHYSICS and MATHEMATICS STUDENTS

Birinci Semester Contact/Credit Hours Đ kinci Semester Contact/Credit Hours

Üçüncü Semester

CENG 201 Data Structures and Algorithms I

Contact/Credit Hours Dördüncü Semester

(3+0) 3 CENG


202 Data Structures and Algorithms II (3+0) 3


EE 271 Digital Logic Design

(3+0) 3

(3+2) 4

CENG

CENG

204 Programming Languages

252 Computer Organization

(3+0) 3

(3+0) 3

(9+2) 10 (9+0) 9

Be ş inci Semester


Contact/Credit Hours Altinci Semester

(3+0) 3 CENG 304 Automata. Th. & Formal Lang.


(3+0) 3

CENG 341 Operating Systems (3+2) 4 CENG 310 Đ nternet Programming (3+0) 3

EE 377 Intro. to Microprocessors (2+2) 3

(8+4) 10

CENG 362 Computer Networks (3+2) 4

(9+2) 10

Yedinci Semester


CENG xxx Technical Elective I

CENG xxx Technical Elective II

**

**

Contact/Credit Hours Sekizinci Semester

(3+0) 3

(3+0) 3

CENG xxx Technical Elective V

**

CENG xxx Technical Elective VI

**

(3+0) 3

(9+0) 9


(3+0) 3

(3+0) 3

(6+0) 6

*

At least 4 of the technical electives must be selected from the technical elective courses offered by the CENG department.

** At least 4 of the technical electives must be selected from the technical elective courses offered by the CENG department.

14

NOTES:

Total credits required in Double Major Program: 54

The minimum cumulative GPA requirement is 3.50

If the prerequisite(s) of a course above is not present in the double major program, it will not be required.

CENG 103 & CENG 112 are accepted as equivalent to CENG 101 and CENG 104 & CENG 219 are accepted as equivalent to CENG 102 in the double major programs..

MINOR PROGRAM

MINOR PROGRAM IN SOFTWARE ENGINEERIN

First Semester Contact/Credit Hours Second Semester

CENG 102 Computer Programming II


(3+2) 4

(3+2)4

Third Semester




(3+2) 4 CENG 252 Computer Organization and

(3+0) 3

(6+2) 7

Architecture

Fifth Semester

CENG 351 Database Management Sysyems



(3+0) 3

(3+2) 4

(6+2) 7


(3+0) 3

(3+0) 3



CENG 401 Software Engineerign

Contact/Credit Hours Eight Semester

(3+0) 3

(3+0) 3


NOTES:

Total credits required in Minor Program: 24


If the prerequisite(s) of a course above is not present in the minor program, it will not be required.

CENG 112 and CENG 103 is accepted as equivalent to CENG 101 in the minor programs

15

COURSE DESCRIPTIONS

CENG 100 Computer Engineering Orientation ECTS 5, Credits (0+2) 1

Providing counseling about the department and computer engineering profession. Hardware and software components of a computer system. Basic computer usage: Basics of operating systems, file operations, internet and office applications.

CENG 101 Introduction to Programming ECTS 7, Credits (3+2) 4

Basic computer literacy, fundamentals of computer progragramming, algorithm development and problem solving using flowcharts and pseudo codes, data types, constants, variables, basic input/output, seqeuences, selection and repetition structures, functions and arrays. Searching and sorting, abstract data types, structures, pointers, strings, input/output, file processing.

CENG 102 Algorithms and Programming ECTS 7, Credits (3+2) 4

Problem solving and design using object-oriented paradigms: Classes, objects, attributes, accessors and modifiers, constructors, destructors, methods, inheritance, abstract classes, interfaces, polymorphism, method overloading and overriding, and templates.

Prerequisite: CENG 101, or Chairman’s consent.

CENG 103 Fundamentals of Computer Programming I ECTS 6, Credits (3+2) 4

Analysis of problems and design of simple algorithms using flowcharts and pseudo codes, program coding, testing, debugging. Basic data types, variables, if-then-else decisions, and for/while/do loops, functions and parameter passing and one and two dimensional arrays. Advanced data types: structures, pointers, strings, input/output, file processing. (Computer Engineering Department students cannot take this course for credit).

CENG 104 Fundamentals of Computer Programming II ECTS 5, Credits (3+2) 4

Analysis and design of algorithms using object-oriented programming: Classes, objects, attributes, methods, constructors, destructors, inheritance, interfaces, polymorphism, method overloading and overriding. Abstract, static and final classes, methods, attributes. Exception handling. (Computer Engineering Department students cannot take this course for credit).


CENG 112 Introduction to Computer Programming ECTS 5, Credits (2+2) 3

Introduction to programming with a high level language, data types and variables, basic control structures: Sequence, conditional structures, repetition, analyzing problems and flowcharting. Arrays, input/output commands, file processing. (Computer Engineering Department students cannot take this course for credit).

CENG 201 Data Structures ECTS 7, Credits (3+2) 4

Study of the basic data structures and their implementations: Arrays, matrices, stacks, queues, hash tables, trees, lists, and graphs. Programming techniques using recursion. Various searching and sorting methods such as insertion sort, merge sort, and quick sort. Basic analysis of algorithms.


CENG 203 Digital Systems ECTS 5, Credits (3+2) 4

Boolean algebra, number systems, data representation, logic theorems, canonical forms, simplification techniques, logic gates, design of combinational circuits, timing and timing problems, sequential circuits, design of sequential circuits and the algorithmic state machine, programmable logic devices, register operations, basic computer organization and design

CENG 204 Programming Languages ECTS 5, Credits (3+0) 3

Syntax and semantics of programming languages, grammars, design of programming languages, data types, variables, expressions and statements, procedures, recursion, parameter passing, dynamic and static memory management. Functional, logic, and object-oriented programming paradigms. Examples from typical and modern programming languages.


16

CENG 217 Object Oriented Design ECTS 6, Credits (2+2) 3

Classes, objects, inheritance, polymorphism, graphical user interfaces, event handling, exception handling, files and streams, multithreading. UML diagrams: Class, object, use-case, sequence and activity diagrams. Introduction to

GoF design patterns. Software design using UML and design patterns.


CENG 219 C++ Programming ECTS 5, Credits (2+2) 3

Object oriented programming paradigm and concepts. Classes and objects, constructors/destructors, accessors and modifiers, abstract data types, methods and attributes, overloading, overriding, polymorhism, inheritance, stream input/output. (Computer Engineering Department students cannot take this course for credit).

Prerequisite: CENG112, or Chairman’s consent.

CENG 252 Computer Organization ECTS 5, Credits (3+0) 3

Understanding of the inner-workings of modern computer systems and tradeoffs present at the hardware-software interface: Instruction set design and addressing modes, register transfer, internal CPU bus structure, ALU

(microprogramming and hardwired control), computer arithmetic, memory system, input-output system and survey of real computers and microprocessors.


CENG 299 Industrial Training I Non-Credit

Students must complete a 30 business-day (6 weeks) summer practice in a software company or in the IT department of any type of company. Students are expected to learn about a real business and work environment and get involved in many aspects of software development process. Observations from industrial training must be documented and presented in the form of a clear and concise technical report.


CENG 303 Intro. to Microprocessors ECTS 4, Credits (2+2) 3

Introduction to computer and microprocessor architecture, addressing modes. Arithmetic, logic and program control instructions. Programming microprocessor, 8086/8088 hardware specifications, interrupts, memory and basic I/O interface.


CENG 304 Automata Theory and Formal Languages ECTS 5, Credits (3+0) 3

Regular expressions, context free grammars and languages. Pumping lemma, finite and pushdown automata,

Chomsky hierarchy, Turing machines, computability theory, determinism and non-determinism, recursive function theory.

Prerequisite: CENG 204, MATH 110, or Chairman’s consent.

CENG 305 Analysis of Algorithms ECTS 5, Credits (3+0) 3

Fundamental concepts and techniques in the analysis of algorithms and the relevance of such analysis to the design of efficient algorithms. Asymptotic notations, worst, average, and best case analysis, models of computation, searching and sorting, amortized analysis. Graph, numerical and combinatorial algorithms. Introduction to NPcompleteness theory, and lower bound techniques.


CENG 309 Signal Processing in Computer Engineeering ECTS 5, Credits (3+0) 3

Fundamentals of signals and systems, classification of signals, continuous signals, Fourier Transforms, Inverse

Fourier Transform, Laplace Transforms, Inverse Laplace Transforms, discrete signals, Fast Fourier Transform,

Discrete Fourier Transforms, Z Transforms, filters, and the other applications.


CENG 310 Web Programming ECTS 6, Credits (3+0) 3

HTML, CSS, client-server architecture, protocols such as HTTP, tools such as web, application, database, FTP, secure shell server. Application development using scripting languages. Session management, multimedia and graphics, application security, XML.

Prerequisite: CENG 217, CENG 351, or Chairman’s consent.

17

CENG 341 Operating Systems CTS 7, Credits (3+2) 4

Basic roles of operating systems on computers. Concepts such as multiprogramming, time sharing, process management, threads, interprocess communication, concurrency and synchronization, deadlocks, memory management and protection, file systems. Case studies on contemporary operating systems.


CENG 351 Database Management Systems ECTS 6, Credits (3+0) 3

Database design using entity-relationship model and relational data model, SQL (data definition and data manipulation languages), data integrity and integrity constrainst, triggers, stored procedures, indexing and application development.


CENG 362 Computer Networks ECTS 7, Credits (3+2) 4

OSI reference model, Internet and TCP/IP. Application layer protocols: HTTP, FTP, SMTP, POP3, and DNS.

Socket programming, transport layer services, flow and congestion control, network layer and IP protocol, addressing, routing, data link layer protocols, local area networks.


CENG 399 Industrial Training II Non-Credit

In this 30 business-days long industrial training, students are expected get involved in software projects in an IT department of a company. The purpose of this industrial training is to gain software development experience in a team environment. Observations must be documented and presented in the form of a clear and concise technical report.


CENG 401 Software Engineering ECTS 6, Credits (3+0) 3

Modeling with UML, introduction to design patterns, project management and software development processes, requirements elicitation and analysis, system design, object design, testing, rational and configuration management, software life cycle, and methodologies. Particular emphasis is on a team project in which a group of students implement a system from its specification.


CENG 404 Combinatorics & Graph Theory ECTS 5, Credits (3+0) 3

Mathematical induction. Combinatorics: Permutations, combinations, binomial coefficients, inclusion-exclusion principle, generating functions, Pólya's theory of counting, Stirling numbers, and stable marriages. Graph theory:

Isomorphism, planarity, circuits, trees, colorings, matching and Ramsey theory.


CENG 410 Introduction to Design Patterns and Frameworks ECTS 5, Credits (3+0) 3

Basic creational, structural and behavioral patterns, some architectural and enterprise patterns. Developing object oriented software with design patterns and frameworks. Several example problems are studied to investigate the development of design patterns and framework.


CENG 411 Introduction to Web Engineering ECTS 3, Credits (3+0)

Web based application development techniques and technologies. These are templates, localization, web multimedia

techniques. Developing web applications using XHTML, CSS, XML, JavaScript and AJAX.


CENG 421 Introduction to Logic Programming ECTS 5, Credits (3+0) 3

Procedural semantics and declarative semantics, techniques for proving the correctness of Prolog programs.

Computation by SLD-resolution, logical consequences of a program, extending logic programs, verification of

Prolog programs, Prolog programming techniques.


18

CENG 431 Introduction to Programming Language Design ECTS 5, Credits (3+0) 3

Lexical and syntax analysis, top-down and bottom-up parsing techniques, semantic analysis, symbol tables, error detection and recovery, type checking, code generation and optimization. Case study: Implementation of a compiler for a simple but nontrivial subset of a modern programming language.


CENG 432 User Interface Design ECTS 5, Credits (3+0) 3

Different prototyping approaches, interface quality, interface design examples, dimensions of interface variability, dialogue genre, dialogue tools and techniques, user interface implementation. Development of user scenarios, user object model and navigational model.


CENG 433 Human–Computer Interaction ECTS 5, Credits (3+0) 3

Methods and principles of human-computer interaction, human-centered design and development of interactive systems, task-centered system design, user-centered design, qualitative and quantitative methods for evaluating interactive systems with users, graphical screen design, design principles and usability heuristics.


CENG 451 Introduction to Management Information Systems ECTS 5, Credits (3+0) 3

Organizational and managerial context of information systems, decision making systems, database systems. Basic concepts in information technology: Computer systems, networks, wireless networks, Internet and telecommunications. E-Business, E-Commerce, M-Commerce, multimedia, computer security, data warehousing and data mining.

CENG 452 Introduction to Data Mining ECTS 5, Credits (3+0) 3

Data warehouse architectures and design issues, basic data mining strategies of supervised learning, unsupervised clustering and association rules. K-nearest neighbor, K-means, decision trees and production rules, neural networks, genetic learning, regression, statistical evaluation techniques.


CENG 453 Introduction to E-Business/E-Commerce ECTS 5, Credits (3+0) 3

Electronic processing and transmission of data including text, sound and video for e-business. Electronic trading of goods and services, online delivery of digital contents, electronic fund transfer, electronic bill of lading, direct consumer marketing and after-sales services. E-business security, shopping carts, methods of electronic payments and XML related technologies.

CENG 454 XML and Web Services ECTS 5, Credits (3+0) 3

Basic concepts in XML and related technologies including XML, DTD, XSD, XPath and XSLT. XML application development using DOM, SAX and XSLT APIs. Web services development using SOAP, WSDL, UDDI, JAX-RPC, and SAAJ.


CENG 455 Special Topics in Database Systems ECTS 5, Credits (3+0) 3

Relational algebra, QBE, normalization theory, physical data organization techniques and indexing, advanced SQL

(data control language), query processing, data recovery, security and integrity, object relational data model, XML and XML-related technologies in databases.

Prerequisite: CENG 351, or Chairman’s Consent.

CENG 456 Multimedia Systems ECTS 5, Credits (3+0) 3

Representation, compression, storage, retrieval of data from different media such as images, text, video and audio.

Multimedia file formats, multimedia programming APIs, multimedia applications.

19

CENG 457 Digital Image Processing ECTS 5, Credits (3+0) 3

Digital images, sampling and quantization of images, arithmetic operations, gray scale manipulations, distance measures, image compression techniques, connectivity, image transforms, enhancement, restoration, segmentation, representation and description.

Prerequisite: CENG 309, or Chairman’s Consent

CENG 458 Computer Vision ECTS 5, Kredi (3+0) 3

Introduction, camera systems, image preprocessing techniques, feature extraction methods, image classification and recognition, industrial and medical applications.

Prerequisite: CENG 309, or Chairman’s Consent.

CENG 459 Machine Learning ECTS 5, Credits (3+0) 3

Machine learning techniques and statistical pattern recognition, supervised learning (generative/discriminative learning, parametric/non-parametric learning, neural networks, support vector machines); unsupervised learning

(clustering, dimensionality reduction, kernel methods); learning theory (bias/variance tradeoffs; VC theory; large margins); reinforcement learning and adaptive control, applications areas (robotic control, data mining, autonomous navigation, bioinformatics, speech recognition, and text and web data processing).

Prerequisite: MATH 113, CENG 201, or Chairman’s Consent

CENG 460 Intro. to Natural Language Processing ECTS 5, Credits (3+0) 3

Theory and practice of natural language processing (NLP), major subfields of NLP: syntax (structure of a sentence), semantics (explicit meaning of a single sentence), and pragmatics (implicit meaning of a sentence when it is used in a specific discourse context), knowledge-based and statistical approaches to NLP, use of NLP techniques and tools in a variety of application areas.

Prerequisite: CENG 204, or Chairman’s Consent

CENG 463 Network Programming ECTS 5, Credits (3+0) 3

Design and implementation of network programs, protocols and systems: Network programming models, concurrency and concurrent programming, advanced socket programming, distributed computing, message-oriented middleware, peer-to-peer programming, mobile agents, multimedia networking, introduction to enterprise applications development.


CENG 464 Distributed Systems ECTS 5, Credits (3+0) 3

Characterization of distributed systems, system models, inter-process communication, distributed object-based systems, operating system support, security, distributed file servers, name services, time and global states, coordination and agreement, transactions and concurrency control, distributed transactions, replication.


CENG 465 Mobile and Wireless Networking ECTS 5, Credits (3+0) 3

Wireless transmission (physical layer), wireless media access (link layer), telecommunication systems (such as

GSM/GPRS, DECT, TETRA, UMTS and IMT-2000), wireless LANs (IEEE 802.11, Bluetooth), mobile network layer (mobile IP, DHCP), mobile transport layer (TCP over wireless), mobile application support and wireless programming.


CENG 481 Introduction to Computer Graphics ECTS 5, Credits (3+0) 3

Basic raster graphics algorithms for drawing 2d and 3d primitives, scan converting shapes, filling shapes, clipping, generating characters, geometrical transformations, viewing in 3D, projections, geometric modeling, input and interaction techniques, illumination and shading, ray tracing, texture mapping.


20

CENG 482 Network Security ECTS 5, Credits (3+0) 3

Techniques for achieving security in multi-user computer systems and distributed computer systems: Basics of cryptography, network security applications and system security, conventional encryption and message confidentiality, public-key cryptography and message authentication, authentication applications. Electronic mail, IP, web, and network management security. Intruders, viruses, and firewalls.


CENG 483 Computer Architecture ECTS 5, Credits (3+0) 3

Reduced Instruction Set Computer (RISC) architecture, pipelined processor design (instruction and arithmetic pipelines), multiprocessor and alternative architectures, dynamic and static interconnection networks, shared memory multiprocessor systems, message passing multiprocessor systems and parallel processing.


CENG 484 Embedded Systems ECTS 5, Credits (3+0) 3

Architecture of embedded systems, hardware/software co-design methodology, embedded system specification and design. Hardware and software components. Real time operating systems and networks for embedded systems.

Application development for embedded systems.

Prerequisite: EE 377, CENG 341, or Chairman’s consent.

CENG 485 Introduction to Cryptography ECTS 5, Credits (3+0) 3

History and overview of cryptography, stream ciphers, block ciphers, Data Encryption Standard (DES), 3DES,

Advanced Encryption Standard (AES), attacks on block ciphers, Public Key Cryptography and Infrastructure, basic number theory, big number arithmetic, Diffie-Hellman key exchange, El Gamal encryption, RSA, attacks on RSA, message integrity, hashing, digital signatures, elliptic curve cryptography and certificates.

Prerequisite: MATH 110, CENG 348, or Chairman’s consent.

CENG 490 Introduction to Artificial Intelligence ECTS 5, Credits (3+0) 3

Introduction to AI programming languages. Basic AI problem solving techniques: Heuristic search and game playing. Knowledge representation, planning, reasoning, decision-making techniques, expert systems, logic and theorem proving.


CENG 491 Introduction to Neural Networks ECTS 5, Credits (3+0) 3

Principles of neural networks, neural network architectures including feed-forward backpropagation networks and self organizing maps, design of effective neural networks, performance evaluation techniques, applications of neural networks in various fields.


CENG 492 Introduction to Pattern Recognition ECTS 5, Credits (3+0) 3

Pattern recognition principles, approaches, algorithms, theoretical foundations of classification, optical character, speech and face recognition. Statistical decision theory, adaptive classifiers, supervised and unsupervised learning techniques.


CENG 493: Introduction to Evolutionary Computing ECTS 5, Credits (3+0) 3

Fundamentals of Evolutionary and Genetic algorithms, application areas, Parameter Control in Evolutionary

Algorithms, the other Heuristics algorithms (Tabu search, .Memetic Algorithms etc.), its applications

Prerequisite: CENG 217, CENG 201 or Chairman’s consent.

CENG 494: Digital Data Communication ECTS 5, Credits (3+0) 3

Principles of data communications, data communication components and services, line control techniques, and network design, synchronous and asynchronous transmission; data encoding and channel capacity, Nyquist and

Shannon relationships; interface standards, RS-232; multiplexing, FDM, TDM, and STDM; modem standards and modulation techniques; error and line control techniques.

Prerequisite: CENG 217, CENG 201 or Chairman’s consent.

21

CENG 497 Senior Design Project I ECTS 3, Credits (0+2) 1

An independent study under the supervision of an advisor: Research on exploring and defining a potential study area suitable for a senior design project. Identification of a specific problem from the selected study area in computer science and engineering. Results from this study are documented and presented in the form of a design project proposal.

Prerequisite: Senior standing, or Chairman’s consent.

CENG 498 Senior Design Project II ECTS 11, Credits (0+6) 3

Design and implementation of the project proposed in Senior Design Project I. Presentation of the results in both oral and written forms.


22

DEPARTMENT OF ELECTRICAL-ELECTRONICS ENGINEERING

Chairman

Muhammet KÖKSAL, Professor

B.S. Middle East Technical University, 1969; M.S. Middle East Technical University, 1972; Ph.D. Middle East

Technical University, 1975

Undergraduate Program in Electrical and Electronics Engineering

Electrical and Electronics engineering involves a synthesis of science, technology, and design that results in such developments as consumer products, electronic components, microchips, computers, robots, electric motors, machinery controls, power generating, controlling, and transmission devices used by electric utilities; lighting, and wiring in buildings, as well as artificial intelligence, signal processing, microwave, and telecommunication equipment. Considering the rapid developments in information technology, for example, many opportunities and challenges have been created for the electrical and electronics engineer. In addition, other electrical/electronic products (as indicated above) have proliferated incredibly in recent years. This means that electrical and electronics engineering has gained an increasing importance and become more popular. It is also a field responsible for a wide range of technologies where new developments are frequent and competition is considerable. Thus, although it is difficult and costly, the members of the faculty in the Department are determined to keep themselves up to date and to keep the Department's laboratories equipped with as many of the state-of-the art technologies that they can so that students are trained to meet the demands of the companies that will be hiring them.

The Electrical and Electronics Engineering Department offers a four-year undergraduate program designed firstly to provide students with hands-on laboratory practice using state-of-the art equipment. In addition, since the ability to design is an important part of electrical and electronics engineering, students are presented with challenging design problems in several courses. The fourth year senior design project course also gives students an opportunity to take on a large challenging project similar to the ones they will have once they are employed.

Also during the fourth year, students have the opportunity to focus on specific and advanced subjects in the

Department and in other departments including computer engineering, industrial engineering, and mathematics.

Required also is that students gain on-the-job experience of 60 working days in an electrical and/or electronics related facility during their summer vacation. Moreover, in today's world, engineering decisions are rarely made without considering the ethical and socio-economic impact, so besides the practical work done, theoretical issues are also brought up. Finally, so that students have the chance to develop skills in communicating clearly and effectively, also important for engineers, students take non-technical elective courses in the Social Sciences and the Humanities.

To fulfill the requirements for a Bachelor of Science degree in Electrical and Electronics Engineering, based on the current ABET recommendations, students must take 56 credit hours of electrical and electronics engineering,

31 credit hours of math and basic sciences, 4 credit hours of computer sciences, 27 credit hours of core and technical electives, and 20 credit hours of social sciences, humanities, economics, and communication courses.

The total number of credit hours required is 138. Students must also complete a minimum of 60 workdays of onthe-job training in an Electrical and Electronics Engineering related facility.

23

TEACHING STAFF

Chairman

Muhammet KÖKSAL, Professor

B.S, Middle East Technical University, 1969; M.S, Middle East Technical University, 1972; Ph.D, Middle East

Technical University, 1975.

Kemal F Đ DANBOYLU, Professor

B.S, University of Petroleum and Minerals, 1985 (Electrical Eng., Mathematical Sciences); M.S, University of

Petroleum and Minerals, 1987; Ph.D, Virginia Tech, 1991.

Erkan Đ MAL, Assoc. Professor

B.S, Gazi University, 1986; M.S, Gazi University, 1989; Ph.D, Sussex University, 1994.

Onur TOKER, Assoc. Professor

B.S, Bogaziçi University, 1990 (Electrical-Electronics Eng., Mathematics, Physics); M.S, Ohio State University,

1992 (Electrical Eng.), 1994 (Mathematics); Ph.D, Ohio State University, 1995.

Yrd.Doç.Dr. Ali UZER

B.S, Gaziantep University, 1995; Yüksek Lisans, Gaziantep University, 1998; Doktora, Gaziantep University,

2005

Bahadır YILDIRIM, Assist. Professor

B.S, Yıldız Technical University, 1990; M.S, University of Colorado, 1993; Ph.D, Arizona State University,

1998.

Erdal KORKMAZ, Assist. Professor

B.S, Delft University of Technology, 1997; M.S, Delft University of Technology, 1997; Ph.D, Delft University of Technology, 2002.

Lokman ERZEN, Assist. Professor

B.S, Middle East Technical University, 1990; M.S, Gaziantep University, 1993; Ph.D, Rensselaer Polytechnic

Institute, 2003.

Özgür ÖZDEM Đ R, Instructor

B.S, Bo ğ aziçi Üniversitesi, 1999; M.S, University of Texas at Dallas, 2002; Ph.D, University of Texas at Dallas,

2007

Cihan ULA Ş , Research Assistant

B.S, Uluda ğ University, 2004.

Emine DO Ğ ANAY, Research Assistant

B.S, Ege University, 2006.

Halil Đ brahim ÇAKAR, Research Assistant

B.S, Mersin University, 2007.

Hasan Seçkin EFEND Đ O Ğ LU, Research Assistant

B.S, Uluda ğ University, 2004.

Selahattin NES Đ L, Research Assistant

B.S, Fatih University, 2004.

Serdar YILMAZ, Research Assistant

B.S, Istanbul University, 2000; M.S, Fatih University, 2003.

Zafer ÇATMAKA Ş , Research Assistant

B.S, Yıldız Technical University, 2005.

24

DEPARTMENT LABORATORIES

Curcuit Design Laboratory

Circuit design laboratory facilitates students with doing experiments using integrated circuits (IC) along with many components, such as resistors, capacitors, LEDs, potentiometers etc. It is especially used for basic experiments to help sophmore students for learning circuit theory. There are 17 sets for different techonogies.

This laboratory is used for educational purposes. Students apply their theoretical information’s to the real world which they learnt at EE201 Circuit Theory I & EE202 Circuit Theory II. This laboratory is for undergraduate students and all students can use this laboratory when they want. Beside this Lecturers and research assistants of department can use the laboratory for Lecture and Recitation hours.

