Course |
Content |
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EE 122 Introduction To Electrical And Electronics Engineering And Ethics |
This course introduces the students to the courses and laboratories they will take during their studies in Electrical and Electronics Engineering. In this way, students can focus on the areas they are interested in. The course also includes factory visits, providing students with insights and experience on how industrial operations work. |
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CS 104 Introduction To Programming In Python II |
This is an introductory course on Object-Oriented Programming using Python. A basic background in programming is required. Topics include classes and objects in Python, writing custom classes, object-oriented thinking, introduction to inheritance, graphical user interface design, and basic graphical concepts. |
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PHYS101 Physics I |
This course covers Newtonian mechanics including kinematics, dynamics, force, work, kinetic and potential energy, momentum, circular and rotational motion, and gravity. |
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PHYL 101 Physics I Laboratory |
This course includes experiments on the practical application of topics covered in Physics I such as kinematics, dynamics, force, energy, momentum, rotational motion, and gravity. |
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PHYS102 Physics II |
This course covers electromagnetism and basic electric circuits: electric fields, electric potential, capacitance, resistance, DC and AC circuits, magnetic fields and forces, electromagnetic induction, inductance, and electromagnetic waves. |
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PHYL102 Physics II Laboratory |
Includes experiments related to electromagnetism and basic electric circuits: electric fields, electric potential, capacitance, resistance, DC and AC circuits, magnetic fields and forces, electromagnetic induction, inductance, and electromagnetic waves. |
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EE 213 Electromagnetic Field Theory |
Electrical and Electronics Engineers of the 21st century must understand the basic principles and laws of electromagnetism to develop and implement better analog or digital electronic systems that consider the effects of electromagnetic propagation and radiation. This is one of the most challenging courses in the Electrical and Electronics Engineering curriculum, yet it provides a strong foundation for advanced courses such as antennas, microwaves, photonics/lasers, and semiconductor engineering. |
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EE 214 Electromagnetic Wave Theory |
Covers Maxwell’s equations, wave propagation in free space and in various materials, transmission line theory, waveguide theory, and antennas. |
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EE 205 Circuit Theory I Laboratory |
Covers laboratory experiments on circuit analysis methods, resistors, inductors, and capacitors. |
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EE 201 Circuit Theory I |
Covers basic circuit elements, circuit analysis techniques, circuit theorems, the behavior of resistors, capacitors, and inductors under current and voltage, operational amplifier characteristics, and first and second-order DC circuits. |
|
EE 202 Circuit Theory II |
Covers phasors, sinusoidal analysis, AC power, three-phase systems, magnetically coupled circuits, frequency response, Laplace transform, Fourier transform, and two-port networks. |
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EE 204 Circuit Theory II Laboratory |
Includes experiments on phasors, sinusoidal analysis, and AC power concepts. |
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EE 221 Digital Systems |
This course introduces the basic concepts of digital systems such as number systems, Boolean algebra, logic circuits and their simplifications, canonical forms, combinational circuits, adders, decoders, encoders, multiplexers, converters, sequential circuit analysis and design, registers, counters, memory, and programmable logic devices. |
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EE 223 Digital Systems Laboratory |
Covers experiments related to basic digital system concepts such as number systems, Boolean algebra, logic circuits and their simplification, canonical forms, combinational circuits, adders, decoders, encoders, multiplexers, flip-flops, sequential circuit analysis and design, registers, and counters. |
|
EE 242 Modern Physics For Engineers |
Topics include: Special Relativity I & II, introduction to quantum physics (blackbody radiation, photoelectric effect, Compton scattering, atomic spectra, Bohr model), wave-particle duality of photons and particles, particle in a box, Schrödinger wave equation, tunneling, simple harmonic oscillator, development of atomic models (Thomson, Rutherford, Bohr), hydrogen atom in quantum theory, quantum numbers, exclusion principle, periodic table, atomic transitions, X-rays of atoms, lasers, molecules and solids, and the structure of the nucleus. |
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EE 299 Summer Training I |
Completion of a project assigned by the internship institution. Provides practical experience and insight into professional engineering practices. |
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EE 301 Semiconductor Device Principles |
