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Emergency Medical Technology-Paramedic |
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EMS 381 - Crit Care Clin Pract I
Lecture Hours: 0
Lab Hours: 3
Credit Hours: 1
The first of two practicum classes that exposes students to critical care transport topics focusing on psychomotor skills and the science behind them. This practicum is designed to prepare the student for EMS 382 ICU and critical care transport experience.
Corequisite: EMS 331
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EMS 382 - Crit Care Clin Pract II
Lecture Hours: 0
Lab Hours: 9
Credit Hours: 3
The second of two practicum classes that exposes students to critical care transport environments that may include experiences with intensive care units, fixed wing transport, rotor wing transport, critical care ground transport, as well as various specialty critical care teams.
Prerequisite: EMS 331
Corequisite: EMS 332
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EMS 444 - EMS Systems, Lead & Mgt
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Explores the fundamental skills of managing and leading in EMS: concepts, prinicples and practices of leaders in the EMS industry. Case study discussions and analysis. Examines EMS systems, operations, resources and regulation of EMS. Industry leaders provide guest lectures.
Prerequisites: BUS 317 and PSY 347
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EMS 456 - Research Methods in EMS
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
An introductory course in EMS research covering hypothesis formulation, design and use of data-gathering instruments, data collection, and methods of data analysis and presentation. Research and technical reports appearing in professional publications and archives are examined.
Prerequisite: MATH 361
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EMS 496 - EMS Capstone Project I
Lecture Hours: 1
Lab Hours: 6
Credit Hours: 3
Students formulate a detailed plan for a project or independent research study within the EMS industry. Project plan will include topic outline and goals, timeline, industry contacts. Faculty advisor will be assigned.
Prerequisites: MATH 361 and WRI 227
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EMS 497 - EMS Capstone Project II
Lecture Hours: 1
Lab Hours: 6
Credit Hours: 3
Implementation and completion of student project planned in EMS 496. Project results to be delivered in a report presented to an audience of EMS peers. Students will have scheduled meeting with a faculty advisor to track progress and determine readiness for presentation.
Prerequisite: EMS 496
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Engineering |
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ENGR 101 - Intro to Engineering I
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
Introduces the student to engineering with a focus on academic success, professional development, ethics, communication, and creative problem solving techniques, engineering tools (CAD/CAE), and design concepts. A discipline-specific team-based laboratory experience encourages consideration of a chosen engineering discipline.
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ENGR 102 - Intro to Engineering II
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
The student will focus on their chosen discipline through an interdisciplinary team-based design project including problem identification, measurement, analysis, and presentation to peers. Emphasis will be placed on proper usage of engineering tools and instruments and sound design practices.
Prerequisite: ENGR 101
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ENGR 111 - MMET Orientation
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
Topics include: survey of the engineering profession, educational and professional development, standards of practice; engineering information, calculations, and analysis. An engineering design project will be incorporated. This course provides knowledge and skills to engineering students which will benefit their future academic and professional endeavors.
Prerequisite: Declared major in the BSME, BSMET, or BSMFG program
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ENGR 120 - Fundamentals of Engineering Design, Analytical Tools, and CAD
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Fundamentals of engineering design, including analytical and computational tools that introduce design concepts and build a foundation of engineering knowledge that will be helpful to students starting off in engineering and technology disciplines. Computer aided design and drafting, problem solving, documentation, analysis, teamwork, and multi-step engineering calculations.
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ENGR 121 - Engineering Principles and Problem Solving
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Topics include modeling of real-world concepts and systems, basic statics, electronics, energy generation, and robotics. Using both analytical and computational tools to represent, analyze, and improve on real-world situations. Identifying the correct type of system to employ, improving the efficiency of existing systems, working in multi-disciplinary groups, developing and presenting ideas, prototyping as well as testing iteratively.
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ENGR 122 - Electronics and Computation in Engineering
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Fundamental electrical and computational topics in engineering. Building and analyzing circuits, using mathematical concepts to develop solutions, and using both analytical and computational tools to gain knowledge and hands-on skills. Troubleshooting and testing of ideas as well as presenting ideas in an organized and systematic manner to others. Provides a basic foundation of knowledge and skills that will transfer well to continued education, technical jobs and self-confidence.