HARDWARE

Com3 Lab

Com3Lab is a useful tool for experiments under the control of PC unit. Com3Lab software provides support for students to follow the course easily. Students can monitor what happened in the experiments. Tutors can control students' studies and their success in experiments with Com3Lab software.

Digital Multimeters

For efficient electrical diagnosis The C.A 5210G is a fully-protected, 4000-count, digital instrument, compliant with standards, for non-deformed, sinusoidal networks.

AC/DC voltage: 400mV to 600V (5 cal.)

Typical accuracy: 1%

Resistance: 400O to 40MO (6 cal.)

Audible continuity test (R < 400)

Impedance: 10MO (Velec low impedance of 270kO)

HOLD function, 40- segment bargraph

Diode test

Capacity: 4 to 40µF (5 cal.).

Shockproof sheath

Electrical safety: IEC 1010 -1.600V Cat III

Dimensions: 177 x 64 x 42mm - weight: 350g

Osciolscopes

35MHz Standard Oscilloscope HM303-6

Vertical: 2 Channels, 1mV/div - 20V/div, 1kHz/1MHz Calibrator

Time Base: 0.2s to 100ns/div; with Magnifier x10 up to 10ns/div

Triggering: DC-100MHz; Component Tester

The HM303 is capable for waveform display in the DC to 100MHz frequency range.

25

DC Power Supplies

-15 < V < +15 V variable output, 1A

+5 V fixed output

AC Stabilizer

EQUIPMENTS

Plug In Board

The plug-in board is the foundation for all of the circuits assembled with STE system "Electrical Engineering and Electronics". It contains a number of electrically interconnected socket areas with 4 mm sockets symmetrically arranged in a 19 mm and 50 mm raster for connecting plug-in elements.

Electronic Components I

Passive Electronic Components:Resistors, Capacitors, Inductors etc.

Electronic Components II

Active Electronic Components:BJTs, FETs, OPAMPs etc.

Sets

There are 17 experiment sets for different techonogies. These are

• DC Technology

• AC Technology

• Discrete Components and Basic Electronic

• Basic Logic Circuits

• Multivibrator Circuits

• Amplifier Circuits

• Oscillator Circuits

• High Frequency Circuit

• Timer Circuits

• Operational Amplifier Basic Circuits

• Active Filters

• Analog Computer Circuits

• Electronic Measuring Instruments Circuits

• Controller Circuits

• Optoelectronic Components

• Power Supply Circuits with Discrete Semiconductors

• Power Supply Circuits with IC's

Electronics Laboratory

This laboratory is designed to be used for Electronics I-II and related courses, project studies and research in both undergraduate and postgraduate education.This laboratory can be used both education and research.

26

HARDWARE

Some of the equipments used:

• Digital multimeter (Protek 506 digital multimeter)

• Oscilloscope

• DC power supply

• Function generator

• Passive electronic components (resistors, capasitors vb.)

• Active Elektronic Components (BJTs, FETs, OPAMP's...)

Digital Multimeter(PROTEK 506)

PROTEK 506 digital multimeter

Features:

10MHz frequency counter

True RMS AC voltage (to 750V) and current (to 20A) readings

DC Volts to 1000V and DC current to 20A.

RS-232 interface and software for downloading measurements to a PC

Decibel mesaurement

Analog Bargraph

10 memory locations

Time and stop watch mode with Alarm

Min., Max., Avg and Relative mode

Capacitance and Inductance measurement

Temperature measurement in Centigrade and Fahrenheit

Pulse generator output

Continuity and Diode test

Logic probe

Auto power off and "keep on" modes

Fused 20A input with warning beeper

Back light

Data hold and run mode

Low battery indicator

All functions have annunciators

Overload protection for all functions

Designed in compliance with UL1244 and VDE-0411

Oscilloskope(TOPWARD)

35MHz Standard Oscilloscope HM303-6

Vertical: 2 Channels, 1mV/div - 20V/div, 1kHz/1MHz Calibrator

Time Base: 0.2s to 100ns/div; with Magnifier x10 up to 10ns/div

Triggering: DC-100MHz; Component Tester

The HM303 is capable for waveform display in the DC to 100MHz frequency range..

DC power supply (TOPWARD 6303)

5 volt / 5 amper

Constant voltage / Current Standart

Series capacitance can be connected with different models (< 240 volt),

Parallel capacitance can be connected with same models ( < 24 amper)

Short circuit security: Standart

External input security: Standart

Digital Function Generator

TOPWARD 8150 digital sweep function generator

Arbitrary Waveform Generators 0.1Hz to 10MHz Digital Function Generator

27

EXPERIMENTS

1.

Measurement Techniques

2.

Diode Characteristics

3.

Series and Parallel Diode Configurations

4.

Half-Wave and Full-Wave Rectification

5.

Light Emitting and Zener Diodes

6.

Bipolar Junction Transistor (BJT) Characteristics

7.

Fixed and Voltage-Divider Bias of BJT

8.

Emitter and Collector Feedback Bias of BJTs

9.

Common Emitter Transistor Amplifiers

10.

Common-Base and Emitter-Follower Transistor Amplifiers

11.

Junction Field Effect Transistor (JFET) Characteristics

12.

JFET Bias Circuits

13.

Compound Configurations

14.

Multistage Amplifiers – RC Coupling

15.

Darlington and Cascode Amplifier Circuits

16.

Frequency Response of Common Emitter Amplifiers

17.

Class A & Class B Power Amplifiers

18.

Current Source and Current Mirror Circuits

19.

Differential Amplifier Circuits

20.

Linear Operational Amplifier Circuits

21.

Comparator Circuits Operation

Communication Laboratory

This laboratory is designed to be used for communication-related courses, project studies and research in both undergraduate and postgraduate education. Some of the relavant courses are Communication I-II,

Communication Electonics, Wireless And Mobile Communications.

Communication laboratuary is used for education and research. Equipment of this laboratory is high quality and sensitive for measuring with computer software interface, because of that senior students are prefered fort his laboratory.

Students can learn teorik education with experimental application in this laboratory; Communication,

Communication Electronics, RF Electronics. Bachelor's and Master student use this laboratory senior project or final project. Bachelor's students can use this laboratory with responsible assistant. Our department instructors and assistants can use this laboratory for extra education time.

HARDWARE

50 MHz Analog/Digital Oscilloscope

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Analog mode:

Basic data and functions

Digital mode:

Single, refresh, envelope, average, roll and XY modes

Low-noise 8-bit Flash A/D converters with max. 100MSa/s real time sampling, 2 GSa/s random sampling and 2 kPts memory per channel

Pre-/Post-Trigger -10 cm to +10cm

Digital time base 100 s – 100 ns/cm, with X magnification up to 20 ns/cm

Programmable mathematical signal processing

RS-232 interface for control and signal data transfer, incl. Windows® software

Protek 506 Digital Multimeter

Dual display for Frequency, AC voltage and Temperature measurements

True RMS AC Voltage, Current and DB Readings

RS-232 interface & software, 10 location memory

Min, Max, Avg and Relative modes

Capacitance, Inductance, Frequency and Temp measurements

Square wave generator, logic function and back light

HM5014 1GHz Spektrum Analyzer with Tracking Generator, Readout and RS232-Interface

Frequency range: 150 kHz to 1 GHz

Amplitude measurement range: – 100 dBm to + 10dBm

Phase Synchronous, Direct Digital frequency Synthesis (DDS)

Resolution bandwidths (RBW): 9 kHz, 120 kHz and 1MHz

Pre-compliance EMI measurement

Serial interface for documentation and control software for documentation included

Additional measurement functions for EMI measurements with optional software

Tracking Generator with output amplitude from – 50 dBm to + 1dBm

HM8134-3 1.2 GHz RF-Synthesizer

Frequency range from 1 Hz to 1.2 GHz

Frequency resolution 1 Hz (accuracy 0.5 ppm)

Output power from –127 dbM to + 13 dBm

High spectral purity

AM / FM / PM and gate modulation

HM8018 3½-Digit LC Meter

Measurement functions: L, C, R

3 ½-digit display with 2,000 counts, basic accuracy 0.5%

4-wire measurement

Max. resolution: 0.1 pF, 0.1 µH, 10 mO, 0.01 µS

Internal bias for electrolytic capacitors selectable

Offset adjustment of cable capacity for the “Kelvin test lead”

AC voltage signal at rear-panel

BNC connector proportional to value shown in the display

HM8040-3 Triple Power Supply Unit

2x 0–20 V / 0.5 A, 5 V / 1 A

3-digit switchable displays for current and voltage

Display resolution 0.1 V/1mA

Adjustable current limiting

Linear in line regulator

Low residual ripple and low noise

Pushbutton for activating/deactivating all outputs

Electronic fuse

HM8030-6 10 MHz Function Generator

Frequency range 50 mHz to 10MHz

High signal purity and amplitude stability

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Distortion factor ‹ 0.5 % up to 1 MHz

Output voltage 20 Vpp (10 Vpp into 50?)

Surge- and short-circuit-proof output

Rise and fall time typ. 15 ns

Internal and external sweep

Pulse width adjustment

Highly accurate digital frequency display

Protek 9502A Function Generator

3Mhz function Generator

Sine, Triangle, Square, Pulse, Ramp, Slesed Sine Waveform

Sync. Out (TTl Square Waveform)

Sweep Function

VCG Input

DC Offset

AM Modulation

Communication Laboratory Set

This set is used for Communication related courses and manufactured at Fatih University by its students as an industrial training project. Some of the experiments that can be taugt by this set are:

AM/FM Modulation and Demodulation

A/D and D/A conversion

PWM Modulation and Demodulation

FSK Modulation and Demodulation

Second-Order Filters

SOFTWARE

Hameg SP107

The software is used for controlling oscilloscope from a windows based computer. It also stores the figures and datas on oscilloscope.

EXPERIMENTS

1.

INTRODUCTION TO COMMUNICATION I LABORATORY

2.

ANALOG TO DIGITAL (A/D) CONVERTORS

3.

DIGITAL TO ANALOG (D/A) CONVERTERS

4.

PWM MODULATORS

5.

PWM DEMODULATORS

6.

SECOND-ORDER FILTERS

7.

AM MODULATORS

8.

AM DEMODULATORS

9.

FSK MODULATORS

10.

FSK DEMODULATORS

11.

FM MODULATORS-I

12.

FM MODULATORS II

13.

FM DEMODULATORS

14.

FREQUNCY MULTIPLICATION USING A NONLINEAR AMP.

15.

NONLINEAR MIXING PRINCIBLES

Control Systems Laboratory

This is a multipurpose control laboratory which is designed to be used for control-related courses, project studies and research in both undergraduate and postgraduate education. Some of the relavent courses are Linear Control

Systems, Process Control, Robotics, Discrete Time Control. As you can see in the following, the laboratory provides the students with comprehensive hardware and software facilities, such as process control system, pneumatic systems, robot station, PLCs, sensors, control station, fluidsim, matlab, simatic7, fide and so on.

HARDWARE

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Compact Process Control System

This system combines four fundamental process control sets with digital and analog sensors and actuators as follows:

•Level controlled system

•Flow rate controlled system

•Pressure controlled system

•Temperature controlled system

The set may be controlled using a PLC or a controller. It is also possible to perform experiments on the processes individually.

Pneumatic Systems Pneumatics equipment set

Training aims:

•Physical fundamentals

•Fundamentals and terminology of control technology: Control sequence, signal flow circuit planning and display

•Pneumatic power components for linear motion

•Pneumatic directional control valves

•Pneumatic pressure, non-return and flow control valves

•Logic elements and diagrams

•Simple controls

•Safety requirements

Electropneumatics equipment set

Training aims:

•Physical fundamentals of electricity and pneumatics

•Function and use of electropneumatic devices

•Display of motion sequences and switch states

•Set-up of controls with relays

•Electrical self-latching switches

•Using a magnetic proximity switch

•Using a pressure switch

•Troubleshooting simple electropneumatic controls

Siemens S7-300 and Festo

Training aims:

•Benefits of the PLC compared to conventional solutions such as electrical, electropneumatic or electrohydraulic solutions

•Functions of system components of a PLC

•Commissioning a PLC

•Application criteria for mechanical, optical, capacitive and inductive proximity switches

•Sequence control and parallel logic

•Systematic programming of a PLC in accordance with international standard IEC 1131-3

•IEC 1131-3 programming languages: Function Block Diagram, Ladder Diagram, Statement List,

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Structured Text and Sequence Language

Training aims:

•Benefits of the PLC compared to conventional solutions such as electrical, electropneumatic or electrohydraulic solutions

•Functions of system components of a PLC•Commissioning a PLC

•Application criteria for mechanical, optical, capacitive and inductive proximity switches•Sequence control and parallel logic

•Systematic programming of a PLC in accordance with international standard IEC 1131-3

•IEC 1131-3 programming languages: Function Block Diagram, Ladder Diagram, Statement List,

Structured Text and Sequence Language

Sensors

•Proximity sensors

This set contains magnetic, inductive, capacitive and optical proximity switches based on ultrasound technology.

•Sensors for distance and displacement

It can be made distance measurement with inductive sensors and optical sensors., position measurement with linear potentiometers and with ultrasound sensors

•Sensors for force and pressure

It contains both digital sensors, such as mechanical and electronic pressure switches, and analog sensors, such as strain gauges and analog pressure sensors.

Mitsubishi RV-2 AJ

Mitsubishi RV-2 AJ is a 5-DOF anthropomorphic robot. One of the tasks that can be accomplished on the robot station is

•To determine the material characteristics of a work piece,

•To remove workpieces from a retainer,

•To deposit workpieces on the assembly retainer,

•To deposit the workpieces into the "red/metallic" magazine or the "black" magazine or

•To pass on the workpieces to a subsequent station.

Com3LAB

It is an interactive, multimedia, teaching and learning environment covering the theory and practice. It consists of a master unit and a number of different courses . Some example experiments are given in the following:

Open-loop and closed-loop control

Controlled systems with/without compensation

Analog and digital PID control

Performance criteria for automatic controls

Practical control system examples

Fault simulation

Advanced experiments

Fuzzy control

Adaptive control

Automation and Bus Technology

PLC: Logic connections, times, counters, data processing and program editing

Simple sensors and signal conditioning with analogue digital transformers and multiplexer

Projecting of an automatization system

Data transfer structures and protocols

Transfer and error analysis

Connection of external components

Link of PROFIBUS users (GSD)

EXPERIMENTS

Robot Arm Control

Process Control

Com3Lab Experiments

PLC Experiments

Electropnomatic Experiments

32

Digital Logic Design Laboratory

The objectives of this laboratory are to learn to: design, implement and test combinational and sequential circuits using gates, MSI circuits ; use a rudimentary features of a hardware-description language (specifically, HDL) for specifying logic circuits; account for the electrical characteristics of devices; use state-of-the-art design software for drawing (schematic capture) and simulating logic circuits; and implement and test some designs via hardware and software projects, using test equipment.

This laboratory presents approximately 18 laboratory experiments in Digital Logic Design I and II courses. The digital circuits can be constructed by using standart integrated circuits (ICs) mounted on breadbords that are easily assembled in the laboratory. The experiments are ordered according to the laboratory book. Each experiment is presented informally and the student is expected to produce the circuit diagram and formulate a procedure for checking the operation of the circuit in the laboratory.laboraty can be used both education and research.

HARDWARE

List of basic ICs used in the laboratory

Definition of ICs: I

JK type Flip-Flops

Parallel Counter

Quadruple 2x1 Multiplexer

Shift Register ( 4-Bit )

AND Gate

NAND gates, NOR gates

XOR Gate

Memory Unit (16x4 Random Access Memory)

OR Gate

Timer

4-Bit Ripple Counter

Inverter

Bidirectional Shift Register

Cs no:

7476

74161

74157

74179 or 74195

7408

7400, 7402

7486

7489

7432

72555 or 555

7493

7404

74194

D type Flip-Flops

4-Bit Binary Adder

4-Bit Synchronous Counter

Breadboards

IC chip Boards

7474

7483

74161

In this laboratory, the chip boards are used as an additional original IC applications. The student may use these instead of using ICs one by one. These units are combinatinal circuits. Some of them includes many chips.

HDL and VHDL based systems

Hardware Description Language (HDL) is an essential CAD tool that offers designers an efficient way for implementing and synthesizing the design on a chip.

HDL Programming Fundamentals: VHDL and Verilog teaches students the essentials of HDL and the functionality of the digital components of a system.Unlike other texts, this book covers both IEEE standardized

HDL languages: VHDL and Verilog.

33

Both of these languages are widely used in industry and academia and have similar logic, but are different in style and syntax. By learning both languages students will be able to adapt to either one, or implement mixed language environments, combining the best features of the two languages in the same project.

The basic concepts of HDL, and covers key topics such as data flow modeling, behavioral modeling, gate-level modeling, and advanced programming.

Several comprehensive projects are included to show HDL in practical application, including examples of digital logic designg, and simulation.

Com3Lab Software

Com3Lab Software The software takes the student in easy stages through each aspect of electrical engineering.

The material contains plenty of examples, animations, videos, spoken commentaries etc.

EXPERIMENTS

• Review of Fundamental Concepts and An Introduction to the TTL Family

• Basic Two-Level Circuits

• Implementation with One Gate Type

• Expression Reduction Techniques

• Multiplexors and Demultiplexors

• 4 bit Binary adders

• Latches Flip-flop

• Sequential Circuits

• Counter Circuits

• Shift Registers

• Serial Addition

• Memory Units

• Lamp Handball

• Clock Pulse Generator

• Parallel Adder

• Binary Multiplexer

Microcontroller Laboratory

The microprocessor laboratory facilitate students with doing experiments using 8 and 16-bit microprocessors along with many components, such as timers, counters, vector interrupt units, AD/DA converter cards etc. It also provides microcontroller applications and interfacing with the physical world. This laboratory is for both education and research.

Microprocessors / Microcontrollers

The microprocessors in the lab are 8085, 8088 Intel which can be used in the experiments run by students. The processor 80C85 is on board in the com3lab and mainly used for teaching purposes. We have the RAM and

EPROM cards, input and output units, and interfacing hardware regarding these processors.

MC 80535, PIC 16F877 and PIC 18F452 are the microcontroller units with its interfacing cards used in the lab experiments. We mount these onto the MFA unit which provides the bus connections. We can load the assembly codes through bus signal generator cards and monitor the results on the bus signal analyzer unit.

34

Equipments

Some of the equipments we use are 8085, 8088 and 80C85 processors, 80535, PIC 16F877 and PIC 18F45 microcontrollers, 64K and 8K RAM/EPROM units, Quadruple Timers, Vector Interrupt Units, Timer/Counters,

2-Channel Analog in-output cards, MC Interface Port 1-3-4-5, V.24 / RS 232 Interface cards etc

Com3LAB

The Com3Lab is used to have all the experiments using a PC control. The students can monitor what happens in the microprocessor, that is on the bus, processor, RAM, etc.

The software takes the student in easy stages through each aspect of electrical engineering. The material contains plenty of examples, animations, videos, spoken commentaries etc.

MFA Unit

The MFA unit provides the bus connections between the processor, RAM and EPROM cards, input and output units and bus signal generator and analyzer and all other required harware for the experiments.

EXPERIMENTS

• Assembly Language Programming .

• Blink "Alive" LED every two seconds by using PIC 18F452.

• Generating a simple PWM wave format without using the internal PWM generator of the PIC18F452.

• Some applications on LCD display.

• Using LM35 Temperature Sensor to measure room temperature and writing the temperature degree on

LCD display.

• The Serial Port Communication by using Hyperterminal Program.

• Data transfer PC to PC by Using Parallel Printer Ports with Debug

E-607 Laboratuvarı Eklenecek

35


First Semester

INFO 111 Basic Computer Skills


CENG 103 Fundamentals of Computer

Programming I




Second Semester





EEE 122 Digital Logic Design

Third Semester

APHR 101 Atatürk's Principles and History of Turkish Rev. I

EEE

EEE

201 Circuit Theory I

285 Electromagnetic Field Theory

MATH 204 Complex Analysis I

MATH 230 Differential Equations


Fourth Semester

APHR 102 Atatürk's Principles and History of Turkish Rev. II

EEE

EEE

202 Circuit Theory II

286 Electromagnetic Wave Theory

EEE 237 Introduction to Microprocessors

MATH 348 Intro. to Probability & Statistics


Fifth Semester

EEE 299 Industrial Training I

EEE

EEE

321

353

Electronics I

Signals and Systems

EEE 361 Electrical Machinery I

EEE 371 Low Voltage Power Systems


+

Sixth Semester

EEE 316 Communications I

EEE

EEE

322

338

Electronics II

Linear Control Systems

EEE

EEE

362 Electrical Machinery II

373 High Voltage Techniques


0 2 NC 2 -

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EEE 399 Industrial Training II

EEE 4xx Technical Elective I

*

EEE 4xx Technical Elective II

*

XXX xxx Technical Elective III

**

XXX xxx Technical Elective IV

**


+


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Eighth Semester

EEE 498 Senior Design Project

EEE 4xx Technical Elective V

*

XXX xxx Technical Elective VI

**

XXX xxx Technical Elective VII

**


**


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* Students must select courses from the specialization options technical electives list shown below.

** Students must select courses from the technical electives lists shown below, excluding the courses of the specialization option.

+Students must select 3-credit courses with the following codes only: ACL, GEO, ELL, HIST, ECON, MAN,

PUB, INT, PHIL, PSY, SOC, ENG, GER, CHN, RUS, SPAN, ARAB, PERS, FRA. Courses from PREP

Program can not be chosen.


Communication Options


EEE 411 Communications II

EEE

EEE

412

413

Wireless and Mobile Com.

Communication Electronics


3 2 4 7 9

3

3

2

2

4

4

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9

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Electronics Option


EEE 421 Anolog Integ. Circuit Design

EEE

EEE

422 Radio-Frequency

Microelectronics

423 Power Electronics I

Theo.

3

3

3

Prac.

2

2

2

Credits

4

4

4

ECTS

7

7

7

Workload

9

9

9

Controls Option


EEE 431 Discrete Time Control Systems

EEE

EEE

432

433

Process Control

Control System Design

Power Systems Option


EEE 471 Power System Analysis I

EEE

EEE

472

473

Power System Analysis II

High Voltage Technique

Electrical Machinery Option


EEE 461 Static Power Conversion I

EEE

EEE

462

463

Static Power Conversion II

Machine Drive Systems


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EEE

EEE

EEE

EEE

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EEE

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EEE

EEE

EEE

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EEE

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EEE

EEE

EEE

EEE

EEE

EEE

EEE

EEE

EEE

EEE

EEE

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EEE

EEE

EEE

EEE

EEE


EEE 401 Data Acquisition and Instr.

EEE 402 EE 402 Instrumentation and

Measurement

EEE

EEE

EEE

EEE

411

412

413

414

Communications II

Wireless and Mobile Com.


Satellite Communications

415

416

417

418

419

421

422

Intro. to Mod. and Coding

Intro. to Optical Fiber Com.

Error-Correcting Codes

Digital Communications

Ran. Proc. for Com., Sig. Proc.

Analog Integ. Circuit Design

Radio-Frequency

Microelectronics

423 Power Electronics I

424 Digital Integ. Circuit Design

425 Introduction to VLSI Design

426 RC Active Filter Design

427 Power Electronics II

428 Solid State Electronics

429 Semiconductor Devices

431 Discrete Time Control Systems

432 Process Control

433 Control System Design

434 Modern Control Theory

435 Robot Dynamics and Control

436 Mechatronics

437 Intelligent Control Systems

438 Microcontroller Based Sys.Des

439 HDL Based Logic Design

444 Opto Electronics

445 Fiber Optic Sensors

451 Digital Signal Processing

452 Fund. of Biomedical Eng.

453 Medical Imaging Systems

455 Spectral Analysis and Filtering

456 Digital Filter Design

457 Intro. to Image Processing

458 Computer Vision

461 Static Power Conversion I

462 Static Power Conversion II

463 Machine Drive Systems

464 Design of Electrical Machines

465 Dynamics of Electrical Machines

466 Utilization of Electrical Energy

471 Power System Analysis I

472 Power System Analysis II

473 High Voltage Technique

474 Electrical Distribution Systems

475 Power System Protection

476 Electrical Power Plants

477 Illumination Techniques and Indoor

Installation

484 Intro. to Antennas and Propagation

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EEE

EEE

EEE

485 Microwave Theory

486 Intro. to Electronic Compatibility

495 Special Topics in Electronics

Engineering I

EEE 496 Special Topics in Electronics

Engineering II

CENG 362 Computer Networks

CENG 451 Introduction to MIS


CENG 463 Network Programming

CENG 465 Mobile and Wireless Networking

CENG 482 Network Security

CENG 483 Computer Architecture

CENG 484 Embedded Systems

CENG 490 Intro. to Art. Intelligence


CENG 492 Intro. to Pattern Recog.

IE 345 Simulation

IE

IE

411

413

Reliability and Maintainability

Human Factors Eng. I

IE

IE

420 Human Factors Eng. II

435 Quality Control

MATH 330 Numerical Analysis II

MATH 437 Numerical Sol. of Ord. Diff.

Eqns.

MATH 450 Game Theory

MATH 466 Finite Element Solutions of Ord.

Diff. Eqns.

