# Courses

## Mechanical Engineeringâ€”Engineering Mechanics

#### MEEM 4200 - Principles of Energy Conversion

Introduces basic background, terminology, and fundamentals of energy conversion. Discusses current and emerging technologies for production of thermal, mechanical, and electrical energy. Topics include fossil and nuclear fuels, thermodynamic power cycles, solar energy, wind energy, and energy storage. No credit for both MEEM4200 and MEEM5290.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall

**Restrictions: **
May not be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** MEEM 3230(C) or CM 3230 or ENG 3200 or MY 3100

#### MEEM 4220 - Internal Combustion Engines I

Teaches the operation and design of various types of internal combustion engines through the application of applied thermodynamics, cycle analysis, combustion, mixtures of gases, fluid dynamics, and heat transfer.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Spring

**Restrictions: **
May not be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** MEEM 3210

#### MEEM 4260 - Fuel Cell Technology

In this course, after fuel cell technology basics and operating principles, fuel cell performance will be briefly described from energy and thermodynamic viewpoints. Major types of fuel cells will be discussed: Polymer Electrolyte Membrane Fuel Cell (PEMFC), Direct Methanol Fuel Cells (DMFC), Alkaline Fuel Cells (AFC), Phosphoric Acid Fuel Cell (PAFC), Molten Carbonate Fuel Cell (MCFC) and Solid Oxide Fuel Cell (SOFC). The balance of the fuel cell power plant, thermal system design and analysis will be discussed that affect the power generation. Finally, the components needed, issues related, and pertinent analysis will be covered to delivering electric power generated from the fuel cell.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering;
Must be enrolled in one of the following Class(es): Senior

**Pre-Requisite(s):** MEEM 3230 or CM 3110

#### MEEM 4295 - Introduction to Propulsion Systems for Hybrid Electric Vehicles

Hybrid electric vehicle analysis will be developed and applied to examine the operation, integration, and design of powertrain components. Model based simulation and design is applied to determine vehicle performance measures in comparison to vehicle technical specifications. Power flows, losses, energy usage, and drive quality are examined over drive-cycles via application of these tools.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall, Summer

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering;
May not be enrolled in one of the following Class(es): Freshman, Sophomore

**Pre-Requisite(s):** MEEM 2200 or ENG 3200

#### MEEM 4296 - Experimental Studies in Hybrid Electric Vehicles

Hybrid electric vehicles and their powertrain components will be examined from the aspects of safety, testing and analysis, energy conversion, losses, and energy storage, and vehicle technical specifications and vehicle development process. The lab will culminate with vehicle testing to perform power flow and energy analysis during a drive-cycle.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-2-2)

**Semesters Offered:** Fall, Summer

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering;
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

#### MEEM 4450 - Vehicle Dynamics

This course will develop the models and techniques needed to predict the performance of a road vehicle during drive off, braking, ride, and steering maneuvers. Topics to be covered include: acceleration and braking performance, drive train performance including an introduction to hybrid electric power train architecture, vehicle handling, suspension modeling, tire models, and steering control. Matlab will be used as a computational tool for implementation of the models.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** (MEEM 3502 and MEEM 3000) or (EE 3305 and MEEM 2700)

#### MEEM 4700 - Dynamic Systems and Controls

Analysis of dynamic systems, use of Laplace transforms to solve differential equations, design of control systems using classic and modern approaches, comparison of control methodologies, application and comparison of time-and-frequency domain specifications to design, basic system identification, digital implementation issues. Emphasizes practical design and application issues.
**Credits:**
4.0

**Lec-Rec-Lab:** (0-3-2)

**Semesters Offered:** Fall, Spring

**Pre-Requisite(s):** MEEM 3700

#### MEEM 4750 - Distributed Embedded Control Systems

This course will develop an understanding for the design and application of embedded control systems. Topics to be covered include: embedded system architecture, model-based embedded system design, real-time control, communication protocols, signal processing, and human machine interface. Embedded applications in advanced hybrid electric vehicles will also be introduced.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-2-2)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** MEEM 4700 or EE 4261 or EE 3261

#### MEEM 5200 - Advanced Thermodynamics

A study of the principles of thermodynamics, including fundamental concepts and introduction of the analytical treatments of the first, second and combined first and second laws of thermodynamics. Topics include irreversibility, availability (exergy), thermodynamic relations, mixtures, chemical reactions, and chemical equilibrium.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall, Summer

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

#### MEEM 5220 - Fuel Cell Technology

Fuel cell technology basics, operating principles and performance will be discussed from energy and thermodynamic viewpoints. Major types will be described and emphasis will be on construction features, performance behavior and analysis. The balance of fuel cell power plant and thermal system design and analysis that affect power generation; as well as hydrogen infrastructure and issues related to delivering electrical power generated from the fuel cell will be covered.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

