Mechatronics Engineering Technology BS

Mechatronics Engineering Technology, BS degree, typical course sequence

Course Sem. Cr. Hrs.
First Year
CHMG-131
General Education – Scientific Principles Perspective: General Chemistry for Engineers
This rigorous course is primarily for, but not limited to, engineering students. Topics include an introduction to some basic concepts in chemistry, stoichiometry, First Law of Thermodynamics, thermochemistry, electronic theory of composition and structure, and chemical bonding. The lecture is supported by workshop-style problem sessions. Offered in traditional and online format. Lecture 2, Recitation 1 (Fall, Spring).
3
CPET-121
General Education - Elective: Computational Problem Solving I
This is the first course in a two-course sequence in computational problem solving of engineering and scientific problems. The problems solved will stress the application of sequence, selection, repetitive, invocation operations, and arrays. The development of proper testing procedures to ensure computational accuracy will be stressed. Students, upon successful completion of this course, will be able to analyze introductory engineering and scientific problems, design, code, test, and document procedural software solutions. Lec/Lab 4 (Fall, Spring).
3
EEET-215
Circuits and Electronics
Develops the skills to analyze introductory AC and DC circuits and electronics. Topics include Ohm’s Law; current and voltage division; simplification of circuits; reactance and impedance; and operational amplifier applications including current sources, strain gauge amplifiers, differential amplifiers and comparator circuits. (Prerequisites: (MATH-111 or MATH-171 or MATH-181) or (NMTH-260 or NMTH-272 or NMTH-275 and NMTH-220) or equivalent courses. Co-requisites: EEET-216 or equivalent course.) Lecture 2 (Fall, Spring).
2
EEET-216
Circuits and Electronics Laboratory
Students, upon completion of this course, will be able to use laboratory tools to analyze and troubleshoot AC and DC and basic electronic circuits. They will be able to operate a power supply, multi-meter, function generator, and oscilloscope. (Co-requisites: EEET-215 or equivalent course.) Lab 2 (Fall, Spring).
1
MATH-171
General Education – Mathematical Perspective A: Calculus A
This is the first course in a three-course sequence (COS-MATH-171, -172, -173). This course includes a study of functions, continuity, and differentiability. The study of functions includes the exponential, logarithmic, and trigonometric functions. Limits of functions are used to study continuity and differentiability. The study of the derivative includes the definition, basic rules, and implicit differentiation. Applications of the derivative include optimization and related-rates problems. (Prerequisite: C- or better in MATH-111 or C- or better in ((NMTH-260 or NMTH-272 or NMTH-275) and NMTH-220) or a math placement exam score greater than or equal to 50.) Lecture 5 (Fall, Spring).
3
MATH-172
General Education – Mathematical Perspective B: Calculus B
This is the second course in three-course sequence (COS-MATH-171, -172, -173). The course includes Riemann sums, the Fundamental Theorem of Calculus, techniques of integration, and applications of the definite integral. The techniques of integration include substitution and integration by parts. The applications of the definite integral include areas between curves, and the calculation of volume. (Prerequisites: C- or better in MATH-171 or 1016-171T or 1016-281 or 1016-231 or equivalent course.) Lecture 5 (Fall, Spring).
3
MCET-101
Fundamentals of Engineering
Students will apply engineering problem solving methods used in industry to complete projects involving engineering topics such as mechanics, circuits, robotics, and thermodynamics. Software tools are used to model their designs, perform design calculations, collect and analyze data. Finally, students will present their work professionally using both written and oral communication software. The goal of the class is to have students become familiar with the many aspects of mechanical engineering through hands on, experiential learning and prepares them to work professionally and effectively in a team setting both in college and in industry. Lecture 3, Recitation 1 (Fall, Spring).
3
MCET-110
Foundations of Metals
This class explores the commonly used engineering metals. Differentiation of materials, with a focus on metals, is made based on an understanding and control of fundamental material properties. This knowledge of properties and materials then informs analysis of which metals are selected for various applications. Corrosion and its mitigation are explored. Materials selection software and internet resources are used. (Co-requisites: MCET-111 or equivalent course.) Lecture 2 (Fall, Spring).
2
MCET-111
Characterization of Metals Lab
This lab class accompanies MCET-110 Foundations of Materials. An emphasis is placed on determining material, primarily metals, properties though experimentation and references, and analyzing why a particular material was selected for an application based on the materials properties. Differentiation of materials families is made based on properties. A variety of discovery activities are used to explore the world of metals, including labs of various types, materials selection software, and internet resources. (Co-requisites: MCET-110 or equivalent course.) Lab 1 (Fall, Spring).
1
MFET-105
Machine Tools Lab
Proficiency with traditional machine shop tools will be demonstrated with an emphasis on safety. Students will demonstrate their abilities to interpret drawings and select the appropriate equipment needed to produce each part. Parts built will be inspected by the student to verify the meeting of part requirements. Students will repair/replace any parts that are found to be out of specifications. Inspection tools will be utilized in the product validation requirement of the course. Topics will be experimentally validated through the creation of mechanical parts that will be assembled into a final product. (Prerequisites: This class is restricted to students in MFET-BS, RMET-BS, MCET-BS, EMET-BS or ENGTEH-BS.) Lab 2 (Fall, Spring).
1
MFET-120
Manufacturing Processes
This course will focus on the understanding and application of manufacturing processes. Students will be challenged to discover and learn how typical piece parts and assemblies are manufactured. Topics include material properties and the following process families: casting, material removal, deformation, consolidation, powder metallurgy, plastics fabrication, EDM, water jet, chemical, LASERS, plasma, and rapid prototyping. (This class is restricted to MFET-BS or RMET-BS or MCET-BS or EMET-BS Major students.) Lecture 3 (Fall).
3
PHYS-111
General Education – Natural Science Inquiry Perspective: College Physics I
This is an introductory course in algebra-based physics focusing on mechanics and waves. Topics include kinematics, planar motion, Newton’s laws, gravitation; rotational kinematics and dynamics; work and energy; momentum and impulse; conservation laws; simple harmonic motion; waves; data presentation/analysis and error propagation. The course is taught using both traditional lectures and a workshop format that integrates material traditionally found in separate lecture, recitation, and laboratory settings. Lab 4, Lecture 2 (Fall, Spring, Summer).
4
 
