University General Course Catalog 2022-2023

Jul 02, 2024

University General Course Catalog 2022-2023 ARCHIVED CATALOG: LINKS AND CONTENT ARE OUT OF DATE. CHECK WITH YOUR ADVISOR.

8. Course Descriptions

Note: Sequencing rules in effect for many Math courses prohibit students from earning credit for a lower numbered Math course after receiving credit for a higher numbered Math course. Sequencing rules are included in the course descriptions of applicable courses.

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Electrical Engineering
	EE 723 - Solid State Devices I (3 units) Development of the theory of solid-state devices, with particular emphasis on controlling material parameters so as to produce desired terminal characteristics. Study of the current literature is required. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 733A - Machine Intelligence (3 units) Intelligent systems Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 733B - Machine Intelligence (3 units) Neural computing. (CS 773B and EE 733B are cross-listed; credit may be earned in one of the two.) Prerequisite(s): CPE 301 . Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 733C - Machine Intelligence (3 units) Advanced applications. Self-organizing, self-adapting systems; cybernetics; neural networks; automated decision making and control; learning automata; expert systems application; knowledge and data engineering; pattern recognition, image processing. Prerequisite(s): CPE 301 . Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 741 - Optical Fiber Communications (3 units) Review of optical fibers, optical receivers, detectors, amplifiers, sources, transmission links, noise considerations, optical fiber communication systems, coherent communication, applications and future developments. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 742 - Optical Fiber Sensors and Applications (3 units) Basic concept; integrated optics for sensors; interferometric-, intensity- and wavelength-based sensors; optical actuators; sensor multiplexing principles; distributed optical fiber sensors; various applications. Prerequisite(s): EE 410 ; EE 410L . Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 743 - Optical Fiber Networking (3 units) Fiber transport system and components; switching techniques; system architecture; ISDN, WAN, MAN, LAN topology; SONET technology; network survivability; residential fiber networks. Grading Basis: Graded Units of Laboratory/Studio: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 751 - Antenna Theory and Design (3 units) Antenna fundamentals; theory, design of dipole, loop, wire, broadband, aperture, microstrip antennas; arrays, method of moments, antenna synthesis; CAD analysis, measurements performed in anechoic chamber. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 752 - Advanced Electromagnetic Field Analysis (1 unit) Electromagnetic wave propagation in nonhomogeneous media, dielectric wave guides, propagation in anisotropic materials, mode coupling in multimode dielectric wave guides, radiation from microstrip patches on ferrite substrates. Grading Basis: Graded Units of Lecture: 1 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 754 - Microwave Semiconductor Devices (3 units) Microwave diodes, junction transistors, field effect transistors, transferred electron devices and avalanche transit-time devices. Device and circuit design are considered with special emphasis on amplifier design. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 756 - Microwave Integrated Circuits (Mics) (3 units) Development of MlCs, analysis of microstrip lines, coupled microstrip lines, microstrip, discontinuities, slot lines and coplanar lines, MIC fabrication and design of microstrip components. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 757 - Microwave Comm Sys (3 units) Basics of microwave communication systems, microwave transmitters, receivers, modulation and amplification, system noise consideration, microwave links and terrestrial communications, cellular radios, satellite systems, DBS. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 761 - Electric Transportation Technology (3 units) This course introduces engineering graduate students to transportation electrification by exposing them to an entire range of topics related to the analysis, design, control, and simulation of electric, hybrid, and plug-in hybrid powertrains. Maximum units a student may earn: 3 Prerequisite(s): Graduate Standing. Grading Basis: Graded Units of Lecture: 3 Offered: Every Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. demonstrate an understanding of research methodology. 3. articulate awareness of the need for, and future of, alternative fuel vehicles and will be able to address future needs in the automotive industry. 4. demonstrate fundamental knowledge of electric propulsion used in electric drive vehicles and understand the basic operating principals of HEVs and their subcomponents, especially their impact on the energy conversion process. Click here for course scheduling information. \| Check course textbook information
	EE 763 - Electric Drive Systems (3 units) Design and control of adjustable speed and positioning electric drive systems with DC and AC motors. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 764 - Power Electronics for Renewable Energy Systems (3 units) Power electronic converters, impact of renewable energy generation on power electronic systems operation, design and control of power electronics, power management and conversion. Grading Basis: Graded Units of Lecture: 3 Offered: Every Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 766 - Computer Solutions and Power System State Estimation (3 units) Power system state estimation will be introduced as one of the important EMS (Energy Management System) functions for healthy monitoring and operation of a power system. Traditional WLS based power system state estimation will be covered along with different formulations. Observability, bad data detection, identification and elimination techniques will be introduced as parts of power system static state estimation. Grading Basis: Graded Units of Lecture: 3 Offered: Every Spring - Odd Years Student Learning Outcomes Upon completion of this course, students will be able to: 1. an ability to apply engineering research and theory to advance the art, science, and practice of the discipline. 2. an ability to design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. demonstrate an understanding of power systems steady-state operation. Click here for course scheduling information. \| Check course textbook information