#### MEEM 5240 - Comp Fluid Dynamics for Engg

Introduces finite-difference and finite-volume methods used in solving fluid dynamics and heat transfer problems. Covers numerical grid generation, turbulence modeling, and application to some selected problems.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Spring - Offered alternate years beginning with the 2001-2002 academic year

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** MEEM 5210

#### MEEM 5250 - Internal Combustion Engines II

Advanced topics in internal combustion engines with emphasis on CI operation, modeling of engines, modeling of combustion processes, tribology, second law applications, and other topics of current interest.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall - Offered alternate years beginning with the 2001-2002 academic year

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following Major(s): Mechanical Engineering, Mechanical Eng-Eng Mechanics, Engineering Mechanics

**Pre-Requisite(s):** MEEM 4220 and MEEM 5200(C)

#### MEEM 5255 - Advanced Powertrain Instrumentation and Experimental Methods

Students will be exposed to unique instrumentation used in modern powertrain research and development. Through hands-on experimentation students will learn techniques for installation, usage, and calibration. Students will also be exposed to data quality checks and techniques to mitigate experimental variation.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-2-2)

**Semesters Offered:** Spring

**Restrictions: **
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

**Pre-Requisite(s):** MEEM 4220(C)

#### MEEM 5295 - Advanced Propulsion Systems for Hybrid Electric Vehicles

Hybrid electric vehicles (HEV) will be studied and simulated using advanced powertrain component analysis and modeling. An in-depth analysis and study of power flows, losses and energy usage are examined for isolated powertrain components and HEV configurations. Simulation tools will be developed and applied to specify powertrain and vehicle components and to develop control and calibration for a constrained optimization to vehicle technical specifications.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** MEEM 4295 or EE 4295

#### MEEM 5296 - Adv Prop Sys for HEV Lab

Hybrid electric vehicles (HEV) and their components will be examined in a series of laboratories. This includes quantification of power flows and losses in components, calibration of component models based upon experimental data, measurement and quantification of drive quality, failure Mode & Effects Analysis, calibration practices and trade-offs. A HEV model will be tuned and validated through analysis and fitting to vehicle test data.
**Credits:**
2.0

**Lec-Rec-Lab:** (0-1-2)

**Semesters Offered:** Spring, Summer

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** MEEM 4296 or EE 4296

#### MEEM 5450 - Vehicle Dynamics

This course will introduce the models and techniques needed to predict the performance of a road vehicle during drive off, braking, ride, and steering manuevers. Topics to be covered include: acceleration and braking performance, drive train performance including an introduction to hybrid electric power train architecture, vehicle handling, suspension modeling, tire models, and steering control. Matlab will be used as a computational tool for implementation of the models.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

#### MEEM 5670 - Experimental Design in Engg

Review of basic statistical concepts. Models for testing significance of one or many factors. Reducing experimental effort by incomplete blocks, and Latin squares. Factorial and fractional factorial designs. Response surface analysis for optimal response.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall, Summer

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

#### MEEM 5680 - Optimization I

Provides introductory concepts to optimization methods and theory. Covers the fundamentals of optimization, which is central to any problem involving engineering decision making. Provides the tools to select the best alternative for specific objectives.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall, Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

#### MEEM 5700 - Dynamic Measurement/Signal Analysis

Assessment of measurement system requirements: transducers, conditioners, and displays of dynamic measurands. Time-, frequency-, probabilistic-, and correlative-domain approaches to dynamic signal analysis: sampled data, discrete Fourier transforms, digital filtering, estimation errors, system identification, calibration, recording. Introduction to wavelet analysis. All concepts reinforced in laboratory and simulation exercises.
**Credits:**
4.0

**Lec-Rec-Lab:** (0-3-3)

**Semesters Offered:** Fall, Summer

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

#### MEEM 5715 - Linear Systems Theory and Design

Overview of linear algebra, modern control; state-based design of linear systems, observability, controllability, pole placement, observer design, stability theory of linear time-varying systems, Lyapunov stability, optimal control, linear quadratic regulator, Kalman filter,
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following Major(s): Mechanical Engineering, Mechanical Eng-Eng Mechanics, Engineering Mechanics

