Power semiconductor and switches and triggering devices: BJT, MOSFET, SCR, IGBT, GTO, TRISE, UJT and DIAC. Rectifiers: Uncontrolled and controlled single phase and three phase. Regulated power supplies: Linear- series and shunt, switching buck, buck-boost, boost and Cuk regulators. AC voltage controllers: single and three phase. Choppers. DC motor control. Single phase cyclo-converter. Inverters: Single and three-phase voltage and current sources. AC motor control. Stepper motor control. Resonance inverters. Pulse-width modulation control of static converters.
Course Catalogue
Course Code: EEE 434
Course Name:
Power Electronics Laboratory
Credit Hours:
1.00
Detailed Syllabus:
This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 433. In the second part, students will design simple systems using the principles learned in EEE 433.
Course Code: EEE 435
Course Name:
Semiconductor Physics
Credit Hours:
3.00
Detailed Syllabus:
Lattice vibration: Simple harmonic model, dispersion relation, acoustic and optical phonons, Band structure: Isotropic and anisotropic crystals, band diagrams and effective masses of different semiconductors and alloys. Scattering theory: Review of classical theory, Fermi-Golden rule, scattering rates of different processes, scattering mechanisms in different semiconductors, mobility. Different carrier transport models: Drift-diffusion theory, ambipolar transport, hydrodynamic model, Boltzman transport equations, quantum mechanical model, simple applications.
Course Code: EEE 441
Course Name:
Random Signals and Processes
Credit Hours:
3.00
Detailed Syllabus:
Probability and random variables. Distribution and density functions and conditional probability. Expectation: moments and characteristics functions. Transformation of a random variable. Vector random variables. Joint distribution and density. Independence. Sums of random variables. Random processes. Correlation functions. Process measurements. Gaussian and Poisson random processes. Noise models. Stationary and Ergodicity. Spectral Estimation. Correlation and power spectrum. Cross spectral densities. Response of linear systems to random inputs. Introduction to discrete time processes, Mean-square error estimation, Detection and linear filtering.
Course Code: EEE 443
Course Name:
Information and Coding Theory
Credit Hours:
3.00
Detailed Syllabus:
Entropy and Mutual Information: Entropy, joint entropy and conditional entropy, Relative entropy and mutual information, chain rules for entropy, relative entropy and mutual information, Jensen’s inequality and log-sum inequality. Differential Entropy: Differential entropy and discrete entropy, joint and conditional differential entropy, properties of differential entropy, relative entropy and mutual information. Entropy Rates of Stochastic Process: Markov Chain, Entropy rate and hidden Markov models. Source Coding: Kraft inequality, optimal codes, Huffman code and its optimality, Shannon-Fano-Elias coding, arithmetic coding. Channel Capacity: Binary symmetric channels and properties of channel capacity, channel coding theorems, joint source and channel coding theorem. Block coding and decoding, BCH, RS codes, Convolutional coding, Viterbi Decoder, Turbo codes, decoding techniques: STBC, SFBC, STFBC. Gaussian Channel: Introduction to Gaussian Channel, Band limited channel, Parallel Gaussian Channel, Gaussian Channel with feedback.
Course Code: EEE 445
Course Name:
Microwave Engineering
Credit Hours:
3.00
Detailed Syllabus:
Introduction to the general characteristics of wave propagation. Physical interpretation of Maxwell’s equations. Propagation of plane electromagnetic waves and energy. Reflection, diffraction, polarization, poynting vector. Transmission lines. Metallic and dielectrically guided waves including microwave waveguides. Antenna fundamentals. Microwaves generators. Microwave tubes: Klystron amplifiers, reflex Klystron oscillators, magnetrons, backward–wave oscillators. Microwave solid-state devices, varactor diodes, Gunn diodes, IMPATT diodes, P-I-n diodes, and their applications. Microwave components: Waveguides, directional coupler, isolators, waveguide couplers, circulators, slotted waveguide.
Course Code: EEE 446
Course Name:
Microwave Engineering Laboratory
Credit Hours:
1.00
Detailed Syllabus:
This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 445. In the second part, students will design simple systems using the principles learned in EEE 445.
Course Code: EEE 447
Course Name:
Digital Communication
Credit Hours:
3.00
Detailed Syllabus:
Introduction: Communication channels, mathematical model and characteristics. Review of probability and stochastic processes. Source coding: Mathematical models of information, entropy, Huffman and linear predictive coding. Digital transmission system: Baseband digital transmission, inter-symbol interference, bandwidth, power efficiency, modulation and coding trade-off. Receiver for AWGN channels: Correlation demodulator, matched filter demodulator and maximum likelihood receiver. Channel capacity and coding: Channel models and capacities and random selection of codes, convolution codes and coded modulation. Spread spectrum signals and systems.
Course Code: EEE 448
Course Name:
Digital Communication Laboratory
Credit Hours:
1.00
Detailed Syllabus:
This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 447. In the second part, students will design simple systems using the principles learned in EEE 447.
Course Code: EEE 449
Course Name:
Optical Fiber Communication
Credit Hours:
3.00
Detailed Syllabus:
Introduction: Introduction to optical fiber communication systems. Elements of optical fiber communication links, advantages over microwave systems. Propagation of light over optical fibers: Transmission characteristics of optical fibers, optical fiber construction, mechanisms of attenuation and dispersion. Optical cables, optical connector, splice and couplers. Optical sources: Light emitting diodes and laser diodes, and their characteristics. Intensity modulation, direct detection, coherent systems.
Optical transmitters and amplifiers. Optical detectors and receivers: PIN photodiodes and avalanche photodiodes, their characteristics. Optical waveguides and optical soliton. Optical link design: Limitations in bandwidth and distance due to attenuation and dispersion. Link budget calculations. Applications: Selection of components for different applications. State-of-the-art applications of optical fiber communications. Analog and digital communication systems. Low BW and bitrate to ultra-wide band and ultra-high bitrate communication systems. Introduction to communication networks (LANs, MANs and WANs).