General Education – First-Year Writing: FYW (WI)
3
YOPS-10
RIT 365: RIT Connections
RIT 365 students participate in experiential learning opportunities designed to launch them into their career at RIT, support them in making multiple and varied connections across the university, and immerse them in processes of competency development. Students will plan for and reflect on their first-year experiences, receive feedback, and develop a personal plan for future action in order to develop foundational self-awareness and recognize broad-based professional competencies. Lecture 1 (Fall, Spring).
0
Second Year
CPET-133
Introduction to Digital and Microcontroller Systems
This course introduces students to the underlying building blocks of digital system and microcontroller design. Digital systems topics that are covered include: number systems, truth tables, Boolean algebra, combinational and sequential logic, and finite state machines. A microcontroller is used to teach register programming, reading and writing digital I/O, bitwise operations and bit-masking and microprocessor architecture. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics. Lab 2, Lecture 2 (Fall).
3
EEET-213
Electronic Devices
This course covers the analysis, design and implementation of active electronic circuits using diodes, bipolar and field effect transistors and operational amplifiers. The electrical and switching characteristics of semiconductor devices used for analog and digital circuits will be emphasized. Classic applications of analog signal conditioning, A/D & D/A conversion and power transformation (AC/DC & DC/DC) will be examined. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics. (Prerequisites: ((EEET-121 and EEET-122) or (EEET-215 and EEET-216)) and (MATH-171 or MATH-181 or MATH-181A) or equivalent courses.) Lab 2, Lecture 2 (Fall).
3
EMET-290
Mechanics for Mechatronics
This course provides an introduction to the analysis and design of structures and machines, with applications to mechatronic components and systems. Students learn to calculate stresses and deflections in axially loaded members, beams, shafts, and columns. Topics include statically indeterminate problems, thermal stress, stress concentration, combined stress by superposition and Mohr’s Circle, thin-walled pressure vessels, columns and structure stability. The fundamentals of kinematics and kinetics of particle motion are developed including the study of Newton’s Laws of Motion, energy methods, impulse and momentum. Students also gain experience with laboratory equipment, experimental methods, team work, project management and communications as they complete laboratory and project assignments. Analysis and design principles are applied to mechatronic components and systems. (Prerequisites: C- or better in MCET-220 or MECE-103 or CVET-210 or equivalent course.) Lecture 3, Recitation 1 (Fall, Spring).
3
ENGT-95
Career Seminar
This course is an introduction to the cooperative educational program at RIT, the programs in the department, and RIT resources. Topics include engineering technology vs. engineering, review of resources available at RIT, the cooperative education placement process, and the ethical expectations of employers for co-op students and RIT during a job search. Seminar 1 (Fall, Spring).
0
MATH-211
General Education – Elective: Elements of Multivariable Calculus and Differential Equations
This course includes an introduction to differential equations, Laplace transforms, numerical methods in differential equations, and the calculus of functions of two variables. The emphasis is on the application of these topics to problems in engineering technology. (Prerequisites: C- or better MATH-172 or MATH-182 or MATH 182A or 1016-232 or equivalent course.) Lecture 3 (Fall, Spring).
3
MCET-150
Engineering Communication and Tolerancing
A course that integrates basic engineering techniques. Topics will emphasize the design and communication of components through the use of hand sketching, solid modeling, dimensioning, tolerancing, and current GD&T standards. Students will be expected to design, build, inspect, and integrate GD&T into designs. (Prerequisites: This class is restricted to students in MFET-BS, RMET-BS, MCET-BS, EMET-BS or ENGTEH-BS.) Lecture 3, Recitation 1 (Spring).
3
MCET-220
Principles of Statics
This course provides an introduction to the analysis and design of structures and machines. Students learn to calculate unknown forces using the concept of equilibrium and free body diagrams and to calculate simple stresses and deflections for axially loaded members. Topics include forces, moments, free body diagrams, equilibrium, friction, stress, strain, and deflection. Examples are drawn from mechanical, manufacturing, and civil engineering technology. Lecture 3, Recitation 1 (Fall, Spring).
3
PHYS-112
General Education – Elective: College Physics II
This course is an introduction to algebra-based physics focusing on thermodynamics, electricity and magnetism, optics, and elementary topics in modern physics. Topics include heat and temperature, laws of thermodynamics, fluids, electric and magnetic forces and fields, DC electrical circuits, electromagnetic induction, opyics, the concept of the photon, and the Bohr model of the atom. The course is taught using both traditional lectures and a workshop format that integrates material traditionally found in separate lecture, recitation, and laboratory settings. (Prerequisites: PHYS-111 or 1017-211 or equivalent course.) Lab 4, Lecture 2 (Fall, Spring).
4
Choose one of the following:
3
   COMM-142
   Introduction to Technical Communication (WI)
This course introduces students to current best practices in written and visual technical communication including writing effective email, short and long technical reports and presentations, developing instructional material, and learning the principles and practices of ethical technical communication. Course activities focus on engineering and scientific technical documents. Lecture 3 (Fall).
 
   COMM-221
   Public Relations Writing (WI)
This course covers a variety of forms of writing for public relations, including news releases, newsletters, backgrounders, public service announcements, magazine queries, interviews, coverage memos, media alerts, features, trade press releases, and public presentations. Students will write for a variety of media including print, broadcast, and the web. Lecture 3 (Fall, Spring).
 
   COMM-253
   Communication (WI)
An introduction to communication contexts and processes emphasizing both conceptual and practical dimensions. Participants engage in public speaking, small group problem solving and leadership, and writing exercises while acquiring theoretical background appropriate to understanding these skills. Lecture 3 (Fall, Spring).
 
   ENGL-360
   Written Argument (WI)
This course will focus on academic writing specifically, the arguments presented in different fields and professions about issues of significance. Students will learn about the rhetorical, ethical, emotional, historical and logical elements of persuasion as they relate to written and visual arguments and they will practice making claims, providing evidence, exploring underlying assumptions and anticipating counter-arguments as they relate to different audiences. In addition to argument analyses, students will develop arguments of their own through inquiry-based essays. Lecture 3 (Fall, Spring).
 
   ENGL-361
   Technical Writing (WI)
Provides knowledge of and practice in technical writing. Key topics include audience analysis; organizing, preparing and revising short and long technical documents; designing documents using effective design features and principles, and formatting elements using tables and graphs; conducting research; writing technical definitions, and physical and process descriptions; writing instructions; and individual and group peer editing. Lecture 3 (Fall, Spring).
 