	EE 767 - Power System Planning (3 units) Power system planning will be introduced as one of the important long-term study tools in power grids for a reliable and efficient power system design and operation. This course will cover load forecasting, reliability analysis, and planning methods of power systems. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. an ability to apply engineering research and theory to advance the art, science, and practice of the discipline. 2. an ability to design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. demonstrate an understanding of long term power system planning studies. Click here for course scheduling information. \| Check course textbook information
	EE 768 - Power System Stability and Control (3 units) This course covers power system small-signal stability, transient stability (time-domain simulations and direct methods), and voltage stability; subsynchronous oscillations; frequency control and stability; power system stability in presence of renewable energy sources; methods to enhance power system stability. Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall - Odd Years Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data, 3. determine and analyze power dynamics under different failure and fault scenarios. Click here for course scheduling information. \| Check course textbook information
	EE 769 - Power System Reliability and Resilience (3 units) Introduction to probability and stochastic processes; system modeling for reliability and resilience; modeling of extreme events and cyber attacks. Reliability and resilience modeling and analysis of bulk power systems, distribution systems, and industrial systems. Component modeling: generator modeling, transmission line modeling, and modeling of protection and cyber layers. Reliability of multi-area and composite system analysis. Application of game theory in enhancing power system resilience. Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. simulate and analyze power system response due to extreme events and cyber attacks and calculate reliability and resilience metrics. Click here for course scheduling information. \| Check course textbook information
	EE 776 - Nonlinear Control Systems (3 units) Nonlinear state equations, phase plane analysis, describing function, Liapunov stability, circle criterion, introduction to nonlinear control systems design. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 778 - Optimal Control (3 units) Parameter optimization, optimal control of continuous and discrete systems, introduction to numerical methods. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 782 - Random Signal Analysis and Estimation Theory (3 units) Random variables and random signals, auto-correlation and cross-correlation functions, power spectral density functions, response of linear system, least squares and maximum likelihood estimation, BLUE, linear and nonlinear Kalman filtering. Prerequisite(s): EE 362 ; STAT 352 . Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 783 - Advanced Signal Processing (3 units) Parametric, adaptive, and model-based signal processing. Detection/estimation of signals in noise. Multidimensional discrete systems. Adaptive array processing. Introduction to intelligent signal processing systems. Grading Basis: Graded Units of Lecture: 3 Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 786 - Deep Learning (3 units) The course is designed to provide a basic understanding of deep learning and applications. The course is self-contained, project-oriented, and designed to prepare students for research in the emerging application of deep learning. Case studies will include applications in Engineering and Medicine. (BME 786 and EE 786 are crosslisted; credit may be earned in one of the two.) Recommended Preparation: EE 291 . Grading Basis: Graded Units of Lecture: 3 Offered: Every Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 2. demonstrate an understanding of research methodology. 3. develop the emerging applications of deep learning in Engineering and Medicine. Click here for course scheduling information. \| Check course textbook information
	EE 790A - Seminar (1 to 3 units) Acoustics Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790B - Seminar (1 to 3 units) Biomedical electronics Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790C - Seminar (1 to 3 units) Communications and networks Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790D - Seminar (1 to 3 units) Computer engineering Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790E - Seminar (1 to 3 units) Control systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790F - Seminar (1 to 3 units) Electronics Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790G - Seminar (1 to 3 units) Image processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790H - Seminar (1 to 3 units) Machine intelligence Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790J - Seminar (1 to 3 units) Microwave Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790K - Seminar (1 to 3 units) Modeling and Simulation Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790M - Seminar (1 to 3 units) Parallel Distributed Processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790N - Seminar (1 to 3 units) Power Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790P - Seminar (1 to 3 units) Signal Processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790Q - Seminar (1 to 3 units) Stochastic Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790R - Seminar- Systems Science (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790S - Seminar: Optical Fibers (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 790T - Seminar: Power Electronics (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791B - Special Topics (1 to 3 units) Biomedical electronics Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791C - Special Topics (1 to 3 units) Communications and networks Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791D - Special Topics (1 to 3 units) Computer engineering Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791E - Special Topics (1 to 3 units) Control systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791F - Special Topics (1 to 3 units) Electronics Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791G - Special Topics (1 to 3 units) Image processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791H - Special Topics (1 to 3 units) Machine intelligence Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791J - Special Topics (1 to 3 units) Microwave Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791K - Special Topics (1 to 3 units) Modeling and Simulation Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791N - Special Topics (1 to 3 units) Power Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791P - Special Topics (1 to 3 units) Signal Processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791Q - Special Topics (1 to 3 units) Stochastic Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791R - Special Topics (1 to 3 units) Systems Science Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791S - Special Topics Optical Fibers (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791T - Special Topics Power Electronics (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 791U - Special Topics: Engineering Education (1 to 3 units) This course will focus on the development of core engineering education research skills in methods and theory. Maximum units a student may earn: 3 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. Click here for course scheduling information. \| Check course textbook information
	EE 792A - Special Problems (1 to 2 units) Acoustics Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792B - Special Problems (1 to 2 units) Biomedical electronics Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792C - Special Problems (1 to 2 units) Communications and networks Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792D - Special Problems (1 to 2 units) Computer engineering Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792E - Special Problems (1 to 2 units) Control systems Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792F - Special Problems (1 to 2 units) Electronics Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792G - Special Problems (1 to 2 units) Image processing Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792H - Special Problems (1 to 2 units) Machine intelligence Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792J - Special Problems (1 to 2 units) Microwave Systems Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792K - Special Problems (1 to 2 units) Modeling and Simulation Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792N - Special Problems (1 to 2 units) Power Systems Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792P - Special Problems (1 to 2 units) Signal Processing Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792Q - Special Problems (1 to 2 units) Stochastic Systems Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792R - Special Problems (1 to 2 units) Systems Science Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792S - Special Problems Optical Fibers (1 to 2 units) Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 792T - Special Problems Power Electronics (1 to 2 units) Maximum units a student may earn: 2 Grading Basis: Graded Units of Lecture: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793A - Independent Study (1 to 3 units) Acoustics Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793B - Independent Study (1 to 3 units) Biomedical electronics Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793C - Independent Study (1 to 3 units) Communications and networks Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793D - Independent Study (1 to 3 units) Computer engineering Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793E - Independent Study (1 to 3 units) Control systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793F - Independent Study (1 to 3 units) Electronics Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793G - Independent Study (1 to 3 units) Image processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793H - Independent Study (1 to 3 units) Machine intelligence Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793J - Independent Study (1 to 3 units) Microwave Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793K - Independent Study (1 to 3 units) Modeling and Simulation Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793M - Independent Study (1 to 3 units) Parallel Distributing Processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793N - Independent Study (1 to 3 units) Power Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793P - Independent Study (1 to 3 units) Signal Processing Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793Q - Independent Study (1 to 3 units) Stochastic Systems Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793R - Independent Study- Systems Science (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793S - Indep Study-Optical