MATH 480 Optimization

PHYS 423 Semiconductor Physics

PHYS 424 Lasers

PHYS 426 Magnetic Prop. of Solids

PHYS 427 Optical Prop. of Solids

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EEE 201 Circuit Theory I

EEE 202

EEE 237

EEE 285

EEE 286

EEE 292

EEE 299

EEE 316

EEE 321

EEE 322

EEE 338

EEE 353

EEE 361

EEE 362

EEE 363

EEE 371

EEE 391

Circuit Theory II

Introduction to Microprocessors

Electromagnetic Field Theory

Electromagnetic Wave Theory

Electronic Circuits and Devices


Communications I

Electronics I

Electronics II


Linear Control Systems

Signals and Systems

Electrical Machinery I

Electrical Machinery II

Introduction to Power Electronics

Low Voltage Power Systems

Introduction to Electrical Circuits

Prerequisite

PHYS 104, MATH 113, or Chairman’s consent

MATH 204, EEE 201, or Chairman’s consent

CENG 102, EEE 122, or Chairman’s consent




Students are required to pass at least 3 EEEcoded courses

EEE 353, or Chairman’s consent


EEE 202, EEE 321, or Chairman’s consent







PHYS 104, MATH 113, or Chairman’s

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EEE 392

EEE 399

EEE 401

EEE 402

EEE 411

EEE 412

EEE 413

EEE 414

EEE 415

EEE 416

EEE 417

EEE 418

EEE 419

EEE 421

EEE 422

EEE 423

EEE 424

EEE 425

EEE 426

EEE 427

EEE 428

EEE 429

EEE 431

EEE 432

EEE 433

EEE 434

EEE 435

EEE 436

EEE 437

EEE 438

EEE 439

EEE 444

EEE 445

EEE 451

EEE 452

EEE 453

EEE 455

EEE 456

EEE 457

EEE 458

EEE 461

EEE 462

EEE 463

EEE 464

EEE 465

EEE 466

EEE 471

EEE 472

EEE 473

EEE 474

Introduction to Electronic Circuits

Indusrial Training II consent


Students are required to pass at least 7 EEEcoded courses excluding EEE 299

Data Acquisition and Instrumentation EEE 322, EEE 353, EEE 237, or Chairman’s consent

Instrumentation and Measurement EEE 202, or Chairman’s consent

Communications II

Wireless and Mobile

Communications





Introduction to Modulation and




Coding

Introduction to Optical Fiber

Communications

Error-Correcting Codes

EEE 286, EEE 311 or Chairman’s consent


Random Processes for

Communications and Signal

Processing

Analog Integrated Circuit Design

Radio-Frequency Microelectronics

Power Electronics I

Digital Integrated Circuit Design

Introduction to VLSI Design

RC Active Filter Design

Power Electronics II

Solid State Electronics

Semiconductor Devices


Process Control

Control System Design

Modern Control Theory

















Robot Dynamics and Control

Mechatronics



Intelligent Control Systems EEE 338, or Chairman’s consent

Microcontroller Based System Design CENG 112, EEE 122, or Chairman’s consent

HDL Based Logic Design CENG 112, EEE 122, or Chairman’s consent

Opto Electronics

Fiber Optic Sensors

Digital Signal Processing

Fundamentals of Biomedical

Engineering

Medical Imaging Systems

Spectral Analysis and Filtering





Digital Filter Design

Introduction to Image Processing

Computer Vision

Static Power Conversion I



Design of Electrical Machines

Dynamics of Electrical Machines









EEE 362, or Chairman’s consent.


Utilization of Electrical Energy

Power System Analysis I

Power System Analysis II




High Voltage Technique EEE 286, or Chairman’s consent

Power System Stability and Dynamics EEE 362, or Chairman’s consent

40

EEE 475

EEE 476

EEE 477

EEE 484

EEE 485

EEE 495

EEE 496

EEE 498

Advanced High Voltage Techniques

Computer Methods in Electric Power

Introduction to Antennas and

Propagation



Engineering

Wave Propagation in Power Systems EEE 202, or Chairman’s consent


Microwave Theory

Special Topics in Electronics

Engineering I

Special Topics in Electronics

Engineering II

Senior Design Project

EEE 286, or Chairman’s consent.



Senior standing, or Chairman’s consent

EE 104

EE 273

EE 273

EE 274

EE 274

EE 271

EE 286

EE 299

EE 377

EE 385

EE 391

EE 392

EE 393

EE 399

EE 411

EE 411

EE 414

EE 416

EE 416

EE 418

EE 422

EE 428

EE 431

Old Course

Code

CHEM 101

CHEM 105

CENG 109

CENG 101

CENG 102

CENG 494

EE 101

*

EE 391

EE 392


Old Course

Name

Principles of Chemistry I

General Chemistry I

Intro. to Computer

Programming

Computer Programming I

Computer Programming II

Intro. To Computer Vision

Introduction to Electrical Eng.

Freshman Design Project

Fundamental of Logic Design I


Digital Logic Design II

Fundamental of Logic Design II



Summer Practice I

Introduction to Microprocessors

New Course

Code

CHEM 105

CHEM 107

CENG 112

CENG 103


Programming II

Computer Vision EE 458

EE 101

**

Introduction to Electronics

Eng.

ENGR 100 Introduction to Engineering

Design

EE 273

EE 271

CENG 252


Digital Logic design

Computer organization

EE 273

EEE 122

EEE 285

EE 299

EEE 237

EEE 286

EE 391

EE 391

New Course

Name

General Chemistry I

General Chemistry

Intro. to Computer

Programming

Fundamentals of Computer

Programming I

Digital Logic Design II




Introduction to

Microprocessors


Intro. to Electrical Circuits and

Electronics

Intro. to Electrical Circuits


Electrical Circuits and

Electronics

Intro. to Electrical Circuits and

Electronics

Fundamentals of Electronic

Circuits

Intro. to Electronic Circuits

Intro. to Circuit Theory

Summer Practice II

Communications II


Communications


Satellite Communication

Communications II

Communications Theory



Disc. Time Sys. & Dig. Cont.

EE 392

EE 292

EE 391

EE 399

EE 416

EEE 416

EE 411

EE 414

EEE 411

EE 418

EEE 428

EEE 429

EE 431

Intro. to Electronic Circuits

Electronic Circuits and Devices


Industrial Training II

Communications II


Communications



Communications II





41

EE 454

EE 464

EE 465

EE 475

EE 475

EE 476

EE 497

EE 498

ENG 101

ENG 102



Engineering


Microcontrollers

Microcontroller Based System

Design

HDL Based Logic Design

Senior Design Project I

Senior Design Project II

Developing Reading and

Writing Skills

Developing Communication

ENG 122

HUM 101

Skills

Academic English II

Humanities I

MATH 331E Numerical Analysis

**

EE 451

EEE 452

EEE 453

EE 475

EEE 438

EEE 439

EEE 498

ENG 101

ENG 102



Engineering



Design


Design

HDL Based Logic Design

Senior Design Project

Advanced English I

Advanced English II

ENG 102

ENG 101

MATH 329

1

EE (old) and EEE (new) are equivalent in all courses not shown in this table.

*

Repeating Students will register for “EE 391-Intro. to Electrical Circuits.”

**

Students who failed this course will have an exemption.

Advanced English II

Advanced English I

Numerical Analysis I

42

DOUBLE MAJOR PROGRAM

First Semester


Fifth Semester

EEE 321 Electronics I


Contact/Credit Hours Second Semester

(3+0) 3

(3+0) 3

Third Semester

EEE

EEE

201

285

Circuit Theory I


MATH 204 Complex Analysis I


(3+2) 4

(3+0) 3

EEE

EEE

202

286

Circuit Theory II



(3+2) 4

(3+0) 3

(3+0) 3

(9+2) 10

MATH 230 Differential Equations (3+0) 3

(9+2) 10

(3+2) 4

(3+2) 4

(6+4) 8

EEE

EEE

EEE

122 Digital Logic Design


322

362

Electronics II

Electrical Machinery II


(3+2) 4

(3+2) 4


(3+2) 4

(3+2) 4

(6+4) 8


EEE 353 Signals and Systems

EEE 371 Low Voltage Power Systems



(3+0) 3 EEE 316 Communications I

(3+0) 3

(3+x) X

(9+2) 6

EEE

EEE

338 Linear Control Systems

4xx Technical Elective II

*


(3+0) 3

(3+2) 4

(3+x) X

(9+4) 7

Total credits required in Double Major Program: 56

The minimum cumulative GPA requirement is 3.50.

If the prerequisite(s) of a course above is not present in the double major program, it will not be required.

Students taking equivalent courses (Equivalence will be decided by the department council) in their main program will be exempt from some of the above courses; If the total credits drops below the minimum level of 42 in this case, it must be completed to at least 42 by sufficient number of the EEE

4xx technical elective courses.

Third Semester


MINOR PROGRAMS

MINOR in ELECTRONICS


(3+2) 4 EEE 202 Circuit Theory II


(3+2) 4

Fifth Semester

EEE 321 Electronics I



*


(3+2) 4 EEE 322 Electronics II


(3+2) 4


(3+2) 4 EEE 4xx Technical Elective II

**


(3+0) 3

Total Credits Required in Minor Program: 23


* Students must select a course from the (3+2) 4 credit minor technical electives list shown below, excluding the courses that are in their main curriculum.

** Students must select a course from the (3+0) 0 credit technical electives list shown below, excluding the courses that are in their main curriculum.

MINOR TECHNICAL ELECTIVES (3+2) 4

EEE 413 Communication Electronics

EEE 421

EEE 422

Analog Integ. Circuit Design

Radio-Frequency Microelectronics

Power Electronics I EEE 423

43

TECHNICAL ELECTIVES (3+0) 3

EEE 401 Data Acquisition and Instr.

EEE 424

EEE 425

Digital Integ. Circuit Design

Introduction to VLSI Design

EEE 426

EEE 427

EEE 444

EEE 445

RC Active Filter Design

Power Electronics II

Opto Electronics

Fiber Optic Sensors

EEE 455

EEE 456

EEE 453

Spectral Analysis and Filtering

Digital Filter Design


MINOR in ELECTRICAL MACHINARY

Third Semester



(3+2) 4 EEE 202 Circuit Theory II

Fifth Semester



(3+2) 4 EEE 362 Electrical Machinery II


(3+2) 4


(3+2) 4



*


(3+2) 4 EEE 4xx Technical Elective II

**


(3+0) 3

Total Credits Required in Minor Program: 23


* Students must select a course from the (3+2) 4 credit minor technical electives list shown below, excluding the courses that are in their main curriculum.

** Students must select a course from the (3+0) 0 credit technical electives list shown below, excluding the courses that are in their main curriculum.

MINOR TECHNICAL ELECTIVES (3+2) 4

EEE 423 Power Electronics I

EEE 461

EEE 462

Static Power Conversion I


EEE 463

EEE 463



TECHNICAL ELECTIVES (3+0) 3

EEE 427 Power Electronics II

EEE 464

EEE 465

EEE 466

Design of Electrical Machines

Dynamics of Electrical Machines

Utilization of Electrical Energy

EEE 474

EEE 475

EEE 476

EEE 477

Electrical Distribution Systems

Power System Protection

Electrical Power Plants

Illumination Techniques and Indoor Installation

44

COURSE DESCRIPTION

EEE 122 Digital Logic Design ECTS 9, Credits (3+2) 4

Binary numbers and codes. Logic elements and networks and their simplification. Truth tables and Boolean algebra, map and table methods for minimizing Boolean expressions. Logic design with gates, MSI and LSI technologies. Combinational logic analysis and design. Sequential logic analysis and design. Design of synchronous and asynchronous counters. Register transfer design. Algorithmic state machines (ASM).

EEE 201 Circuit Theory I ECTS 7, Credits (3+2) 4

Circuit variables. Circuit elements and mathematical models. Simple resistive circuits. Multi-terminal and multiport algebraic components. Techniques of circuit analysis. Reactive components. First and second order RLC circuits.

Prerequisite: PHYS 104, MATH 113, or Chairman’s consent.

EEE 202 Circuit Theory II ECTS 7, Credits (3+2) 4

Sinosoidal steady-state analysis. Three-phase circuits. Laplace transform and its use in circuit analysis. Transfer function; gain and phase characteristics, filters. Fourier series and its applications to circuit analysis.

Prerequisite: MATH 204 , EEE 201, or Chairman’s consent.

EEE 237 Introduction to Microprocessors ECTS 5, Credits (2+2) 3

Introduction to microprocessors, computer organization and embedded systems. Microprocessors and their architectures. Addressing modes. Data movement instructions. Arithmetic and logic instructions. Program control instructions. Interrupts. Programming the microprocessors. Design of simple microprocessor based systems.

Prerequisite: CENG 103, EEE 122, or Chairman’s consent.

EEE 285 Electromagnetic Field Theory ECTS 6, Credits (3+0) 3

Vector Analysis. Electrostatic and Magnetostatic forces and fields in vacuum and in material bodies. Energy and potential. Steady electric current and conductors. Dielectric properties of materials. Boundary conditions for electrostatic and magnetostatic fields. Poisson’s and Laplace’s Equations. Magnetic circuits and inductance.

Prerequisite: PHYS 104, MATH 114, or Chairman’s consent.

EEE 286 Electromagnetic Wave Theory ECTS 5, Credits (3+0) 3

Time-varying fields and Maxwell’s wave equations. Electromotive force. Uniform plane electromagnetic waves in free space and in different media. Electromagnetic wave propagation. Plane wave reflection, refraction and dispersion. TEM waves. Transmission lines. Graphical methods and transient analysis. Guided waves.

Introduction to antennas.

Prerequisite: MATH 230, EEE 285, or Chairman’s consent.

EEE 292 Electronic Circuits and Devices ECTS 7, Credits (3+2) 4

Concept of voltage, current and power. Ohm's law, KCL, KVL. Nodal and mesh analysis. Thévénin equivalent circuits. Semiconductor diodes and diode applications.Transistor biasing and operation. Operational amplifiers and applications. (Electronics Engineering Department students cannot take this course for credit).

Prerequisite: PHYS 104, MATH 113, or Chairman's consent.

EEE 299 Industrial Training I Non-Credit

This is a 6 weeks long summer practice that has to be performed in an industrial organization involved in the design and/or manufacturing and/or maintenance and/or research & development of electronic devices and equipment. The student is to investigate the organization critically regarding their ongoing electronics engineering practices. Observations from the summer practice must be documented and presented in the form of a clear and concise technical report.

Prerequisite: Students are required to pass at least 3 EE-coded courses.

EEE 316 Communications I IECTS 5, Credits (3+0) 3

Revision of Fourier transform. Amplitude modulation: Standart AM, DSB, SSB, VSB, QAM and AM transmission and receiption. Angle modulation: FM and PM transmission and reception. Digital communication techniques: FSK, PCM, PDM, PWM, DPCM and DM.

Prerequisite: EEE 353, or Chairman’s consent.

45

EEE 321 Electronics I ECTS 7, Credits (3+2) 4

Theory of semiconductor materials. pn junction diodes. Zener diodes. Diode circuit analysis and applications.

Bipolar junction transistors (BJTs). Field effect transistors (FETs). DC biasing of BJTs and FETs. Transistor modeling. BJT and FET small signal analysis.


EEE 322 Electronics II ECTS 7, Credits (3+2) 4

Frequency response of BJT and FET amplifiers and their correspondng Bode plots. BJT and FET large signal analysis. Differential and multistage amplifiers. OPAMPs. Power amplifiers. Feedback and oscillator circuits.

Filters and tuned amplifiers. Regulated power supplies.

Prerequisite: EEE 202, EEE 321, or Chairman’s consent.

EEE 338 Linear Control Systems ECTS 7, Credits (3+2) 4

Mathematical models of systems. State variable models: Signal-flow graph state models. Characteristics and performance of feedback control systems. The stability of linear feedback systems: The Routh-Hurwitz criterion.

The root locus method. Frequency response methods: The Bode diagram. Stability in the frequency domain:

Nyquist criterion.


EEE 353 Signals and Systems ECTS 5, Credits (3+0) 3

Continuous-time signals and systems. Continuous-time LTI systems. The Fourier transform and its applications.

State variables for continuous-time systems. Discrete-time signals and systems. Discrete-time LTI systems. The z-transform and its applications. State variables for discrete-time systems.


EEE 361 Electrical Machinery I ECTS 7, Credits (3+2) 4

Electromagnetic circuits; properties of ferromagnetic materials. Single-phase and three-phase transformers. Per

Unit System. Principles of electromechanical energy conversion: Linear and nonlinear systems; singly and multiply excited, translational and rotational systems. DC machines: Theory, generators, motors, speed control.


EEE 362 Electrical Machinery II ECTS 7, Credits (3+2) 4

Electromagnetic fields created by AC electric machine windings: pulsating and rotating magnetic fields, emf induced in a winding. Induction machines: equivalent circuit, steady-state analysis, speed control. Synchronous machines: equivalent circuit, steady-state analysis, stability. Single-phase induction machines. Special electrical machines.


EEE 363 Introduction to Power Electronics ECTS 5, Credits (3+0) 3

Power diodes, thyristors, power transistors, and power MOSFET. Thyristor commutation techniques. Single and three phase controlled rectifiers. A.C. voltage controllers and cycloconverters. D.C. choppers. PWM inverters.

Resonant pulse converters. Power supplies. D.C. drives. A.C.drives.


EEE 371 Electrical Distribution Systems ECTS 5, Credits (3+0) 3

Basic considerations. Load characteristics and forecasting methods. Distribution substations. Subtransmission, primary and secondary distribution. Choice of voltage levels. Operational characteristics of cables, aerial lines and transformers. System voltage regulation. Power factor correction. Fusegear, switchgear, current and voltage transformers. Overcurrent and thermal protection. Earthing methods. Economics of distribution systems.

Prerequisite: EEE 202, or Chairman’s consent.

EEE 373 High Voltage Techniques ECTS 7, Credits (3+0) 3

Field analysis: experimental and numerical (finite difference, finite element and charge simulation) methods and applications. Electrical breakdown in gases: ionization processes. Townsend's breakdown criterion, Paschen's

Law, bread-down in electronegative gases, time lags. Streamer-Kanal mechanism, breakdown in non-uniform field and corona. Electrical break-down of liquids: breakdown mechanism of pure and commercial liquids.

Electrical breakdown of solids: Intrinsic, electromechanical, thermal and erosion mechanism. Insulating materials: dielectric gases; insulating oils and solid dielectrics.


46

EEE 391 Introduction to Electrical Circuits I ECTS 5, Credits (3+0) 3

Concept of voltage, current and power. Ohm’s law, KCL, KVL. Nodal and mesh analysis. Thévénin and Norton equivalent circuits. Capacitor and inductor. Operational amplifiers.

Prerequisite: PHYS 104, MATH 113, or Chairman’s consent. (Electronics Engineering Department students cannot take this course for credit).

EEE 392 Introduction to Electronic Circuits II ECTS 5, Credits (3+0) 3

Semiconductor diodes and diode applications. BJTs: Transistor construction and operation. DC biasing for BJTs:

Operating point. FETs: Construction and characteristics of FETs, MOSFET, enhancement type MOSFET. FET biasing. Operational amplifiers and applications.

Prerequisite: EEE 391, or Chairman’s consent. (Electronics Engineering Department students cannot take this course for credit).

EEE 399 Industrial Training II Non-Credit

This is a 6 weeks long summer practice that has to be performed in an industrial organization involved in the design and/or manufacturing and/or maintenance and/or research & development of electronic devices and equipment. The student is to investigate the organization critically regarding their ongoing electronics engineering practices and suggests improvements. Observations and suggested improvements must be documented and presented in the form of a clear and concise technical report.

Prerequisite: Students are required to pass at least 7 EEE-coded courses excluding EEE 299.

EEE 401 Data Acquisition and Instrumentation ECTS 5, Credits (3+0) 3

Measurement of variables: Electrical, mechanical, thermal, fluid digital transducers. Analog signal conversion.

Computer interface components and techniques. Computer interface systems and standards. Signal processing for data acquisition. Case studies in computerized of complex instrumentation.

Prerequisite: EEE 322, EEE 353, EEE 237, or Chairman’s consent.

EEE 402 Instrumentation and Measurement ECTS 5, Credits (3+0) 3

Units and principles of measurment. Error measurement. Probability of error; estimation, detection. Electronic measurements and electronic measuring instruments: Instrument amplifiers, signal sources, oscilloscopes, digital frequency meters, digital avo-meters, spectrum analyser. High frequency microwave measurement techniques.

Power measurement.


EEE 411 Communications II ECTS 7, Credits (3+2) 4

Introduction to probability theory. Random processes. Review of modulation techniques. AM and FM systems performance in presence of noise. Noise in digital communication systems. Optimal detection of signals and optimum receivers. Introduction to information theory. Error-correction codes.


EEE 412 Wireless and Mobile Communications ECTS 7, Credits (3+2) 4

The fundamentals of wireless channels and channel models, wireless communication techniques, and wireless networks. Statistical models for time-varying narrow band and wide band channels, fading models for indoor and outdoor systems, macro- and micro-cellular system design, channel access and spectrum sharing using TDMA,

FDMA, and CDMA, time-varying channel capacity and spectral efficiency, modulation and coding for wireless channels, antenna arrays, diversity combining and multi-user detection, dynamic channel allocation, and wireless network architectures and protocols.


EEE 413 Communication Electronics ECTS 7, Credits (3+2) 4

Nonlinear controlled sources: piecewise linear, square-law, exponential and differential pair characteristics. Low level amplitude modulation and analog multiplication. Narrow band transformer as a coupler. Nonlinear loading of tuned circuits. Tuned large signal amplifiers and frequency multipliers. Phased locked loops. Sinusoidal oscillators. Frequency synthesizers, mixers, modulators, and demodulators. Basic transmitters and receivers.


47

EEE 414 Satellite Communications ECTS 5, Credits (3+0) 3

Theory and practice of satellite communications. Orbits and launchers, spacecraft, link budgets. Modulation, multiplexing, coding and multiple access techniques. Propagation effects. Receivers and noise temperatures.

Telemetry, tracking and command. Systems performance.


EEE 415 Introduction to Modulation and Coding ECTS 5, Credits (3+0) 3

Discrete sources and entropy. Channels and channel capacity. Run-length-limited codes. Linear block errorcorrecting codes. Cyclic codes. Convolutional codes. Trellis-coded modulation. Information theory and cryptography. Shannon's coding theorems.


EEE 416 Introduction to Optical Fiber Communications ECTS 5, Credits (3+0) 43

An introduction to optical communication systems. Optical fiber waveguides. Transmission characteristics of optical fibers. Optical fibers, cables and connections. Optical fiber measurements. Optical sources: Lasers,

LEDs. Optical detectors. Receiver noise considerations. Optical fiber communication systems.

Prerequisite: EEE 286, EEE 316 or Chairman’s consent.

EEE 417 Error-Correcting Codes ECTS 5, Credits (3+0) 3

Algebraic block codes, e.g., Hamming, Golay, Fire, BCH, Reed-Solomon (including a self-contained introduction to the theory of finite fields). Convolutional codes and concatenated coding systems. Encoding and decoding algorithms. Software projects.


EEE 418 Digital Communications ECTS 5, Credits (3+0) 3

Random Signals, Bandwidth of Digital Data, Character Coding, Pulse Code Modulation, Uniform and

Nonuniform Quantization, Correlative Coding, Detection of Binary Signals in Gaussian Noise, Intersymbol

Interference, Equalization, Coherent and Noncoherent Detection, Error Performance of Binary Systems, M-Ary

Signaling and Performance, Waveform Coding, Cyclic and Block Codes, Types of Error Control, Convolutional

Encoding and Decoding Algorithms.


EEE 419 Random Processes for Communications and Signal Processing ECTS 5, Credits (3+0) 3

Introduction to single-parameter random processes. Stationarity and correlation functions. Power spectral density. Gaussian processes. Response of linear systems to random processes.


EEE 421 Analog Integrated Circuit Design ECTS 7, Credits (3+2) 4

Integrated-circuit fabrication. Integrated-circuit devices and modeling. Constant-current and voltage sources.

Differential amplifiers. Operational amplifier characteristics and applications. IC active filters and switchedcapacitor circuits. Voltage comparators and regulators. Current mirrors. Wide bandwidth and video amplifiers.

Voltage-controlled oscillators and waveform generators. Phase-locked loops. D/A and A/D converters.


EEE 422 Radio-Frequency Microelectronics ECTS 7, Credits (3+2) 4

Thermal noise, noise figure, system noise calculations. Non-linear devices, 1-dB compression point, intercept point IP3, sensitivity, and dynamic range. Digital modulation techniques: PSK, FSK, ASK. Frequency hopping and DSSA spread spectrum techniques. Heterodyne and homodyne transceiver architectures. Low noise RF amplifiers, oscillators, voltage-controlled oscillators and mixers.


EEE 423 Power Electronics I ECTS 7, Credits (3+2) 4

Semiconductor power devices and switching circuits. Complementary components and systems. AC-to-DC converters. AC-to-AC converters. DC-to-DC converters. DC-to-AC converters. Switching power supplies.


EEE 424 Digital Integrated Circuit Design ECTS 5, Credits (3+0) 3

Simple NMOS and CMOS logic gates. Processing and layout of bipolar and CMOS devices. Integrated circuit devices and modeling. NMOS and CMOS logic design. Transmission-gate and fully differential CMOS logic

48

design. CMOS timing and I/O considerations. Latches, flip-flops, and synchronous system design. Bipolar and

BiCMOS logic design. Static and dynamic random-access memory design.


EEE 425 Introduction to VLSI Design ECTS 5, Credits (3+0) 3

Size and complexity of integrated circuits (IC), IC design process. Trends in very large scale integrated (VLSI) circuit design. IC production process. Semiconductor processes. Design rules and process parameters. Layout techniques and practical considerations. Device modeling, circuit simulation. Basic integrated circuit building blocks.


EEE 426 RC Active Filter Design ECTS 5, Credits (3+0) 3

Introduction to analog filter design. Study of approximations, passive systems, analysis, sensitivity and stability of active structures. Design of active filters using controlled sources, operational amplifiers, and generalized impedance converters. Study of fabrication technologies for discrete, hybrid, switched capacitor and transconductance amplifier filters.


EEE 427 Power Electronics II ECTS 5, Credits (3+0) 3

Power conditioners and uninterruptible power supplies. DC motor drives. Induction motor drives. Synchronous motor drives. Residential and industrial applications. Thyristors. Snubber circuits. Gate and base drive circuits.

Design of magnetic components.


EEE 428 Solid State Electronics ECTS 5, Credits (3+0) 3

Semiconductor materials. Crystal structure of solids. Schrodinger’s wave equation. Introduction to quantum theory of solids. Semiconductors in equilibrium. Intrinsic semiconductor. Energy bands and charge carriers.

Extrinsic semiconductor. Carrier drift and diffusion. Excess carriers and ambipolar transport. Pn junction and pn junction diode. Semiconductor technology.


EEE 429 Semiconductor Devices ECTS 5, Credits (3+0) 3

Review of solid state physics. Schottky diode and hetero junctions. Fundamentals of bipolar junction transistors.

MOS-capacitor, MOS and junction filed effect transistors. Principles of optoelectronic devices: Solar cells, ,

LEDs, detectors and laser diodes. IC-process technology.

Prerequisite: EEE 322, or Chairman’s consent.

EEE 431 Discrete Time Control Systems ECTS 7, Credits (3+2) 4

Review of discrete-time systems and the z-transform. z-plane analysis of discrete-time control systems:

Sampling and reconstruction, the pulse transfer function, realization of digital controllers and digital filters.