   SOIS-325
   Business Communication (WI)
This course focuses on the development of communication skills essential to functioning effectively in the business world. Students learn the process of analyzing communication situations and responding to them. Topics include an overview of business communication, writing well, delivering business communications, tools for talking in crucial conversations, oral and interpersonal communication including listening skills, public speaking, cross-cultural communication, communicating in the digital age and teamwork. *Note: This course cannot be taken by students in Saunders College of Business.* (This class is restricted to undergraduate students with at least 2nd year standing. Saunders College of Business students are not permitted to take this course.) Lecture 3 (Fall, Spring).
 
 
General Education – Artistic Perspective
3
 
General Education - Global Perspective
3
Third Year
EMET-499
EMET Co-op (spring, summer)
EMET Co-op. Department permission is required. (Prerequisites: ENGT-95 or equivalent course.) CO OP .
0
MFET-340
Automation Control Systems
This course will provide a thorough understanding of the manufacturing automation principles, practices and system integration. Students will design a fully automated control system from selection of components, specifying the Programmable Logic Controller (PLC), and developing the ladder logic required to operate the system. Students will have the tools to effectively be able to fully design an automated control system as in done in varying industries. (Co-requisite: MFET-341 or equivalent course.) Lecture 2 (Fall, Spring).
2
MFET-341
Automation Control Systems Lab
This course will provide a thorough hands-on experience in using Programmable Logic Controllers (PLCs) for manufacturing automation and system integration. Industry best practices for programming PLCs and the essentials of Human Machine Interface (HMI) for data entry, manipulation, and recording system status will be included. (Co-requisites: MFET-340 or equivalent course.) Lab 2 (Fall, Spring).
1
MFET-585
Robots & Automation
This course deals with the technology and application of robots and Computer Numerical Control (CNC) in a Computer Integrated Manufacturing (CIM) environment. It will provide a thorough understanding of robotic and CNC hardware and software. The hardware aspects include robot and CNC configurations, drive mechanisms, power systems (hydraulic, pneumatic, and servo actuators), end-effectors and end-of-arm-tooling, sensors, control systems, machine vision, programming, safety, and integration. The software aspect deals with the various methods of textual and lead through programming. Digital Interfacing of robots with other CIM components such as programmable logic controllers, computer-controlled machines, conveyors, etc. will be introduced. Robotic cell design and the socio-economic impact of robotics will also be discussed. A strong laboratory hands-on training component is a co-requisite for this course – MFET-586. Students may not take and receive credit for this course if they have already taken MFET-685. (Prerequisites: MCET-220 or CVET-210 or MECE-103 or equivalent course. Students cannot take and receive credit for this course if they have taken MFET-685. Co-requisites: MFET-586 or equivalent course.) Lecture 3 (Fall).
2
MFET-586
Robots & Automation Lab
This laboratory course provides hands on experience with robotics and CNC in manufacturing. (Co-requisites: MFET-585 or equivalent course.) Lab 2 (Fall).
1
STAT-145
General Education – Elective: Introduction to Statistics I
This course introduces statistical methods of extracting meaning from data, and basic inferential statistics. Topics covered include data and data integrity, exploratory data analysis, data visualization, numeric summary measures, the normal distribution, sampling distributions, confidence intervals, and hypothesis testing. The emphasis of the course is on statistical thinking rather than computation. Statistical software is used. (Prerequisite: MATH-101 or MATH-111 or NMTH-260 or NMTH-272 or NMTH-275 or a math placement exam score of at least 35.) Lecture 3 (Fall, Spring, Summer).
3
 
General Education – Ethical Perspective
3
 
General Education - Social Perspective
3
Fourth Year
EEET-427
Control Systems
Develops the knowledge of control system concepts and applies them to electromechanical systems. Systems are characterized and modeled using linear systems methods, focused with a controls perspective. Impulse responses, step responses, and transfer functions are reviewed. Principles of stability and damping are developed and applied to the specification and design of open and closed loop compensators to deliver specific input-output performance. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics. Student must register for BOTH the Lecture and Laboratory components of this course. (Prerequisites: MATH-211 or MATH-231 and (CPET-253 or (CPET-251 and CPET-252)) or (EEET-247 and EEET-248) or equivalent courses.) Lab 2, Lecture 3 (Fall, Spring).
4
EMET-499
EMET Co-op (spring, summer)
EMET Co-op. Department permission is required. (Prerequisites: ENGT-95 or equivalent course.) CO OP .
0
MCET-430
Thermal Fluid Science I
This course provides an introduction to the properties of pure substances, gas laws, first law of thermodynamics, along with an introduction to fluid mechanics are studied and applied. Students learn through an integrated presentation of thermodynamics and fluid mechanics how to approach and solve reasonable thermal-fluid problems. Topics include the first law of thermodynamics, specific heat, ideal gases, work, energy, lumped systems, fluid statics, conservation of mass/energy, laminar, and turbulent flow. Examples are drawn from mechanical, and electrical mechanical engineering technology. (Prerequisites: Grade of C- or better in PHYS-112 or equivalent course.) Lecture 3, Recitation 1 (Fall, Spring).
3
STAT-146
Introduction to Statistics II
This course is an elementary introduction to the topics of regression and analysis of variance. The statistical software package Minitab will be used to reinforce these techniques. The focus of this course is on business applications. This is a general introductory statistics course and is intended for a broad range of programs. (Prerequisites: STAT-145 or equivalent course.) Lecture 6 (Fall, Spring, Summer).
4
 