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ENGR 207 - Seminar
Lecture Hours: 6
Lab Hours: 6
Credit Hours: 6
(Hours to be arranged each term.)
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ENGR 211 - Engineering Mechanics: Statics
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Fundamental principles of mechanics of rigid bodies and the application of these principles to engineering problems.
Prerequisite: PHY 201 or PHY 221
Pre- or Corequisite: MATH 252
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ENGR 212 - Engineering Mech: Dynamics
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Kinematics of particles and rigid bodies. Kinetics of particles and rigid bodies in plane motion, including Newton’s second law, work and energy, and impulse and momentum.
Prerequisites: ENGR 211 and MATH 252
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ENGR 213 - Engr Mech: Strength of Mat
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Internal stresses and deformations of structural members and machines when subjected to external forces.
Prerequisites: ENGR 211 and MATH 252
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ENGR 236 - Fund of Elec Circuits
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Resistive circuits, operational amplifiers, capacitors, inductors, transient analysis, sine waves, AC circuit analysis, resonance, transformers. Not for Electronics Engineering Technology and Computer Engineering Technology students.
Prerequisites: MATH 252 , and PHY 202 or PHY 222
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ENGR 266 - Engineering Computation
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Programming and problem solving using current computer software. General programming techniques using conditional statements, looping, subroutines, and data input/output will be stressed. Consideration of features specific to the software being used will also be presented.
Prerequisite: MATH 112
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ENGR 267 - Engineering Programming
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Computer programming principles. Control structures. Structural programming principles. Functions and scripts. MATLAB programming. LabVIEW programming. Application of engineering programming principles in projects.
Prerequisite: MATH 251
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ENGR 305 - Nanoscience & Nanotech
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Survey of chemical and physical phenomena as applied to nanoscale materials, including metal and semiconductor nanoparticles and carbon nanostructures. Discussion of major synthesis and characterization techniques. Biological and engineering applications of nanoscale materials.
Prerequisites: CHE 202 or CHE 222 , and PHY 222 or PHY 223
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ENGR 318 - Engineering Mech: Fluids
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Fundamental properties of fluids, fluid statics and pressure variation, flow characterization, momentum and forces due to fluid motion, energy of fluids in motion, and flow in conduits. Emphasis on civil and mechanical engineering applications of fluid mechanics principles.
Prerequisites: ENGR 211 and MATH 252
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ENGR 326 - Electric Power Systems
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Study related to theory and application of industrial electric power systems. Topics covered include transformers, motors, generators, motor controls, and protective devices.
Prerequisite: ENGR 236
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ENGR 355 - Thermodynamics
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An introductory course in thermodynamics, the science of heat energy conversion. Develops understanding of energy, heat, work, efficiency, and ideal thermodynamic cycles. Teaches first and second laws of thermodynamics and perfect gas law.
Prerequisites: MATH 252 , and PHY 202 or PHY 222
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ENGR 407 - Seminar
Lecture Hours: 12
Lab Hours: 0
Credit Hours: 12
(Hours to be arranged each term.)
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ENGR 415 - Occupational Safety
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Topics include current occupational safety and health issues. Practical application of regulations in the industrial setting. Compliance to Industrial Hygiene and General Safety Standards. Common safety violations and implementation of safety programs.
Prerequisite: Junior standing in any MMET program
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ENGR 422 - Process Control
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Design of continuous and batch process control systems. Advanced control schemes, including model-based methods.
Prerequisite: ENGR 464
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ENGR 445 - Engineering Project Management
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Applications of the Critical Path Method to organization and control of engineering projects. Applications software will be used to create and evaluate project networks to develop management reports.
Prerequisite: Junior standing in Engineering or Engineering Technology
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ENGR 461 - Modeling and Simulation of Dynamic Systems
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Conservation laws of physics are used to develop lumped-parameter models of continuous-time dynamic systems. Modeling and analysis of engineering systems containing mechanical, electrical, electromechanical, fluid, and thermal components. Computational methods are used to simulate a range of practical engineering problems.
