Engineering Courses


Applied Technology Courses


APTC 490. SENIOR CAPSTONE: PRODUCTION LAB. 4 Credits.

Cross-listed: TECH 490, CMTC 490, DNTC 490, MNTC 490.
Pre-requisites: senior standing.
Satisfies: senior capstone university graduation requirement.
The course simulates the real world situation that many of the graduates from the department will face. The students will work in teams to apply techniques of production management, product design/development, plant layout, scheduling, cost accounting, assembly, inspection and quality control to produce a product. The course will simulate a real world design team concept by utilizing a design group that contains members of different program majors. The team, to accomplish its goals, is required to draw on each other's unique skills learned in stated goal. In industry often a design team is formed to develop a new product. The team is made up of members from different departments in the company. Learning to deal with the team dynamics while learning to take advantage of the synergy that can be gained by a diverse team is a valuable learning process for our business as well as civic life. Each student team is to produce a new product (to be massed produced and demonstrated by producing a minimum quantity of 25 units built with unskilled labor utilizing jigs, fixtures and/or CNC controlled machines) and create a final written report to demonstrate how the process and goals of the course have been realized.

APTC 491. SENIOR PROJECT. 3-10 Credits.

Cross-listed: TECH 491, CMTC 491, DNTC 491, MNTC 491.
Pre-requisites: permission of the instructor.
Independent and/or group study and implementation of a design and development project. (variable time).

APTC 495. INTERNSHIP. 1-15 Credits.

Cross-listed: TECH 495, CMTC 495, DNTC 495, MNTC 495.
Notes: Graded Pass/Fail. This course may be repeated.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean.
A maximum of 5 credits may be earned toward electives for a Technology major. Students considering electives for a Technology minor should consult with their departmental advisor.

APTC 496. EXPERIMENTAL COURSE. 1-6 Credits.

Cross-listed: TECH 496, CMTC 496, DNTC 496, MNTC 496.
Experimental Course.

APTC 497. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-6 Credits.

Cross-listed: TECH 497, CMTC 497, DNTC 497, MNTC 497.
Workshop, short course, conference, or seminar.

APTC 498. SEMINAR. 1-6 Credits.

Cross-listed: TECH 498, CMTC 498, DNTC 498, MNTC 498.
Seminar.

APTC 499. DIRECTED STUDY. 1-5 Credits.

Cross-listed: TECH 499, CMTC 499, DNTC 499, MNTC 499.
Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.


Construction Management Technology Courses


CMTC 235. CONSTRUCTION MATERIALS AND TECHNIQUES. 5 Credits.

Pre-requisites: METC 102 or TECH 102, or two years of high school drafting or equivalent.
This course introduces various materials and techniques used in construction. Students gain an understanding of the fundamental principles of structural, physical and long-term performance of some of these materials through lecture and lab experiments. Students also gain an understanding of some of the mechanical and non-mechanical properties of various materials, common construction methods and knowledge of material properties and applications in construction.

CMTC 305. CONSTRUCTION ESTIMATING. 4 Credits.

Pre-requisites: CMTC 235.
This course provides students with the ability to estimate construction costs by reading and interpreting technical drawings. Primary focus is on calculating materials, labor and equipment cost for both residential and commercial building projects. Students generate quantity takeoffs for specific building projects.

CMTC 320. NON-METALLIC PROCESSES. 5 Credits.

Pre-requisites: METC 110; junior/senior status or permission of instructor.
Survey of non-metallic materials (such as woods, plastics, and ceramics) and the industrial processes utilized to convert raw materials into finished products. Course includes characteristics and properties of non-metallic materials and utilization of industrial tools and processing equipment.

CMTC 335. ARCHITECTURE. 4 Credits.

Pre-requisites: METC 110 or TECH 110.
Design, layout, and development of residential dwellings and large structures. (4 hour lecture per week)

CMTC 345. SOILS/SURVEYING. 4 Credits.