Stability analysis of closed-loop systems in the z-plane, transient and steady-state response analysis. State-space analysis. Pole placement and observer design. Polynomial equations approach to control systems design.

Quadratic optimal control systems.


EEE 432 Process Control ECTS 7, Credits (3+2) 4

Introduction to process control. Analog and digital signal conditioning. Sensors: Thermal, mechanical, optical.

Final control: Industrial electronics, actuators, control elements. Discrete-state process control: Relay controllers and ladder diagram, PLCs. Controller principles: Control system parameters, controller modes. Analog controllers. Digital control: Computers in digital control, process-control networks. Control-loop characteristics.


EEE 433 Control System Design ECTS 7, Credits (3+2) 4

Review of modeling and continuous-time signals and systems. SISO Control: Analysis of SISO control loops, synthesis of SISO controllers, fundamental limitations in SISO control. Digital computer control: Approximate continuous designs, at-sample design. Advanced SISO control. MIMO control: Analysis of MIMO control loops, exploiting SISO techniques in MIMO control, fundamental limitations in MIMO control. Advanced MIMO control: MIMO controller parameterizations, decoupling.


49

EEE 434 Modern Control Theory ECTS 5, Credits (3+0) 3

Background and preview: Highlights of classical control theory, state variables and the state space description of dynamic systems. Vectors and linear vector spaces. Simultaneous linear equations. Eigenvalues and eigenvectors. Functions of square matrices and the Cayley-Hamilton theorem. Solution of continuous and discrete time state equations. Stability. Controllability and observability for linear systems. State space realization of transfer functions. Introduction to optimal control theory and nonlinear control systems.


EEE 435 Robot Dynamics and Control ECTS 5, Credits (3+0) 3

Introduction to robotics. Robot kinematics: Position analysis, The Denavit-Hartenberg representation.

Differential motions and velocities: The manipulator Jacobian, derivation of the Jakobian, inverse Jakobian.

Dynamic analysis and forces: A short review of Lagrangian mechanics, dynamic equations for MDOF robots, static force analysis of robots. Trajectory planning. Actuators. Sensors. Image processing and analysis with vision systems. Robot control: Independent joint control, multivariable control, force control, variable structure and adaptive control, fuzzy logic control


EEE 436 Mechatronics ECTS 5, Credits (3+0) 3

Introduction to mechatronics and measurement systems. Signal conditioning. Data presentation systems.

Actuating systems: Pnuematic and hydraulic, mechanical, electrical. System models. System response. Closedloop controllers. Digital logic. Microprocessors. Data acquisition. PLCs. Communication systems: Networks, protocols. Fault finding. Mechatronics systems: Case studies.


EEE 437 Intelligent Control Systems ECTS 5, Credits (3+0) 3

Fundamental principles of intelligent systems and their utility in modeling, identification and control of complex engineered systems. Intelligent control approaches. The enabling technologies: Soft computing, conventional methods and information theory; application to data management, sensor fusion, inspection systems, diagnostics/prognostics, supervisory control and fault-tolerant control. Application domains: Textile and fiber processes, pulp and paper, aerospace and automotive systems, etc.


EEE 438 Microcontroller Based System Design ECTS 5, Credits (3+0) 3

Introduction to microcontrollers. Hardware summary. Instruction set summary. Timer operation. Serial port operation. Interrupts. Assembly language programming. Program structure and design. Tools and techniques for program development. Design and interface examples: LCD, ADC, and sensors, stepper motor, keyboard, DAC.


EEE 439 HDL Based Logic Design ECTS 5, Credits (3+0) 3

Introduction to electronic design automation. Hardware modeling in HDL. Event-driven simulation and testbenches. Logic System, data types, and operators for modeling in HDL. User-defined primitives. Propagation delay models. Behavioral descriptions in HDL. Synthesis of combinational logic. Synthesis of sequential logic.

Synthesis of language constructs. Switch-level models. Rapid prototyping with Xilinx FPGAs.


EEE 444 Opto Electronics ECTS 5, Credits (3+0) 3

Maxwell’s equations. The optical fiber: Types, effects of dispersion, attenuation, nonlinearities. Coupling between optical sources and waveguides. Optical detectors and noise. Optical sources: Optical radiation and amplification, lasers. Optical devices: Sensors and modulators.


EEE 445 Fiber Optic Sensors ECTS 5, Credits (3+0) 3

Optical fibers, light sources and detectors, optical modulators. Fundamental building blocks of fiber optic sensors. Fiber optic sensors technology. Extrinsic or hybrid fiber optic sensors, intensity sensors for monitoring temperature, position and other environmental aspects; the Fabry-Perot based fiber optic sensor; grating and displacement fiber optic sensors; and polarization. Intrinsic fiber optic sensors where sensing occurs in the interaction of a light beam with an environmentally perturbed optical fiber.


50

EEE 451 Digital Signal Processing ECTS 7, Credits (3+2) 4

Relationship between continuous-time and discrete-time signals. Review of z-transform. Discrete Fourier transform (DFT). Fast Fourier transform (FFT). Introduction to digital filters. Laboratory sessions can be devoted to real-time implementation of digital signal processing algorithms on digital processor chips.

Experiments involving A/D and D/A conversion, aliasing, digital filtering, sinusoidal oscillators, Fourier transforms, and finite word length effects.


EEE 452 Fundamentals of Biomedical Engineering ECTS 5, Credits (3+0) 3

Introduction to cell physiology: the neuron, synapses and the neural models. Sources of bioelectrical potentials and theory of ECG, EEG, EMG. Electrodes for bioelectric and related instrumentation. Physiology and measurement of neural, circulatory, respiratory and metabolic systems. Phonocardiography. Patient care and monitoring. Telemetry.


EEE 453 Medical Imaging Systems ECTS 5, Credits (3+0) 3

X-Ray imaging: Radiography/mammography, fluoroscopy. CT: Operational modes, the CT gantry, image reconstruction, spiral CT, special imaging techniques, image quality, image artifacts, radiation safety, quality control. MRI: Concepts of magnetic resonance, principles of magnetic resonance imaging, pulse sequences, measurement parameters and image contrast, additional sequence modifications, artifacts, motion artifact, reduction techniques, MR angiography, advanced imaging applications, MR spectroscopy, instrumentation, contrast agents, clinical protocols. PET Scan. Ultrasound scan: The nature of diagnostic ultrasound, ultrasound interaction with tissue, ultrasound power and intensity, the ultrasound beam, the ultrasound imager, doppler ultrasound, ultrasound image artifacts, ultrasound quality control, biologic effects of ultrasound. IR scan.


EEE 455 Spectral Analysis and Filtering ECTS 5, Credits (3+0) 3

An introduction to the application of probability theory to the analysis and design of engineering systems dealing with random signals. Random variables and signals. Correlation functions. Power spectral densities. Gaussian processes. Time and frequency domain descriptions of system responses to random signals. Matched filters and

Wiener filters.


EEE 456 Digital Filter Design ECTS 5, Credits (3+0) 3

Introduction to digital filter design techniques. Properties of finite impulse-response filters. Design of linearphase finite filters. Minimum-phase and complex approximation. Implementation of finite impulse-response filters. Properties of infinite impulse-response filters. Design and implementation of infinite-response filters.

Comparison of filtering alternatives.


EEE 457 Introduction to Image Processing ECTS 5, Credits (3+0) 3

Digital images, sampling and quantization of images. Arithmetic operations, gray scale manipulations, distance measures, connectivity. Image transforms. Image enhancement. Image restoration. Image Segmentation. Image representation and description.


EEE 458 Computer Vision ECTS 5, Credits (3+0) 3

Image formation, image processing for feature detection, object recognition and representation, motion analysis, simple motion estimation problems, stereo vision, camera models and projections.

Prerequisite: EEE 353, or Chairman’s consent

EEE 461 Static Power Conversion I ECTS 7, Credits (3+2) 4

Power switches and their characteristics. Power converter definitions, classification. VTA method. Midpoint and bridge rectifiers: non-ideal commutation, harmonics, input power factor, utility-factor, winding utilization and unbalances in rectifier transformers. Applications.


EEE 462 Static Power Conversion II ECTS 7, Credits (3+2) 4

Introduction to forced commutated circuits, analysis, classification of techniques. Centretap inverter. Voltage-fed inverters; waveshaping; PWM, stepped and square-waveforms, voltage regulation, harmonics. Current-fed

51

inverters; analysis, effect of SCR turn-off time on voltage waveform, overlap. DC-DC switching converters; time-ratio control, effect of loading, parameter optimization. Device failure mechanisms. Thermal considerations, maximum ratings, protection of switching elements. Series and parallel operation of switching elements.


EEE 463 Machine Drive Systems ECTS 7, Credits (3+2) 4

Elements of electric drive systems, power electronic devices, power electronic circuits, joint speed-torque characteristics of electric motors and mechanical loads, speed-torque characteristics of electric motors, speed control of direct current motors, speed control of induction motors, braking of electric machines, braking of dc motors, braking of induction motors, transient time of electric drives system.


EEE 464 Design of Electrical Machines ECTS 5, Credits (3+0) 3

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.

Prerequisites: EEE 362 or Chairman’s consent.

EEE 465 Dynamics of Electrical Machines ECTS 5, Credits (3+0) 3

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.

Prerequisites: EEE 362 or Chairman’s consent.

EEE 466 Utilization of Electrical Energy ECTS 5, Credits (3+0) 3

Basic operating characteristics and classification of electrical drives. Solid state DC motor control. Solid state

AC motor control. Dynamic behavior of electrical machines. Electric braking. Starting of electrical machines.

Intermittent loads. Drive applications. Modern methods of reactive power compensation. Electrical energy saving.

Prerequisites: EEE 362 and EEE 423 or consent of the department.

EEE 471 Power System Analysis I ECTS 7, Credits (3+2) 4

Basic structure of electrical power systems. Electrical characteristics of transmission lines, transformers and generators. Representation of power systems. Per Unit System. Symmetrical three-phase faults. Symmetrical components. Unsymmetrical faults.

Prerequisite: EEE 361, or Chairman’s consent..

EEE 472 Power System Analysis II ECTS 7, Credits (3+2) 4

Matrix analysis of power systems networks and methods of solution. Load flow and short circuit analysis.

Economic operation of power systems. Transient stability analysis.


EEE 473 Power System Protection ECTS 5, Credits (3+2) 4

Current and voltage transformers. Overcurrent protection. Comparators and static relay circuits. Differential protection and its application to generators, transformers and bus bars. Motor protection. Pilot wire protection of feeders. Introduction to distance and other protection systems.

Prerequisite: EEE 371 or Chairman’s consent.

EEE 474 Low Voltage Power Systems ECTS 5, Credits (3+0) 3

Power calculations in distribution systems. Power measurements. Secondary networks and load characteristics.

Voltage drop and power loss calculation in networks. Voltage drop and power loss calculations for selection of conductor cross-sections. Low voltage power distribution in buildings. Selection of fuses, contactors and power switches. Grounding.


EEE 476 Electrical Power Plants ECTS 5, Credits (3+0) 3

Elactrical power plant types and their structures and operation principles. Power plant planning. Operation specification in accordance to design criteria’s and load demand curves. Power plant construction cost and unit

52

kWh cost. Power plant electrical instalation and generator operation. Reactive compensation. Selection of power transformers and switchyard design.


EEE 477 Illumination Techniques and Indoor Installation ECTS 5, Credits (3+0) 3

Light theories. Eye, sensitivity and vision types. Light reflection, absorption and transmission phenomenon.

Definition of lighting terms. Lighting methods. Internal lighting systems and calculations. Lighting apparatus and armatures. Fotometric measurements. Pre-project preparation fundamentals. Interior electrical installations, low current and high current systems and drawings. 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. Hardware Equipment for Computer Aided Design.

Representation of CAD Packet Program (AutoCAD). Usage of Primary Drawing Commands. 2-Dimentional

Drawing. Text Operations. Project Applications.


EEE 484 Introduction to Antennas and Propagation ECTS 5, Credits (3+0) 3

Review of electromagnetic radiation. Radiation from current elements, loops, short wires. Antenna parameters.

Reciprocity, equivalence and induction theorems. Linear antennas. Radiation pattern and impedance. Antenna arrays and the general antenna formulas. Receiving antenna theory. Elements of ground wave, tropospheric and ionospheric propagation.


EEE 485 Microwave Theory ECTS 5, Credits (3+0) 3

Propagation in cylindrical waveguides: Rectangular, circular, coaxial. Mode theory: TE, TM, and TEM modes.

Transmission line theory and Smith’s chart. Dispersion and wave velocities. Microwave antennas. Passive components: Matched load, attenuators, corners, directional couplers, tuners, tees, strip lines. Scattering parameters and microwave circuits. Ferrite components. Microwave resonators and filters. Klystrons.


EEE 486 Introduction to Electromagnetic Compatibility ECTS 5, Credits (3+0) 3

Electromagnetic compatibility requirements and principles, nonideal component behavior, conducted and radiated emissions and susceptibility, crosstalk, shielding, system design.


EEE 495 Special Topics in Electronics Engineering I ECTS 5, Credits (3+0) 3

The Course description for this course is announced at the beginning of each semester. This course will generally cover state-of-the-art recent subjects which are not covered in other courses offered by the Department of

Electronics Engineering.

Prerequisite: Chairman’s Consent

EEE 496 Special Topics in Electronics Engineering II ECTS 5, Credits (3+0)3

The Course description for this course is announced at the beginning of each semester. This course will generally cover state-of-the-art recent subjects which are not covered in other courses offered by the Department of

Electronics Engineering.


EEE 498 Senior Design Project ECTS 9, Credits (0+6) 23

A technical project to be carried out by the fourth year student under the supervision of the student’s adviser.

The purpose of the course is to provide the student with the experience of conceiving, designing, and implementing a hardware project or hardware-related software project, and of presenting her/his result in both oral and written form. The project may consist of either design and construction of hardware or the production of software that has basic engineering significance.

Prerequisite: Senior standing, or Chairman’s consent.

53

DEPARTMENT of ENVIRONMENTAL ENGINEERING

Chairman

Sami GÖREN, Assistant Professor

B.S, Istanbul Technical University, 1989; M.S, Kanazawa University, 1993; Ph.D, Kanazawa University, 1998,

Departmen of Environmental Engineering Undergraduate Program

“Sustainable Development” is a new and more sensible goal that every country should be implementing. It is now clear that humans are altering the lithosphere, biosphere, atmosphere, and hydrosphere at a rate higher than the healing rate of nature, so every nation is forced to be concerned about natural resources and living standards. This is the job of well-educated engineers, responsible scientists, technologists, lawyers, and managers. Although each has a part to play in solving environmental problems, the role of environment engineers is greater. They have the responsibility of dealing with the perturbated local and global environment. Thus, the curriculum of the

Environmental Engineering Department aims to produce efficient researchers to deal with new environmental problems created every day.

To fulfill the requirements for a Bachelor of Science degree in Environmental Engineering, students must take

Mathematics and Basic Science courses (mathematics, physics, chemistry, and biology), Engineering Science,

Computer Science, Social Science, Economics, and 60 credit hours of Departmental courses. The total number of credit hours required is 138. Students must also complete a minimum of 60 workdays of on the job training in an

Environmental Engineering related facility. The Department also offers a Master of Science Program in

Environmental Engineering for those students who are interested in Environmental Sciences and Technologies.

Nowadays, environmental costs are being added to sustainable indexes because of the common usage of limited resources around the world. Therefore, Environmental Engineering research and development studies have continuously made remarkable contributions to more economic, more efficient and cleaner production. Educate students at international standards and make them devoted and hardworking Environmental Engineers for the benefit of the country. Thereafter, provide students with engineering-management skills so that not only to protect the nature at national level or international level but also to leave the nature to the next generation.

Our strong parts are;

The language of technical education is English

Our department is the first established environmental engineering department among all private universities

Education and teaching is directed towards private sector and the infrastructure of the department is based on practice

The department has well-equipped laboratories for undergraduate education

Young and dynamic educational staff provides good communication between academic members and students

Number of the scientific publications per academic member is high

Our wastewater treatment plant supplies a practical experience for our students

Student organizations are supported and participation of students to the university administration is provided

Seminars and technical trips are prepared by Environmetal Club, which ensures that students can see on-site applications of theoretical data given in the lectures.

Participation of the experts from the industry to support the practical courses strengthens the education.

Contribution for integration between industry and students

To keep in touch with graduated students

The department has several cooperation programs with international universities.

Our future plans are;

To establish new laboratories

To increase number of the enrolled students

To improve the infrastructure of laboratories

To open a Ph.D. program

54

TEACHING STAFF

Chairman

Sami GÖREN, Assistant Professor

B.S, Istanbul Technical University, 1989; M.S, Kanazawa University, 1993; Ph.D, Kanazawa University, 1998,

Mehmet BORAT, Professor

B.S, Istanbul Technical University, 1961; M.S, Yıldız Technical University, 1968; Ph.D, Istanbul Technical

University 1993

Didem AKÇA GÜVEN Assistant Professor

B.S, Istanbul Technical University, 1992; M.S Istanbul Technical University, 1996; Ph.D Istanbul Technical

University, 2003

Ferhat KARACA Assistant Professor

B.S, Yıldız Technical University, 1996; M.S Fatih University, 1999; Ph.D Yıldız Technical University, 2005

Gökçe TEZCANLI GÜYER, Assistant Professor

B.S, Yıldız Technical University, 1995; M.S Bosphorus University, 1998; Ph.D Bosphorus University, 2003

Mustafa PETEK, Assistant Professor

B.S, Istanbul University, 1987; M.S, Istanbul University, 1992; Ph.D, Istanbul University 1999

Omar O M ALAGHA, Assistant Professor

B.S, Cairo University, 1989; M.S Middle East Technical University, 1996; Ph.D, Middle East Technical University,

2000

Bertan BA Ş AK, Instructor

B.S, Istanbul University, 1999; M.S, Fatih University, 2003; Ph.D, Istanbul Technical University

Sevil AKTAN, Instructor

B.S, Istanbul Technical University, 1991; M.S, Fatih University, 2004; Ph.D, Istanbul Technical University

Ay ş e Bü ş ra Ş ENGÜL, Research Asisstant

B.S, Fatih University, 2005; M.S, Fatih University, 2007

Esra GENÇ Đ LHAN, Research Asisstant

B.S, Fatih University, 2004;

Hatice Nur ARAS, Research Asisstant

B.S, Atatürk University, 2001; M.S, Atatürk University, 2003

Đ smail ANIL, Research Asisstant


Nihan UYGUR, Research Asisstant

B.S, Fırat University, 2004

Semra YILMAZ, Research Asisstant

B.S, Fatih University, 2004

55

LABORATORIES of DEPARTMENT

Environmental Chemistry Laboratory

In this laboratory, laboratory courses, research projects,industrial analysis, treatability and design studies can be done. By this way, this laboratory can serve students, researchers, and industry. Undergraduate students, master students, research assistants, and academics can use this laboratory

.

Environmental Chemistry Laboratory is equipped with Spectrophotometer, dissolved oxygen meter, COD and BOD apparatus, Kjeldahl Nitrogen apparatus, desiccator, conductivity meter, pH meter, turbidimeter, drying oven, furnace, incubator, water bath, balance, magnetic stirrer, heater, refrigerator, Jar Test apparatus, Imhoff cone, and analysis kits (used for open land purposes).

In this laboratory, conductivity, turbidity, total solids, total suspended solids, fixed and volatile solids, total dissolved solids, settleable solids, pH, color, dissolved oxygen, alkalinity, acidity, chlorine (residual), hardness, BOD

5

, COD, total nitrogen (kjeldahl), ammonia, nitrite, nitrate, organic nitrogen, phosphorus (total, orthophosphates and polyphosphates), chloride (Argentometric), sulfite (SO

3

2-

), sulfide (S

2-

), sulfate (SO

4

2-

), total iron, oil & grease and phenol analyses can be made for the purpose of laboratory courses and industrial analysis studies; moreover, treatment and design studies can be accomplished.

Experiments and studies of “Investigation of Nitrogen Removal Potential in Fatih University Wastewater Treatment

Plant” and “

Determination and assessment of the pollution which effects the Büyükçekmece lake and watershed”

research projects are being performed in this laboratory. These projects were founded by Fatih

University.

Environmentlal Microbiology Research Laboratory

This laboratory was established due to the fact that drinking water, tapwater, and ground water can be analyzed microbiologically. Master students, Ph.D. students, research assistants and academics are used this laboratory

.

Hardware

Microscopes, colony counter, COD Thermo Reactor, photolab machine, portable sterilizer, incubator, drying oven, furnace, refrigerator, deep freeze, water bath, sterilization apparatus, vortex machine, pH meter, centrifuge, and balance which are strongly required tools for microbiological experiments

Preparation of microbiological experiments for students such as sterilization, isolation, staining of bacteria, bacterial growth, MPN Test, membrane method, soil, and drinking water, tapwater can be made for the purpose of laboratory courses. With the intend of industrial analysis studies, total bacteria count, total coliform count, fecal coliform count,

56

Fecal streptococcus count, Staphylococcus aureus, Pseudomonas aureginosa, Salmonella, microscopic control, and

E. coli experiments can be made.

Projects

1.

Electricity generation from organic wastes using Shewanella putrefacience (Founded by State Planing

Organization)

2.

Investigation of Mutagenic Effects on living organisms of Total Pollutant in Marmara Sea with UmuC-

Gene, SOS CHROMOTEST Kit, and LUMIStox (Founded by Fatih University).

3.

Determination of the mutagenic effects of pollution in Haliç on living organisims by SOS CHROMOTEST

Method (Founded by Fatih University).

Air Pollution Research Laboratory

This laboratory is equipped with a good sampling and analysis facilities for indoor and outdoor air pollution research which give the students an opportunity to accomplish a good research in air pollution field. Undergraduate and graduate students, research assistants and academics can use this laboratory.

This laboratory has some research facilities including: Varian FS240 Atomic Absorption Spectrophotometry (AAS) with Graphite furnace technique for the determination of very low elemental concentrations, laminar flow chamber,

Tork Z400 (VOTA sampler for atmospheric organics) PM

2.5 and PM

10

Andersen dichotomous sampler, Wet only sequential rainwater collation system, Meteorological station, Personal PC, Digital dispenser, micro pipettes, sampling and storage bottles of different ranges, pH meter, conductivity meter, balance, mixer and heater, and refrigerator.

Ammonia determination by spectrophotometric methods, SO

2

, NO

X

and O

3

determinations by impinge method.

Particulate matter (PM

2.5 and PM

10

) sampling, rainwater sampling, major and trace element analysis with AAS.

57

Projects

1.

Investigation of traffic related inhalable particulate matter in Đ stanbul (Founded by Fatih Üniversity)

2.

Đ stanbul’daki Trafik Kaynaklı Solunabilen Askıda Parçacık Maddelerin (PM

10

ve PM

2,5

) Ara ş tırması

(Founded by Đ stanbul Metropolian Municipality).

3.

Production of electronic controlled fully automatic sequential rain sampler (Founded by Fatih Üniversity)

Soil Mechanics and Materials Laboratory

In this laboratory, laboratory courses, research projects and industrial analysis studies can be done. By this way, this laboratory can serve students, researchers, and industry. Undergraduate students, master students, research assistants, and academics can use this laboratory

.

Soil Mechanics and Material Laboratory possesses standard sieves for Grain Size Distribution Test, Standard Proctor

Test apparatus, Atterberg Limits apparatus, soil sampling apparatus (disturbed and undisturbed), GPS device, sand cone, drying oven, balances, microscopes, various containers, and different kinds of mechanical and glass tools.

Water content determination, organic matter determination, grain size distribution, atterberg limits, in-situ unit weight, standard proctor, in-situ sampling, maximum & minimum density, and compaction (standard & modified) tests can be done. On the other hand, soil research of project site (before construction), construction site supervision

(upper and lower part of construction), damage determination of buildings, sampling of distributed and nondistributed soil, coordination determination, and forming polygon services are given with the help of this laboratory.

Experiments and studies of “Monitoring the Soil Displacements in the Campus” research project is being performed in this laboratory. This project was founded by Fatih University (P50080705).

58


First Semester

CHEM 107 General Chemistry


ENVE 101 Intro. to Env. Engineering




3

3

2

0

4

2

0

0

2

0

4

3

2

NC

4

7

4

4

-

7

10

6

3

-

10

PHYS 103 General Physics I 3 2 4

17

7

29

10

39

Second Semester


Programming

Theo.

3

ENG 102 Advanced English II 3

ENGR 100 Introduction to Engineering Design 0

IE 104 Engineering Graphics


PHYS 104 General Physics II 3

2

4

Prac.

2

0

2

2

0

2

Credits

4

3

1

3

4

4

ECTS

6

4

3

4

7

7

Workload

8

6

5

6

10

10

19 31 44

Third Semester

ENVE 203 Environmental Chemistry I

ENVE 206 Environmental Microbiology

ENVE 205 Engineering Thermodynamics




*


2 2 3 6 7

2

2

2

0

3

2

6

5

8

7

3

2

3

0

0

0

3

2

3

5

2

5

7

4

7

16 29 40

Fourth Semester

ENVE 200 Seminar and Technical Trip

ENVE 210 Materials Science in Env.Eng.

ENVE 204 Environmental Chemistry II

ENVE 212 Environmental Ecology




*


0 2 1 3 6

3

2

2

0

2

0

3

3

2

4

6

5

6

7

7

3

2

3

0

0

0

3

2

3

17

5

3

5

31

7

4

7

44

*

Students must select 3 credit non-technical elective courses with the following codes only: ACL, ELL, RLL, CLL,

SLL, GEO, HIST, ECON, MAN, PUB, INT, PHIL, PSY, SOC, GER, CHN, RUS, SPAN. Courses from PREP program can not be chosen.

**

At least 4 of the technical electives must be selected from the technical elective courses offered by the

Environmental Engineering Department.

***

Students can choose courses from the following department courses; Industrial Engineering, Bioengineering and

Genetic, Chemistry, Biology, Geography, Mathematics with the consent of the advisor.