Prerequisites: EE 225 or EE 320 , ENGR 267 , MATH 321 , MATH 322 or MATH 341 , and PHY 223 , all with grade “C” or better. Mechanical Engineering majors who have completed MECH 326 and MECH 480 , both with grade “C” or better may enroll without having completed EE 225 and/or EE 320 .
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ENGR 462 - Control Engineering II: Modern Methods
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Modeling, simulation, and control of continuous and discrete processes using state-space methods. State functions, state equations, transfer matrices. State-space model building, state-feedback control and observation, pole placement, state vector transformations. Discrete-time control systems.
Prerequisites: EE 461 and ENGR 461 , both with grade “C” or better
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ENGR 464 - Autonomous Systems
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
A capstone course in the Robotics, Control, and Autonomous Systems Engineering sequence. A unified treatment using dynamics, modeling, simulation, and control in the analysis and synthesis of autonomous control systems.
Prerequisites: ENGR 462 and ENGR 463 , both with grade “C” or better
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ENGR 465 - Capstone Project
Lecture Hours: 0
Lab Hours: 6
Credit Hours: 2
Students apply material learned in other courses, develop expertise on a specific topic, work closely with a faculty member to implement the project, and improve professional communication skills by writing a project report. Course may be repeated for credit.
Prerequisites: Junior standing and instructor consent
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ENGR 485 - Fund of Engineering Exam Prep
Lecture Hours: 1
Lab Hours: 0
Credit Hours: 1
A preparation course covering the requirements of, and providing a review for, the NCEES FE exam.
Prerequisite: Senior standing in an MMET program
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ENGR 491 - MMET Senior Projects I
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
The first course of a three-term sequence that offers a capstone experience for students in an MMET program. This experience involves the application of knowledge and skills acquired from prior coursework to an engineered system, system optimization, project management, and material related to a group engineering project. This course will be focused on the proposal and planning stages of the project assigned.
Prerequisites: Senior standing in an MMET program and instructor consent
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ENGR 492 - MMET Senior Projects II
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
The second course of a three-term sequence that offers a capstone experience for students in an MMET program. This experience involves the application of knowledge and skills acquired from prior coursework to an engineered system, system optimization, project management, and material related to a group engineering project. This course will be focused on the design and analysis of the project assigned.
Prerequisite: ENGR 491
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ENGR 493 - MMET Senior Projects III
Lecture Hours: 1
Lab Hours: 6
Credit Hours: 3
The third course of a three-term sequence that offers a capstone experience for students in an MMET program. This experience involves the application of knowledge and skills acquired from prior coursework to an engineered system, system optimization, project management, and material related to a group engineering project. This course will be focused on the implementation and assessment stages of the project assigned.
Prerequisite: ENGR 492
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ENGR 507 - Seminar
Lecture Hours: 12
Lab Hours: 0
Credit Hours: 12
(Hours to be arranged each term.)
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ENGR 511 - Res Meth & Innov: Intel Prop
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Intellectual property (IP) development, evaluation, and strategy, IP fundamentals, patent fundamentals, conducting patentability searches, evaluating the patentability potential of an invention, drafting invention disclosures for patent applications, assessing the value of a patent or patent portfolio, and IP licensing.
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ENGR 512 - Res Meth & Innov: Res Meth
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Fundamental concepts of scientific research. An introduction to the concepts underlying peer-reviewed research, evaluating the relevance and impact of sources, conducting literature reviews, evaluating published findings, using research productivity tools, using statistical methods, designing research studies, and writing scholarly articles.
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ENGR 513 - Res Meth & Innov: Strat & Inno
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Strategy and innovation concepts with a focus on technology commercialization. Business strategy frameworks, financial analysis, strategic marketing, operations management, business models, project management, business law, and entrepreneurship.
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ENGR 522 - Process Control
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Design of continuous and batch process control systems. Advanced control schemes, including model-based methods.
Prerequisites: ENGR 561 and ENGR 564
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ENGR 561 - Modeling and Simulation of Dynamic Systems
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Conservation laws of physics are used to develop lumped-parameter models of continuous-time dynamic systems. Modeling and analysis of engineering systems containing mechanical, electrical, electromechanical, fluid, and thermal components. Computational methods are used to simulate a range of practical engineering problems.
