Electronics communication Engineering

ELE 111 Introduction to Electronics Engineering

Relevance of Electronics Engineering curriculum to the practice of engineering in manufacturing and R&D environments. Various approaches and methods in problem solving. Introduction to, electronics and systems. Examples of applications.
ELE 211(E) Basics of Electrical Circuits

Physical electrical circuits. Modeling and measurements of currents and voltages in physical circuits. Definitions of charge, flux, power and energy and modeling their waveforms. Kirchoff's laws: Current and voltage equations. Circuit graphs. Graph matrices. Ideal 2- terminal and multi-terminal circuit elements: Linear and non-linear resistors, inductors and capacitors. Modeling of physical elements. Small-signal analysis. Solution of resistive circuits: Node voltage and mesh current methods. Circuit theorems: Tellegen's theorem. Superposition theorem. Reciprocity theorem. Thevenin and Norton theorems. Maximum power transfer theorem. Solution of dynamic circuits: Responses of first and second order dynamic circuits
ELE 222(E) Electronic Devices

Components and basic circuits: Operational amplifiers, concepts and application examples. Diodes: Terminal characteristics, analysis of diode circuits, semiconductor principles and structure of junction diode. DC biasing, BJT as an amplifier. MOSFET: Structure and operating modes.
ELE 242 Analysis of Circuits and Systems

State equations of higher order circuits and their solutions in t and s domain. State transition matrix. Zero state zero input responses. Stability, Routh criteria. Controllability and observability. Analysis of dynamical systems in W-domain. Sinusoidal steady state. Phasors, phasor network equations. Power and energy. Three phase systems. Network and system equations in s domain. Bode diagrams. Block diagram and signal flow graphs.
ELE 232 Signal Processing

Classification of signals and systems. Fourier analysis of continuous and discrete signals and systems. Modulation concept and sampling theorem. Sampling in time and frequency domain. Discrete and fast Fourier transforms. Transformation of continuous time systems into discrete time systems. Representation of difference eqations. State space equations and their solution. z transformation and their properties. Analysis of discrete time systems in z domain. Introduction to filtering.
TEL 212 Introduction to Electromagnetic Fields

Elementary electromagnetic field theory as summarized in Maxwell.s equations for time varying fields in integral and differential form, energy storage and quasistatic fields, EM field and materials, vector calculus and potential functions, time domain analysis of waves, PC assisted instruction of field calculations.
ELE 341 Analog Electronic Circuits

Multistage amplifiers. Operational amplifier circuits and applications. Circuits derived from op amps. Analog multipliers. Frequency response of amplifiers. Feedback, stability problems in feedback circuits, compensation. Sinusoidal oscillators. Power amplifiers.
ELE 321(E) Introduction to Digital Systems

Representation of information, switching algebra, combinational network analysis and design, sequential network analysis and design, binary arithmetic and arithmetic-logic unit, computer organization and machine level programming, input output, control and design.
ELE 331(E) Microwaves

Current and voltage waves in transmission lines, frequency and time domain analysis, powewr and energy flow, impedance matching, Smith Chart, microstrip lines, pulse transmission on lines, basic principles of circuit analysis by S-parameters, basics of microwave radio propagation and introduction to antennas
Control Systems

Feedback concept, mathematical models, controllers, analysis of linear control systems, stability, Nyquist and Bode diagrams, root curves methods, synthesis in time and frequency domain, non-linear control system devices, linearization, phase plane, multi-input, multi- output, continuous and discrete control systems
ELE 311 Introduction to Electronics Laboratory

* 1. Supply voltage circuits
* 2. DC characteristics of BJTs and MOSFETs
* 3. Amplifiers
* 4. Linear applications of operational amplifiers
* 5. Lojic gates and flip-flops
* 6. Non-linear applications of operational amplifiers

ELE 322(E) Digital Electronic Circuits

Ideal inverter, various types of (NMOS, resistive-load, etc.) inverters, CMOS inverter, NAND, NOR gates, complex gates, transmission gates, various flip-flop circuits, read-only memories (ROM), static and dynamic random-access memories (SRAM and DRAM)
ELE 332 Network Synthesis

Network synthesis problem. Filter approximation: Butterworth and Chebyshev approximations, impedance and frequency normalization, Passive network synthesis: Positive real functions. Synthesis of LC, RC, RL, RLC networks: Cauer.s and Foster.s realizations. Synthesis of passive 2-ports, Positive real matrices, Synthesis of 2-ports converted to synthesis of 2-terminals. Ladder network synthesis: zero shifting technique. Active network synthesis: decomposition, coefficient matching and signal flow graph methods. Examples of active network synthesis using modern active devices (current conveyor, OTA, opamp)
ELE 352(E) Microprocessor Systems