General Education – Immersion 1
3
 
Open Elective
3
Fifth Year
EEET-241
Electrical Machines and Transformers
Develops the knowledge and ability to analyze and specify motors, generators, and transformers for use in systems such as wind turbines and electric vehicles. Topics include efficiency, energy conservation, power factor, magnetism, electro-magnetic force, fields, armatures, commutators, rotors, stators, brushes, starters, controllers, DC machines, AC motors, alternators, single phase and three phase dynamos, three phase circuits, phasors, transformer properties, isolation, efficiency, and voltage regulation. (Prerequisites: (EEET-121 and EEET-122) or (EEET-215 and EEET-216) or equivalent courses. Co-Requisites: EEET-242 or equivalent course.) Lecture 2 (Fall, Spring).
2
EEET-242
Electrical Machines and Transformers Lab
Provides experience with motors, generators, and transformers. Topics include power factor, magnetism, electro-magnetic force, fields, armatures, commutators, rotors, stators, brushes, starters, controllers, DC machines, AC motors, alternators, single phase and three phase dynamos, three phase circuits, phasors, transformer properties, isolation, efficiency, and voltage regulation. (Co-requisites: EEET-241 or equivalent course.) Lab 2 (Fall, Spring).
1
MCET-530
Thermal Fluid Science II
This course provides an in-depth coverage on the application of the first and second law of thermodynamics and conservation principles, mass and energy, to the analysis of open systems and power cycles, including refrigeration, heat pump and power cycles. It also introduces the fundamentals of heat transfer theory, conduction, radiation, free and forced convection, and its application to heat exchangers including free surface and conduit flow. Case studies based on real-world thermal systems are used to illustrate the connection between these interdisciplinary subjects. (Prerequisites: C- or better in MCET-430 or (MECE-210 and MECE-211) or equivalent course.) Lecture 3, Recitation 1 (Fall, Spring).
3
MECA-518
Mechatronics ET Capstone Prep
This is the first of a two-course sequence for Mechatronics Capstone Project where students address open-ended problems. Emphasis is placed on teamwork, the design process, and project management tools addressing project scope, schedule, risk, cost, milestones and deliverables. The course also focuses on developing good oral, written and interpersonal communication skills. In this course, student teams develop their proposed final mechatronics system after identifying customer needs, and possible alternative concepts. The final system design must be supported by sound engineering analyses and by engineering designs necessary to build a prototype to be implemented in MECA-519. This course is intended to be taken as a capstone design experience near the conclusion of the student's program of study. (Prerequisites: (EMET-290 or (MCET-221 and MCET-320)) and (STAT-146 or MATH-251) and EEET-427 or equivalent courses.) Lec/Lab 2 (Fall).
1
MECA-519
Mechatronics ET Capstone (WI-PR)
This is the second of the two-course sequence for Mechatronics Capstone project where students demonstrate the proposed problem resolution developed in MECA-518. Focus is on design implementation, analysis, testing, documentation, demonstration, and presentation of a fully functional prototype. Continued emphasis is placed on teamwork and on developing good oral, written and interpersonal communication skills. (Prerequisites: MECA-518 or equivalent course.) Lecture 3 (Spring).
3
MFET-436
Engineering Economics
This course provides in depth coverage of engineering economic analysis, which is the financial side of engineering decision making. Students are also taught ethical decision making through an introduction to an engineering professional code of conduct. Project planning/management are introduced to students. Presentation skills are enhanced with an emphasis on presenting to executives. (Prerequisites: Completion of MATH-111 or any other higher level MATH class is required.) Lecture 3 (Fall, Spring).
3
 
General Education – Immersion 2, 3
6
 
General Education - Elective
3
 
Open Electives
9
Total Semester Credit Hours
126

The proposed curriculum outline provides an overview of the course work/topic areas in this new program and is subject to change.

Please see General Education Curriculum (GE) for more information.

(WI) Refers to a writing intensive course within the major.

Please see Wellness Education Requirement for more information. Students completing bachelor's degrees are required to complete two different Wellness courses.

Accelerated Dual-Degree Programs

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Mechatronics Engineering Technology, BS degree/Manufacturing and Mechanical Systems Integration, MS degree, typical course sequence