Prerequisite: Graduate standing in Engineering
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ENGR 562 - Control Engineering II: Modern Methods
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Modeling, simulation, and control of continuous and discrele processes using state-space methods. State functions, state equations, transfer matrices. State-space rnodel building, state-feedback control and observation, pole placement, state vector transforrnations. Discretelime control systems.
Prerequisites: EE 461 or an equivalent undergraduate course in control system engineering, and ENGR 561 both with grade “C” or better
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ENGR 563 - Motion Control in Mechanisms and Robotics
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Motion control components, beginning with the study of the function, classification, position, velocity, and acceleration of fundamental mechanisms and robot kinematic chains. Dynamic response of open- and closed-loop mechanisms to periodic and non-periodic loading. Motion and torque control.
Prerequisites: ENGR 561 with grade “C” or better, and graduate standing in Engineering
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ENGR 564 - Autonomous Systems
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
A capstone course in the Robotics, Control, and Autonomous Systems Engineering sequence. A unified treatment using dynamics, modeling, simulation, and control in the analysis synthesis of autonomous control systems.
Prerequisites: ENGR 562 , ENGR 563 both with grade “C” or better, and graduate standing in Engineering
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ENGR 596 - Grad Research & Development
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Selected engineering topics at the graduate level. Course may be repeated for credit.
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ENGR 597 - Graduate Project
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Graduate project in engineering topics. Course may be repeated for credit.
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ENGR 598 - Graduate Thesis
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Graduate thesis in engineering topics. Course may be repeated for credit.
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ENGR 599 - Practicum
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Supervised practical experience in engineering topics at the graduate level. Course may be repeated for credit.
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Engineering Technology |
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ENGT 101 - Engr Tech
Lecture Hours: 2
Lab Hours: 6
Credit Hours: 4
Engineering terminology and problem solving tools including computer aided drafting, technical sketching, word processing, spread sheets, multiview projections, significant figures, and engineering problem solving techniques.
Prerequisite: MATH 100
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ENGT 103 - Engineering Terminology
Lecture Hours: 3
Lab Hours: 2
Credit Hours: 4
Terminology, symbols, and units commonly used in the engineering field. Interpretation and reproduction techniques of engineering drawings and graphs. A brief overview of the field of civil engineering. This course is designed primarily for the Office Systems Technology program.
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ENGT 104 - Elec Nomenclature/Symbols
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
A survey course in basic electricity and electronics, emphasizing terminology and nomenclature. This course is designed primarily for the Office Systems Technology program.
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ENGT 107 - Seminar
Lecture Hours: 0
Lab Hours: 0
Credit Hours: 15
(Hours to be arranged each term.)
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ENGT 207 - Seminar
Lecture Hours: 6
Lab Hours: 0
Credit Hours: 6
(Hours to be arranged each term.)
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ENGT 307 - Seminar
Lecture Hours: 0
Lab Hours: 0
Credit Hours: 15
(Hours to be arranged each term.)
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ENGT 310 - Intro to Geo Energy
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Overview of geothermal energy: distribution, geology, hydrology, and geochemistry; exploration and extraction techniques; uses including power generation, space heating, agriculture, process and multistage utilization; and environmental, economic, and legal considerations. Field trips to local sites.
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ENGT 311 - Passive Solar/Cell Desgn
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Residential passive solar heating and super-insulation construction techniques including heat load calculations using the Balcomb SHF method. Technical and economic analysis of solar electric cells, storage batteries, and inverter technology.
Prerequisite: PHY 202 or instructor consent
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ENGT 312 - Critical Path Techniques
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
Scheduling techniques used by management on engineering and industrial projects. The course will concentrate on the Critical Path Method (CPM), but will also include comparisons with Gantt Charts and Program Evaluation Review Technique (PERT). Concepts will be applied to mini-projects in class and expanded through the use of selected computer software packages.
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ENGT 370 - Intro to Auto/Robotics
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
A survey of automation and all areas of robotics with an emphasis on the industrial robot. It will include history, terminology, use, future, impact on society, and hands-on labs.