Basic microprocessor architecture and operation principles, memory and addressing, memory design, data, address and control busses, interfaces, parallel and serial ports, timers, interrupt controllers, memory management units, programming in assembly language, microprocessor applications
ELE 342 Telecommunication Engineering Basics

Amplitude modulation techniques. Amplitude modulators and demodulators. Frequency and phase modulation. Frequency modulators and demodulators. Frequency division multiplexing. Pulse modulation techniques. Quantization, compressing-expanding, analog-digital converters, delta modulation. Baseband data transmission. Intersymbol interference, Nyquist channel, multilevel baseband transmission, error performance analysis. Digital modulation techniques. Amplitude-shift, phase-shift and frequency-shift keying.
ELE 312 Analog Electronic Circuits Laboratory

* 1. Low-frequency power amplifiers
* 2. Analog integrated circuits building blocks
* 3. Frequency and pulse response of BJT amplifiers
* 4. Feedback and stability in transistorized amplifiers
* 5. Broad-band amplifiers
* 6. Low-frequency oscillators
* 7. Active filters
* 8. PLL applications

ELE 412 Semiconductor Devices

Constituents of semiconductor crystal. Poisson, current and continuity equations. Energy band diagrams. Thermal equilibrium. Injection level. Trapping. BJT in equilibrium. BJT under bias. High-bias effects in BJT. BJT dynamics. MOSFET structure. MOSFET under bias. Strong inversion and subthreshold models. Structural optimization of MOSFET. Secondary effects and MOSFET dynamics.
ELE 413 Very Large Scale Integrated Circuit Design I

VLSI design techniques and foundations. ASIC design, gate-arrays, standard-cells. Full custom design approaches. Floorplanning in chip-level. Separation of the system building blocks. Standard cell placement & routing algorithms. Verification of design, logic simulation, timing simulation, transistor level simulation. Design techniques for regular building blocks: memory arrays, PLAs. Testable system design techniques. Reliability. Introduction of improving VLSI design techniques and tools.
ELE 414 Microelectronic Analog Circuit Design

Characteristics and behavioral models of op-amps. OTA, op-amp and operational current amplifier configurations, power stages, amplifier specifications, CMOS and BiCMOS design criteria, electrical and physical design. Miscellaneous microelectronic analog circuits: Comparators, analog multipliers, oscillators.
ELE 415 Analog Integrated Circuits

Basic building blocks: current and voltage sources, supply voltage and temperature independent biasing. Basic amplifier structures. Operational amplifiers: basic structures, basic performance parameters. Integrated oscillator structures. Analog multipliers. Analog MOS building blocks: Current sources, amplifier stages. MOS operational amplifiers, OTAs, current conveyors, analog multipliers, oscillators, D/A and A/D converters.
ELE 416 High Frequency Electronics

System noise and inter-modulation distortion, Serial and Parallel Resonant Circuits and impedance matching structures; Single and double tuned transformers, High frequency oscillators; crystal oscillators and VCOs. Tuned amplifiers; Tuned amplifiers using IC blocks, crystal, ceramic and SAW filter performances and the tuned amplifiers constructed with them.
ELE 417 RF Microelectronic Circuits

Introduction to RF and wireless technology. Modulation and detection. Multiple access techniques and wireless standards. Transceiver architecture. Low noise amplifiers and mixers. Oscillators. Power amplifiers.
ELE 418 RF Laboratory

* 1. s-parameters measurement setup
* 2. Noise figure measurement setup
* 3. 1 dB compression and IP3 intercept point measurement setup
* 4. Passive matching structures for low noise and power amplifiers
* 5. Linearization techniques for power amplifiers

ELE 419 Digital System Design

Adder circuits. The r's and (r-1)'s complement. Subtraction with r's and (r-1)'s complement. Realization of Boolean functions with multiplexers. ROM design with multiplexers. Design with Field Programmable Gate Arrays (FPGA). Register design. Algorithmic State Machine (ASM): ASM chart, control implementation, design with multiplexers and PLA's, some examples. State reduction in completely specified and incompletely specified sequential machines. State assignment in synchronous sequential circuits. Design of asynchronous circuits: Race-free state assignment. Asynchronous circuit design with Programmable Logic Controllers (PLC).
ELE 420 Artificial Neural Networks

As a motivation biological neural systems. Definition of Artificial Neural Networks (ANN) . Supervised and unsupervised learning. Adaptive linear element. Mean square learning rule. Design of linear associative memory. Multiple layered perceptron design. Back propagation algorithm. Radial based ANN. Dynamic ANN. Hopfield net, cellular ANN. Self organized map of Kohonen. Pattern, image, speech processing and control with hardware and software realization of ANN.
ELE 421 Introduction to Medical Electronics