59

Fifth Semester

APHR 101 Atatürk's Principles and History of Turkish Rev. I

ENVE 299 Industrial Training I

ENVE 307 Air Pollution

ENVE 315 Hydrology

ENVE 317 Fluid Mechanics

ENVE 301 Biological Processes

ENVE 303 Unit Operations & Processes of

Water Treatment


2 0 2 2 4

-

3

2

3

3

2

-

0

0

0

0

2

NC

3

2

3

3

3

-

5

5

7

5

6

-

7

7

8

7

8

16 30 41

Sixth Semester

APHR 102 Atatürk's Principles and History of Turkish Rev. II

ECON 388 Engineering Economics

ENVE 344 Solid Waste Management

ENVE 304 Unit Operations & Processes of

Waste Water Treatment

ENVE 312 Water Supply and Sewerage

MATH 348 Intro. to Probability & Statistics


2 0 2 3 4

3

3

3

0

0

0

3

3

3

5

5

6

7

7

8

2

3

2

0

3

3

17

6

5

30

8

7

41


ENVE 399 Industrial Training II

ENVE 409 Wastewater Treatment

ENVE 497 Senior Project I

ENVE 4xx Technical Elective I**

ENVE 4xx Technical Elective II**

XXX 4xx Technical Elective III***

XXX 4xx Technical Elective IV***


*


- - NC - -

2

0

2

2

3

1

5

2

7

8

3

3

3

0

0

0

3

3

3

5

5

5

7

7

7

3

3

0

0

3

3

19

5

5

32

7

7

50

Eighth Semester

ENVE 498 Senior Project II

ENVE 4xx Technical Elective V

**

ENVE 4xx Technical Elective VI

**


***

XXX xxx Technical Elective VII

***

XXX xxx Non-Technical Elective IV

*

Total Credits Required in Degree Program : 138



0 4 2 3 8

3

3

0

0

3

3

5

5

7

7

3

3

3

0

0

0

3

3

3

5

5

5

7

7

6

17 28 42

60



ENVE 402 Environmental Biotechnology

ENVE 403 Environmental Modelling

ENVE 404 Environmental Science

ENVE 407 Air Pollution Control

ENVE 408 Marine Pollution

ENVE 411 Energy and Environment

ENVE 415 Soil Mechanics

ENVE 416 Earth Reinforcement

ENVE 417 Environmental Law

ENVE 420 Engineering Ethics

ENVE 422 Noise Pollution and Control

ENVE 424 Landfill Design

ENVE 425 Occupational Health and Safety

ENVE 426 Innovative Techniques in Solid

Waste Treatment

ENVE 427 Environmental Toxicology

ENVE 428 Resource Recovery and

Recycling

ENVE 429 Soil Pollution and Remediation

ENVE 430 Environmental Policies in the EU and Turkey

ENVE 431 Environmental Planning and

Management

ENVE 432 Environmental Impact

Assessment

ENVE 441 Project Management in

Environmental Engineering

ENVE 450 Environmental Sampling and

Analysis

ENVE 451 Environmental Data Analysis


3 0 3 5 7

3

3

0

0

3

3

5

5

7

7

3

2

3

3

2

3

3

3

3

3

3

0

0

0

2

2

0

0

0

0

0

0

3

3

3

3

3

3

3

3

3

3

3

5

5

5

5

5

5

5

5

5

5

5

7

7

7

7

7

7

7

7

7

7

7

3

3

3

3

3

3

3

2

3

0

0

0

0

0

0

0

2

0

3

3

3

3

3

3

3

3

3

5

5

5

5

5

5

5

5

5

7

7

7

7

7

7

7

7

7


ENVE 204 Environmental Chemistry II

ENVE 317 Fluid Mechanics

ENVE 497 Senior Project I

ENVE 498 Senior Project II


Prerequisite

ENVE 203 veya Consent of the Chairman

MATH 230 veya Consent of the Chairman

Senior Standing or Consent of the Chairman

ENVE 497 veya Consent of the Chairman

Old Course

Code

ENVE 324

ENVE 225

IE 350

ENVE 201

ENVE 206

ENVE 409


Old Course

Name

Landfill Design Material

Materials Science in

Env.Eng.

New Course

Code

ENVE 424

ENVE 210

Engineering

Thermodynamics

ENVE 205

Introduction to Microbiology ENVE 206

Environmental. Microbiology ENVE 206

Laboratory

Water and Ww.Treat.Plant Des.I ENVE 409

New Course

Name

Landfill Design

Materials Science in Env.Eng

Engineering

Thermodynamics

Environmental Microbiology

Environmental Microbiology

Wastewater Treatment

61

ENVE 417

ENVE 203

ENVE 208

ENVE 301

ENVE 303

ENVE 304

ENVE 312

Environmental Law&Ethics ENVE 417

Environmental Chemistry ENVE 203

ENVE 204 Environmental Chemistry

Laboratory

Principles of Biological

Treatment

ENVE 301

Un. Op. & Proc. of W &

Ww.

Treat. I

Un. Op. & Proc. of W &

Ww. Treat. II

Water Supply, Collect. Eng.

& Des.

ENVE 303

ENVE 304

ENVE 312

Environmental Law

Environmental Chemistry I

Environmental Chemistry II

Biological Processes

Unit Operations & Processes of Water Treatment

Unit Operations & Processes of Wastewater Treatment

Water Supply and Sewerage

62

First Semester

Third Semester


ENVE 206 Environmental Microbiology

Fifth Semester

ENVE 301 Biological Processes

DOUBLE MAJOR

Credit/Hours Second Semester

Credit/Hours Fourth Semester

(2+2) 3 ENVE 204 Environmental Chemistry II

(2+2) 3 ENVE 212 Environmental Ecology

(4+4) 6

Credit/Hours

Credit/Hours

(2+2) 3

(2+0) 2

(4+2) 5

Credit/Hours Sixth Semester

(3+0) 3 ENVE 304 Unit Operations&Processes of

(2+2) 3

Waste Water Treatment

ENVE 312 Water Supply and Sewerage

Credit/Hours

(3+0) 3

ENVE 303 Unit Operations&Processes of Water

Treatment

ENVE 307 Air Pollution


ENVE 409 Waste Water Treatment

ENVE xxx Technical Elective I

ENVE xxx Technical Elective II

(3+0) 3

(8+2) 9

ENVE 344 Solid Waste Management

Credit/Hours Eighth Semester

(2+2) 3 ENVE xxx Technical Elective III

(3+0) 3

(3+0) 3

(8+2) 9

ENVE xxx Technical Elective IV

(2+2) 3

(3+0) 3

(8+2) 9

Credit/Hours

(3+0) 3

(3+0) 3

(6+0) 6

NOTES:

The minimum cumulative GPA requirement: 3.00

Total credits required in double major program:44

Undergraduate students of the following departments can apply for the Environmental Engineering Double Major Program:

Computer Engineering, Electrical and Electronic Engineering, Genetic and Bioengineering, Industrial Engineering, Chemistry,

Geography, Biology, Public Administration and Management

MINOR PROGRAM

Credit/Hours First Semester

ENVE 101 Introduction To Environmental

Engineering

Third Semester


Fifth Semester

ENVE 307 Hava Kirlili ğ i

ENVE 315 Hydrology


ENVE 417 Environmental Law

Credit/Hours Second Semester

(2+0) 2

(2+0) 2

Credit/Hours Fourth Semester

(2+2) 3 ENVE 204 Çevre Kimyası II

(2+2) 3

ENVE 212 Environmental Ecology

Credit/Hours Sixth Semester

(3+0) 3 ENVE 344 Solid Waste Management

(2+0) 2

(5+0) 5

Credit/Hours Eighth Semester

(3+0) 3 ENVE 408 Marine Pollution

(3+0) 3

NOTES:

The minimum cumulative GPA requirement: 3.00

Total credits required in minor program: 24

Credit/Hours

(2+2) 3

(2+0) 2

(4+2) 5

Credit/Hours

(3+0) 3

(3+0) 3

Credit/Hours

(3+0) 3

(3+0) 3

63


ENVE 101 Introduction to Environmental Engineering ECTS 4, Credits (2+0) 2

Definitions of the environmental engineering concepts at introductory level, such as, engineering and engineering history, engineering ethics, global environmental pollution, pollution of air, water, soil, noise and light. Water supply, water treatment, sewerage and sewage treatment, solid and hazardous waste management, nuclear pollution,

Environmental impact assessment.

ENGR 100 Introduction to Engineering Design ECTS 3, Credits (0+2) 1

Essentials of engineering design; problem formulation, team work, concept generation, project planning, proposal writing, resume writing, engineering economics, environmental impact, engineering ethics, codes and standards, reporting and presenting technical information. In this course, students are expected to work in groups to complete an engineering design project and to report on the work in both oral and written forms.

ENVE 200 Seminar and Technical Trip ECTS 3, Credits (0+2) 1

Widening of students perspectives and awareness of topics of interest to environmental engineers through seminars offered by invited speakers from industry, government, business and academia. Undergraduate students register to this course will also give seminar. Also there will be visits to water and wastewater treatment plants, sanitary landfills, incinerators, industries, etc. where students will be provided with technical information as well as practical aspects of pollution control method.

ENVE 203 Environmental Chemistry I ECTS 6, Credits (2+2) 3

The aim and definition of Environmental chemistry is to introduce to the students the following concepts: the classification of pollution parameters, analytical chemistry and quantitative analysis, instrumental analysis, gravimetric analysis, units and data analysis, Sampling and sample preparation, analysis of chlorine, sulfate and iron in water and wastewater.

ENVE 204 Environmental Chemistry II ECTS 6, Credits (2+2) 3

The different pollution parameter definition, water and wastewater sampling, transportation and protection, total suspended matter, alkalinity, acidity, hardness, dissolved oxygen, DOD, COD, Nitrogen, Phosphorus, oil and grease analysis will be the main experiments that will be performed during this course.

ENVE 206 Environmental Microbiology ECTS 6, Credits (2+2) 3

The aim and definition of Environmental microbiology is to introduce to the students the following concepts:

Morphology, biochemistry, and physiology of the microorganisms with special emphasis on the identification and cultivation of the environmentally significant and epidemic bacteria.

In laboratory period, examination of microorganisms in water, air, and soil and their behaviour in the contaminated environment.

ENVE 210 Materials Science in Environmental Engineering ECTS 4,Credits (3+0)3

The study of basic material science and review of the engineering materials for Environmental Engineering.

Mechanical and physical properties of basic materials, and the definitions and principles of the materials used in

Environmental Engineering projects.

ENVE 212 Environmental Ecology ECTS 5,Credits (2+0)2

Overview of the class and introduction to the science of ecology, ecosystem concepts, energy flow, and structure of terrestrial ecosystems, terrestrial and aquatic ecosystems, population ecology; population dynamics, biogeography, and population interactions, population change and global change, biodiversity fisheries, conservation.

ENVE 299 Industrial Training I Non-Credit

Every third year Environmental Engineering student is obliged to make a summer practice of 30 working days in a professional company, laboratory or project design organization doing environmental engineering applications.

Observations from the summer practice must be documented and presented in the form of a clear and concise technical report.

64

ENVE 301 Biological Processes ECTS 5, Credits (3+0)3

Microbial processes. Characterization of wastewater and sludge. Stoichiometry of microbial growth. Kinetics of microbial growth. Activated sludge systems. Biological Nitrogen Removal, Biological Phosphorus Removal,

Principles of Attached Growth Treatment Processes, Fundamentals of Anaerobic Treatment Processes, Sludge

Treatment.

ENVE 303 Unit Operations and Processes of Water Treatment ECTS 6, Credits (3+2) 3

Water characteristics, physical, chemical and biological concepts. Process selection. Screening, aeration, coagulation and flocculation, sedimentation and flotation, filtration, ion exchange, chemical precipitation and softening, disinfection, adsorption, membrane processes, odor and taste removal, iron and manganese removal.

ENVE 304 Unit Operations and Processes of Wastewater Treatment ECTS 6, (3-0)3

Concepts of reactors and reactions in environmental engineering. Reaction kinetics and their applications. Residence time and distribution. Ideal reactors. Real reactors. Reactor kinetics. Characterization of wastewaters. Screening, grit removal and sedimentation. Biological oxidation. Oxygen transfer and aeration. Oxidation ponds, aerated lagoons, activated sludge process, trickling filters, rotating biological contactors, anaerobic treatment. treatment sludge handling and disposal.

ENVE 307 Air Pollution ECTS 5, Credits (3+0) 3

Types and resources of air pollutants, air pollution control (particulate and gaseous pollutants, indoor air pollution, acid rain, destruction of ozone layer, greenhouse effect, air quality and modeling (lapse rate and dispersion), plume model.

ENVE 312 Water Supply and Sewerage ECTS 6, Credits (2+2) 3

Public water supply requirements and its measurements. Drinking water quality. Demand for water; population forecasts. Sources of water; ground and surface water intake structures and their designs. Collection and distribution of water, distribution system hydraulics and service reservoirs. Pumping. Pipes, pipeline construction and valves.

Network design. Sewage design, separate and combined sewers. Computer methods.

ENVE 315 Hydrology ECTS 5, Credits (2+0) 2

Hydrological cycle, precipitation, evaporation, evapotranspiration, surface and subsurface water resources and their interactions, hydrography, rainfall runoff models, flood frequency analyses.

ENVE 317 Fluid Mechanics ECTS 7, Credits (3+0) 3

Fluid properties and fluid flow, basic equations and their applications, pipe flow, open channel flow, conservation of mass, momentum concepts will be given.

Prerequisite: MATH 230, or Chairman’s consent.

ENVE 344 Solid Waste Management ECTS 5, Credits (3+0) 3

Sources, types and composition of solid wastes. Properties of municipal solid wastes. Temporary storage of solid wastes at the source. Recycling and resource recovery of solid wastes. Collection. Transportation. Optimization of transportation. Transfer stations. Sanitary landfill. Open dumps rehabilitation. Landfill gases. Composting.

Incineration. Medical waste management. Hazardous wastes.

ENVE 399 Industrial Training II Non-Credit

Every fourth year Environmental Engineering student is obliged to make a summer practice of 30 working days in a professional company, laboratory or project design organization doing environmental engineering applications.

Observations and suggested improvements must be documented and presented in the form of a clear and concise technical report.

ENVE 402 Environmental Biotechnology ECTS 5, Credits (3+0) 3

Stoichiometry and bacterial energetics, microbial kinetics, biofilm kinetics, reactors, activated sludge process, biological nitrogen removal; nitrification, denitrification, fundamentals of biological phosphorus removal, fundamentals of anaerobic treatment, detoxification of hazardous chemicals, degradation of xenobiotics.

65

ENVE 403 Environmental Modelling ECTS 5, Credits (3+0) 3

This course allows the student to acquire, in a time-efficient and uncomplicated manner, knowledge in the formation and construction of dynamic models. Simulation models are increasingly used to investigate processes and solve practical problems in a wide variety of disciplines eg. climatology, ecology, hydrology, geomorphology, engineering.

Environmental Modelling addresses the development, testing and application of such models, which apply across traditional boundaries, and demonstrate how interactions across these boundaries can be beneficial.

ENVE 404 Environmental Science ECTS 5, Credits (3+0) 3

This course is a multidisciplinary introduction to the environmental sciences; the natural environment and its interaction with human society, environmental effects of urban and industrial development, air-water-soil pollution, energy and environment and new guidelines in environmental decision making.

(Offered to non-environmental engineering students only).

ENVE 407 Air Pollution Control ECTS 5, Credits (3+0) 3

Uncontrolled industrial emissions may cause adverse effects on local and global scale. Stack gases and ambient air measurements of hazardous pollutants especially acid rain precursors (e.g. NOx and SO

2

) and green house gases (e.g.

CO2) are essential task in taking necessary measures to prevent and control industrial air pollution. The different sampling and analysis techniques for stack gases and ambient air will be discussed.

ENVE 408 Marine Pollution ECTS 5, Credits (3+0) 3

Marine environment, pollution and contamination. Conservative pollutants, halogenated hydrocarbons, non conservative pollutants. Global, regional and national marine pollution control activities, selected case studies, preparation and presentation of Term Papers.

ENVE 409 Wastewater Treatment ECTS 5, Credits (2+2) 3

The basic of wastewater treatment, sludge disposal and the role of the engineer. Wastewater Engineering, concepts and definitions. Physical, chemical and biological characteristics of wastewater. Classification of wastewater treatment methods. Design of facilities for physical, chemical, and biological treatment of wastewater. Treatment plant hydraulics. Design of the facilities for the treatment and disposal of sludge. Issues related to treatment plant performance.

ENVE 411 Energy and Environment ECTS 5, Credits (3+0) 3

Green energy, alternative energy sources, renewable energy sources, environmentally friendly fuels and energy policies will be covered for Turkey and the World.

ENVE 415 Soil Mechanics ECTS 5, Credits (2+2) 3

The analysis and classification of soils, models for soil consolidation and shear strength, stability of slopes, bearing capacity and settlement of foundations will be discussed. Site investigation for sanitary landfills and pollution control installation will be given. Fundamental soil mechanics tests will be performed at laboratory.

ENVE 416 Earth Reinforcement ECTS 5, Credits (2+2) 3

Techniques and materials used in foundation construction and ground improvement. Types and application methods of reinforcement materials, interaction between reinforcement materials and soil will be taught. Drainage of foundation excavations, methods of ground water control, in-situ tests and their interpretations and case studies for soil deformation will be studied. Soil analysis will be done by different tests at laboratory and site.

ENVE 417 Environmental Law ECTS 5, Credits (3+0) 3

Introduction to environment and law. History, structure and sources of environmental law. Principles and rules establishing standards. Relationship between other branches of law. Environmental management strategies and legislation in Turkey; fundamental law, environmental law, laws related with environment, Turkish environmental regulations, international agreements. Environmental law in European community. Adaptation of Turkish Laws to

EU Legislation. Some important environmental trials and case studies.

ENVE 420 Engineering Ethics ECTS 5, Credits (3+0) 3

Basic concepts. Morals and ethics. Professional ethics. Sources of the ethics. Responsibilities and rights of a human being. Professions and professionalism. Engineer, and his/her position in the society. Short engineering history.

66

Responsibilities of the engineer against him/herself and his/her colleagues. Workplace responsibilities.

Responsibilities and rights of the engineer against his/her employers and customers. Environmental ethics. Code of ethics for engineers in Turkey. Code of ethics for engineers prepared by different engineering societies. Gifts, bribes, kickbacks. Case studies.

ENVE 422 Noise Pollution and Control ECTS 5, Credits (3+0) 3

Sound production and propagation. Physical properties of noise. The hearing mechanism. Vibration. Regulations on the control of noise and vibration, and other legislations. Community noise sources. Urban noise. Transportation noise. Construction noise. Industrial noises. Other noise sources. Measurement of noise and vibration. Effects of noise and vibration. Transmission of the sounds outdoors. Control of noise sources by design. Controlling the transmission path. Control of noise source by redress. Protection of the noise receivers.

ENVE 424 Landfill Design ECTS 5, Credits (3+-0) 3

Characteristics of solid waste and management, introduction to landfill techniques, classifications and basic functions of design materials, construction and management of safe and economic sanitary landfills, equipment and site planning for landfills.

ENVE 425 Occupational Health and Safety ECTS 5, Credits (3+-0) 3

Definitions. Factors affecting health. General principles for occupational health and safety. Goals of the occupational safety. Occupational accidents. Occupational diseases. Statistics on work accidents and evaluation of labor accidents.

Obligations of the employers. Obligations of the workers. Code of Labor and related regulations. Working environment. Safety and personel protective equipments. Training of the workers.

ENVE 426 Innovative Techniques in Solid Waste Treatment ECTS 5, Credits (3+-0) 3

The major aim of this course is to give the students an overview of the current and innovative techniques in solid waste management. Emphasis is put on solutions applicable in developing countries, while ethical aspects are also covered. Contents of this course are; introduction to integrated solid waste management. Physical, chemical and biological properties of waste, physical transformations (shredding, separation, compaction, …), thermal-chemical transformations (incineration, gasification, pyrolysis, …), biological transformations: aerobic and anaerobic processes, sanitary landfills, typical waste treatment processes, selectively collected of household waste, selection of some typical industrial waste streams.

ENVE 427 Environmental Toxicology ECTS 5, Credits (3+-0) 3

Principles of environmental toxicology, environmental fate of toxicants, toxicants in the environment, biological effects of toxicants, biological effects of toxicants: experimental approaches, environmental and nutritional factors in cellular regulation and nutritional toxicants, perspectives in toxicology, perspectives in aquatic toxicology, environmental stress and development in marine organisms, food toxicology, air pollutants, health risk assessment of toxicants, legal aspects of environmental toxicology, toxicant exposure and dose assessment .

ENVE 428 Resourse Recovery and Recycling ECTS 5, Credits (3+0)3

Resource recovery at the source - Process modification – Waste minimization – Reuse - Recoverable and recyclable wastes – Materials specifications – Waste size reduction – Component separation – Drying and dewatering –

Recovery of chemical and biological conversion methods – Recovery of thermal conversion methods – Refuse derived fuels - Packaging wastes – Used tires.

ENVE 429 Soil Pollution and Remediation ECTS 5, Credits (3+0)3

This course deals with different aspect of soil pollution with the aim of acquiring an understanding of these complex subjects. First the international and national legislation dealing with contaminated soil is discussed. Second the behaviour in the soil and the transport to the groundwater and the atmosphere for different pollutant types are studied. Finally the principle of risk based analysis is explained and an overview of the different remediation techniques is given.

ENVE 430 Environmental Policies in the EU and Turkey ECTS 5, Credits (3+0)3

Regarding to Turkey’s accession to the full membership of the EU, one of the important but the neglected element of the Copenhagen Criteria is the environmental integration of Turkey with the EU. The course will both try to

67

introduce and compare the environmental policies of Turkey and the EU and also will attempt to shed the light for a more effective environmental integration of Turkey with the EU.

ENVE 431 Environmental Planning And Management ECTS 5, Credits (3+0)3

The course will cover the state-of-art techniques and methods of contemporary environmental planning and management such as environmental standards, ISO 14000 series of “International Environmental Management

Standards”, environmental auditing, economic tools of environmental management, marketable pollution quotas, green taxes, waste markets, national/local agenda 21s, environmental impact assessment, environmental institutions at home and abroad, Turkish environmental law and so many others.

ENVE 432 Environmental Impact Assessment ECTS 5, Credits (3+0)3

Historical information about the environmental impact assessment activities and procedures. Case studies. Major developments and new infrastructure projects. Regulations of environmental impact assessment in Turkey.

Regulations of environmental impact assessment in other countries. Environmental impact assessment and implementation procedures. Project introduction general format according to Turkish Regulation. Scope determination and commission of inspection and evaluation. The special format of environmental impact assessment report or environmental impact assessment report special format. Sensitive areas. Environmental impact assessment methods. Assessment of the environmental impacts, Public participation meetings. Monitoring and controlling of the projects during the construction, operational and post operational phases. Report preparation.

ENVE 441 Project Management in Environmental Engineering ECTS 5, Credits (3+0) 3

Fundamentals of project scheduling techniques will be studied under the scope of this course. Cost estimation, escalations, resource allocation, conflict resolution, human resources management will be done by computer based project management information system. Critical Path Method (CPM) will be used for complex projects. CPM analyzes what activities have the least amount of scheduling flexibility and then predicts project duration schedule based on the activities that fall along the “critical path.” Activities that lie along the critical path cannot be delayed without delaying the finish time for the entire project. Proposal writing, bid preparation, laws, regulations and safety requirements related to economic project management and their environmental impacts will also be studied by reallife case studies.

ENVE 450 Environmental Sampling and Analysis ECTS 5, Credits (2+2) 3

The Environmental Sampling and Analysis class offers students the opportunity to learn the environmental engineering business. The class provides useful information on analytical methods for contaminants in air emissions, ground and surface water, industrial wastewater, sediment, and soil. Focuses on the essentials of obtaining reliable samples, including calculating how many samples to collect for specific objectives and confidence levels and quality control/quality assurance objectives. Presents typical problems and solutions, sampling equipment, preservation techniques, and special considerations for each matrix.

ENVE 451 Environmental Data Analysis ECTS 5, Credits (3+0)3

This course is designed to give students the knowledge and practical experience they need to interpret lab and field data. The objective of the course is to provide the students with a basic and applied knowledge of probabilistic and statistical methods to analyze some phenomena, with an emphasis on several environmental data study. Subject of this course includes: Acquisition and processing of environmental information focusing on several areas such as air and water pollution, sediment analysis, microbiology, etc. Analysis and interpretation of real- time and historical environmental data. Use of computers for analysis and display, assessment of spatial and temporal variability. Basic principles of statistics and GIS. Use of MS Excel software with Statplus and SPSS software. Methods of time series data analysis, including probability and statistics, power spectral density, correlation, sampling and coherence.

ENVE 495 Special Topics in Environmental Engineering I ECTS 5, Credits (3+0) 3

Courses not listed in the catalog. Contents vary from year to year according to the interests of students and the instructor in charge.

Prerequisite:Chairman’s Consent

68

ENVE 496 Special Topics in Environmental Engineering II ECTS 5, Credits (3+0) 3

Courses not listed in the catalog. Contents vary from year to year according to the interests of students and the instructor in charge.


ENVE 497 Senior Project I ECTS 2, Credits (0+2) 1

This is an independent study under the supervision of a faculty member. Each student is expected to do research trying to explore and define a potential study area suitable for a senior design project. A specific environmental engineering problem must then be identified from within the selected study area. Results from this study must be documented and submitted in the form of a design project proposal.

Prerequisite: Senior Standing or Chairman’s Consent

ENVE 498 Senior Project II ECTS 3, Credits (0+4) 2

This is a guided study under the supervision of a faculty member. Each student is expected to work on the design project he/she has proposed in the “ENVE 497 Senior Project I” course. Results from this study must be submitted in the form of a clear and concise technical report.

Prerequisite: ENVE 497 or Chairman’s Consent

69

Chairman

H. Rıdvan ÖZ, Professor

DEPARTMENT OF GENETICS AND BIOENGINEERING

B.S, Middle East Technical University, 1992; M.S, Celal Bayar University, 1995; Ph.D. Celal Bayar University,

1999

Undergraduate Program in Genetics and Bioengineering

Genetics and Bioengineering is one of the largest disciplines. Similar to the integration of physics, chemistry and engineering sciences which was established in the last century, it is necessary to integrate biology and engineering sciences in the 21.century. This is the application of engineering principles and methods to the problems encountered in medicine and biology. Genetics and Bioengineering unifies biology and other sciences

(like mathematics and different sciences). Even the bases of genetics and bioengineering is biology, genetics and bioengineers should use sophisticated engineering tools and methods. Quantitative approaches, measurement modelling ve integration of information is important in genetics and bioengineering as they are important in engineering.