**Pre-Requisite(s):** MEEM 4700 or EE 4261 or EE 3261

#### MEEM 5750 - Distributed Embedded Control Systems

This course will develop an understanding for the design and application of embedded control systems. Topics to be covered include: embedded system architecture, model-based embedded system design, real-time control, communication protocols, signal processing, and human machine interface. Embedded applications in advanced hybrid electric vehicles will also be introduced.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-2-2)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering;
Must be enrolled in one of the following Major(s): Mechanical Engineering, Mechanical Eng-Eng Mechanics, Engineering Mechanics

**Pre-Requisite(s):** MEEM 4700 or EE 4261 or EE 3261

## Chemical Engineering

#### CM 3974 - Fuel Cell Fundamentals

This course provides an introduction to fuel cells and fuel cell systems. Topics include an overview of fuel-cell construction, fuel-cell chemistry, fuel-cell losses and efficiency, and integrating fuel cells into vehicles.
**Credits:**
1.0

**Lec-Rec-Lab:** (1-0-0)

**Semesters Offered:** Fall, Spring

**Pre-Requisite(s):** CH 1112 or (CH 1150 and CH 1151)

#### CM 5760 - Vehicle Battery Cells and Systems

The behavior and application of batteries will be examined by introducting concepts from thermodynamics, materials science, transport processes and equivalent circuits. The non-ideal power source behavior of rechargeable batteries in applications will be treated using electrolyte: electrode transport and electrode materials chemistry. Prior exposure to freshman chemistry, elementary electrical circuits, and elementary transport theory is assumed.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall - Offered alternate years beginning with the 2010-2011 academic year

**Restrictions: **
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

**Pre-Requisite(s):** MEEM 2200 or CM 3230 or MY 3100 or EE 2110 or MEEM 5990

## Engineering Fundamentals

#### ENG 3200 - Thermodynamics/Fluid Mechanics

Provides engineering students with a unified understanding of the fundamental conservation laws and property accounting applied to thermodynamic and fluid dynamic systems. Topics will include but are not limited to: ideal gas behavior; heat, work, and energy; 1st and 2nd laws of thermodynamics; heat pumps; cycles; hydrostatics; Bernoulli; pipe flow and loss; and lift and drag. Uses MATLAB.
**Credits:**
4.0

**Lec-Rec-Lab:** (0-4-0)

**Semesters Offered:** Fall, Spring

**Pre-Requisite(s):** MA 2160 and CH 1112 or (CH 1150 and CH 1151) and PH 2100 and ENG 1102

## Enterprise

#### ENT 3974 - Fuel Cell Fundamentals

This course provides an introduction to fuel cells and fuel cell systems. Topics include an overview of fuel cell construction, fuel cell chemistry, fuel cell losses and efficiency, and integrating fuel cells onto vehicles.
**Credits:**
1.0

**Lec-Rec-Lab:** (1-0-0)

**Semesters Offered:** Fall

**Pre-Requisite(s):** CH 1112 or (CH 1150 and CH 1151)

#### ENT 4900 - Senior Enterprise Project Work V Non-Capstone

Interdisciplinary teams work as part of an enterprise to address real-world projects or problems of significance to industry, government and communities. Fourth-year students gain experience in defining project objectives and planning strategies to achieve these objectives, and leading teams to accomplish project goals. This course is for students who are not participating in Enterprise to fulfill their capstone requirements.
**Credits:**
2.0

**Lec-Rec-Lab:** (0-0-6)

**Semesters Offered:** Fall, Spring, Summer

**Restrictions: **
May not be enrolled in one of the following College(s): College of Engineering;
Must be enrolled in one of the following Class(es): Senior

## Materials Science and Engineering

#### MY 4165 - Corrosion and Environmental Effects

Mechanisms of corrosion processes, electrochemical and oxidation kinetics, and fundamentals of corrosion engineering.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall, Spring

**Pre-Requisite(s):** MY 2100

#### MY 5100 - Thermodynamics and Kinetics I

Solution thermodynamics and application to phase equilibria. Driving force for phase transformations. Chemical thermodynamics applied to materials processing. Corrosion and oxidation of metals. Applications to engineering situations.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

#### MY 5110 - Thermodynamics and Kinetics II

The kinetics of liquid-to-solid and solid-to-solid phase transformations. Diffusion-controlled phase transformations, including nucleation, growth, coarsening, spinodal decomposition, eutectic and eutectoid transformations, cellular transformations, and massive transformations. Martensitic transformations.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** MY 5100

#### MY 5410 - Materials for Energy Applications

Advanced solid materials for hydrogen energy will be introduced, including hydrogen storage materials, hydrogen production catalysts, and proton exchange membranes with emphasis on structures and properties. Silicon semiconductors, compound semiconductors, and nanostructured semiconductors will be discussed for solar energy applications.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Spring