Prerequisites: MATH 112 and a programming course
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ENGT 390 - Co-op Field Practice
Lecture Hours: 6
Lab Hours: 0
Credit Hours: 6
An approved work program related to the student’s field of specialization for a continuous three-month or six-month period. The employer and the type, level, and difficulty of the particular job must be approved by the student’s engineering technology department prior to the employment period. A written comprehensive report of each season’s activity must be submitted during the following term of residence.
Prerequisites: Associate degree and two terms of residence
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ENGT 391 - Co-op Field Practice
Lecture Hours: 6
Lab Hours: 0
Credit Hours: 6
An approved work program related to the student’s field of specialization for a continuous three-month period.
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ENGT 407 - Seminar
Lecture Hours: 6
Lab Hours: 0
Credit Hours: 6
Hours to be arranged with approval of curriculum coordinator.
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ENGT 415 - Occupational Safety
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Topics include current occupational safety and health issues. Practical application of regulations in the industrial setting. Compliance to Industrial Hygiene and General Safety Standards. Common safety violations and implementation of safety programs.
Prerequisite: Junior standing in MFG
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ENGT 471 - Micro/Appl/Auto/Robot
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
This is an applied course in using microprocessors to support controlling motion, such as in robic manipulators and automated equipment and interfacing sensor inputs.
Prerequisites: CST 331 and ENGT 370
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ENGT 490 - Co-op Field Practice
Lecture Hours: 6
Lab Hours: 0
Credit Hours: 6
An approved work program related to the student’s field of specialization for a continuous three-month or six-month period. The employer and the type, level, and difficulty of the particular job must be approved by the student’s engineering technology department prior to the employment period. A written comprehensive report of each season’s activity must be submitted during the following term of residence.
Prerequisites: Associate degree and two terms of residence
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ENGT 491 - Co-op Field Practice
Lecture Hours: 6
Lab Hours: 0
Credit Hours: 6
An approved work program related to the student’s field of specialization for a continuous three-month period.
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ENGT 500 - Research Methods
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Study of industrial analytical techniques used to develop new technologies, including the use of computer aided engineering systems and software for design purposes. Examination of research and development methods, current industrial practices and applications of new technologies.
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ENGT 507 - Seminar
Lecture Hours: 0
Lab Hours: 0
Credit Hours: 12
(Hours to be arranged each term.) In-depth examination of current theories, research, trends, and processes of industry. Individual study, information exchange, and research of selected industrial topics.
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ENGT 518 - Data Communications
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Data communications and computer network protocols, hardware elements, and software algorithms. Error handling, routing, flow control, host-to-host communications, and local area networks.
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ENGT 521 - ASIC Design I
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Techniques for designing Application Specific Integrated Circuits (ASICs). Comprehensive study of computer concepts using computer aided design tools. Implementation of ASIC devices in digital computing systems including: modeling (using VHDL), digital synthesis, place and routing functions, and layout. Design exercises accomplished using hardware description languages and simulation.
Prerequisite: VLSI or ASIC coursework or experience
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ENGT 522 - ASIC Design II
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Techniques used to transform hardware description language-based designs to physical layout. Applications of synthesis tools for floor planning and layout of Application Specific Integrated Circuits. Comprehensive study of logic design, layout generated design, and advanced CMOS circuit techniques used when designing with standard cells.
Prerequisite: ENGT 521
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ENGT 523 - Advanced ASIC Design
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Introduction to very large scale integration (VLSI) technology and design of CMOS integrated circuits including: the device fabrication process and design rules as they apply to device layout. Analysis, design, simulation and layout rules presented. Logic gates and functions design.
Prerequisite: ENGT 522
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ENGT 545 - Adv Microcomputers
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Microprocessor technology and its application to the design of practical digital computing systems. Design techniques used to develop and design newer generation microprocessor-based computing systems. Assembly language programming and interfacing of microprocessor-based systems.
Prerequisite: Microprocessor coursework or experience
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ENGT 546 - Adv Comp Architectures
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Advanced topics in computer architectures including design of computer hardware, organizational structures, and architectural properties of parallel, vector and multi-processing systems. Computer organizational structures of memory and I/O subsystems, multiprocessor computer architectures, and data flow computers.