The origin of the action potential, bioelectrical sources, and the main properties of bioelectrical signals. Origin and properties of other physiological parameters. Electroneurography, electrocardiography, electroencephalography, electromyography, electroretinography and evoked potentials. Other physiological measurements: blood pressure, blood volume, blood flow, heart sound, respiratory system measurements.
ELE 422 The Origin and Sensing Methods of Biological Signals

Introduction to human physiology: The cell and its function, origin of the action potential; bioreceptors; nervous, muscular, cardiovascular, respiratory, gastrointestinal, urinary and endocrin systems; the special sense organs; biological signals originated from human systems. Sensing and preprocessing of biological signals: Characteristics of biological signals, the basic amplifiers and basic circuits used for analog processing of biological signals, instrumentation amplifier; electrodes, features and applications; resistive, capacitive, inductive, piezoelectric, electromagnetic and termic transducers; transducer amplifiers and their calibration.
ELE 423 Modeling and Control of Biological Systems

Derivation of mathematical models of biological systems. Fundamental concepts; biological resistors and memories, models of neurons, signal analysis of biological systems and closed loop concept. Applications: The control loops of eye and sensing organs, the control of body temperature, the control of blood pressure, motion control loops
ELE 424 Ultrasound and Applications in Medicine

Basic features of ultrasound propagation: wave equation, characteristic impedance, diffraction, scattering, focusing, and Doppler effect, generation and detection of ultrasound, velocity and attenuation measurement techniques. Interaction of ultrasonic waves with tissue. Imaging methods: A and M mode imaging, static and dynamic (real time) imaging, three dimensional imaging, tissue characterization with ultrasound, biological effects of ultrasound, application of ultrasound in therapy
ELE 425 Very Large Scale Integrated Circuit Design II

Introducing of the CADENCE VLSI design environment. Examining the VLSI Design Flow. System level architectural design. Logic design and verification. Usage of VERILOG environment. Automatic synthesis of logic design. SYNOPSYS environment. Introduction of standard-cell libraries and their usage. Standard cell placement & routing. Full custom design strategies. Layout design in CADENCE - ARTIST design environment. Chip-level floorplanning and power distribution . VLSI test methods and design for testability.
ELE 426 Microelectronic Analog System Design

Types of analog filters and their frequency-response specifications. Active RC, Gm /C and SC filter configurations. Electrical and physical design of active filter circuits: Components, parasitics, on-chip tuning, noise and offset. Data converter design: DAC and ADC. Examples of integrated analog system design.
ELE 427 Microelectronics Technology

Brief history of the microelectronics technology. Planar technology. Micro-lithography. Thin films; Evaporation, sputtering and CVD techniques. Thermal oxidation of silicon. Doping techniques; diffusion, ion implantation and epitaxy. In process measurement and evaluation techniques. Process simulation; SUPREM. Process design; junction isolated bipolar IC and CMOS IC fabrication processes. Packaging. Yield analysis.
ELE 428 Industrial Electronics

Linear and nonlinear applications of operational amplifiers: Current sources, AC-DC converters, function generators, comparators, Schmitt trigger, oscillator applications. Analog building blocks: OTA applications, instrumentation amplifiers. PLL applications. Power Supplies: Design with linear regulator ICs, switched mode power supplies. Power MOSFET and its applications: Switching properties, safe-operation area, driver circuits, amplifiers, bridge operation. Sensors: temperature, moisture, pressure, displacement, light intensity sensors.
ELE 429 Communication Electronics Circuits

Communication System Blocks, Mixers; Diode, Active Mixers, balanced and unbalanced configurations and their applications, High Power RF Amplifiers; Class A, AB and B linear power amplifiers, high efficiency power amplifiers, design of Class D and E type amplifiers. Phase-Locked Loops (PLL) and their applications, Frequency synthesizers, Modulator and de- modulator circuits.
ELE 430 Radio-Television Systems

General receiver principles, superheterodyne receivers, selectivity, sensitivity, image frequency, receiver distortions, AM & FM broadcasting principles and systems, multiple carrier techniques and OFDM; PAL/SECAM/NTSC TV systems, PAL coding and decoding, picture artifacts, sampling and quantization of video signals, digital processing of video, video compression, MPEG, advanced TV systems, video recording, satellite and cable delivery of video signals.
ELE 431 Advanced Electronics Laboratory