**Restrictions: **
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

#### MY 5760 - Vehicle Battery Cells and Systems

The behavior and application of batteries will be examined by introducing concepts from thermodynamics, materials science, transport processes and equivalent circuits. The non-ideal power source behavior of rechargeable batteries in applications will be treated using electrolyte: electrode transport and electrode materials chemistry. Prior exposure to freshman chemistry, elementary electrical circuits, and elementary transport theory is assumed.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall - Offered alternate years beginning with the 2010-2011 academic year

**Restrictions: **
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

**Pre-Requisite(s):** MEEM 2200 or CM 3230 or MY 3100 or EE 2110 or MEEM 5990

## Electrical Engineering

#### EE 3120 - Electric Energy Systems

An overview of the generation and utilization of electrical energy. Covers three-phase circuits, transformers, photovoltaics, batteries, electromechanical energy conversion, and an overview of electric power systems, including economic issues.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall, Spring, Summer

**Pre-Requisite(s):** EE 2110 or EE 3010 or (EE 2111 and EE 2112(C))

#### EE 4219 - Introduction to Electric Machinery and Drives

Provides a thorough understanding of how electric machines can be used to drive loads with control of speed, torque and position. Topics include basic electro-mechanics, rotating machinery, dc machines, ac machines, power electronics and load modeling. Applications include industrial systems, hybrid/electric vehicles and electric power systems.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Spring

**Pre-Requisite(s):** EE 2110 or EE 2112 or EE 3010

#### EE 4220 - Introduction to Electric Machinery and Drives Laboratory

Provides a hands on understanding of how electric machines can be used to drive loads with control of speed, torque, and position. Topics include basic electro-mechanics, rotating machineer, dc machines, ac machines, power electronics, and load modeling.
**Credits:**
1.0

**Lec-Rec-Lab:** (0-0-2)

**Semesters Offered:** Spring

**Pre-Requisite(s):** EE 4219(C)

#### EE 4221 - Power System Analysis 1

Covers power transmission line parameters and applications, symmetrical components, transformer and load representations, systems faults and protection, and the per unit system.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall

**Pre-Requisite(s):** EE 3120 and (EE 2112 or EE 2110)

#### EE 4222 - Power System Analysis 2

Topics covered include symmetrical components; symmetrical faults; unbalanced faults; generating the bus impedance matrix and using it in fault studies; power system protection; power system operation; power system stability.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Spring

**Pre-Requisite(s):** EE 4221

#### EE 4227 - Power Electronics

Fundamentals of circuits for electrical energy processing. Covers switching converter principles for dc-dc, ac-dc, and dc-ac power conversion. Other topics include harmonics, pulse-width modulation, feedback control, magnetic components and power semiconductors.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall, Summer

**Pre-Requisite(s):** EE 3120 and (EE 3130(C) or EE 3131)

#### EE 4228 - Power Electronics Lab

Fundamentals of design, construction and control of circuits for electrical energy processing. Covers switching converter principles for dc-dc, ac-dc, and dc-ac power conversion. Other topics include harmonics, pulse-width modulation, feedback control, magnetic components and power semiconductors.
**Credits:**
1.0

**Lec-Rec-Lab:** (0-0-3)

**Semesters Offered:** Fall

**Pre-Requisite(s):** EE 4227(C)

#### EE 4295 - Introduction to Propulsion Systems for Hybrid Electric Vehicles

Hybrid electric drive vehicle analysis will be developed and applied to examine the operation, integration, and design of powertrain components. Model based simulation and design is applied to determine vehicle performance measures in comparison to vehicle technical specifications. Power flows, losses, energy usage, and drive quality are examined over drive-cycles via application of these tools.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Fall, Summer

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering;
May not be enrolled in one of the following Class(es): Freshman, Sophomore

**Pre-Requisite(s):** MEEM 2200 or ENG 3200

#### EE 4296 - Experimental Studies in Hybrid Electric Vehicles

Hybrid electric drive vehicles and their powertrain components will be examined from the aspects of safety, testing and analysis, energy conversion, losses, and energy storage, and vehicle technical specifications and vehicle development process. The lab will culminate with vehicle testing to perform power flow and energy analysis during a drive-cycle.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-2-2)

**Semesters Offered:** Fall

**Restrictions: **
Must be enrolled in one of the following College(s): College of Engineering;
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

#### EE 4910 - EE Design Project 2

The second semester of a program of study in which a group of students work on an engineering design project in consultation with a faculty member. (Senior project ready as defined by major substitutes for prerequisites)
**Credits:**
2.0