Prerequisite: Course work or experience in computer architecture and organization
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ENGT 565 - Semicond Dev Phy/Process
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Simple models and physical insight to solid state physics. Crystal structure and symmetry, crystal lattices, reciprocal lattices, equilibrium and nonequilibrium processes in semiconductors. Thermal properties, energy band, and semiconductor properties.
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ENGT 581 - Master’s Project I
Lecture Hours: 1
Lab Hours: 9
Credit Hours: 4
Students prepare the proposal for the Master’s project under the guidance of a project advisor. Project proposal guidelines and accepted format presented. Approval of the proposal by the student’s project committee constitutes completion of the course.
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ENGT 582 - Master’s Project II
Lecture Hours: 1
Lab Hours: 9
Credit Hours: 4
Students complete task specified by the project advisor. Preliminary results of the student’s project presented to the student’s project committee. Acceptance of these results constitutes completion of the course.
Prerequisite: ENGT 581
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ENGT 583 - Master’s Project III
Lecture Hours: 1
Lab Hours: 9
Credit Hours: 4
Students produce the final report demonstrating the completion of the project. Final results of the student’s Master’s project presented to the student’s project committee. Acceptance of the report by the student’s project committee constitutes completion of the course.
Prerequisite: ENGT 582
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Environmental Sciences |
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ENV 107 - Seminar
Lecture Hours: 0
Lab Hours: 0
Credit Hours: 15
(Hours to be arranged each term.)
Prerequisite: ENV major or instructor consent
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ENV 108 - Mentorship and Team Building
Lecture Hours: 1
Lab Hours: 0
Credit Hours: 1
We develop a strong sense of community, trust, inclusion, and belonging within the Environmental Science program among all students and faculty. We introduce student mentorship opportunities and engage in team building exercises and environmental exploration during a weekend camping trip. Course is required every Fall. Can be taken multiple times for credit.
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ENV 111 - Intro to Env Sciences
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
A topical overview of environmental sciences stressing the integration of the social, natural and physical sciences. Emphasis on active learning.
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ENV 207 - Seminar
Lecture Hours: 6
Lab Hours: 6
Credit Hours: 6
(Hours to be arranged each term.)
Prerequisite: ENV major or instructor consent
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ENV 214 - Watershed Sci & Tech
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Science and technology of watershed processes, monitoring, and assessment. Applications and case studies focused on sustainable management and restoration of water resources and their associated aquatic, riparian, and upland ecosystems. Local and regional sites of interest are highlighted.
Prerequisite: ENV 111 or GEOG 105 , or instructor consent
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ENV 217 - Intro to Natural Resources Management
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
An introduction to management of natural resources including water, air, forests, wildlife and fisheries, minerals, and energy. Explore structured decision making, risk assessment, uncertainty, stakeholder engagement, adaptive management, conservation and scenario planning, and climate and environmental mitigation, adaptation, and resiliency.
Prerequisite: ENV 111
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ENV 224 - Scientific Reason & Method
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Fundamental principles and practices of scientific reasoning and methodology, including contrasts with other ways of making knowledge, the power of questions, theories versus hypotheses, understanding experiments, supporting claims, drawing inferences, reproducibility, and coping with uncertainty in typical uncontrolled natural experiments.
Prerequisite: ENV 111 or GEOG 105 , or instructor consent
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ENV 226 - Environmental Data Analysis
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduction to compilation, manipulation, and analysis of datasets common to environmental analysis. Includes measures of central tendency and spread; characterizing data distribution; linear regression; exceedance probability and cumulative frequency functions; understanding time series; and basic principles of graphical data displays.
Prerequisite: ENV 111 or GEOG 105 , or instructor consent
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ENV 265 - Field Methods Environ Science
Lecture Hours: 1
Lab Hours: 6
Credit Hours: 3
Basic principles of experimental design, site and instrument selection for field research. Basic instrumentation and data acquisition techniques are used to contribute to authentic research programs at different locations alongside environmental science professionals.