Pre-requisites: CMTC 335.
This course introduces soil mechanics and site surveying. Through lecture and field work the course examines characteristics and compositions of soil, soil classification systems and the strength of soil masses. Students practice fundamentals of construction surveying, including taping, leveling, angular measurement, traversing, topographic surveying, building layout and grade staking.

CMTC 354. BUILDING CODES. 4 Credits.

Pre-requisites: CMTC 335.
Building Codes is a comprehensive course pertaining to International Building Codes (IBC). Emphasis is placed on code requirements for both commercial and residential applications to include structural, mechanical, plumbing, fire, fuel gas and private sewage code requirements.

CMTC 490. SENIOR CAPSTONE: PRODUCTION LAB. 4 Credits.

Cross-listed: APTC 490, TECH 490, DNTC 490, MNTC 490.
Pre-requisites: senior standing.
Satisfies: senior capstone university graduation requirement.
The course simulates the real world situation that many of the graduates from the department will face. The students will work in teams to apply techniques of production management, product design/development, plant layout, scheduling, cost accounting, assembly, inspection and quality control to produce a product. The course will simulate a real world design team concept by utilizing a design group that contains members of different program majors. The team, to accomplish its goals, is required to draw on each other's unique skills learned in stated goal. In industry often a design team is formed to develop a new product. The team is made up of members from different departments in the company. Learning to deal with the team dynamics while learning to take advantage of the synergy that can be gained by a diverse team is a valuable learning process for our business as well as civic life. Each student team is to produce a new product (to be massed produced and demonstrated by producing a minimum quantity of 25 units built with unskilled labor utilizing jigs, fixtures and/or CNC controlled machines) and create a final written report to demonstrate how the process and goals of the course have been realized.

CMTC 491. SENIOR PROJECT. 3-10 Credits.

Cross-listed: APTC 491, TECH 491, DNTC 491, MNTC 491.
Pre-requisites: permission of the instructor.
Independent and/or group study and implementation of a design and development project. (variable time).

CMTC 495. INTERNSHIP. 1-15 Credits.

Cross-listed: APTC 495, TECH 495, DNTC 495, MNTC 495.
Notes: Graded Pass/Fail. This course may be repeated.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean.
A maximum of 5 credits may be earned toward electives for a Technology major. Students considering electives for a Technology minor should consult with their departmental advisor.

CMTC 496. EXPERIMENTAL COURSE. 1-6 Credits.

Cross-listed: APTC 496, TECH 496, DNTC 496, MNTC 496.
Experimental Course.

CMTC 497. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-6 Credits.

Cross-listed: APTC 497, TECH 497, DNTC 497, MNTC 497.
Workshop, short course, conference, or seminar.

CMTC 498. SEMINAR. 1-6 Credits.

Cross-listed: APTC 498, TECH 498, DNTC 498, MNTC 498.
Seminar.

CMTC 499. DIRECTED STUDY. 1-5 Credits.

Cross-listed: APTC 499, TECH 499, DNTC 499, MNTC 499.
Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.


Design Technology Courses 


DNTC 490. SENIOR CAPSTONE: PRODUCTION LAB. 4 Credits.

Cross-listed: APTC 490, CMTC 490, TECH 490, MNTC 490.
Pre-requisites: senior standing.
Satisfies: senior capstone university graduation requirement.
The course simulates the real world situation that many of the graduates from the department will face. The students will work in teams to apply techniques of production management, product design/development, plant layout, scheduling, cost accounting, assembly, inspection and quality control to produce a product. The course will simulate a real world design team concept by utilizing a design group that contains members of different program majors. The team, to accomplish its goals, is required to draw on each other's unique skills learned in stated goal. In industry often a design team is formed to develop a new product. The team is made up of members from different departments in the company. Learning to deal with the team dynamics while learning to take advantage of the synergy that can be gained by a diverse team is a valuable learning process for our business as well as civic life. Each student team is to produce a new product (to be massed produced and demonstrated by producing a minimum quantity of 25 units built with unskilled labor utilizing jigs, fixtures and/or CNC controlled machines) and create a final written report to demonstrate how the process and goals of the course have been realized.

