can anybody help me to find syllabus for masters in electrical engineering?

Answer 1

EE 413: Introduction to Digital Control
Syllabus Current Class
3 hr Lecture; Prerequisites:


Sampling of continuous-time signals and transform analysis. State-variable analysis for linear discrete-time systems and design of digital control.


EE 459: Transistor Circuits
Syllabus Current Class
3 hr. Lecture; Prerequisite: EE 355, EE 356 or equiv.


Analysis and design of subcircuits used in analog integrated circuit modules. Transistor models, low-frequency response of multistage amplifiers, current sources, output stages and active loads. 3 hr. lec.


EE 465: Introduction to Digital Image Processing
Syllabus Current Class
3 hr. Lecture; Prerequisites :


Introduction to the vision process and fundamental mathematical characterization of digitized images, 2-dimensional transform methods used in image processing. Histogram analysis and manipulation, image filtering techniques, image segmentation and morphology.


EE 487: Electric Vehicle Design II
Syllabus Current Class
2 hr. Lecture; Prerequisites EE 221


Introduction to all electric and hybrid electric vehicles. Review for safety considerations, energy storage, motor and instrumentation technologies. Simulations software for energy requirements, efficiency and capabilities of EV?s is required. Participation is expected in the design, construction, and testing of an EV.


EE 511: Applied Nonlinear Control II
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 411 or consent


Study of major analytical tools that are being used to analyze and control nonlinear systems such as phase plane analysis, Lyapunov theory, describing function analysis, feedback linearization, and sliding control.


EE 513: Stochastic Systems Theory
Syllabus Current Class
3 hr. Lecture; Prerequisites: Consent


Probability distribution and density functions. Bayes rule and conditional probability. Stochastic process and linear systems. Gauss-Markov Process. Optimal linear estimation. Introduction to Wiener and Kalman filtering. Decision theory fundamentals.


EE 515: Linear Control Systems
Syllabus Current Class
3 hr. Recitation; Prerequisites: Consent


Basic concepts in the theory of linear control systems; state variable representation, solution of state equations, controllability, observability, stability, transfer function descriptions, design of controllers and observers.


EE 517: Optimal Control
Syllabus Current Class
3 hr., Prerequisites: Consent


Methods of direct synthesis and optimization of feedback systems; Wiener theory; Pontryagin's maximum principle, dynamic programming; adaptive feedback systems.


EE 519: Digital Control
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 411 or equivalent or consent


Sampling of continuous-time signals; transform analysis; analysis of discrete-time systems. Translation of analog design. Controllability and observability; State-space design methods; and introduction to optimal control for discrete systems.


EE 531: Advanced Electrical Machinery
Syllabus Current Class
3 hr. Lecture; Prerequisites: consent


Theory and modeling of synchronous, induction, and direct-current machines, and their steady-state and transient analysis.


EE 533: Comp Appl Power System Analysis
Syllabus Current Class
3 hr. Recitation; Prerequisites: EE 436 or consent


Steady state analysis by digital computers of large integrated electrical power systems. Bus admittance and Impedance matrices, load flow studies, economic dispatch and optimal power flow, steady state security analysis, fault studies.


EE 535: Power System Control and Stability II
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 515


Review of stability theory, classical transient analysis, dynamical models of synchronous machines, power system stability under small and large perturbations, dynamic simulation of power systems.


EE 537: Advanced Power Electronics / Drives II
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 435 or consent.


Study of solid-state power semiconductor devices with emphasis on their applications in power conditioned electric motor drive systems. Examination of control philosophies, steady-state models, and numerical simulation. Current topics of interest from the literature.


EE 551: Linear Integrated Circuits
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 355, EE 356, or equivalent.


Techniques of integrated circuit design and fabrication. Development of models descriptive of linear and nonlinear transistor operation. Design and analysis of high-frequency tuned, direct-current, and differential amplifiers. (Intended for students specializing in communication and electronics)


EE 553: Integrated Logic Circuits
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 251, EE 252 or equivalent. of consent


Techniques of integrated circuit design and fabrication. Development of transistor model for nonlinear operation. Design, analysis, and comparison of emitter-coupled, direct-coupled, diode-transistor, and transistor-transistor integrated logic circuits. (Intended for students specializing in digital circuits.)

EE 561: Communication Theory
Syllabus Current Class
3 hr. Lecture; Prerequisites: EE 461 or consent

Detailed study of probability theory and its use in describing random variables and stochastic processes. Emphasis on applications to problems in communication system design.


EE 687: Materials Engineering
Syllabus Current Class
3 Hr.


A study of materials engineering fundamentals emphasizing semiconductor, polymer, metal, and ceramic/cementitious material systems. Mechanical and physical properties, theoretical aspects, testing, design criteria, manufacturing, and economics of material systems. Laboratory testing and evaluation. (Equivalent to CHE 387, CE 387, EM 387, IMSE 387, and MAE 387)


EE 691: Advanced Topics I, II, S
Syllabus Current Class
1 - 6 hr.; Prerequisites: consent


Investigation of advanced topics not covered in regularly scheduled courses.


EE 695: Advanced Independent Study
Syllabus Current Class
1 - 6 hr.; Prerequisites: consent


Individual investigation in advanced subjects not covered in formal courses.


EE 697: Master's Degree Research or Thesis I, II, S
Syllabus Current Class
1 - 15 hr.; Prerequisites: consent


Research activities leading to a thesis, problem report, research paper, or equivalent scholarly project


EE 711: Nonlinear Control System Analysis
Syllabus Current Class
3 hr.; Prerequisites: consent


Application of Liapunov's and Popov's methods to nonlinear control systems, together with classical techniques.


EE 713: Large-Scale System Modeling and Control
Syllabus Current Class
3 hr.; Prerequisites: EE 515


Characterization of large-scale systems, model simplification through aggregation and perturbation methods, optimal and chained aggregation, balanced realization and cost component procedures; optimal model reduction; simplification effects; decentralized control; feasibility and design.


EE 715: Stochastic Estimation and Control
Syllabus Current Class
3 hr.; Prerequisites: EE 517 or consent


Techniques of optimal estimation and control for linear systems. Balanced emphasis is placed on both continuous and discrete time systems. Some advanced topics of interest will be considered.


EE 731: Real-Time Control of Power Systems
Syllabus Current Class
3 hr.; Prerequisites: EE 515, EE 517, and EE 533


Application of computers to modern control theory for reliable and economic real-time operation of integrated power systems.


EE 733: Protection of Power System
Syllabus Current Class
3 hr.; Prerequisites: EE 436 or consent


Principles of relay protection of faults on transmission lines and other devices. Use of overcurrent, differential distance, and pilot relaying systems. Special relay applications. Determination of short-circuit currents and voltages from system studies.


EE 735: HVDC Transmission
Syllabus Current Class
3 hr. Lecture. Prerequisites: EE 435, EE 533, or consent


Line-commutated converter analysis, operation of two-terminal and multiterminal DC systems, harmonics and filters, modeling of AC/DC system and design of modulation controllers

Answer 2

You might want to specific a school.
Or just goto the web page ...

Answer 3

check the university library. I'll think about it.

Answer 4

nope sry