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ENV 307 - Seminar
Lecture Hours: 0
Lab Hours: 0
Credit Hours: 15
(Hours to be arranged each term.)
Prerequisite: ENV major or instructor consent
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ENV 314 - Environmental Law & Policy
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Overview of legislative, regulatory, and policy-based activities involving the development, management, and restoration of natural resources. Emphasis on the National Environmental Policy Act, Environmental Impact Statements, Endangered Species Act, and Historical Preservation through local, regional, and national case studies.
Prerequisite: ENV 111
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ENV 336 - Environmental Hydrology
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Study of the hydrologic cycle; quantitative measurement of precipitation, infiltration, runoff, streamflow and storage in watersheds. Curve fitting, hydrographic analysis, statistical analysis of extreme flows, flood routing, and runoff modeling for small and urban watersheds.
Prerequisites: MATH 252 and MATH 361
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ENV 355 - Careers/Professionalism in Env Sci
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Practical seminar focusing on career opportunities in environmental sciences, professional standards, culture, ethics, and skills to enhance communication and collegiality. Assists students with workforce transition, including job search, preparation of resume packages and portfolios, interviewing tips, and job-offer negotiation.
Prerequisite: ENV 111
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ENV 365 - Adv Field Methods in Env Sci
Lecture Hours: 1
Lab Hours: 6
Credit Hours: 3
Basic principles of experimental design, site and instrument selection for field research. Basic instrumentation and data acquisition techniques are used to contribute to authentic research programs at different locations alongside environmental science professionals. Course may be repeated for credit.
Prerequisites: MATH 112 and WRI 122
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ENV 375 - Forest Ecology & Management
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Examine abiotic and biotic factors affecting the structure, function, composition, and distribution of forest communities including wildland fire; sustainable forest management practices and policies; and core concepts required for careers in forestry, wildland fire, natural resources, range, and wildlife.
Prerequisite: BIO 211 or BIO 212 or instructor consent
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ENV 407 - Seminar
Lecture Hours: 15
Lab Hours: 0
Credit Hours: 15
(Hours to be arranged each term.)
Prerequisite: ENV major or instructor consent
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ENV 420 - Externship in Env Sci
Credit Hours: Varies (1-9)
Students work in applied settings related to environmental sciences under the supervision of a mentor. Regular contact with extern advisor and mentor. Written externship report and presentation required.
Prerequisites: BIO 211 , BIO 212 , BIO 213 or CHE 221 , CHE 222 , CHE 223
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ENV 427 - Greenhouse Gas Accounting/Footprints
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Course topics include US and international greenhouse gas (GHG) management policies. GHG assessment methods and tools, emissions trading programs, climate risk and risk management, data and information sources, measurement standards and protocols and related sustainability concepts and policies. Course also listed as REE 427 (cannot be used for graduation credit by students who have taken REE 427 ).
Prerequisites: Junior or Senior standing
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ENV 434 - Advanced Data Analysis
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Overview of advanced concepts and methods of analysis specific to ecological data sets using program R. Bayesian and parametric methods, analysis of variance, linear regression, generalized linear modeling, generalized additive modeling, mixed-effect models, multi-model inference, ordination, and time-series analysis.
Prerequisites: ENV 226 and MATH 361
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ENV 435 - Atmospheric Physics
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
The physics of transport and diffusion of air pollution. Atmospheric thermodynamics. Mixing heights, plume rise, and fundamentals of atmospheric turbulence. Eulerian and Lagrangian dispersion models.
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ENV 465 - Ecological Resto. & Monitoring
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Principles and practices of ecological restoration, including ecosystem assessment; evaluation; and restoration, planning, design, implementation, and monitoring. Labs including fields visits and evaluation of local restoration projects.
Prerequisite: ENV 314
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ENV 469 - Treatment Wetlands
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Treatment wetland features: biological, chemical, and physical properties. Planning, design, and performance assessment principles for municipal, agricultural, and stormwater treatment wetlands. Considers vegitation and microbiology, aerobic and anaerobic biogeochemistry, hydraulics, and treatment efficiencies. Local case studies.
Prerequisites: CHE 202 and MATH 251
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