DNTC 491. SENIOR PROJECT. 3-10 Credits.

Cross-listed: APTC 491, CMTC 491, TECH 491, MNTC 491.
Pre-requisites: permission of the instructor.
Independent and/or group study and implementation of a design and development project. (variable time).

DNTC 495. INTERNSHIP. 1-15 Credits.

Cross-listed: APTC 495, CMTC 495, TECH 495, MNTC 495.
Notes: Graded Pass/Fail. This course may be repeated.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean.
A maximum of 5 credits may be earned toward electives for a Technology major. Students considering electives for a Technology minor should consult with their departmental advisor.

DNTC 496. EXPERIMENTAL COURSE. 1-6 Credits.

Cross-listed: APTC 496, CMTC 496, TECH 496, MNTC 496.
Experimental Course.

DNTC 497. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-6 Credits.

Cross-listed: APTC 497, CMTC 497, TECH 497, MNTC 497.
Workshop, short course, conference, or seminar.

DNTC 498. SEMINAR. 1-6 Credits.

Cross-listed: APTC 498, CMTC 498, TECH 498, MNTC 498.
Seminar.

DNTC 499. DIRECTED STUDY. 1-5 Credits.

Cross-listed: APTC 499, CMTC 499, TECH 499, MNTC 499.
Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.


Electrical Engineering Courses


EENG 160. DIGITAL CIRCUITS. 4 Credits.

Pre-requisites: MTHD 104 or equivalent.
Fundamentals of digital computer design including appropriate number systems, boolean algebra, and basic digital circuits. Methods introduced will include the use of Karnaugh Maps and the Quine-Mckluskey procedure. Computer laboratory work will involve the use of current software for the design, analysis, and simulation of digital circuits.

EENG 209. CIRCUIT THEORY I. 5 Credits.

Pre-requisites: PHYS 153 or permission of the instructor.
This course is intended to provide electrical engineering students with an understanding of electricity and its applications. Topics include AC/DC circuit-analysis methods such as nodal and mesh analysis, superposition, Norton Theorem, Thevenin Theorem and transient analysis.

EENG 210. CIRCUIT THEORY II. 5 Credits.

Pre-requisites: EENG 209 with a minimum grade ≥2.0.
This course covers circuit analysis using Laplace transform, phasors and AC analysis, AC Power, three-phase circuits, magnetically coupled circuits and the ideal transformer.

EENG 250. DIGITAL HARDWARE. 2 Credits.

Notes: a continuation of EENG 160.
Pre-requisites: EENG 160 with a minimum grade ≥2.0.
This course presents logic families, hardware characteristics, noise control and modern programmable logic.

EENG 260. MICROCONTROLLER SYSTEMS. 4 Credits.

Pre-requisites: CSCD 255 and EENG 160, both with a minimum grade ≥2.0.
This is an introductory course on microprocessor and microcontroller systems organization. It provides low-level programming principles for microcomputer based systems. The course emphasizes assembly and C language programming techniques and laboratory experiments in input/output programming, memory organization, interrupts and interfacing methods.

EENG 320. SIGNALS AND SYSTEMS I. 5 Credits.

Pre-requisites: EENG 210 or concurrent enrollment or permission of the instructor; MATH 163 with a minimum grade ≥2.0.
This course is an introduction to continuous-time signal analysis. Topics include: generalized functions and the relationship to basic signals including impulses, pulses and unit step; system properties such as linearity, time-invariance and causality; and Fourier analysis.

EENG 321. SIGNALS AND SYSTEMS II. 5 Credits.