Course Sem. Cr. Hrs.
First Year
CHMG-131
General Education – Scientific Principles Perspective: General Chemistry for Engineers
This rigorous course is primarily for, but not limited to, engineering students. Topics include an introduction to some basic concepts in chemistry, stoichiometry, First Law of Thermodynamics, thermochemistry, electronic theory of composition and structure, and chemical bonding. The lecture is supported by workshop-style problem sessions. Offered in traditional and online format. Lecture 2, Recitation 1 (Fall, Spring).
3
CPET-121
General Education – Elective: Computational Problem Solving I
This is the first course in a two-course sequence in computational problem solving of engineering and scientific problems. The problems solved will stress the application of sequence, selection, repetitive, invocation operations, and arrays. The development of proper testing procedures to ensure computational accuracy will be stressed. Students, upon successful completion of this course, will be able to analyze introductory engineering and scientific problems, design, code, test, and document procedural software solutions. Lec/Lab 4 (Fall, Spring).
3
EEET-215
Circuits and Electronics
Develops the skills to analyze introductory AC and DC circuits and electronics. Topics include Ohm’s Law; current and voltage division; simplification of circuits; reactance and impedance; and operational amplifier applications including current sources, strain gauge amplifiers, differential amplifiers and comparator circuits. (Prerequisites: (MATH-111 or MATH-171 or MATH-181) or (NMTH-260 or NMTH-272 or NMTH-275 and NMTH-220) or equivalent courses. Co-requisites: EEET-216 or equivalent course.) Lecture 2 (Fall, Spring).
2
EEET-216
Circuits and Electronics Lab
Students, upon completion of this course, will be able to use laboratory tools to analyze and troubleshoot AC and DC and basic electronic circuits. They will be able to operate a power supply, multi-meter, function generator, and oscilloscope. (Co-requisites: EEET-215 or equivalent course.) Lab 2 (Fall, Spring).
1
MATH-171
General Education – Mathematical Perspective A: Calculus A
This is the first course in a three-course sequence (COS-MATH-171, -172, -173). This course includes a study of functions, continuity, and differentiability. The study of functions includes the exponential, logarithmic, and trigonometric functions. Limits of functions are used to study continuity and differentiability. The study of the derivative includes the definition, basic rules, and implicit differentiation. Applications of the derivative include optimization and related-rates problems. (Prerequisite: C- or better in MATH-111 or C- or better in ((NMTH-260 or NMTH-272 or NMTH-275) and NMTH-220) or a math placement exam score greater than or equal to 50.) Lecture 5 (Fall, Spring).
3
MATH-172
General Education – Mathematical Perspective B: Calculus B
This is the second course in three-course sequence (COS-MATH-171, -172, -173). The course includes Riemann sums, the Fundamental Theorem of Calculus, techniques of integration, and applications of the definite integral. The techniques of integration include substitution and integration by parts. The applications of the definite integral include areas between curves, and the calculation of volume. (Prerequisites: C- or better in MATH-171 or 1016-171T or 1016-281 or 1016-231 or equivalent course.) Lecture 5 (Fall, Spring).
3
MCET-101
Fundamentals of Engineering
Students will apply engineering problem solving methods used in industry to complete projects involving engineering topics such as mechanics, circuits, robotics, and thermodynamics. Software tools are used to model their designs, perform design calculations, collect and analyze data. Finally, students will present their work professionally using both written and oral communication software. The goal of the class is to have students become familiar with the many aspects of mechanical engineering through hands on, experiential learning and prepares them to work professionally and effectively in a team setting both in college and in industry. Lecture 3, Recitation 1 (Fall, Spring).
3
MCET-110
Foundations of Metals
This class explores the commonly used engineering metals. Differentiation of materials, with a focus on metals, is made based on an understanding and control of fundamental material properties. This knowledge of properties and materials then informs analysis of which metals are selected for various applications. Corrosion and its mitigation are explored. Materials selection software and internet resources are used. (Co-requisites: MCET-111 or equivalent course.) Lecture 2 (Fall, Spring).
2
MCET-111
Characterization of Metals Lab
This lab class accompanies MCET-110 Foundations of Materials. An emphasis is placed on determining material, primarily metals, properties though experimentation and references, and analyzing why a particular material was selected for an application based on the materials properties. Differentiation of materials families is made based on properties. A variety of discovery activities are used to explore the world of metals, including labs of various types, materials selection software, and internet resources. (Co-requisites: MCET-110 or equivalent course.) Lab 1 (Fall, Spring).
1
MFET-105
Machine Tools
Proficiency with traditional machine shop tools will be demonstrated with an emphasis on safety. Students will demonstrate their abilities to interpret drawings and select the appropriate equipment needed to produce each part. Parts built will be inspected by the student to verify the meeting of part requirements. Students will repair/replace any parts that are found to be out of specifications. Inspection tools will be utilized in the product validation requirement of the course. Topics will be experimentally validated through the creation of mechanical parts that will be assembled into a final product. (Prerequisites: This class is restricted to students in MFET-BS, RMET-BS, MCET-BS, EMET-BS or ENGTEH-BS.) Lab 2 (Fall, Spring).
1
MFET-120
Manufacturing Processes
This course will focus on the understanding and application of manufacturing processes. Students will be challenged to discover and learn how typical piece parts and assemblies are manufactured. Topics include material properties and the following process families: casting, material removal, deformation, consolidation, powder metallurgy, plastics fabrication, EDM, water jet, chemical, LASERS, plasma, and rapid prototyping. (This class is restricted to MFET-BS or RMET-BS or MCET-BS or EMET-BS Major students.) Lecture 3 (Fall).
3
PHYS-111
General Education – Natural Science Inquiry Perspective: College Physics I
This is an introductory course in algebra-based physics focusing on mechanics and waves. Topics include kinematics, planar motion, Newton’s laws, gravitation; rotational kinematics and dynamics; work and energy; momentum and impulse; conservation laws; simple harmonic motion; waves; data presentation/analysis and error propagation. The course is taught using both traditional lectures and a workshop format that integrates material traditionally found in separate lecture, recitation, and laboratory settings. Lab 4, Lecture 2 (Fall, Spring, Summer).
4
UWRT-150
General Education – First Year Writing: FYW: Writing Seminar (WI)
Writing Seminar is a three-credit course limited to 19 students per section. The course is designed to develop first-year students’ proficiency in analytical and rhetorical reading and writing, and critical thinking. Students will read, understand, and interpret a variety of non-fiction texts representing different cultural perspectives and/or academic disciplines. These texts are designed to challenge students intellectually and to stimulate their writing for a variety of contexts and purposes. Through inquiry-based assignment sequences, students will develop academic research and literacy practices that will be further strengthened throughout their academic careers. Particular attention will be given to the writing process, including an emphasis on teacher-student conferencing, critical self-assessment, class discussion, peer review, formal and informal writing, research, and revision. Small class size promotes frequent student-instructor and student-student interaction. The course also emphasizes the principles of intellectual property and academic integrity for both current academic and future professional writing. Lecture 3 (Fall, Spring, Summer).
3
YOPS-10
RIT 365: RIT Connections
RIT 365 students participate in experiential learning opportunities designed to launch them into their career at RIT, support them in making multiple and varied connections across the university, and immerse them in processes of competency development. Students will plan for and reflect on their first-year experiences, receive feedback, and develop a personal plan for future action in order to develop foundational self-awareness and recognize broad-based professional competencies. Lecture 1 (Fall, Spring).
0
Second Year
CPET-133
Introduction to Digital and Microcontroller Systems
This course introduces students to the underlying building blocks of digital system and microcontroller design. Digital systems topics that are covered include: number systems, truth tables, Boolean algebra, combinational and sequential logic, and finite state machines. A microcontroller is used to teach register programming, reading and writing digital I/O, bitwise operations and bit-masking and microprocessor architecture. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics. Lab 2, Lecture 2 (Fall).
3
EEET-213
Electronic Devices
This course covers the analysis, design and implementation of active electronic circuits using diodes, bipolar and field effect transistors and operational amplifiers. The electrical and switching characteristics of semiconductor devices used for analog and digital circuits will be emphasized. Classic applications of analog signal conditioning, A/D & D/A conversion and power transformation (AC/DC & DC/DC) will be examined. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics. (Prerequisites: ((EEET-121 and EEET-122) or (EEET-215 and EEET-216)) and (MATH-171 or MATH-181 or MATH-181A) or equivalent courses.) Lab 2, Lecture 2 (Fall).
3
EMET-290
Mechanics for Mechatronics
This course provides an introduction to the analysis and design of structures and machines, with applications to mechatronic components and systems. Students learn to calculate stresses and deflections in axially loaded members, beams, shafts, and columns. Topics include statically indeterminate problems, thermal stress, stress concentration, combined stress by superposition and Mohr’s Circle, thin-walled pressure vessels, columns and structure stability. The fundamentals of kinematics and kinetics of particle motion are developed including the study of Newton’s Laws of Motion, energy methods, impulse and momentum. Students also gain experience with laboratory equipment, experimental methods, team work, project management and communications as they complete laboratory and project assignments. Analysis and design principles are applied to mechatronic components and systems. (Prerequisites: C- or better in MCET-220 or MECE-103 or CVET-210 or equivalent course.) Lecture 3, Recitation 1 (Fall, Spring).
3
EMET-499
EMET Co-op (summer)
EMET Co-op. Department permission is required. (Prerequisites: ENGT-95 or equivalent course.) CO OP .
0
ENGT-95
Career Seminar
This course is an introduction to the cooperative educational program at RIT, the programs in the department, and RIT resources. Topics include engineering technology vs. engineering, review of resources available at RIT, the cooperative education placement process, and the ethical expectations of employers for co-op students and RIT during a job search. Seminar 1 (Fall, Spring).
0
MATH-211
General Education – Elective: Elements of Multivariable Calculus and Differential Equations
This course includes an introduction to differential equations, Laplace transforms, numerical methods in differential equations, and the calculus of functions of two variables. The emphasis is on the application of these topics to problems in engineering technology. (Prerequisites: C- or better MATH-172 or MATH-182 or MATH 182A or 1016-232 or equivalent course.) Lecture 3 (Fall, Spring).
3
MCET-150
Engineering Communication and Tolerancing
A course that integrates basic engineering techniques. Topics will emphasize the design and communication of components through the use of hand sketching, solid modeling, dimensioning, tolerancing, and current GD&T standards. Students will be expected to design, build, inspect, and integrate GD&T into designs. (Prerequisites: This class is restricted to students in MFET-BS, RMET-BS, MCET-BS, EMET-BS or ENGTEH-BS.) Lecture 3, Recitation 1 (Spring).
3
MCET-220
Principles of Statics
This course provides an introduction to the analysis and design of structures and machines. Students learn to calculate unknown forces using the concept of equilibrium and free body diagrams and to calculate simple stresses and deflections for axially loaded members. Topics include forces, moments, free body diagrams, equilibrium, friction, stress, strain, and deflection. Examples are drawn from mechanical, manufacturing, and civil engineering technology. Lecture 3, Recitation 1 (Fall, Spring).
3
PHYS-112
General Education – Elective: College Physics II
This course is an introduction to algebra-based physics focusing on thermodynamics, electricity and magnetism, optics, and elementary topics in modern physics. Topics include heat and temperature, laws of thermodynamics, fluids, electric and magnetic forces and fields, DC electrical circuits, electromagnetic induction, opyics, the concept of the photon, and the Bohr model of the atom. The course is taught using both traditional lectures and a workshop format that integrates material traditionally found in separate lecture, recitation, and laboratory settings. (Prerequisites: PHYS-111 or 1017-211 or equivalent course.) Lab 4, Lecture 2 (Fall, Spring).
4
 