The goals of Genetics and Bioengineering program are to give education about technology used in basic medical sciences and engineering sciences, and to graduate technical persons who are capable of establishing connection between medical sciences and engineering sciences. Rapid changes in technology shows itself in agriculture, chemistry and biology fields. Cheaper production of chemical matters using biological processes, production of biology based chips, investigation and imitation of motion of living bodies are some examples of these changes.

Genetics and Bioengineering undergraduate program aims the development of new technologies using biological systems and processes. For this reason, the students will learn how to investigate biological mechanisms and circumstances from the point of engineering view by understanding basic principles of engineering. So that the students will understand the fundamentals of molecular biology, biochemsitry, genetics, cell biology, biomaterials, biodynamics, bioheat transfer, biorobotics by establishing a very strong ground on basic sciences like mathematics, physics and chemistry, and engineering.

The goals of genetics and bioengineering education can be listed as follows:

To give successful education about engineering and basic sciences

To give genetics and bioengineering konwledge and experience

To conduct basic and experimental high quality researches and to apply engineering and physical sciences to medical and biological problems.

To prepare a ground for the students so that they can learn how to apply engineering technologies to living systems in a safe way.

To give problem solving and team forming abilities which are necessary for genetics and bioengineering carrier.

To develop effective communication abilities and joining into interdisciplinary teams.

To give education to the students in a broad spectrum and their preparation for carrier in a wide range.

The graduates of the program will be called as Genetics and Bioengineers.

The graduates can work as researcher or administrator in the industries (chemical, pharmaceutical, food, e.g.) related with different fields of biological sciences and biotechnology. They also transfer the studies performed by them in the laboratories to the industry. For example, they can work as designers in food and agricultural fields by obtaining new materials and processes using biological systems and processes. In addition to this, they can find opportunities to work in hospitals, drug industry, in the firms related with protection fo environment, in

Turkish Standards Institute (TSE, Türk Standartları Enstitüsü), Hıfzısıhha to perform genetic diagnosis and medication, in firms manufacturing prothesis, implants, in automotive or transportation industry about human comfort during driving.

To fulfill the requirements for a Bachelor of Science degree in Genetics and Bioengineering, students must take a total of at least 140 credit hours consisting of 119 credit hours of required courses and 21 credit hours of electives. Of the required courses, 63 credit hours are offered by the department of Genetics and Bioengineering and 50 credit hours are courses in fields such as Mathematics, Computer Engineering, Biology, Chemistry,

Physics, Turkish, History, and 15 credit hours of the electives are technical elective courses while the remaining

70

6 credit hours are non-technical elective courses. Students must also successfully complete a minimum of 60 workdays of summer practice as part of their graduation requirements.

71

TEACHING STAFF

Chairman

Halil Rıdvan Öz, Professor

B.S, Middle East Technical University, 1992, M.S, Celal Bayar University, 1995; Ph. D. Celal Bayar University,

1999

Fahri AKBA Ş , Assistant Professor

B.S, Đ stabul University, 1990; M.S, Đ stanbul University, 1993; Ph. D. Đ stanbul University, 2000

Mustafa Fatih Abasıyanık, Assistant Professor

B.S, Ankara University, 1991; M.S, Fatih University, 2000; Ph. D. Gebze Technology Institute, 2004

Nurullah Arslan, Assistant Professor

B. S. Anadolu University, 1984; M.S, The University of Michigan, 1992, M.S, Đ stanbul Technical University,

1987, Ph. D. The University of Illinois at Chicago, 1999

72


Biofluids Laboratory

In this laboratories experimental in vitro modeling studies are aimed to understand the critical flow regions inside Cardiovascular system. The formation of intimal hyperplasia inside human blood vessels is studied in this laboratory. Currently, the effect of the flow inside a connection of graft to vein used in hemodialysis patients are studied under steady and unsteady flow conditions. This project is supported by TUBITAK. In this laboratories, the flow inside by-pass grafts, the flow inside carotid arteries, the flow inside aneursyms located in the brain or the other parts of the vascular system are aimed to study. We have collaboration with surgeons, radiologists, and nephrologists from Cerrahpasa, Siyami Hersek and Istanbul Research hospitals. In vivo studies are done in these hospitals

In vitro cardiovascular graft modeling studies, new graft design improvement

Experimental flow studies to improve new artificial heart models and heart valve designs

To provide an experiemtal infrastructure for engineers, surgeons, radiologists, biologists, chemists and physicts working interdisiplinary

Collaboration among the universities and centers of the researchers with Fatih university

To offer research opportunities for M.S., Ph.D. and Postdoc students

Biosignal Processing Laboratory

It is used for processing of biosignals, these signals are obtained from human body. MR, PET Scan, CT, EEG,

ECG, lung sound are analyzed for diagnosis purposes. General aim is the acquisiton of signals, processing and manufacturing PBC. Especially the main subect is lung sound analysis. The system to be produced can be used for all systems.

It is a research laboratory and used in researche and master programs. The acquisiton of lung sounds, preamplification, analog filtering, digitization and processing in computers is performed. It is aimed to obtain information about diseases. Also it is aimed to design a portable PBC. The staff. Assoc. Prof. Halil Rıdvan Öz,

Assoc. Prof. OnurToker, Res: Assoc. Zafer Çatmaka ş .

Computational Bioengineering Laboratory

In this research laboratory, the solution of the bioengineeing problems is aimed numerically. Besides Fortran and

C programming languages, Matlab, FLUENT, ANSYS co mmercial softwares are used to solve biofluid dynamics, solid mechanics problems and the problems related areas in bioengineeing computationally

Computational solution of the bioengineering problems

To offer research opportunities for M.S., Ph.D. and Postdoc student

73


First Semester

GBE 101 Introduction to Bioengineering

CENG 103


Programming. I







2 0 2 1 3

3

4

3

3

3

-

2

0

2

2

0

2

4

4

4

4

3

NC

21

7

7

7

7

4

-

33

8

10

10

10

6

-

47

Second Semester

CENG 104 Computing in Engineering



GBE

ENG

102 Microbiology

102 Advanced English II

Third Semester

GBE 201 Biostatistics

GBE

GBE

203

205

Biomaterials

Biomechanics

CHEM 201 Analytical Chemistry I

MATH 331 Numerical Analysis


Fourth Semester

GBE 202 Systems Physiology

GBE

GBE

204

206

Biophysics

Cell Biology

GBE 216 Cell Biology Lab.

CHEM 204 Organic Chemistry I



Fifth Semester

GBE 299 Practical Training I

APHR 101 Atatürk's Prin. and Hist. of

Turkish Rev. I

GBE

GBE

GBE

GBE

GBE

GBE

301

303

305

307

309

319

Biodynamics

Exp.Des.and Mod. in Bioeng.

Biothermodynamics

Biochemistry

Genetics

Genetics Lab.


2 2 3 5 8

4

3

3

3

0

2

0

0

Theo. Prac.

3 0

3

3

4

3

2

Theo.

-

3

3

0

4

3

2

2

3

3

3

3

3

0

0

0

0

0

0

Theo. Prac.

3 0

0

0

2

0

0

0

Prac.

-

0

0

0

0

0

0

2

4

4

3

3

17

Credits ECTS Workload

3 5 6

3

3

4

3

2

18


3 5 7

3

3

1

4

3

2

19

Credits

NC

2

3

3

3

3

3

1

18

7

7

4

4

27

5

5

7

5

2

29

5

5

2

7

5

2

31

ECTS

-

2

5

5

5

5

6

2

30

10

10

7

6

41

7

7

7

7

4

38

7

7

2

7

7

4

41

Workload

-

4

7

7

7

7

7

2

41

74

Sixth Semester

APHR 102 Atatürk's Prin. and Hist. of

Turkish Rev. II

GBE

GBE

GBE

302

304

306

Introduction to Biorobotics

Biofluid Mechanics

Transport Processes in

Bioengineering

GBE

GBE

GBE

308 Biosignals and Systems

310 Molecular Biology

320 Molecular Biology Lab.

Theo.

2

3

3

3

3

3

0

Prac.

0

0

0

0

0

0

2

Credits

2

3

3

3

3

3

1

18

ECTS

2

5

5

5

5

6

2

30

Workload

4

7

7

7

7

7

2

41


GBE

GBE

GBE

GBE

GBE

GBE

XXX

399

401

403

413

4xx

4xx

Practical Training II

Bioengineering Project I

Molecular Genetics

Molecular Genetics Lab.

Technical Elective I

Technical Elective II

Xxx Non-Technical Elective I

Theo. Prac.

- -

2

3

0

3

3

3

0

0

2

0

0

0


NC - -

2

3

6

6

7

7

1

3

3

3

2

6

6

5

2

7

7

7

15 31 37

Eighth Semester

GBE 402 Bioengineering Project II

GBE 4xx Technical Elective III

GBE 4xx Technical Elective IV

GBE 4xx Technical Elective V


Theo.

2

3

3

3

3



Prac.

0

0

0

0

0



2 6 7

3

3

6

6

7

7

3

3

6

5

7

7

17 29 42


GBE 404 Human Body Dynamics

GBE 405 Bionics

GBE 406 Biorobotics

GBE 407 Biomechatronics

GBE

408 Digital Biosignal Processing

GBE 409 Biosensors

GBE 410 Bioheat Transfer

GBE 411 Reactor Kinetics and Design in Biotechnology

GBE 412 Process Dynamics and Control

GBE 414 Industrial Biotechnology

GBE 415 General Biotechnology

GBE 416 Developmental Biology

GBE 417 Systems Biology

GBE 418 Synthetics Biology

GBE 419 Molecular Biology of the

Gene

GBE 420 Human Genetics

GBE 421 Gene Therapy

GBE 422 Protein Design

GBE 423 Genomics and Proteomics

Theo. Prac.

3

3

0

0

3

3

3

0

0

0

3

3

3

0

0

0

3

3

3

3

3

3

3

3

3

3

3

0

0

0

0

0

0

0

0

0

0

0


3

3

6

6

7

7

3

3

3

6

6

6

7

7

7

3

3

3

6

6

6

7

7

7

3

3

3

3

3

3

3

3

3

3

3

6

6

6

6

6

6

6

6

6

6

6

7

7

7

7

7

7

7

7

7

7

7

75

GBE 424 Genetic Disorders &

Counseling

BIOL 407 Microbial Genetics

GBE 425 Tissue Engineering

GBE 426 Neurobiology

GBE 427 Neuroengineering

GBE 428 Molecular Engineering

GBE 429 Complex System

GBE 430 Genetic Algorithm

GBE 431 Biopharmaceuticals

GBE 432 Forensic Technology

GBE 433 Bionanotechnology

BIOL 204 Ecology

GBE 434 Aquaculture

GBE 435 Ecology

BIOL 401 Toxicology

BIOL 403 Clinical Microbiology

BIOL 404 Immunology

BIOL 405 Virology

BIOL 408 Cancer Biology

BIOL 419 Bioinformatics

BIOL 411 Enzymology

BIOL 410 Food Microbiology &

Biotechnology


ENVE 204 Introduction to Environmental

Sciences

ENVE 402 Environmental Biotechnology

ENVE 417 Environmental Law and Ethics

EEE 401 Data Acquısition and

Instrumentation

EEE 435 Robot Dynamics and Control

EEE 457 Introduction to Image

Processıng

EEE 465 Medical Imaging Systems

CENG 490 Introduction to Artificial

Intelligence

CENG 491 Introduction to Neural

Networks

CHEM

CHEM

415 Organic Reaction Mechanism

419 Introductory Organometallic

Chemistry

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

Course Code

GBE 101

GBE 201

GBE 202

GBE 203

GBE 204

GBE 205

GBE 206

GBE 216

GBE 301

GBE 302

GBE 303

GBE 304

TABLE of PREREUISITE

Course Name

Microbiology

Biostatistics

Systems Physiology

Prerequisite

GBE 101, or Chairman’s Consent

MATH 114, or Chairman’s Consent

BIOL 108, or Chairman’s Consent

Biomaterials

Biophysics

Biomechanics

Cell Biology

Cell Biology Lab.

Biodynamics

Introduction to Biorobotics

CHEM 107, or Chairman’s Consent

BIOL 108, GBE 203, or Chairman’s Consent

PHYS 103, MATH 113, or Chairman’s Consent




GBE 205, GBE 301, or Chairman’s Consent

Exp. Des. and Mod. in Bioeng. GBE 202, 203, 205, or Chairman’s Consent

Biofluid Mechanics GBE 301, or Chairman’s Consent

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

5

5

5

5

5

5

5

5

5

5

5

5

6

6

6

5

5

5

6

6

5

6

6

6

5

6

6

6

6

5

5

5

5

5

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

7

76

GBE 305

GBE 306

GBE 307

GBE 308

GBE 309

GBE 310

GBE 309

GBE 319

GBE 401

GBE 402

GBE 403

GBE 413

GBE 404

GBE 405

GBE 406

GBE 407

GBE 408

Biothermodynamics

Transport Processes in

Bioengineering

Biochemistry

Biosignals and Systems

Genetics

Genetics Lab.

Molecular Biology

Molecular Biology Lab.

Bioengineering Project I

Bioengineering Project II

Molecular Genetics

Molecular Genetics Lab.

Human Body Dynamics

Bionics

Biorobotics

Biomechatronics

Digital Biosignal Processing

PHYS 104, GBE 205, or Chairman’s Consent



BIOL 108, GBE 201, GBE 203, GBE 301, or


BIOL 108, GBE 206, GBE 216 or Chairman’s Consent

BIOL 108, GBE 206, GBE 216 or Chairman’s Consent



GBE 301, GBE 305, GBE 309, GBE 310, or










GBE 409

GBE 410

GBE 411

Biosensors

Bioheat Transfer

Reactor Kinetics and Design in

Biotechnology




GBE 412 Process Dynamics and Control GBE 303, GBE 306, or Chairman’s Consent

GBE 414 Industrial Biotechnology GBE 303, GBE 306, or Chairman’s Consent

GBE 415

GBE 416

General Biotechnology

Developmental Biology



GBE 417

GBE 418

GBE 419

GBE 420

GBE 421

GBE 422

GBE 423

GBE 424

Systems Biology

Synthetics Biology



Molecular Biology of the Gene GBE 303, GBE 306, or Chairman’s Consent

Human Genetics GBE 303, GBE 306, or Chairman’s Consent

Gene Therapy

Protein Design

Genomics and Proteomics

Genetic Disorders &

Counseling



GBE 303, GBE 306, GBE 419, or Chairman’s Consent

GBE 303, GBE 306, GBE 421, or Chairman’s Consent

BIOL 407 Microbial Genetics

GBE 425 Tissue Engineering

GBE 426

GBE 427

Neurobiology

Neuroengineering

GBE 428

GBE 429

GBE 430

GBE 431

Molecular Engineering

Complex Systems

Genetic Algoritm

Biopharmaceuticals







GBE 308, or Chairman’s consent


GBE 432

GBE 433

GBE 434

GBE 435

Forensic Technology

Bionanotechnology

Aquaculture

Ecology

BIOL 401 Toxicology

BIOL 403 Clinical Microbiology

BIOL 404 Immunology

BIOL 405 Virology

BIOL 408 Cancer Biology

BIOl 419 Bioinformatics

BIOL 411 Enzymology

BIOL 410 Food Microbiology &

Biotechnology













77


ENVE 204 Introduction to Environmental

Sciences



ENVE 402 Environmental Biotechnology GBE 303, GBE 306, or Chairman’s Consent

ENVE 417 Environmental Law and Ethics GBE 303, GBE 306, or Chairman’s Consent

EEE 401 Data Acquısıtıon and

Instrumentation


EEE 435

EEE 457

Robot Dynamics and Control GBE 302, GBE 308, or Chairman’s Consent

Introduction to Image

Processıng


EEE 465 Medical Imaging Systems

CENG 490 Introduction to Artificial



Intelligence

CENG 491 Introduction to Neural

Networks


CHEM 415 Organic Reaction Mechanism GBE 303, GBE 306, or Chairman’s Consent

CHEM 419 Introductory Organometallic

Chemistry


78

First Semester

Third Semester

GBE 203 Biomaterials

GBE 205 Biomechanics

DOUBLE MAJOR

FOR COMPUTER ENGINEERING STUDENTS



(3+0) 3 GBE 204 Biophysics

(3+0) 3

(6+0) 6



(3+0) 3

(3+0) 3

Fifth Semester

GBE 301 Biodynamics

GBE 305 Biothermodynamics

GBE

GBE

GBE

307 Biochemistry

309 Genetics

319 Genetics Lab


(3+0) 3 GBE 302 Introduction to Biorobotics

(3+0) 3 GBE 304 Biofluid Mechanics


(3+0) 3

(3+0) 3

(3+0) 3 GBE 306 Transport Processes in Bioengineering

(3+0) 3 GBE 310 Molecular Biology

(0+2) 1

(12+2) 13

GBE 320 Molecular Biology Lab

(3+0) 3

(3+0) 3

(0+2) 1

(12+2) 13


GBE 403 Molecular Genetics

GBE 413 Molecular Genetics Lab

GBE

GBE xxx Technical Elective I xxx Technical Elective II


(3+0) 3 GBE 401 Bioengineering Project I

(0+2) 1 GBE xxx Technical Elective III

(3+0) 3 GBE xxx Technical Elective IV

(3+0) 3

(9+2) 10


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9

First Semester

Total Credits Requıred In Double Major Program: 54

The Mınımum Cumulatıve Gpa Requırement Is 3.50.

The Students Who Took One Of More Of These Courses Before Should Take Other Courses

From Gbe

FOR ELECTRIC-ELECTRONICS ENGINEERING STUDENTS

Contact/Credit Hours Second Semester Contact/Credit Hours

Third Semester





(3+0) 3

(6+0) 6


(3+0) 3

(3+0) 3

Fifth Semester

GBE 301 Biodynamics

GBE

GBE

305 Biothermodynamics

307 Biochemistry

GBE

GBE

309 Genetics

319 Genetics Lab



GBE

GBE

413 Molecular Genetics Lab xxx Technical Elective I

GBE xxx Technical Elective II




(3+0) 3



(3+0) 3

(3+0) 3


(0+2) 1 GBE 320 Molecular Biology Lab

(12+2) 13

(3+0) 3

(0+2) 1

(12+2) 13





(3+0) 3

(9+2) 10


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9

Total Credıts Requıred In Double Major Program: 54



From Gbe

79

FOR ENVIRONMENTAL ENGINEERING STUDENTS

First Semester

Third Semester





(3+0) 3



(3+0) 3

(3+0) 3

Fifth Semester

GBE 301 Biodynamics


GBE

GBE

309 Genetics

319 Genetics Lab





(3+0) 3

(3+0) 3



(9+2) 10

(3+0) 3

(0+2) 1

(9+2) 10



GBE

GBE


GBE

GBE xxx Technical Elective II xxx Technical Elective III




(3+0) 3 GBE xxx Technical Elective V

(3+0) 3 GBE xxx Technical Elective VI

(3+0) 3 GBE xxx Technical Elective VII

(12+2) 13


(2+2) 3

(3+0) 3

(3+0) 3

(3+0) 3

(3+0) 3

(14+2) 15




From Gbe

FOR INDUSTRIAL ENGINEERING STUDENTS

First Semester

Third Semester






(3+0) 3

(6+0) 6



(3+0) 3

(3+0) 3

Fifth Semester

GBE

GBE

301 Biodynamics


GBE

GBE

GBE

307 Biochemistry

309 Genetics

310 Genetics Lab





(3+0) 3

(3+0) 3




(12+2) 13

(3+0) 3

(3+0) 3

(0+2) 1

(12+2) 13


GBE

GBE

403 Molecular Genetics

413 Molecular Genetics Lab

GBE

GBE xxx Technical Elective I xxx Technical Elective II





(3+0) 3

(9+2) 10


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9




From Gbe

80

FOR BIOLOGY STUDENTS

First Semester

Third Semester




GBE xxx Technical Elective I


GBE

GBE xxx Technical Elective III xxx Technical Elective IV


Fifth Semester

GBE 301 Biodynamics

GBE

GBE

303 Exp. Des. And Mod. In Bioeng.




(9+0) 9 GBE 308 Biosignals and Systems


(3+0) 3



(3+0) 3

(3+0) 3

(3+0) 3

(12+0) 12



(3+0) 3 MATH 230 Differential Equations

(6+0) 6


(3+0) 3

(3+0) 3

(3+0) 3

(12+0) 12

GBE

GBE

401 Bioengineering Project I xxx Technical Elective V

(3+0) 3 GBE xxx Technical Elective VI



(3+0) 3

(3+0) 3

(6+0) 6


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9




From Gbe

FOR CHEMISTRY STUDENTS

Contact/Credit Hours Second Semester Contact/Credit Hours First Semester

Third Semester



Fifth Semester

GBE 301 Biodynamics

GBE

GBE


309 Genetics

GBE 319 Genetics Lab



(3+0) 3 GBE 202 Systems Physiology

(6+0) 6


(3+0) 3

(3+0) 3

(6+0) 6







(9+2) 10 GBE 308 Biosignals and Systems

(3+0) 3

(0+2) 1

(3+0) 3

(3+0) 3

(3+0) 3

(12+2) 13



GBE

GBE







(3+0) 3

(9+2) 10


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9




From Gbe

81

FOR PHYSICS STUDENTS

First Semester

Third Semester





(3+0) 3 GBE 202 Systems Physiology



(3+0) 3

(3+0) 3

(6+0) 6

Fifth Semester

GBE 301 Biodynamics

GBE

GBE


309 Genetics




(3+0) 3

(3+0) 3

GBE

GBE

320 Molecular Biology Lab

304 Biofluid Mechanics

(0+2) 1

(9+2) 10

GBE

GBE


(3+0) 3

(0+2) 1

(3+0) 3

306 Transport Processes in Bioengineering (3+0) 3

308 Biosignals and Systems (3+0) 3

(12+2) 13



GBE

GBE

413 Molecular Genetics Lab. xxx Technical Elective I

GBE

GBE xxx Technical Elective II xxx Technical Elective III



(0+2) 1

(3+0) 3

GBE

GBE xxx Technical Elective IV xxx Technical Elective V

(3+0) 3

(3+0) 3

(12+2) 13


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9




From Gbe

FOR MATHEMATICS STUDENTS

First Semester Contact/Credit Hours Second Semester Contact/Credit Hours

Third Semester



Fifth Semester

GBE 301 Biodynamics

GBE

GBE



GBE

GBE

309 Genetics

319 Genetics Lab



(3+0) 3

(6+0) 6

GBE 202 Systems Physiology


(3+0) 3

(3+0) 3

(6+0) 6



(3+0) 3

(3+0) 3

GBE

GBE


(3+0) 3

306 Transport Processes in Bioengineering (3+0) 3

308 Biosignals and Systems (3+0) 3

(3+0) 3

(0+2) 1

(12+2) 13 (9+0) 9



GBE

GBE





(0+2) 1

(3+0) 3

GBE

GBE xxx Technical Elective III xxx Technical Elective IV

(3+0) 3

(9+2) 10

GBE xxx Technical Elective IV


(2+2) 3

(3+0) 3

(3+0) 3

(3+0) 3

(11+2) 12




From Gbe

82

MINOR PROGRAM

FOR COMPUTER ENGINEERING STUDENTS

First Semester

Third Semester

GBE

GBE

203 Biomaterials

205 Biomechanics

Fifth Semester

GBE 301 Biodynamics

GBE 309 Genetics

GBE 319 Genetics Lab.



(3+0) 3

(3+0) 3

(6+0) 6



(3+0) 3

(0+2) 1

(6+2) 7



GBE 310 Molecular Genetics Lab




(3+0) 3 GBE xxx Technical Elective II

(3+0) 3

(9+0) 9

Total Credıts Requıred In Mınor Program: 31


FOR ELECTRIC-ELECTRONICS ENGINEERING STUDENTS

First Semester

GBE 101 Introduction to Bioengineering


(2+0) 2

(2+0) 2

Third Semester



Fifth Semester

GBE 301 Biodynamics

GBE

GBE

309 Genetics

319 Genetics Lab


(3+0) 3

(3+0) 3

(6+0) 6



(3+0) 3

(0+2) 1

(6+2) 7



GBE

GBE




(0+2) 1 GBE xxx Technical Elective II

(3+0) 3

(6+2) 7






(3+0) 3

(3+0) 3


(2+2) 3

(3+0) 3

(5+2) 6




(3+0) 3

(3+0) 3


(2+2) 3

(3+0) 3

(5+2) 6

83

FOR ENVIRONMENTAL ENGINEERING STUDENTS

First Semester

Third Semester


Fifth Semester

GBE 309 Genetics





(3+0) 3



(3+0) 3

(3+0) 3

Contact/Credit Hours Sixth Semester Contact/Credit Hours

(3+0) 3 GBE 306 Transport Processes in Bioengineering (3+0) 3

(0+2) 1

(3+2) 4

(3+0) 3


GBE

GBE

GBE

403 Molecular Genetics







(3+0) 3

(9+2) 10



FOR INDUSTRIAL ENGINEERING STUDENTS

First Semester

Third Semester





(3+0) 3


(2+2) 3

(3+0) 3

(3+0) 3

(8+2) 9



(3+0) 3

(3+0) 3

Fifth Semester

GBE 301 Biodynamics


GBE

GBE

309 Genetics

319 Genetics Lab



(3+0) 3

(3+0) 3

(0+2) 1

(9+2) 10







(6+0) 6




(3+0) 3

(3+0) 3


(2+2) 3

(3+0) 3

(5+2) 6

84

FOR ART AND SCIENCE FACULTY STUDENTS

First Semester

Third Semester





(3+0) 3

(3+0) 3

(6+0) 6



Fifth Semester

GBE 301 Biodynamics



(3+0) 3 GBE 306 Transport Processes in Bioengineering


(3+0) 3

(3+0) 3

(6+0) 6




GBE xxx Technical Elective III




(3+0) 3

(9+0) 9




(2+2) 3

(3+0) 3

(6+0) 6

85

COURSE DESCRIPTION

GBE 101 Introduction to Bioengineering ECTS 1, Credits (2-0) 2

Introduction to the engineering profession in general biology and bioengineering in particular; careers in bioengineering; and problem solving strategies.

GBE 102 Microbiology ECTS 4, Credits (3-0) 3

Contentss of bacteria, archaeobacteria, viruses, prions, viroids, cyanobacteria, mycoplasmas, structure and classification of microorganisms. Structure and function of microbial cells, microbial cell wall, capsules, endospores, antimicrobial agent to bacteria, classification.