Pre-requisites: EENG 320 and MATH 163, both with a minimum grade ≥2.0.
Introduction to Laplace Transform, Z-transform, the Fourier Series, the Fourier Transform, the Discrete Fourier Transform (DFT), the Discrete-Time Fourier Transform (DTFT) and Sampling Theorem. Introduction to analysis of Linear Time Invariant (LTI) system using above techniques for continuous and discrete time.

EENG 330. MICROELECTRONICS I. 5 Credits.

Pre-requisites: CHEM 151; EENG 209 and MATH 163, both with a minimum grade ≥2.0 and concurrent enrollment in EENG 210.
This course introduces the characterization, modeling, and application of semiconductor devices in the context of analog integrated circuits. Emphasis is placed on the development of models for circuit-level behavior of diodes, bipolar transistors, and MOS transistors and applies the models to the analysis and design of linear amplifiers.

EENG 331. MICROELECTRONICS II. 5 Credits.

Pre-requisites: EENG 330 and MATH 163, both with a minimum grade ≥2.0.
This course is the second in the characterization, modeling and application of semiconductor devices in the context of analog integrated circuits. The emphasis is on the metal-oxide-semiconductor (MOS) transistor. Topics include differential amplifiers, frequency response and feedback effects.

EENG 350. ENERGY SYSTEMS. 5 Credits.

Pre-requisites: EENG 210 and MATH 163, both with a minimum grade ≥2.0.
This course provides an introduction to the different energy sources, methods of electric energy conversion, the electric power system, transformers and electrical machines.

EENG 360. HARDWARE DESCRIPTION LANGUAGES. 5 Credits.

Pre-requisites: CSCD 255 and EENG 160, both with a minimum grade ≥2.0.
This course introduces methodologies and computer-aided design (CAD) tools for the design of complex electronic systems. The emphasis is on high-level description languages and their use for specifying, designing, simulating and synthesizing digital very large scale integration (VLSI) circuits in MOS (metaloxide-semiconductor) technologies. Theoretical knowledge will be complemented by hands-on use of several commercial CAD tools.

EENG 383. APPLIED STOCHASTIC PROCESSES. 4 Credits.

Pre-requisites: MATH 163 or permission of the instructor and must be taken concurrently with EENG 388.
This course provides an introduction to the basic concepts of stochastic processes and their application to engineering problems. Topics include analysis of continuous and discrete random signals and systems, as well as modern estimation techniques.

EENG 388. STOCHASTIC PROCESSES LAB. 1 Credit.

Pre-requisites: MATH 163 or permission of the instructor and must be taken concurrently with EENG 383.
This laboratory course introduces basic concepts of stochastic processes and their application to engineering problems.

EENG 401. ENGINEERING APPLIED ELECTROMAGNETICS. 5 Credits.

Pre-requisites: EENG 210, MATH 241.
This course provides students with the technical basis to analyze electromagnetic applications systems. Topics include waves and phasors, vector analysis, electrostatics, magnetostatics, Maxwell’s equations for time-varying fields and plane wave propagation.

EENG 415. INTRODUCTION TO COMPUTER COMMUNICATION NETWORKS. 5 Credits.

Pre-requisites: junior standing.
Fundamentals of data communication, telephone/cellular/computer networks, layered network architecture, OSI model, data link layer functions and protocols including ARQ, network layer functions and protocols including IP, transport layer functions and protocols including TCP. Basic MATLAB programming experience is necessary for this course.

EENG 420. DIGITAL SIGNAL PROCESSING. 5 Credits.

Pre-requisites: EENG 321.
This course provides an introduction to digital signal processing. Convolution, time invariance and stability of discrete-time systems are presented. In addition, various signal processing techniques such as Z-transform, discrete Fourier transform (DFT) and fast Fourier transform (FFT) are studied. Time and frequency domain techniques for designing and applying infinite impulse response (IIR) and finite impulse response (FIR) digital filters are introduced.

EENG 425. PRINCIPLES OF DIGITAL IMAGE PROCESSING. 5 Credits.

Pre-requisites: EENG 321.
Image representation, color spaces, image filtering and enhancement, image transforms and image/video coding.