General Education – Artistic Perspective
3
 
General Education – Global Perspective
3
Choose one of the following:
3
   COMM-142
   General Education – Elective: Introduction to Technical Communication
This course introduces students to current best practices in written and visual technical communication including writing effective email, short and long technical reports and presentations, developing instructional material, and learning the principles and practices of ethical technical communication. Course activities focus on engineering and scientific technical documents. Lecture 3 (Fall).
 
   COMM-221
   General Education – Elective: Public Relations Writing
This course covers a variety of forms of writing for public relations, including news releases, newsletters, backgrounders, public service announcements, magazine queries, interviews, coverage memos, media alerts, features, trade press releases, and public presentations. Students will write for a variety of media including print, broadcast, and the web. Lecture 3 (Fall, Spring).
 
   COMM-253
   General Education – Elective: Communication
An introduction to communication contexts and processes emphasizing both conceptual and practical dimensions. Participants engage in public speaking, small group problem solving and leadership, and writing exercises while acquiring theoretical background appropriate to understanding these skills. Lecture 3 (Fall, Spring).
 
   ENGL-360
   General Education – Elective: Written Argument
This course will focus on academic writing specifically, the arguments presented in different fields and professions about issues of significance. Students will learn about the rhetorical, ethical, emotional, historical and logical elements of persuasion as they relate to written and visual arguments and they will practice making claims, providing evidence, exploring underlying assumptions and anticipating counter-arguments as they relate to different audiences. In addition to argument analyses, students will develop arguments of their own through inquiry-based essays. Lecture 3 (Fall, Spring).
 
   ENGL-361
   General Education – Elective: Technical Writing
Provides knowledge of and practice in technical writing. Key topics include audience analysis; organizing, preparing and revising short and long technical documents; designing documents using effective design features and principles, and formatting elements using tables and graphs; conducting research; writing technical definitions, and physical and process descriptions; writing instructions; and individual and group peer editing. Lecture 3 (Fall, Spring).
 
   SOIS-325
   General Education – Elective: Business Communication
This course focuses on the development of communication skills essential to functioning effectively in the business world. Students learn the process of analyzing communication situations and responding to them. Topics include an overview of business communication, writing well, delivering business communications, tools for talking in crucial conversations, oral and interpersonal communication including listening skills, public speaking, cross-cultural communication, communicating in the digital age and teamwork. *Note: This course cannot be taken by students in Saunders College of Business.* (This class is restricted to undergraduate students with at least 2nd year standing. Saunders College of Business students are not permitted to take this course.) Lecture 3 (Fall, Spring).
 