GBE 201 Biostatistics ECTS 4, Credits (3-0) 3

Motivated by specific biological and medical issues, this course teaches introductory statistical techniques to investigate real-world experimental data from the health sciences, molecular, cellular, environmental, and evolutionary biology.

Prerequisite: MATH 114, or Chairman’s Consent

GBE 202 Systems Physiology ECTS 5, Credits (3-0) 3

An overview of the functioning systems of the human body. The physiology of cells as well as the muscular, nervous, circulatory, respiratory, endocrine, digestive and urogenital systems are explored. Emphasis is placed on the integration of the individual function of different cells and organ systems into a functional whole, the feedback mechanisms that account for necessary balances and the consequences of disease. Examples of engineering approaches used to monitor physiological processes and correct physiological deficiencies are included.

Prerequisite: BIOL 108, or Chairman’s Consent

GBE 203 Biomaterials ECTS 5, Credits (3-0) 3

This course is designed to introduce students to the various classes of biomaterials in use and their application in selected subspecialties of medicine including an understanding of material bulk and surface properties, standard characterization tools, the various biological responses to implanted materials, the clinical context of their use, manufacturing processes, and issues dealing with cost, sterilization, packaging, and design of biomedical devices. It also addresses professional and ethical responsibility encountered in designing medical implants.

Prerequisite: CHEM 107, or Chairman’s Consent

GBE 204 Biophysics ECTS 5, Credits (3-0) 3

This intermediate-level 4 credit-hour course is focused on the application of physical principles to 1) develop quantitative understanding of biophysical processes in natural and engineered molecules, membranes, tissues and organs and to 2) apply biophysical principles to the solution of biomedical engineering problems and the design of biomedical devices to advance health and the human condition.

Prerequisite: BIOL 108, GBE 203, or Chairman’s Consent

GBE 205 Biomechanics ECTS 5, Credits (3-0) 3

The course presents the principles of classical mechanics using case studies involving human movement. vector algebra, vector differentiation, human body structure (bones, muscles, ligaments, and tendons), static analysis, strength analysis, Method of Lumped masses.

Prerequisite: PHYS 103, MATH 113 or Chairman’s consent

GBE 206 Cell Biology ECTS 5, Credits (3-0) 3

Introduction to the cell structure and function, intracellular compartmentalization, cell division, nucleic acid and protein structure, protein assembly, modification and trafficking, cell to cell communication.

Prerequisite: BIOL 108, or Chairman’s Consent

GBE 216 Cell Biology Laboratory ECTS 1, Credits (0-2) 1

Specimen preparations for studying the ultra structures of the cell, plasma membrane, cellular organelles, cell motility, mitosis, cytokinesis, cellular fractionation and analysis of subcellular fractions.

Prerequisite: BIOL 108, or Chairman’s Consent

86

GBE 301 Biodynamics ECTS 6, Credits (3-0) 3

Newton’s laws of motion, Energy methods, Impulse and Momentum, Fundamentals of motion analysis of human movement and its application to the study of function and dysfunction of the musculoskeletal system. Solution methods of the inverse dynamics problem.

Prerequisite: GBE 207, or Chairman’s Consent

GBE 302 Introduction to Biorobotics ECTS 6, Credits (3-0) 3

Fundamentals of mechanisms, motion analysis, robotics, hand-arm kinematics, neck-body kinematics, kontrol, kinetics, force transfer.

Prerequisite: GBE 207, GBE 301, or Chairman’s Consent

GBE 303 Experimental Design and Modeling in Bioengineering ECTS 6, Credits (3-0) 3

This course investigates measurement, error analysis and the treatment of uncertainties in biomedical engineering. Students will be provided an introduction to statistics, including probability and distributions, confidence intervals, sampling and hypothesis tests on the mean. Sources of potential bias (and how to avoid them) and various experimental designs commonly utilized in biomedical engineering will also be explored.

Useful computational tools will be introduced and utilized throughout the course.

Prerequisite: GBE 202, 203, 207, or Chairman’s Consent

GBE 304 Biofluid Mechanics ECTS 6, Credits (3-0) 3

Fluid properties. Dimensional analysis. Statics and kinematics. Conservation equations. Inviscid and incompressible flows. Bernoulli's equation. Integral momentum theorems. Viscous flows. Boundary layer theories. Compressible Flows. Cardiovascular physiology, the human circulation, primarily applied to blood flow at the arterial level. vascular implants and measurements in the cardiovascular system.


GBE 305 Biothermodynamics ECTS 6, Credits (3-0) 3

This is a study of the physical and mathematical concepts of thermodynamics with an emphasis on physiological and biological examples. Students apply the first and second law of thermodynamics to biomedical examples involving gas mixtures, phase and chemical equilibrium, and material balances.

Prerequisite: PHYS 104, or Chairman’s Consent

GBE 306 Transport Processes in Bioengineering ECTS 6, Credits (3-0) 3

This course involves the study of mass, momentum and heat transfer within the human body, between the human body and the environment, and in the design of devices and systems which are involved with transport processes in a medical and clinical setting. The underlying principles of mass, momentum and energy transfer will be addressed followed by a study of such processes which are ongoing in the human body. The design of biomedical devices and systems which involve transport processes will also be studied.


GBE 307 Biochemistry ECTS 6, Credits (3-0) 3

Introduction to biological macromolecules, proteins, nucleic acids, polysaccharides, lipids, enzymes, coenzymes, enzyme kinetics, inhibitors, kinetic of inhibitors, techniques used in biochemical applications such as electrophoresis, western blotting, ELISA, protein purification techniques.

Prerequisite: CHEM 208, or Chairman’s Consent

GBE 308 Biosignals and Systems ECTS 6, Credits (3-0) 3

Basics of electrical systems, RLC circuits. Approaches such as the Transfer Function and the Fourier and the

Laplace transforms are important tools for bioengineers that often considered borrowed from electrical engineering. Basic engineering concepts that underlie biological systems, medical devices, biocontrol, and biosignal analysis, EEG, EKG, MRI, Lung.

Prerequisite: BIOL 108, GBE 201, GBE 203, GBE 301, or Chairman’s Consent

GBE 299 Practical Training I ECTS -, Credits (0-0) 0

Students must complete a 30 business-day (6 weeks) summer practice in a bio company. Students are expected to learn about a real business and work environment and get involved in many aspects of genetic and bioengineering development process. Observations from practical training must be documented and presented in the form of a clear and concise technical report.

87

GBE 309 Genetics ECTS 5, Credits (3-0) 3

Introduction to the basics of genetics, chemical basis of heredity, maternal effects and heredity, gene expression and environmental effects, transmission of genetic information, gene arrangement, chromosome structure and disorders, population genetics.

Prerequisite: BIOL 108, GBE 206, GBE 216 or Chairman’s Consent

GBE 319 Genetics Laboratory ECTS 1, Credits (0-2) 1

The objectives are to develop laboratory skills on basic genetic applications including genetics of Drosophila fly, polytene chromosomes of Drosophila, inheritance related to sex, human genetics determining human phenotypes and genotypes, pedigree analysis.

Prerequisite: BIOL 108, GBE 206, GBE 216 or Chairman’s Consent

GBE 310 Molecular Biology ECTS 6, Credits (3-0) 3

The course covers the topics on Small Molecules, Energy, and Biosynthesis, Macromolecules (Structure, Shape, and Information ), How Cells Are Studied, Protein Function, Basic Genetic Mechanisms, Recombinant DNA

Technology, Control of Gene Expression.

Prerequisite: CHEM 107, BIOL 108, GBE 203, GBE 204, GBE 309, or Chairman’s Consent

GBE 320 Molecular Biology Laboratory ECTS 2, Credits (0-2) 1

The objectives are to develop laboratory skills related to recombinant DNA technology, PCR amplification of target gene, restriction enzyme digestion, ligation, preparation of competent bacterial cells, transformation, protein expression, colony isolation and protein purification.

Prerequisite: CHEM 107, BIOL 108, GBE 203, GBE 204, GBE 309, or Chairman’s Consent

GBE 399 Practical Training II ECTS -, Credits (0-0) 0

Students must complete a 30 business-day (6 weeks) summer practice in a company related with bioengineering.

Students are expected to learn about a real business and work environment and get involved in many aspects of genetic and bioengineering development process and research orientation. Observations from practical training must be documented and presented in the form of a clear and concise technical report.


GBE 401 Bioengineering Project I ECTS 6, Credits (2-0) 2

This course uses each student's required senior project as source information that the student will repeatedly present to the class in both a written and oral format. Due the communication emphasis of the class, it covers the

University's upper-division communication/writing requirement. During the course of the class, each student provides several oral presentations that are followed-up with instructional criticism from the class and the instructor.

Prerequisite: GBE 301, GBE 305, GBE 307, GBE 308, GBE 309, GBE 310, or Chairman’s Consent

GBE 403 Molecular Genetics ECTS 6, Credits (3-0) 3

Nucleic acids structure, chromosomal DNA, DNA replication, DNA repair, genetic recombination, control of gene expression, RNA and protein synthesis, viruses, plasmids, transposable genetic elements, recombinant

DNA technology.

Prerequisite: GBE 309, GBE 319, GBE 310, GBE 320, or Chairman’s Consent

GBE 413 Molecular Genetics Laboratory ECTS 2, Credits (0-2) 1

The objectives are to develop laboratory skills on the analysis of the cell at the molecular level. The laboratory applications include DNA extraction, electrophoresis, Poltmerase chain reaction, mutation analysis, RNA extraction, mRNA expression analysis,

Prerequisite: GBE 309, GBE 319, GBE 310, GBE 320, or Chairman’s Consent

GBE 402 Bioengineering Project II ECTS 6, Credits (2-0) 2

This course is a continuation of GBE 401 where each student was required to present his or her senior project.

The class requires each student to further refine both the oral and written presentation of his or her senior project to a professional level through additional presentations in several different time formats and through submitted drafts of his or her senior thesis. Due to the communication emphasis of the class, it along with GBE 401 covers the University's upper-division communication/writing requirement. At the conclusion of the semester, each student provides a senior thesis and participates in a public senior project fair where they provide a five-minute oral presentation followed by a twenty-minute poster presentation.


88

GBE 404 Human Body Dynamics ECTS 6, Credits (3-0) 3

Basics of vibrations, types of waves. Lumped parameter systems, health risks arising from occupational exposure to vibration, ergonomists and occupational health professionals guidance on the subject, whole body vibration, hand-arm vibration, and motion sickness. Vibration measurements and standards are also addressed.


GBE 405 Bionics ECTS 5, Credits (3-0) 3

This course introduces the application of methods and systems found in nature to the study and design of engineering systems and modern technology. The transfer of technology between lifeforms and synthetic constructs is considered.


GBE 406 Biorobotics ECTS 6, Credits (3-0) 3

Sensory Systems, A Spiking Neuron Controller for Robot Phonotaxis, Environmental Information, Animal

Behavior, and Biorobot Design: Reflections on Locating Chemical Sources in Marine Environments, Insect

Strategies of Visual Homing in Mobile Robots, Aerial Minirobot that Stabilizes and Tracks with a Bio-Inspired

Visual Scanning Sensor, Motor Systems, Construction of a Hexapod Robot with Cockroach Kinematics Benefits both Robotics and Biology, Build Robots with Complex Motor System to Understand Cognition, Cognitive

Systems, Perceptual Invariance and Categorization in an Embodied Model of the Visual System, Investigating

Models of Social Development using a Humanoid Robot


GBE 407 Biomechatronics ECTS 6, Credits (3-0) 3

The biological models useful to engineering, the current state of the field, and the progress and challenges awaiting future researchers. It reflects the interdisciplinary nature of the science, integrating materials, structures, actuators, sensors, interfaces, control, adaptability, and intelligence, among others.


GBE 408 Digital Biosignal Processing ECTS 6, Credits (3-0) 3

Biosignals,EEG or ECG or ... algorithms of cleaning, classifying and others, mathematical tools for that, like

Fourier Transform, Neural Networks, Wavelet Transform, Statistics.


GBE 409 Bionsensors ECTS 6, Credits (3-0) 3

Give a comprehensive introduction to the basic features of biosensors. Discuss the types of most common biological agents (e.g., chromorphores, fluorescence dyes) and the ways in which they can be interfaced with a variety of transducers to create a biosensor for biomedical applications. Focus on optical biosensors and systems

(e.g., fluorescence spectroscopy, microscopy) for biomedical applications, especially fiberoptically based biosensing techniques. New technologies such as molecular beacons, Q-dots, bioMEMS, confocal microscopy and multiphoton microscopy, and OCT will be covered.


GBE 410 Bioheat Transfer ECTS 6, Credits (3-0) 3

1-D steady heat conduction, thermal resistances, extended surfaces. 2-D steady heat conduction, shape factor, finite difference methods. Transient conduction, lumped capacitance method, 1-D transient conduction, product solutions. Boundary layers, laminar and turbulent flow, convective transfer boundary layer equations, dimensionless parameters, Reynolds analogy. External flow, empirical correlations. Internal flow correlations.


GBE 411 Reactor Kinetics and Desing in Biotechnology ECTS 6, Credits (3-0) 3

Introduction to the principles and practices of biochemical engineering. Important engineering, biochemical and physiological considerations in the design of bioreactor processes: enzyme kinetics, mass transfer limitations, microbial growth, and product formation kinetics. Fermentation reactor selection, design, scale-up, and control.


GBE 412 Process Dynamics and Control ECTS 6, Credits (3-0) 3

A systematic introduction to dynamic behavior and automatic control of industrial processes; lab includes instrumentation, measurement and control of process variables by using conventional hardware and real-time digital computers.


89

GBE 414 Industrial Biotechnology ECTS 6, Credits (3-0) 3

The immense diversity and metabolic versatility of microorganisms are beginning to be exploited in an everincreasing number of industrial applications. The advantages of using microorganisms, as outlined below, are manifold, but unless bio-industrial processes are competitive with traditional methods their potential will not be realised. By using new and exciting techniques to manipulate genes, natural diversity can be extended to increase yield, rate and specificity, thereby making reactions more efficient and economical. The drive towards sustainable development has led to a green revolution in chemistry. Microbial transformations require milder conditions than chemically catalysed reactions and are more specific, resulting in cleaner, greener processes.

Renewable raw materials, and even waste products, can be worked by microorganisms to create useful products ranging from fuels to food supplements, reducing reliance on non-sustainable, petroleum-based products.

Moreover, biotransformations can result in stereo- and regio-selective products, which are becoming a prerequisite for the manufacture of pharmaceuticals and other so-called 'fine chemicals'. Some microbial products, such as bioadhesives and biopolymers, are biodegradable, which not only serves to protect the environment, but also improves targeted drug delivery. From using Bacillus species as templates for silicone nano-devices to the employment of bacteriorhodopsin as an information storage device, even the computer industry cannot escape the impact of microorganisms. In this course, the first lecture focuses on biodiversity, then next few lectures concentrate on the principles of enzymatic reactions and state-of-the-art approaches being used to improve them. The remaining lectures illustrate specific processes, and have been organised under a number of headings, including: Biosynthesis of fine chemicals; Large-scale application of enzymes; Metabolic pathway engineering; Exploitation of anaerobic metabolism to produce commodity chemicals; Biomaterials and nanobiotechnology.


GBE 415 General Biotechnology ECTS 6, Credits (3-0) 3

Cell production methods in biotechnological processes; Cytochiometry of microbial reproduction and material production; Basis of fermentation technology; Fundamentals of enzyme engineering; Purification and recovery techniques of biomolecules; Classification, operation and control of bioreactors; Mixed cultures; Utilization of genetically modified microorganisms; Material production by plant cell cultures; Material production by animal cell cultures.


GBE 416 Developmental Biology ECTS 6, Credits (3-0) 3

Fertilization; the cleavage; embryonic polarization and embryonic axes; gastrulation; patterns of development; mechanisms of cellular differentiation; specification of cell fate; cellular interactions during organ formation; limb development; eye development; gonad development and sexual differentiation; embryonic development of

Drosophila, zebrafish, chick, Xenopus and mouse.


GBE 417 Systems Biology ECTS 6, Credits (3-0) 3

This course introduces the mathematical modeling techniques needed to address key questions in modern biology. An overview of modeling techniques in molecular biology and genetics, cell biology and developmental biology is covered. Key experiments that validate mathematical models are also discussed, as well as molecular, cellular, and developmental systems biology, bacterial chemotaxis, genetic oscillators, control theory and genetic networks, and gradient sensing systems. Additional specific topics include: constructing and modeling of genetic networks, lambda phage as a genetic switch, synthetic genetic switches, circadian rhythms, reaction diffusion equations, local activation and global inhibition models, center finding networks, general pattern formation models, modeling cell-cell communication, quorum sensing, and finally, models for Drosophila development.


GBE 418 Synthetic Biology ECTS 6, Credits (3-0) 3

A review of polymer concepts including synthesis and characterization of polymers will be provided. This course will provide a description of polysaccharides, proteins, aliphatic polyesters, polyurethanes, polyethers and polyanhydrides. Topics covered will be the source/synthesis, typical monomers, physical properties and degradation chemistry of important biopolymers. Methods of forming shaped articles from these polymers will be described.


GBE 419 Molecular Biology of the Gene ECTS 6, Credits (3-0) 3

This course deals with the rapidly developing fields of modern molecular genetics, genetic technology and the study of genes in families and populations. It includes a survey of the organisation of DNA within genes and

90

chromosomes, DNA replication and repair, the processes and control of gene expression, gene transfer and mobility, mutations, and the structure of proteins. Work on genetic technology includes consideration of the use of recombinant DNA and the polymerase chain reaction, and the applications of biotechnology. Modes of inheritance, the mechanisms of linkage and recombination, genetic mapping, genetic evolution and aspects of human and medical genetics are also surveyed.


GBE 420 Human Genetics ECTS 6, Credits (3-0) 3

Organization, structure, function, and mapping of the human genome; the biochemical and molecular basis, screening, prevention, and treatment of various human diseases, including cancer; genetic variation in humans; gene frequencies in human populations; human behavioral genetics, human developmental genetics, medical genetics and other aspects of human heredity.


GBE 421 Gene Theraphy ECTS 6, Credits (3-0) 3

Recent technologies that are already in use or may be used in future to correct genetic defects in human; human somatic cell gene therapy; viral and nonviral gene transfer techniques; gene therapy applications in hereditary and acquired diseases; ethical issues in genetic modification of humans; case studies: gene therapy for cystic fibrosis, gene therapy for ADA deficiency.


GBE 422 Protein Design ECTS 6, Credits (3-0) 3

Emphasis is on recent papers. Topics include: computational strategies for protein design; selection methods; applications of designed proteins in biotechnology, material sciences, and medicine; and long-range prospects for a synthetic biology. Practical problems of design related to issues of protein folding, structure, function, energetics, and evolution. Prerequisite: introductory biochemistry.


GBE 423 Genomics and Proteomics ECTS 6, Credits (3-0) 3

Structural organisations of human, D. melanogaster, C. elegans, A. thaliana, yeast and microbial genomes; gene orthologs; repetitive sequences; functional genomics; structural genomics; Pairwise and multiple sequence alignment; Coding region identification; introduction to the world of proteomics, definition, examples and methodology for determination of characteristics; in silico approaches to determining and predicting protein structure; methods of analysis of protein diversity and abundance; 2D gels, Mass Spectrometry and other high throughput methods.

Prerequisite: GBE 303, GBE 306, GBE 419, or Chairman’s Consent

GBE 424 Genetic Disorders and Counseling ECTS 6, Credits (3-0) 3

Genetic basis of inherited disorders; methods for prenatal diagnosis; multifactorial disorders; molecular diagnosis; identification and characterization of novel genes; historical case studies; gene therapy and tissue engineering. Genetic mechanisms; inbreeding populations; prenatal diagnosis, amniocentesis and chorionic villi sampling; DNA isolation, PCR analysis, RFLP, DNA fingerprinting methods; case studies; ethical implications of genetics information; the eugenics movement; genetics technologies for individuals and for society

Prerequisite: GBE 303, GBE 306, GBE 419 or Chairman’s Consent

GBE 425 Tissue Engineering ECTS 6, Credits (3-0) 3

Principles and practices of bioartificial organ and tissue development; cellular/material interaction and translation of information from two-dimensional surfaces to three-dimensional scaffolds; selection and processing of biomaterials to form tissue scaffolds; analysis of tissue engineered devices, standards, and regulation.


GBE 426 Neurobiology ECTS 6, Credits (3-0) 3

Neuronal cells; receptor control of neuronal excitability; molecular biology of G-protein coupled receptors; the brain and the central nervous system; blood-brain barrier; inhibitory amino acids and dopamine; cellular mechanisms of learning and memory; neurodegenerative diseases; transgenic animals as model systems for neurodegenerative diseases.


91

GBE 427 Neuroengineering ECTS 6, Credits (3-0) 3

Introduces the theory of neural signaling. Students will learn the fundamental theory of cellular potentials and chemical signaling, the Hodgkin Huxeley Contents of action potential generation, circuit representations of neurons and be able to derive and integrate equations describing the circuit as well as design computer models.


GBE 428 Molecular Engineering ECTS 6, Credits (3-0) 3

This course describes current developments in molecular structure and organization at synthetic material interfaces and the subsequent influences on cells and, in particular, cell membranes. It is designed to lay the groundwork for an improved understanding of events at the biomaterial-living system interface.


GBE 429 Complex Systems ECTS 6, Credits (3-0) 3

Introduction to product/process development in the context of complex systems. Evolutionary design principles, including the interrelationship between product cooperation, symbiosis, parasitics, and pathogenics. Building a design team and creating a mission statement, identifying customer needs, generating specifications, concept generation, concept selection, and creation of a product development environment. Students will work in interdisciplinary design teams to take a product/process of their choosing through the initial stages of the development process.


GBE 430 Genetic Algorithm ECTS 6, Credits (3-0) 3

Genetic algorithm is a domain-independent algorithm for search, optimization, and machine learning. Genetic programming is a domain-independent automatic programming technique that extends the genetic algorithm to the breeding of populations of computer programs capable of producing human-competitive results. Topics; mathematical basis for genetic algorithms; implementation on parallel computers and field-programmable gate arrays; problems of system identification, control, classification, analysis of genome and protein sequences; automatic synthesis of the design of topology, sizing, placement, and routing of analog electrical circuits; automatic synthesis of controllers and antennas and other complex network structures and reverse engineering of metabolic pathways and networks of chemical reactions.


GBE 431 Biopharmaceuticals ECTS 6, Credits (3-0) 3

Fundamental mechanisms of membrane transport, pharmacokinetics, modeling, and quantitation of these processes.


GBE 432 Forensic Technology ECTS 6, Credits (3-0) 3

Fundamental concepts of forensic science; collection and preservation of DNA evidence; contamination; genetic basis of diversity; molecular biological techniques used in DNA typing; sequence polymorphisms; case studies; qualitative interpretation of case samples; strength of forensic DNA results; population statistics; likelihood ratio; quantitative interpretation of case samples.


GBE 433 Bionanotechnology

Bionanotechnology is the key integrative technology of the 21 st

ECTS 5, Credits (3-0) 3

century and aims to use the knowledge, gathered from the natural construction of cellular systems, for the advancement of science and engineering. Investigating the topology and communication processes of cell parts can lead to invention of novel biological devices with exciting applications. Microscale to nanoscale research, protein based nanodevices, engineering design principles of biomolecular nanodevices, prototype nanodevices based on redox proteins, bacteriorhodopsins and natural fibers, and the future developments in the field.


GBE 434 Aquaculture ECTS 6, Credits (3-0) 3

Principles and techniques of aquaculture, with emphasis on warm-water species which spend all or part of their lives in salt water. Status and potential of aquaculture, including detailed deiscussions of established and candidate species. Design and management of aquaculture systems. Importance of water quality, feeding and nutrition, diseases and predators, genetics and breeding, and economic considerations in aquaculture.


92

GBE 435 Ecology ECTS 6, Credits (3-0) 3

Biosphere and biomes, ecosystems, structure and relationships, populations, protecting life, a survey of the patterns and theory regarding the interactions among plants, living organisms and their environment.


93

DEPARTMENT OF INDUSTRIAL ENGINEERING

Chairman

Mazhar ÜNSAL, Professor

BS, Robert College, Mechanical Engineering, 1970; MS, Virginia Polytechnic Institute and State University,

1972; MS, Virginia Polytechnic Institute and State University, 1975; PhD, Virginia Polytechnic Institute and

State University, 1975

Undergraduate Program in Industrial Engineering

Industrial engineers deal with complex problems in organizations. Industrial engineering students learn special industrial engineering techniques and how to apply these techniques in order to improve organizations in various ways such as in their performance, optimal use of resources, quality, productivity, or cost-effectiveness.

Employment opportunities for industrial engineers are not limited to the manufacturing sector. Industrial engineers are problem solvers in almost any type of organization and they find jobs in a wide variety of sectors.

There are industrial engineers working in such areas as municipality utilities, health services, transportation systems, storage and distribution companies, banks, consulting companies, and in manufacturing industries.

The vision of the Industrial Engineering Department is to train high qualified industrial engineers who satisfy businees world's requirement , in addition, to contribute to science and business sectors with our academic studies in this area. The mission of the Industrial Engineering Department is to provide effective solutions to production and service sector's problems through giving high quality education and to be a reputable Industrial

Engineering Department in the world. The aim of the Industrial Engineering Department is to train industrial engineers qualified to design, model, analyze, and manage complex systems. In their first year, students spend their time mostly in basic science courses such as mathematics, chemistry, physics, technical drawing and computer programming. In their second year they begin to take basic industrial engineering courses such as probability-statistics, operations research, materials science, and manufacturing. In their third year, they take specialized industrial engineering courses in operations analysis, simulation and production planning. In their last year as seniors, students register for 2 compulsory courses, 6 technical elective courses, and the senior design project course. It is in this course that students take on challenging projects and apply the skills they have gained in order to solve applied industrial engineering problems.

To fulfill the requirements for a Bachelor of Science degree in Industrial Engineering, students must take a total of at least 138 credit hours consisting of 111 credit hours of required courses and 27 credit hours of electives. Of the required courses, 49 credit hours are offered by the Industrial Engineering Department and 62 credit hours are courses in fields such as Mathematics, Computer Engineering, Chemistry, Physics, English, Turkish, History, and Economics. 18 credit hours of the electives are technical elective courses while the remaining 9 credit hours are non-technical elective courses. Students must also successfully complete a minimum of 60 workdays of summer practice as part of their graduation requirements.