**Lec-Rec-Lab:** (0-1-3)

**Semesters Offered:** Spring

**Pre-Requisite(s):** EE 4901

#### EE 5200 - Advanced Methods in Power Systems

Advanced analysis and simulation methods for load flow, symmetrical components, short circuit studies, optimal system operation, stability, and transient analysis. Application of commonly used software reinforces concepts and provides practical insights.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following Major(s): Electrical Engineering, Electrical Engineering;
May not be enrolled in one of the following Class(es): Freshman, Sophomore, Junior

**Pre-Requisite(s):** EE 4222

#### EE 5221 - Advanced Electric Machinery and Drives

Advanced electromechanics of rotating and linear machines. Topics include dynamic analysis of machines, reference frame transformations, reduced order models, models of mechanical loads, power electric drives for motors, and digital simulation of machines and electric drive systems. Applications discussed will include renewable energy and electric propulsion systems.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall - Offered alternate years beginning with the 2013-2014 academic year

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

#### EE 5223 - Power System Protection

Real-time monitoring and protection of modern power systems. Secure and reliable operation of radial and grid systems. Protection of transmission lines, buses, generators, motors, transformers, and other equipment against disturbances.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Spring - Offered alternate years beginning with the 2008-2009 academic year

#### EE 5227 - Advanced Power Electronics

Advanced topics of circuits for electrical energy processing. Covers switching converter principles for dc-dc, ac-dc, and dc-ac power conversion. Other topics include harmonics, pulse-width modulation, classical feedback control, nonlinear control, magnetic components, power semiconductors, and digital simulation.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Fall - Offered alternate years beginning with the 2012-2013 academic year

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** EE 3120

#### EE 5228 - Advanced Power Electronics Lab

Advanced concepts for design, construction, and control of circuits for electrical energy processing. Covers switching converter principles for dc-dc, ac-dc, and dc-ac power conversion. Other topics include harmonics, pulse-width modulation, feedback control, magnetic components and power semiconductors.
**Credits:**
1.0

**Lec-Rec-Lab:** (0-0-3)

**Semesters Offered:** Fall - Offered alternate years beginning with the 2012-2013 academic year

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** EE 5227(C)

#### EE 5230 - Power System Operations

Study of advanced engineering and economic algorithms and analysis techniques for the planning, operation, and control of the electric power system from generation through transmission to distribution.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** On Demand

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following Major(s): Electrical Engineering, Electrical Engineering

#### EE 5250 - Distribution Engineering

Modeling and analysis of electrical distribution systems; load characteristics, load modeling, unbalanced three-phase overhead and underground line models, and distribution transformers. Analysis of primary system design, applications for capacitors, voltage drop, power loss, distribution system protection, and introduction to advanced distribution automation.
**Credits:**
3.0

**Lec-Rec-Lab:** (3-0-0)

**Semesters Offered:** Spring - Offered alternate years beginning with the 2007-2008 academic year

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate

**Pre-Requisite(s):** EE 4221

#### EE 5295 - Advanced Propulsion Systems for Hybrid Electric Drive Vehicles

Hybrid electric vehicles (HEV) will be studied and simulated using advanced powertrain component analysis and modeling. An in-depth analysis and study of power flows, losses, and energy usage are examined for isolated powertrain components and HEV configurations. Simulation tools will be developed and applied to specify powertrain and vehicle components and to develop control and calibration for a constrained optimization to vehicle technical specifications.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-3-0)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** MEEM 4295 or EE 4295

#### EE 5296 - Adv Prop Sys for HEV Lab

Hybrid electric vehicles (HEV) and their components will be examined in a series of laboratories. This includes quantification of power flows and losses in components, calibration of component models based upon experimental data, measurement and quantification of drive quality, failure Mode & Effects Analysis, calibration practices and trade-offs. A HEV model will be tuned and validated through analysis and fitting to vehicle test data.
**Credits:**
2.0

**Lec-Rec-Lab:** (0-1-2)

**Semesters Offered:** Spring, Summer

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** MEEM 4296 or EE 4296

#### EE 5750 - Distributed Embedded Control Systems

This course will develop an understanding for the design and application of embedded control systems. Topics to be covered include: embedded system architecture, model-based embedded system design, real-time control, communication protocols, signal processing, and human machine interface. Embedded applications in advanced hybrid electric vehicles will also be introduced. Credit may not be received for both MEEM4750 and MEEM5750.
**Credits:**
3.0

**Lec-Rec-Lab:** (0-2-2)

**Semesters Offered:** Spring

**Restrictions: **
Must be enrolled in one of the following Level(s): Graduate;
Must be enrolled in one of the following College(s): College of Engineering

**Pre-Requisite(s):** MEEM 4700 or EE 4261