Third Year
EEET-241
Electrical Machines and Transformers
Develops the knowledge and ability to analyze and specify motors, generators, and transformers for use in systems such as wind turbines and electric vehicles. Topics include efficiency, energy conservation, power factor, magnetism, electro-magnetic force, fields, armatures, commutators, rotors, stators, brushes, starters, controllers, DC machines, AC motors, alternators, single phase and three phase dynamos, three phase circuits, phasors, transformer properties, isolation, efficiency, and voltage regulation. (Prerequisites: (EEET-121 and EEET-122) or (EEET-215 and EEET-216) or equivalent courses. Co-Requisites: EEET-242 or equivalent course.) Lecture 2 (Fall, Spring).
2
EEET-242
Electrical Machines and Transformers Lab
Provides experience with motors, generators, and transformers. Topics include power factor, magnetism, electro-magnetic force, fields, armatures, commutators, rotors, stators, brushes, starters, controllers, DC machines, AC motors, alternators, single phase and three phase dynamos, three phase circuits, phasors, transformer properties, isolation, efficiency, and voltage regulation. (Co-requisites: EEET-241 or equivalent course.) Lab 2 (Fall, Spring).
1
EEET-427
Control Systems
Develops the knowledge of control system concepts and applies them to electromechanical systems. Systems are characterized and modeled using linear systems methods, focused with a controls perspective. Impulse responses, step responses, and transfer functions are reviewed. Principles of stability and damping are developed and applied to the specification and design of open and closed loop compensators to deliver specific input-output performance. Laboratory exercises are designed to illustrate concepts, reinforce analysis and design skills, and develop instrumentation techniques associated with the lecture topics. Student must register for BOTH the Lecture and Laboratory components of this course. (Prerequisites: MATH-211 or MATH-231 and (CPET-253 or (CPET-251 and CPET-252)) or (EEET-247 and EEET-248) or equivalent courses.) Lab 2, Lecture 3 (Fall, Spring).
4
EMET-499
EMET Co-op (summer)
EMET Co-op. Department permission is required. (Prerequisites: ENGT-95 or equivalent course.) CO OP .
0
MFET-340
Automation Control Systems
This course will provide a thorough understanding of the manufacturing automation principles, practices and system integration. Students will design a fully automated control system from selection of components, specifying the Programmable Logic Controller (PLC), and developing the ladder logic required to operate the system. Students will have the tools to effectively be able to fully design an automated control system as in done in varying industries. (Co-requisite: MFET-341 or equivalent course.) Lecture 2 (Fall, Spring).
2
MFET-341
Automation Control Systems Lab
This course will provide a thorough hands-on experience in using Programmable Logic Controllers (PLCs) for manufacturing automation and system integration. Industry best practices for programming PLCs and the essentials of Human Machine Interface (HMI) for data entry, manipulation, and recording system status will be included. (Co-requisites: MFET-340 or equivalent course.) Lab 2 (Fall, Spring).
1
MFET-585
Robots & Automation
This course deals with the technology and application of robots and Computer Numerical Control (CNC) in a Computer Integrated Manufacturing (CIM) environment. It will provide a thorough understanding of robotic and CNC hardware and software. The hardware aspects include robot and CNC configurations, drive mechanisms, power systems (hydraulic, pneumatic, and servo actuators), end-effectors and end-of-arm-tooling, sensors, control systems, machine vision, programming, safety, and integration. The software aspect deals with the various methods of textual and lead through programming. Digital Interfacing of robots with other CIM components such as programmable logic controllers, computer-controlled machines, conveyors, etc. will be introduced. Robotic cell design and the socio-economic impact of robotics will also be discussed. A strong laboratory hands-on training component is a co-requisite for this course – MFET-586. Students may not take and receive credit for this course if they have already taken MFET-685. (Prerequisites: MCET-220 or CVET-210 or MECE-103 or equivalent course. Students cannot take and receive credit for this course if they have taken MFET-685. Co-requisites: MFET-586 or equivalent course.) Lecture 3 (Fall).
2
MFET-586
Robots & Automation Lab
This laboratory course provides hands on experience with robotics and CNC in manufacturing. (Co-requisites: MFET-585 or equivalent course.) Lab 2 (Fall).
1
MFET-600
MMSI Graduate Seminar
This course provides students that are new to the MMSI program an opportunity to develop an understanding of the department’s research activities. The students will become more knowledgeable about the Manufacturing & Mechanical Systems Integration program, career options, the capstone and thesis project process (finding an advisor, required documentation and policies regarding completing a project on co-op) and department policies and procedures related to successful completion of the MMSI program. (This course is restricted to graduate or BS/MS students in the MMSI-MS, MCET-BS/MS, MFET-BS/MS, and EMET-BS/MS programs.) Seminar 2 (Fall).
0
MFET-650
Manufacturing and Mechanical Systems Fundamentals (Counts as Undergraduate Open Elective)
This course is intended to help students learn to think like systems engineers. This course will provide a thorough understanding of the systems fundamentals, its design, modeling, and integration. Topics include a thorough coverage of systems architecture, conceptualization, modeling, development and management. Students in this course will be taught industry practices for systems engineering and management from concept stage to post implementation stage. System engineering and modeling tools will also be introduced to assist with the conceptualization, development, and implementation of systems. (This course is restricted to graduate or BS/MS students in the MMSI-MS, MFSI-MS, MCSI-MS and EMSI-MS programs.) Lecture 3 (Fall).
3
MFET-730
Six Sigma for Design and Manufacturing
This course presents the philosophy and tools that will enable participants to develop quality strategies and drive process improvements that are linked to and integrated with business plans. Continuous improvement principles are presented, within the six sigma format. The course will help prepare students for six sigma black belt certification. Students can receive credit for only one of the following: MFET-730, CQAS-701, or ISEE-682. (Prerequisites: Students may not take and receive credit for MFET-730 and STAT/CQAS-701 or ISEE-682.) Lecture 3 (Spring).
3
STAT-145
General Education – Elective: Introduction to Statistics I
This course introduces statistical methods of extracting meaning from data, and basic inferential statistics. Topics covered include data and data integrity, exploratory data analysis, data visualization, numeric summary measures, the normal distribution, sampling distributions, confidence intervals, and hypothesis testing. The emphasis of the course is on statistical thinking rather than computation. Statistical software is used. (Prerequisite: MATH-101 or MATH-111 or NMTH-260 or NMTH-272 or NMTH-275 or a math placement exam score of at least 35.) Lecture 3 (Fall, Spring, Summer).
3
 