94

TEACHING STAFF

Chairman

Mazhar ÜNSAL, Professor

B.S, Robert Koleji, 1970; M.S, Virginia Polytechnic Institute and State University, 1972 (Mechanical

Engineering); M.S, Virginia Polytechnic Institute and State University, 1975 (Mathematics); Ph.D, Virginia

Polytechnic Institute and State University, 1975

O ğ uz BORAT, Professor

B.S, Đ stanbul Teknik University, 1965; Ph.D., Đ stanbul Teknik University, 1968

Talip ALP, Professor

B.S, The Pitman College English, 1962; Ph.D., Manchester University, 1970

Ali TÜRKYILMAZ, Assist. Professor

B.S, Yıldız Teknik University, 1996; M.S, Fatih University, 2000; Ph.D., Đ stanbul Teknik University, 2007

Erkan TOPAL, Assist. Professor

B.S, Erciyes University, 1983; M.S, Ege University, 1986; Yüksek B.S, Rensselaer Polytechnic Institute, 1992;

Ph.D., Rensselaer Polytechnic Institute, 1994

Fahrettin ELDEM Đ R, Assist. Professor

B.S, Rensselaer Polytechnic Institute, 1997; M.S, Rensselaer Polytechnic Institute, 1999; Ph.D., Rensselaer

Polytechnic Institute, 2003

Mehmet Ş EVKL Đ , Assist. Professor

B.S, Sakarya University, 1997; M.S, Fatih University, 2000; Ph.D., Đ stanbul Teknik University, 2005

Ömer Fahrettin DEM Đ REL, Assist. Professor

B.S, Marmara University, 1992; M.S, Rensselaer Polytechnic Institute, 1995; Ph.D., Rensselaer Polytechnic

Institute, 2000

Özgür UYSAL, Assist. Professor

B.S, Bo ğ aziçi University, 1994; M.S, Fatih University, 2000; Ph.D., Marmara University, 2006

Metin Ş ATIR, Instructor

B.S, Yıldız Teknik University, 1997; M.S, Fatih University, 1999; Yüksek B.S, Fatih University, 2003

Ali GÖRENER, Res.Assist.

B.S, Kocaeli University, 2004; M.S, Đ stanbul Ticaret University, 2006; Yüksek B.S, Yıldız Teknik University,

2007

Ali ĐŞ ER Đ , Res.Assist.


Ay ş e Nurdan SERT, Res.Assist.

B.S, Yıldız Teknik University, 2006

M.Seyyit ÖZTEK Đ N, Res.Assist.


Mustafa AKKURT, Res.Assist.


Recep KIZILASLAN, Res.Assist.

B.S, Đ stanbul Kültür University, 2006

95


Computer Integrated Flexible Manufacturing Laboratory

Our FMS Lab consists of a CNC lathe, CNC Mill, and a robot in which the functions of an organization, from product definition to the disposition of the final product, are designed and integrated to achieve organizational goals, most efficiently and effectively. The coordination of the functions is achieved using computer, communication, and information technologies.

Equipment&Resources :

Software Programs:

Emco WinNC Sinumerik Turn, Cosimir Factory

Emco WinNC Sinumerik Mill, Cosimir Robotics

Emco WinCAM Turn, Cosimir Control

Emco WinCAM Mill

Esprit CAD System

Courses:

IE 226 Manufacturing Processes

IE 445 Computer Integrated Manufacturing Systems

IE 476 Modeling and Analysis of Manufacturing Systems

IE 480 Special Topics in Industrial Engineering

IE 487 Independent Study

IE 490 Design Project.

Ergonomics – Human Factors Test Laboratory

The HF/Usability Laboratory is a teaching/research center/laboratory within the Department of Industrial

Engineering. It is also used by the Computer Engineering Department, the Management Department and teh

Graduate School of Sciences and Engineering. The HF/Usability Laboratory is availablefor use to both commercial and research-oriented organizations.

The failure of many computer-based systems to be effective in meeting users' requirements motivated our desire to promote HF/usability practices and principles. Our goal has been to establish a comprehensive HF/usability laboratory as Turkey's foremost HF/usability resource. In doing so we are able to provide a range of usability services, resources and facilities for the Turkey industry in a HF/usability perspective.

Stationary HF/usability Laboratory

Commonly stationary HF/usability lab consists of observer side and participant side:

We have several tools in the observer room to collect the HF/usability data and efficiently analyze it. All of our tools have been designed to help us quickly get HF/usability data back to the software team.

96

Portable HF/usability Laboratory

This portable lab was especially configured for a variety of HF/usability research applications. It is flexible and can be used in different settings (e.g. for observing focus groups, in a lab and in the field

Research areas:

Any research study can be performed by the highlight of the contents of the courses offered in HF/Usability Lab.

EC, TUBITAK, KOSGEB etc. research and development projects

With HF/usability evaluation of IT products and industrial products. Already contacts and interest for cooperation from Turkish and German companies.

Industrial Engineering Computer Laboratories

The computer laboratory enable users to perform general computing tasks, such as word processing, email, and

Internet surfing, as well as more advanced computing required for course work and research.

Students use this computer lab for either Course lab such as computer programming, simulation, and optimization courses or homeworks assignment.

97

First Semester

INFO 111

CENG 103

Programming


Basic Computer Skills







0 2 NC - -

3 2 4 6 8

3

3

4

3

2

0

0

2

4

3

4

4

7

4

7

7

10

6

10

10

19 31 44

Second Semester



ENGR 100 Introduction to Eng. Design





2 2 3 5 8

3

0

2

4

3

0

2

2

0

2

3

1

3

4

4

18

4

2

4

7

7

29

6

5

6

10

10

45

Third Semester

IE 225 Materials Science

BIO 203 Biomechanics

ECON 101 Introduction to Economics I


MATH 345 Introduction to Probability

Theory


Fourth Semester

IE 216 Operations Research I

IE 226 Manufacturing Processes

ECON 102 Introduction to Economics I


MATH 346 Introduction to Statistics


Fifth Semester

APHR 101 Atatürk's Principles and

History of Turkish Rev. I

IE

IE

299 Practical Training I

305 Work Methods and

Measurement

IE

IE

315 Operations Research II

320 Production Planning and

Control I

IE

IE

325 Cost Analysis and Control

341 Database Management in

Industrial Engineering


3 0 3 6 8

3

3

0

0

3

3

7

5

7

8

3

3

2

0

0

0

3

3

2

17

5

5

2

30

7

7

4

41


3 1 3 6 8

2

3

3

3

2

2

0

0

0

0

3

3

3

3

2

17

6

5

5

5

3

30

8

7

7

7

4

41


2 0 2 2 4

-

2

3

3

3

2

-

2

1

0

0

2

NC

3

3

3

3

3

17

-

6

6

5

6

5

30

-

7

8

7

7

7

40

98

Sixth Semester

APHR 102 Atatürk's Principles and

History of Turkish Rev. II

ECON 388 Engineering Economics

IE 345 Simulation

IE 425 Production Planning and

Control II

IE 435 Quality Control


*

Theo.

2

3

3

3

2

3

Prac.

0

0

1

0

2

0

Credits

2

3

3

3

3

3

17

ECTS

3

5

6

6

5

5

30

Workload

4

7

8

7

7

7

40


IE 399 Practical Training II

IE

IE

413

460

Human Factors Engineering I

Facilities Location and Design

IE

IE

IE

487 Independent Study

4xx Technical Elective I

**

IE 4xx Technical Elective II

**


*

4xx Technical Elective III

**


- - NC - -

2

3

2

0

3

3

6

6

7

7

0

3

3

3

3

2

0

0

0

0

NC

3

3

3

3

3

5

5

4

4

3

7

7

6

6

18 32 43

Eighth Semester

IE 490 Design Project

IE 4xx Technical Elective IV

**


*

XXX xxx Technical Elective V

***

XXX xxx Technical Elective VI

***


0

3

3

3

3

6

0

0

0

0

3

3

3

3

3

8

5

5

5

5

12

7

7

7

7

15 28 40



*

Students must select 3 credit non-technical elective courses with the following codes only: ACL, ELL, RLL,

CLL, SLL, GEO, HIST, ECON, MAN, PUB, INT, PHIL, PSY, SOC, GER, CHN, RUS, SPAN. Courses from

PREP program cannot be chosen .

**

At least 4 of the technical electives must be selected from the technical elective courses offered by the IE

Department.

***

Students must select IE, CENG, ECON, MAN, or MATH courses from the technical elective course list given below.



IE 411 Reliability and Maintainability

IE

IE

416 Activity Net. and Project Man.

420 Human Factors Engineering II

IE

IE

430 Total Quality Management

441 Operations Scheduling


3 0 3 5 7

3

3

0

0

3

3

5

5

7

7

3

3

0

0

3

3

5

5

7

7

IE

IE

IE

IE

IE

445 Computer Integrated

Manufacturing Systems

448 System Design

452 Quality by Design

455 Optimization

470 Analysis and Design of

Supply Chains

3

3

3

3

3

0

0

0

0

0

3

3

3

3

3

5

5

5

5

5

7

7

7

7

7

99

IE 473 Enterprise Resource Planning

Systems

IE 476 Modeling and Analysis of

Manufacturing Systems

481 Special Topics in Indust. Eng I IE

IE 480 Special Topics in Indust. Eng II

CENG 433 Human–Computer-Interaction

CENG 434 Personalization Engineering

CENG 451 Intro. to MIS

CENG 452 Introduction to Data Mining


CENG 490 Intro. to AI


CENG 493 Evolutionary Computing

ECON 231 Econometric Theory I

ECON 232 Econometric Theory II

ECON 321 Public Finance I

ECON 322 Public Finance II

MAN 201 Principles of Accounting I

MAN 202 Principles of Accounting II

MAN 209 Principles of Marketing

MAN 303 Managerial Finance I

MAN 304 Managerial Finance II

MAN 314 Human Resources Mgt

MAN 361 Organizational Behavior

MAN 401 Strategic Management

MAN 434 Entrepreneurship

MAN 446 Marketing Research

MATH 222 Advanced Linear Algebra


MATH 330 Numerical Analysis II

MATH 445 Regression and Correlation

Analysis

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

0

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

3

5 7



IE 216

IE 225

IE 226

Operations Research I

Materials Science

Manufacturing Processes

GBE 203

IE 315

IE 320

Biomechanics

Operations Research II

Production Planning and Control I

IE 345

IE 341

IE 411

IE 416

IE 420

IE 425

IE 430

IE 435

IE 441

IE 445

Simulation

Activity Networks and Project

Management

Human Factors Engineering II

Production Planning and Control II

Total Quality Management

Quality Control

Operations Scheduling

Computer Integrated Manufacturing

Systems

Data Management in Industrial

Engineering

Reliability and Maintainability

Prerequisite



IE 225, or Chairman’s Consent

PHYS 103, or Chairman’s Consent


IE 216 and MATH 345, or Chairman’s

Consent


B Đ LM 103 and B Đ LM 104, or Chairman’s

Consent

MATH 345 and MATH 346, or


MATH 345, MATH 346, and IE 216, or




IE 435, MATH 345 and MATH 346 and, or Chairman’s Consent



IE 226 and IE 235, or Chairman’s Consent

5

5

6

6

5

5

5

5

5

5

5

5

4

5

5

5

5

5

5

5

4

5

5

6

5

5

5

5

5

7

7

8

8

7

7

7

7

7

7

7

7

6

7

7

7

7

7

7

6

6

7

7

8

7

7

7

7

7

100

IE 452

IE 455

IE 476

IE 487

IE 490

Quality by Design

Optimization

Modeling and Analysis of Manufacturing

Systems

Independent Study

Design Project

MATH 345 and MATH 346, or


IE 216 and IE 315 or Chairman’s Consent


All freshman and sophomore year IE courses

IE 487


Old Course

Code

Old Course Name

New Course

Code

New Course Name

CENG 104

EE 391

IE 235

IE 350

Computer Programming II


Intro to Engg Mechanics

Engineering Thermodynamics


IE 4xx Technical Elective XI


ENVE 205 Engineering Thermodynamics

DOUBLE MAJOR

Credit Hours Second Semester


First Semester

Third Semester



MATH 345 Intro to Probability Theory

Credit Hours Fourth Semester

(3+0) 3 IE 216 Operations Research I

(3+0) 3

(3+0) 3

IE 226

MATH 230

Manufacturing Processes

Differential Equations

(9+0) 9

MATH 346 Introduction to Statistics

Credit Hours

(2+2) 3

(2+2) 3

Credit Hours

(3+1) 3

(2+2) 3

(3+0) 3

(3+0) 3

(11+3) 12

Fifth Semester

IE

IE

305

315

Work Methods and Measurement

Operations Research II

IE

IE

320

341

Production Planning and Control I

Database Management in

Industrial Engineering

Credit Hours Sixth Semester

(2+2) 3

(3+1) 3

IE

IE

345

425

Simulation

Production Planning and Control II

(3+0) 3

(2+2) 3

IE 435 Quality Control

Credit Hours

(3+1) 3

(3+0) 3

(2+2) 3

(6+4) 12 (8+3) 9


IE

IE

413

460

Human Factors Engineering I

Facilities Location and Design

IE 4xx Technical Elective I

Credit Hours Eighth Semester

(2+2) 3

(3+0) 3

IE

IE

4xx

4xx

Technical Elective II

Technical Elective III

(3+0)

(8+2) 6

IE 4xx Technical Elective Iv

Credit Hours

(3+0) 3

(3+0) 3

(3+0) 3

(9+0) 6

Total credits required in Double Major Program: 57

The minimum cumulative GPA requirement is 3.50.

If the prerequisite(s) of a course above is not present in the double major program, it will not be required.

Students Taking Equivalent Courses (Equivalence Will Be Decided By The Department Council)

In Their Main Program Will Be Exempt From Some Of The Above Courses; If The Total Credits

Drops Below The Minimum Level Of 42 In This Case, It Must Be Completed To At Least 42 By

Sufficient Number Of The Ie 4xx Technical Elective Courses.

Undergraduate students of the following departments can apply for the Industrial Engineering

Double Major Program: Computer, Environmental, Electrical and Electronic, Genetic and

Bioengineering, Mathematics, Economics, Management

101

MINOR PROGRAM

First Semester Contact/Credit Hours Second Semester

Third Semester Contact/Credit Hours Fourth Semester

MATH 345 Introduction To Probability Theory

*

(3+0) 3 MATH 346 Introduction To Statistics

*

IE 305 Work Methods And Measurement

*

(2+2) 3 IE 216 Operations Research I

*



(3+0) 3

(3+0) 3

Fifth Semester

IE 320 Production Plan. And Control I

*

IE 315 Operations Research II *


(3+0) 3 IE


425 Production Plan. And Control II

*

(3+0) 3

(3+1) 3 IE 435 Quality Control * (2+2) 3


IE

IE xxx Technical Elective I

** xxx Technical Elective II

**


(3+0) 3 IE xxx Technical Elective III

**

(3+0) 3

Total Credits Required Đ n Minor Program: 18

The Minimum Cumulative Gpa Requirement Is 3.00.

At Least Four Of These Courses Should Be Selected To Qualify For The Minor Program.

**

Students Must Select Courses From The Technical Electives List Shown Below.


(3+0) 3

102


ENGR 100 Introduction to Engineering Design ECTS 2, Credits (0+2) 1

Essentials of engineering design; problem formulation, team work, concept generation, project planning, proposal writing, resume writing, engineering economics, environmental impact, engineering ethics, codes and standards, reporting and presenting technical information. In this course, students are expected to work in groups to complete an engineering design project and to report on the work in both oral and written forms.

IE 104 Engineering Graphics ECTS 4, Credits (2+2) 3

Introduction to computer aided drawing, geometrical constructions, orthographic drawing and sketching, auxiliary views, sections, dimensioning, tolerances, working drawings, 3D drawing and solid modeling.

IE 216 Operations Research I ECTS 6, Credits (3+1) 3

Introduction to deterministic models in operations research, introduction to linear programming, the simplex method, duality and sensitivity analysis; transportation model, assignment problem, networks.

Prerequisite: MATH 220, or Chairman’s consent.

IE 225 Materials Science ECTS 6, Credits (3+0) 3

Introduction to materials science, study of engineering materials such as metals, ceramics, polymers and composites, nature of materials, mechanical and physical properties, heat treatment of metals.

Prerequisite: CHEM 105, or Chairman’s consent.

IE 226 Manufacturing Processes ECTS 6, Credits (2+2) 3

Review of manufacturing processes, casting, molding and related processes, metal forming, bulk deformation processes and sheet metal working, shaping processes for plastics, material removal processes, powder metallurgy.

Prerequisite: IE 225, or Chairman’s consent.

IE 299 Industrial Training I Non-Credit

This is a 6 week long summer practice in a manufacturing or a production organisation. The student is to investigate the organisation critically regarding their ongoing industrial engineering practices. Observations from the summer practice must be documented and presented in the form of a clear and concise technical report.

IE 305 Work Methods and Measurement ECTS 5, Credits (2+2) 3

Work methods design and improvement, process analysis, operations analysis, hand motions, principles of motion economy, time measurement, performance rating, standard times, MTM, learning curves. The course is mainly based on software like DesignTools, etc.

IE 315 Operations Research II ECTS 5, Credits (3+1) 3

Integer linear programming, dynamic programming, decision analysis and game theory. queuing theory,

Markovian decision processes


IE 320 Production Planning and Control I ECTS 5, Credits (3+0) 3

Forecasting, aggregate planning, deterministic inventory control, stochastic inventory control, master production scheduling, material requirements planning

Prerequisites: IE 216 and MATH 345, or Chairman’s consent.

IE 325 Cost Analysis and Control ECTS 5, Credits (3+0) 3

Introduction to accounting practices, cost accounting, standard cost, overhead cost, product costing methods, design of cost accounting systems, methods of cost analysis, cost control, computer applications.

IE 341 Data Management in Industrial Engineering ECTS 5, Credits (2+2) 3

Design of relational databases, applications using MS Access and SQL, web based database applications using

HTML and Java

103

IE 345 Simulation ECTS 5, Credits (3+1) 3

Introduction to simulation, manual and spreadsheet simulation, event-scheduling/time-advance algorithm, statistical models of simulation, random number generation, random variate generation, input modeling, output analysis, laboratory applications using a simulation programming package


IE 399 Industrial Training II Non-Credit

This is a 6 week long summer practice in a manufacturing or a production organisation. The student is to investigate the organisation critically regarding their ongoing industrial engineering practices and suggest improvements. Observations and suggested improvements must be documented and presented in the form of a clear and concise technical report.

IE 411 Reliability and Maintainability ECTS 5, Credits (2+2) 3

Definitions and basic concepts, failure data, failure modes, reliability in terms of hazard rate and failure density, component reliability and hazard models, bath-tub curve, applicability of the Weibull distribution, system reliability models and use of redundancy in system design, relationship between reliability, maintainability and availability, preventive maintenance, predictive/condition-based maintenance, designing-out-of-maintenance, terotechnology and total productive maintenance, reliability-centred maintenance, corrective maintenance time distributions, introduction to life testing.

Prerequisites: MATH 345 and MATH 346, or Chairman’s consent.

IE 413 Human Factors Engineering I ECTS 5, Credits (2+2) 3

Principles for developing safe and user-friendly systems, factors contributive to people's physical and psychological well-being, and on their performance; anatomy, demographics and physiology; biomechanics and posture; anthropometry; energy and force production; psycho-physiological and cognitive aspects of information intake, information handling, and decision making; social and organizational aspects; physical environment: climatic, visual and acoustic environment; vibration; human senses; the human as a system component, human reliability, training and instruction; occupational hygiene; workplace design.

IE 416 Activity Networks and Project Management ECTS 5, Credits (3+0) 3

Activity network fundamentals, introduction to graph theory and graph theoretic applications, network methods for project planning and scheduling, critical path analysis, CPM and PERT models, scheduling with limited resources, time-cost trade-off and resource assignment, network crashing, PERT-cost and probabilistic network analysis, project feasibility-appraisal-selection and planning, prospects and case studies.

Prerequisites: IE 216, MATH 345 and MATH 346, or Chairman’s consent.

IE 420 Human Factors Engineering II ECTS 5, Credits (3+0) 3

Usability Engineering: methods for gathering information about users, user's task analysis, requirements for making usable produces, design heuristics, usability evaluation methods, predicting and analysing usability problems, usability testing; Affective Engineering: physical and cognitive aspects of emotions, emotion sensing, affect recognition, synthesizing emotions, affective human factors / Kansei engineering / hedonic ergonomics in design of products, interfaces and environments.

Prerequisite: IE 413, or Chairman’s consent.

IE 425 Production Planning and Control II ECTS 6, Credits (3+0) 3

Sequencing and scheduling, just in time systems, cellular manufacturing, optimized production technology, comparison of MRP JIT and OPT.


IE 430 Total Quality Management ECTS 5, Credits (3+0) 3

TQM philosophies and the evolution of TQM, identification and measurement of quality costs, economics of quality, reduction of quality costs, quality planning, responsibility and authority, organizing for total quality, leadership and motivation, empowerment and achieving total commitment, essential feature of kaizen, quality circles, zero defects program, the seven tools, quality function deployment, benchmarking, 5-S campaign, six sigma quality improvement, ISO 9000 and QS 9000 quality system standards, essential features of the Malcolm

Baldridge National Quality Award, partial and total productivity measures, measurement and improvement of productivity, evaluation of corporate strengths and weaknesses, strategic planning.

Prerequisites: MATH 345, MATH 346 and IE 435 or consent of the chairman.

104

IE 435 Quality Control ECTS 5 , Credits (2+2) 3

Basic concepts of QC, tools of analysis, and techniques of statistical quality control, including use of control charts for variables and attributes, process capability analysis, cum sum and EWMA charts, Taguchi methods, acceptance sampling plans, applications based on utilization of a specialized software package.


IE 441 Operations Scheduling ECTS 5, Credits (3+0) 3

Single machine scheduling, flow shop scheduling, the general job shop scheduling, open shop scheduling, tool scheduling on NC machines, stochastic single and parallel machines, solution by exact and heuristic methods.


IE 445 Computer Integrated Manufacturing Systems ECTS 5, Credits (2+2) 3

Introduction to computer integrated manufacturing systems and automation, computer-aided design, computeraided manufacturing, computer-aided process planning, computer numerical control machining, PLC, robotics,

FMS. AGV, AS/RS.

Prerequisites: IE 226 and IE 235, or Chairman’s consent.

IE 448 System Design ECTS 5, Credits (3+0) 3

Principle of systems, characteristics of systems, conceptual design, preliminary design, detailed design, use of top-down approach in functional analysis and objective tree, requirement analysis, tests and reviews, tools of analysis and design, product recovery, applications in TQM, SCM, and concurrent engineering.

IE 452 Quality by Design ECTS 5, Credits (3+0) 3

Economics of reducing variation - goal-post philosophy and Taguchi's quadratic loss function, off-line and online quality control, inadequate process capability and importance of parameter design, experimental design, features of experiments, comparison of several treatments, completely randomized design, analysis of variance, factorial experiments, confounding, fractional replication and fractional factorial designs, response surface designs and methodology, Taguchi's robust design methodology, signal-to-noise ratios and other performance measures, case study applications.

Prerequisites: MATH 345 and MATH 346, or Chairman’s consent.

IE 455 Optimization ECTS 5, Credits (3+0) 3

Modeling of industrial engineering problems, application of selected solution algorithms to linear, nonlinear, discrete and continuous mathematical programming problems.

Prerequisites: IE 216 and IE 315, or Chairman’s consent.

IE 460 Facilities Location and Design ECTS 5, Credits (3+0) 3

Objectives, steps of facility design, data collection, Material flow, material handling, group technology, developing block layouts, machine layout, computer aided design applications.

IE 470 Design and Operation of Supply Chains ECTS 5, Credits (3+0) 3

Supply chain as a system, integration, performance measures, the bullwhip effect, the role of the internet and information technology, supplier selection, multi echlon inventory, warehouse and plant location, integrated models for production/inventory, location/inventory, and location/routing, supply chains for product recovery.

IE 473 Enterprise Resource Planning Systems ECTS 5, Credits (3+0) 3

Introducation to enterprise systems, the architecture of an enterprise system, building enterprise systems and development/deployment of enterprise wide solution using software.

IE 476 Modeling and Analysis of Manufacturing Systems ECTS 5, Credits (3+0) 3

Analysis of assembly lines, shop scheduling, group technology, machine setup and operation sequencing, material handling systems, warehousing.

Prerequisite: IE 425, or Chairman’s consent.

IE 481 Special Topics in Industrial Engineeering I ECTS 5, Credits (3+0) 3

The course description for this course is announced at the beginning of each semester. This course will generally cover state-of-the-art recent subjects which are not covered in other courses offered by the Department of

Industrial Engineering.

Prerequisite: Chairman’s consent.

105

IE 480 Special Topics in Industrial Engineeering II ECTS 5, Credits (3+0) 3

The course description for this course is announced at the beginning of each semester. This course will generally cover state-of-the-art recent subjects which are not covered in other courses offered by the Department of

Industrial Engineering.

Prerequisite: Chairman’s consent.

IE 487 Independent Study ECTS 3, Credits (0+2) NC

This is an independent study under the supervision of a faculty member. Each student is expected to do research trying to explore and define a potential study area suitable for a senior design project. A specific industrial engineering problem must then be identified from within the selected study area. Results from this study must be documented and submitted in the form of a design project proposal.

Prerequisite: All freshman and Sophomore year IE courses.

IE 490 Design Project ECTS 8, Credits (0+6) 3

This is a guided study under the supervision of a faculty member. Each student is expected to work on the design project he/she has proposed in the “IE 489 Independent Study” course. The design project should normally include utilization of a digital computer. Results from this study must be submitted in the form of a clear and concise technical report.

Prerequisite: IE 487

106

01_Engineering Faculty Introduction_08 Mart 08+

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Engineering Faculty

Undergraduate Catalogue www.eng.fatih.edu.tr

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01_Engineering Faculty Introduction_08 Mart 08+

Fatih University

Engineering Faculty

Undergraduate Catalogue www.eng.fatih.edu.tr

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3

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Determination and assessment of the pollution which effects the Büyükçekmece lake and watershed”

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