IC building blocks: current and voltage sources, current and voltage references, amplifier stages, operational amplifier applications, operational transconductance amplifier (OTA) applications, current-conveyor applications, oscillator circuits, analog multiplier applications, IC characterization.
ELE 432 Microprocessor System Design

Software and hardware design of microprocessor-based systems and system components. Microprocessor peripherals; description and applications of parallel/serial communication interface units , integrated timer/counter circuits , memory elements , A/D and D/A converters, universal logic elements . Single-chip microcontrollers and multiprocessor digital systems. Realization of digital filters.
ELE 433 Digital Filters and Systems

Filtering by discrete (fast) Fourier transformation. Design aspects of digital filters and realization problem finite impulse filter design methods. Infinite impulse filter design, i) linear phase filters ii) windowing, iii) frequency sampling iv) optimal filter design methods. Infinite impulse response filter design : i) numerical integration methods ii) impulse invariance methods iii) bilateral z-transformation method. Filter design based on least-squares method. i) Pade method ii) FIR Wiener filter. System identification, inverse-filter design, prediction, signal processing applications using software realization State-space representation of discrete time systems. Observable, controllable, canonical representation. Controllability, observability, stability. Methods to design control systems. System design by state feedback (pole implementation) state observer design. Design of optimal control systems.
ELE 434 Nonlinear Circuits and Systems

Classification of algebraic and dynamic systems. State-space and input output representation of continuous and discrete time systems. State-space analysis stability of equilibrium points. Oscillators. Small signal analysis. Approximate analysis: Harmonic balance methods, numerical methods. Partitioning into linear dynamical and nonlinear algebraic subsystems. Input- output stability. Synthesis of nonlinear resistors and transfer functions. Design of algebraic systems as function approximation problem. Design of continuous and discrete-time dynamical systems: Synthesis of equilibrium points, design based on Lyapunov functions.
ELE 435 Engineering Systems Analysis

General look to engineering systems. Engineering systems other than electrical systems: mechanical, hydraulic, electro-mechanical and thermal systems. Application of disciplines developed for the analysis of the electrical circuits to these engineering systems. Existing ande the solutions of the system equations of these systems. Controbility and observability of the engineering systems. System components and modeling. Non-energical multiport components (transducer) and their advanced models
ELE 436 Digital System Design Laboratory

* 1. Characteristics of TTL and CMOS gates
* 2. Combinational circuit design
* 3. Flip-flops and triggering methods
* 4. Synchronous sequential circuit design
* 5. Using BUS in digital systems
* 6. Counters
* 7. Registers
* 8. Arithmetic operation units
* 9. Design of combinational logic circuits with programmable logic controller
* 10. Design of asynchronous sequential logic circuits with programmable logic controller

ELE 437 Biomedical Devices

Physiological effects of electricity and electrical safety. Microcomputers in medical instrumentation. Clinical measurement devices. Electrosurgical and physical therapy devices. Radiology and nuclear medicine devices. Computers in medicine. Computer axial tomography. Advanced topics in medical electronics.
ELE 438 Fundamentals of Medical Electronics Design

Design of high order active filters. Modeling and simulation of human cardiovascular system. The general principles in the design of microprocessor supported biomedical systems. The design of bioelectric signal processing systems: human reaction time measurement device, electrocardiography, arrhythmia detector, right leg driver, blood flow and heath rate measuring devices. Data compression techniques. Biotelemetry. Recording of biological signals to the magnetic recorders.
ELE 439 Therapeutic Medical Systems

Design of therapeutic medical equipment - basic concepts, definition and description of medical problems/conditions, physiology underlying the diseases/disabilities that can benefit from therapeutic devices and systems, applicable therapy techniques, design criteria for optimal benefit in a specific application, safety issues, effect of feedback control on system performance, open and closed loop feedback control, applicable transducers, exemplary applications in areas such as sensory problems (partial to total loss of vision, hearing, etc.), mobility problems, internal and external organ deficiencies, cardiovascular problems and cancer.
ELE 440 Computer Aided Devices in Medicine

Origins and properties of biological signals. Transducers for biological signals. Patient isolation methods. Fundamentals of computer units. Computer assisted biological signal acquisition, processing and monitoring. Archiving and transmitting of biological signals and images in and between medical centers. Computer aided telemetric system design. Microprocessor based blood pressure, body temperature, electrocardiogram, and electromyogram measurement devices.
ELE 441 Medical Electronics Laboratory

Some basic devices used for biological signal processing; electrocardiographic amplifier; transducers and electrodes; right leg driver; hydromechanical and electrical models of human cardiovascular system, digital processing of biological signals, adaptive and digital filters.
Sayfa Sorumlusu