General Education – Ethical Perspective
3
 
General Education – Social Perspective
3
 
MMET Concentration Course (Counts as Undergraduate Open Elective)
3
Fourth Year
EMET-499
EMET Co-op (summer)
EMET Co-op. Department permission is required. (Prerequisites: ENGT-95 or equivalent course.) CO OP .
0
MECA-518
Mechatronics ET Capstone Prep
This is the first of a two-course sequence for Mechatronics Capstone Project where students address open-ended problems. Emphasis is placed on teamwork, the design process, and project management tools addressing project scope, schedule, risk, cost, milestones and deliverables. The course also focuses on developing good oral, written and interpersonal communication skills. In this course, student teams develop their proposed final mechatronics system after identifying customer needs, and possible alternative concepts. The final system design must be supported by sound engineering analyses and by engineering designs necessary to build a prototype to be implemented in MECA-519. This course is intended to be taken as a capstone design experience near the conclusion of the student's program of study. (Prerequisites: (EMET-290 or (MCET-221 and MCET-320)) and (STAT-146 or MATH-251) and EEET-427 or equivalent courses.) Lec/Lab 2 (Fall).
1
MECA-519
Mechatronics ET Capstone (WI-PR)
This is the second of the two-course sequence for Mechatronics Capstone project where students demonstrate the proposed problem resolution developed in MECA-518. Focus is on design implementation, analysis, testing, documentation, demonstration, and presentation of a fully functional prototype. Continued emphasis is placed on teamwork and on developing good oral, written and interpersonal communication skills. (Prerequisites: MECA-518 or equivalent course.) Lecture 3 (Spring).
3
MCET-430
Thermal Fluid Science I
This course provides an introduction to the properties of pure substances, gas laws, first law of thermodynamics, along with an introduction to fluid mechanics are studied and applied. Students learn through an integrated presentation of thermodynamics and fluid mechanics how to approach and solve reasonable thermal-fluid problems. Topics include the first law of thermodynamics, specific heat, ideal gases, work, energy, lumped systems, fluid statics, conservation of mass/energy, laminar, and turbulent flow. Examples are drawn from mechanical, and electrical mechanical engineering technology. (Prerequisites: Grade of C- or better in PHYS-112 or equivalent course.) Lecture 3, Recitation 1 (Fall, Spring).
3
MCET-530
Thermal Fluid Science II
This course provides an in-depth coverage on the application of the first and second law of thermodynamics and conservation principles, mass and energy, to the analysis of open systems and power cycles, including refrigeration, heat pump and power cycles. It also introduces the fundamentals of heat transfer theory, conduction, radiation, free and forced convection, and its application to heat exchangers including free surface and conduit flow. Case studies based on real-world thermal systems are used to illustrate the connection between these interdisciplinary subjects. (Prerequisites: C- or better in MCET-430 or (MECE-210 and MECE-211) or equivalent course.) Lecture 3, Recitation 1 (Fall, Spring).
3
STAT-146
General Education – Elective: Introduction to Statistics II
This course is an elementary introduction to the topics of regression and analysis of variance. The statistical software package Minitab will be used to reinforce these techniques. The focus of this course is on business applications. This is a general introductory statistics course and is intended for a broad range of programs. (Prerequisites: STAT-145 or equivalent course.) Lecture 6 (Fall, Spring, Summer).
4
STAT-670
Design of Experiments
How to design and analyze experiments, with an emphasis on applications in engineering and the physical sciences. Topics include the role of statistics in scientific experimentation; general principles of design, including randomization, replication, and blocking; replicated and unreplicated two-level factorial designs; two-level fractional-factorial designs; response surface designs. Lecture 3 (Fall, Spring).
3
 
MMET Concentration Course
3
 
General Education – Elective
3
 
Open Elective
3
 
General Education – Immersion 1, 2
6
Fifth Year
DECS-744
Project Management
A study in the principles of project management and the application of various tools and techniques for project planning and control. This course focuses on the leadership role of the project manager, and the roles and responsibilities of the team members. Considerable emphasis is placed on statements of work and work breakdown structures. The course uses a combination of lecture/discussion, group exercises, and case studies. (This class is restricted to degree-seeking graduate students or those with permission from instructor.) Lecture 3 (Fall, Spring).
3
MFET-436
Engineering Economics
This course provides in depth coverage of engineering economic analysis, which is the financial side of engineering decision making. Students are also taught ethical decision making through an introduction to an engineering professional code of conduct. Project planning/management are introduced to students. Presentation skills are enhanced with an emphasis on presenting to executives. (Prerequisites: Completion of MATH-111 or any other higher level MATH class is required.) Lecture 3 (Fall, Spring).
3
 
MMET Concentration Course
3
Choose one of the following:
3
   ACCT-603
   Accounting for Decision Makers
A graduate-level introduction to the use of accounting information by decision makers. The focus of the course is on two subject areas: (1) financial reporting concepts/issues and the use of general-purpose financial statements by internal and external decision makers and (2) the development and use of special-purpose financial information intended to assist managers in planning and controlling an organization's activities. Generally accepted accounting principles and issues related to International Financial Reporting Standards are considered while studying the first subject area and ethical issues impacting accounting are considered throughout. (This class is restricted to degree-seeking graduate students or those with permission from instructor.) Lecture 3 (Fall, Spring, Summer).
 
   ACCT-706
   Cost Management
The development and use of cost data for external reporting and internal cost management (planning and control). Topics include job costing, process costing, joint product costing, cost reassignments, standard costs, activity-based costing, decentralization and transfer pricing, and cost variances. Consideration is given to manufacturing, service and retail organizations. (Prerequisites: ACCT-603 or equivalent course.) Lecture 3 (Spring).
 
Choose one of the following:
3
   MFET-788
   MMSI Thesis Planning
Students will rigorously develop their thesis research ideas, conduct literature reviews, identify and plan methodologies, prepare schedules, and gain a clear understanding of the expectations of the faculty and the discipline. Each student will be required to prepare a committee approved thesis research proposal and may begin work on their thesis. (Enrollment in this course requires permission from the department offering the course.) Lecture 3 (Spring).
 
   
   MMET Elective Course
 
Choose one of the following:
3
   MFET-797
   MMSI Capstone Project
This course provides the MMSI graduate students an opportunity to complete their degree requirements by addressing a practical real-world challenge using the knowledge and skills acquired throughout their studies. This course is not only the culmination of a student's course work but also an indicator of the student's ability to use diverse knowledge to provide a tangible solution to a problem. The capstone project topic can be in the areas of product development, manufacturing automation, management system, quality management or electronics packaging. The course requires a comprehensive project report and a final presentation. (Enrollment in this course requires permission from the department offering the course.) Project 3 (Fall, Spring, Summer).
 
   MFET-790
   MMSI Thesis
The MMSI thesis is based on thorough literature review and experimental substantiation of a problem, by the candidate, in an appropriate topic. A written proposal has to be defended and authorized by the faculty adviser/committee. The proposal defense is followed by experimental work, a formal written thesis, and oral presentation of findings. The candidate should have completed the requisite courses for the program before enrolling for the thesis. (Prerequisites: MFET-788 or equivalent course.) Thesis 3 (Fall, Spring, Summer).
 
   MFET-795
   MMSI Comprehensive Exam and MMET Elective
A written comprehensive exam is one of the non-thesis or non-project methodology for completion of the MS-MMSI degree. Students will demonstrate a fundamental knowledge of the theories and foundation principles. This course will require the student to do an independent review of the concepts within the core courses and the chosen concentration area, and will culminate in a comprehensive written examination. The student must receive a passing grade of at least 80 percent to be successful. Students will have one additional opportunity to pass the exam, if their initial attempt results in a failing grade. (Enrollment in this course requires permission from the department offering the course.) Comp Exam 3 (Fall, Spring, Summer).
 
 
MMET Elective
3
 
General Education – Immersion 3
3
 
Open Elective
3
Total Semester Credit Hours
153

Please see General Education Curriculum (GE) for more information.

(WI) Refers to a writing intensive course within the major.

Please see Wellness Education Requirement for more information. Students completing bachelor's degrees are required to complete two different Wellness courses.