Covers the operational principles of semiconductor devices such as p-n junction diodes, BJTs, and MOSFETs. The course develops an understanding of solid-state physics focused on semiconductors, including crystal structures, energy band structures, semiconductor doping, p-type and n-type materials, and carrier dynamics. |
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EE 302 Analog Electronics |
Covers small-signal analysis, MOSFETs, BJTs, frequency response, multistage amplifiers, feedback, and operational amplifiers. |
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EE 304 Analog Electronics Laboratory |
Laboratory applications of the theories taught in EE 302. Students perform experiments on analog electronic circuits, analyzing real-world performance. |
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EE 313 Signals And Systems |
Covers the fundamentals of signal and system analysis: processing and analysis of continuous and discrete-time signals, system properties, time and frequency domain representations, linear time-invariant (LTI) systems, convolution and impulse response, Fourier analysis, spectral response of LTI systems, sampling and filtering, Laplace and Z-transforms. |
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EE 332 Introduction To Telecommunications |
Covers signal analysis and transmission, amplitude modulation (AM), quadrature amplitude modulation (QAM), frequency modulation (FM), phase modulation (PM), phase-locked loops (PLL), sampling, quantization, pulse transmission, and fundamentals of digital data communication technologies. |
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EE 342 Introduction To Control Engineering |
Teaches the fundamentals of feedback, analysis of dynamic systems, stability and performance analysis, and both time and frequency domain methods. Theoretical topics are supported by MATLAB simulations. |
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EE 312 Energy Conversion |
Covers principles of energy conversion including magnetic circuits, electromechanical energy conversion, transformers, DC and AC motors and generators, stepper motors, and fundamentals of photovoltaic, vibrational, and thermoelectric energy conversion. |
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EE 399 Summer Training II |
Completion of a project assigned by the internship institution, building on practical engineering experience and technical problem-solving skills. |
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EE 445 Microcontrollers |
Covers architecture and organization of microcontrollers, bus structures, types and buffering techniques, serial and parallel communication, peripheral control and programming. Emphasizes the design, implementation, testing, and documentation of microprocessor-based systems. |
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EE 491 Senior Project I |
A semester-long team project conducted under the supervision of a faculty advisor. The project involves original research, literature review, design, prototyping, and testing phases. Emphasis is placed on teamwork, innovation, and engineering problem-solving. |
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EE 492 Senior Project II |
The project progresses to implementation and evaluation stages, with final documentation and presentation. Students complete a working prototype and assess its functionality and performance. |
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EE 403 Digital Electronics |
Topics include diode-resistor logic, resistor-transistor logic, transistor-transistor logic, DC analysis of BJT and MOSFET circuits, CMOS inverters, pseudo-CMOS logic, regenerative circuits, Schmitt triggers, latches, flip-flops, multivibrators, 555 timers, RAM, ROM, ADCs, and DACs. |
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EE 482 Power Electronics And Applications |
Covers electrical power calculations, harmonics, Fourier series, controlled/uncontrolled half- and full-bridge rectifiers, DC/DC converters (buck, boost, buck-boost), power supplies, DC/AC inverters with control algorithms, AC/AC converters, simulation of converters, selection of semiconductor switching devices, driver circuits, and heatsinks. |
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EE 484 Power Distribution |
Covers current and power calculations in three-phase systems, ring and radial network configurations, selection of cost-effective conductors, poles and components used in distribution systems, and characteristics and selection criteria of underground and overhead lines. |
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ENEE 301 Lasers |
Focuses on the wave nature of light, semiconductor science, light-emitting diodes, stimulated emission devices, optical amplifiers, and lasers. |
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ENEE 302 Electrical Installations |
Covers the design and analysis of medium- and low-voltage electrical systems, including practical aspects of electrical installation projects. |
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EE 486 Power Systems Analysis |
Analyzes systems composed of generators, transformers, and transmission lines under AC sources. Introduces power system analysis techniques and theorems used in modern energy systems. |
|
ENEE 303 Biomedical Imaging |
Explores imaging techniques used in biomedical applications and the physical principles underlying those methods, providing foundational knowledge of imaging technologies in the healthcare sector. |