Fibers (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 793T - Indep Study-Power Electronics (1 to 3 units) Maximum units a student may earn: 3 Grading Basis: Graded Units of Independent Study: X Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 795 - Comprehensive Examination (1 to 3 units) Course is used by graduate programs to administer comprehensive examinations either as an end of program comprehensive examination or as a qualifying examination for doctoral candidates prior to being advanced to candidacy. Maximum units a student may earn: 3 Grading Basis: Satisfactory/Unsatisfactory Units of Independent Study: X Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 796 - Professional Paper (3 units) Professional paper. Maximum units a student may earn: 3 Grading Basis: Satisfactory/Unsatisfactory Units of Independent Study: 3 Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 797 - Thesis (1 to 6 units) Grading Basis: Graded Units of Independent Study: X Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 799 - Dissertation (1 to 24 units) Grading Basis: Graded Units of Independent Study: X Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
	EE 899 - Graduate Advisement (1 to 4 units) Provides access to faculty for continued consultation and advisement. No grade is filed and credits may not be applied to any degree requirements. Limited to 8 credits (2 semester) enrollment. For non-thesis master’s degree students only. Maximum units a student may earn: 8 Grading Basis: Satisfactory/Unsatisfactory Units of Independent Study: X Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. apply engineering research and theory to advance the art, science, and practice of the discipline. 2. design and conduct experiments as well as to analyze, interpret, apply, and disseminate the data. 3. understand research methodology. Click here for course scheduling information. \| Check course textbook information
Elementary Education
	EDEL 433 - Methods for Teaching PK-8 Mathematics (3 units) Mathematical and psychological bases for scope, sequence and appropriate instructional strategies in pre-K, elementary and middle school mathematics. Prerequisite(s): Admission to teacher education; completion of all general education requirements. Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. examine the Common Core Standards, research on mathematics teaching and learning, and to develop math teaching skills to support students’ learning. 2. teach mathematics efficiently and effectively by using the Common Core Standards of Mathematical Practices as a natural part of their teaching. Click here for course scheduling information. \| Check course textbook information
	EDEL 443 - Methods for Teaching PK-8 Science (3 units) Methods and pedagogy that offer effective techniques, management, and content in teaching science to children grades PK-8. Prerequisite(s): Content science courses listed in Elementary Education Major and acceptance in major. Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. demonstrate understanding of Inquiry-based instruction as demonstrated by writing a 5E lesson plan. Click here for course scheduling information. \| Check course textbook information
	EDEL 453 - Methods for Teaching PK-8 Social Studies (3 units) Teaching content and processes for social studies in PK-8 classrooms. Development of instructional materials and strategies. Prerequisite(s): Admission to teacher education; CH 201 or CH 202 ; CH 203 ; and GEOG 106 . Recommended preparation: EPY 330. Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. demonstrate a strong foundation of theory, teaching methods, and technology in the areas of the Social Studies C3 Framework, History, Geography, and cultural and multi-cultural education. Students will demonstrate their knowledge through the composition and presentation of a unit of study. Click here for course scheduling information. \| Check course textbook information
	EDEL 483 - Elementary Supervised Teaching Internship (1 to 12 units) CO14 Maximum units a student may earn: 12 Grading Basis: Satisfactory/Unsatisfactory Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. render and appropriately challenging lesson and class plan. 2. actively participate in, and from time to time, lead, student assessments designed to target that student’s classroom performance. 3. engage with students in the classroom such that a climate of learning is established, promoted and expanded. 4. model how to behave in a classroom such that everyone is valued and respected. 5. use instructional technology to support the teaching and learning process. 6. manage a classroom, its students, and the many and myriad events that may occur throughout the school day. 7. show an evolving strategy of maintaining accurate and useful student records. Click here for course scheduling information. \| Check course textbook information
	EDEL 633 - Methods for Teaching PK-8 Mathematics (3 units) Mathematical and psychological bases for scope, sequence and appropriate instructional strategies in pre-K, elementary and middle school mathematics. Grading Basis: Graded Units of Lecture: 3 Offered: Every Fall and Spring Student Learning Outcomes Upon completion of this course, students will be able to: 1. examine the Common Core Standards, research on mathematics teaching and learning, and to develop math teaching skills to support students’ learning. 2. teach mathematics efficiently and effectively by using the Common Core Standards of Mathematical Practices as a natural part of their teaching. 3. examine the Common Core Standards, research on mathematics teaching and learning, and to develop math teaching skills to support students’ learning. 4. teach mathematics efficiently and effectively by using the Common Core Standards of Mathematical Practices as a natural part of their teaching. Click here for course scheduling information. \| Check course textbook information