EENG 430. CMOS DIGITAL INTEGRATED CIRCUITS DESIGN. 5 Credits.

Pre-requisites: EENG 160; EENG 331.
This course provides students with the theoretical and practical knowledge required for analyzing and designing digital integrated circuits and systems in complementary metal-oxide-semiconductor (CMOS) technology. Lab includes hands-on use of a variety of state-of-the-art computer-aided design (CAD) tools and design techniques.

EENG 435. ANALOG INTEGRATED CIRCUITS DESIGN. 5 Credits.

Pre-requisites: EENG 331.
This course provides students with the theoretical and practical knowledge required for analyzing and designing analog integrated circuits and systems in CMOS and BJT technologies. Topics include operational amplifier design, biasing and reference circuits, stability, and selected applications of analog circuits (e.g. filters, comparators, data converters, transceiver blocks).

EENG 440. DIGITAL COMMUNICATION SYSTEMS. 5 Credits.

Pre-requisites: EENG 321, EENG 383.
This course provides students with a solid background in modern digital communication systems. Random processing is applied in the realm of communication theory. Common digital modulation and demodulation techniques are presented. Other topics include bandpass transmission of binary data, coherent/noncoherent communications, intersymbol interference and equalization.

EENG 442. MOBILE COMMUNICATIONS. 5 Credits.

Pre-requisites: EENG 321 and EENG 383.
This course covers antennas and propagation, signal encoding techniques; spread spectrum, coding and error control, cellular and wireless control.

EENG 450. POWER SYSTEMS ANALYSIS. 5 Credits.

Pre-requisites: EENG 350.
The course provides students with the ability to analyze power systems from technical and economic perspectives. It includes symmetrical components, calculation of line parameters, power flow control, representation of transmission lines and power components.

EENG 452. PROTECTIVE RELAYS. 5 Credits.

Pre-requisites: EENG 450.
This course provides students with the technical basis to analyze and design protection for power systems. Topics include per unit and phasors, symmetrical components, relay input sources, protection fundamentals, system grounding principles and protection of power system components.

EENG 460. COMPUTING SYSTEMS: ORGANIZATION AND DESIGN. 5 Credits.

Pre-requisites: CSCD 255, EENG 360.
This course provides the theoretical and practical knowledge required for analyzing and designing complex computing systems. Topics include computer performance, MIPs assembly language, integer and floating point arithmetic, designing a processor, pipelining and memory hierarchies. Assembly programming and design using VHDL are offered in weekly labs.

EENG 461. EMBEDDED SYSTEM DESIGNS. 5 Credits.

Pre-requisites: EENG 160 or permission of the instructor.
This course provides students with the theoretical and practical knowledge required for analyzing and designing embedded computing systems. The key challenge of embedded systems is to optimize the various design metrics and to assess the impact that the organization and interfacing of hardware/software components have on system performance. Hands-on experience using various hardware, such as Field Programmable Gate Arrays (FPGA) and microcontrollers, will be offered in weekly labs.

EENG 470. CONTROL SYSTEMS. 5 Credits.

Pre-requisites: EENG 321.
This course reviews basic topics such as transfer function, step response and stability conditions. Other topics include feedback systems, analysis techniques such as root-locus analysis, transient and steady-state response analyses and frequency response analysis are studied. In addition, state-space analysis techniques are explained within the context of state-space system models. Analysis and design of proportional, integral, and derivative (PID), PI and PD controllers are presented.

EENG 471. DIGITAL CONTROL SYSTEMS. 5 Credits.

Pre-requisites: EENG 470.
This course provides students with the technical basis to understand and analyze digital control systems. Topics include frequency response, modeling digital control systems, steady-state error, stability, Z-domain design and state-space models. An introduction to Lyapunov techniques is presented.

EENG 490A. SR CAPSTONE: DESIGN LAB I. 2 Credits.