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8. Course Descriptions

EE 723 - Solid State Devices I

EE 733A - Machine Intelligence

EE 733B - Machine Intelligence

EE 733C - Machine Intelligence

EE 741 - Optical Fiber Communications

EE 742 - Optical Fiber Sensors and Applications

EE 743 - Optical Fiber Networking

EE 751 - Antenna Theory and Design

EE 752 - Advanced Electromagnetic Field Analysis

EE 754 - Microwave Semiconductor Devices

EE 756 - Microwave Integrated Circuits (Mics)

EE 757 - Microwave Comm Sys

EE 761 - Electric Transportation Technology

EE 763 - Electric Drive Systems

EE 764 - Power Electronics for Renewable Energy Systems

EE 766 - Computer Solutions and Power System State Estimation

EE 767 - Power System Planning

EE 768 - Power System Stability and Control

EE 769 - Power System Reliability and Resilience

EE 776 - Nonlinear Control Systems

EE 778 - Optimal Control

EE 782 - Random Signal Analysis and Estimation Theory

EE 783 - Advanced Signal Processing

EE 786 - Deep Learning

EE 790A - Seminar

EE 790B - Seminar

EE 790C - Seminar

EE 790D - Seminar

EE 790E - Seminar

EE 790F - Seminar

EE 790G - Seminar

EE 790H - Seminar

EE 790J - Seminar

EE 790K - Seminar

EE 790M - Seminar

EE 790N - Seminar

EE 790P - Seminar

EE 790Q - Seminar

EE 790R - Seminar- Systems Science

EE 790S - Seminar: Optical Fibers

EE 790T - Seminar: Power Electronics

EE 791B - Special Topics

EE 791C - Special Topics

EE 791D - Special Topics

EE 791E - Special Topics

EE 791F - Special Topics

EE 791G - Special Topics

EE 791H - Special Topics

EE 791J - Special Topics

EE 791K - Special Topics

EE 791N - Special Topics

EE 791P - Special Topics

EE 791Q - Special Topics

EE 791R - Special Topics

EE 791S - Special Topics Optical Fibers

EE 791T - Special Topics Power Electronics

EE 791U - Special Topics: Engineering Education

EE 792A - Special Problems

EE 792B - Special Problems

EE 792C - Special Problems

EE 792D - Special Problems

EE 792E - Special Problems

EE 792F - Special Problems

EE 792G - Special Problems

EE 792H - Special Problems

EE 792J - Special Problems

EE 792K - Special Problems

EE 792N - Special Problems

EE 792P - Special Problems

EE 792Q - Special Problems

EE 792R - Special Problems

EE 792S - Special Problems Optical Fibers

EE 792T - Special Problems Power Electronics

EE 793A - Independent Study

EE 793B - Independent Study

EE 793C - Independent Study

EE 793D - Independent Study

EE 793E - Independent Study

EE 793F - Independent Study