Pre-requisites: senior standing.
Satisfies: senior capstone university graduation requirement.
This course will simulate the industrial environment, where students will have to work in a team to solve a real world problem, from design to implementation. Team dynamics will be strictly monitored and each student’s unique skills will be utilized in different stages of the design process. Dealing with problems typical of a team environment will result in an invaluable learning experience both in the professional and civic lives of the students.

EENG 490B. SR CAPSTONE: DESIGN LAB II. 3 Credits.

Pre-requisites: EENG 490A.
Satisfies: senior capstone university graduation requirement.
See course description for EENG 490A.

EENG 491. SENIOR PROJECT. 1-6 Credits.

Pre-requisites: permission of instructor.
Independent and/or group study and implementation of a design and development project. (variable time)

EENG 495. INTERNSHIP. 1-6 Credits.

Notes: graded Pass/Fail.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean.

EENG 496. EXPERIMENTAL COURSE. 1-5 Credits.

EENG 498. SEMINAR. 1-6 Credits.

Seminar.

EENG 499. DIRECTED STUDY. 1-10 Credits.

Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.

EENG 599. INDEPENDENT STUDY. 1-5 Credits.

Independent Study.


Mechanical Engineering Courses


MENG 199. DIRECTED STUDY. 1-5 Credits.

Directed Study

MENG 201. MATLAB. 4 Credits.

Pre-requisites: MATH 141.
This course introduces the student to the application of basic MATLAB building blocks to engineering problems. Students will get a thorough introduction to data visualization, data analysis, symbolic calculations, numeric computations and other basic skills related to MATLAB.

MENG 207. ELECTRICITY. 4 Credits.

Pre-requisites: MATH 162, PHYS 153 or PHYS 133 .
This course is intended to provide students with a basic understanding of electricity and its applications. In this course, basic concepts of current, voltage and resistance will be presented as well as basic circuit-analysis methods including inductor and capacitor.

MENG 217. 3D PARAMETRIC COMPUTER AIDED DESIGN. 4 Credits.

Pre-requisites: METC 110 or High School AUTOCAD or permission of instructor
This course uses the computer to draft parametric models in three dimensions. File management methods, rapid prototyping and 2D drawing development techniques are discussed. (Four hours per week.)

MENG 240. STATICS. 4 Credits.

Pre-requisites: PHYS 151, MATH 161 or Technical Calculus I or equivalent.
Fundamentals of applied mechanics, equivalent force systems, equations of equilibrium, structures, three dimensional force systems and friction. (two hours lecture, four hours laboratory per week)

MENG 241. STRENGTH OF MATERIALS. 4 Credits.

Pre-requisites: MENG 240, MATH 162, PHYS 152 or Technical Calculus II or equivalent.
A study of the internal stresses, internal deformations and deflections of materials. Topics may include: shear and moment diagrams for beams, combined loading on beams, temperature stresses and torsional loading. (four hours lecture per week)

MENG 242. DYNAMICS. 4 Credits.

Pre-requisites: MENG 240.
Kinematics and kinetics of particles and rigid bodies using vector analysis; force mass acceleration, work and energy, impulse and momentum, translating and rotating coordinate system.

MENG 300. LABORATORY ANALYSIS AND REPORTS. 5 Credits.

Pre-requisites: PHYS 133 or PHYS 153, MATH 162; and declared into one of the following: Mechanical Engineering, Mechanical Engineering Technology, Electrical Engineering; or permission of instructor.
This course examines the different aspects of laboratory analysis and report writing. This includes description of engineering problems, analysis of data including error analysis and data interpretation, instrumentation and measurements. In addition, the application of spreadsheets for solving and analyzing engineering problems, creating technical graphs, trending and curve fitting and project management will be addressed.

MENG 353. INDUSTRIAL MATERIALS. 5 Credits.

Pre-requisites: CHEM 121 or CHEM 151.
Students in this course achieve a thorough understanding of engineering materials, their properties, responses and applications. Laboratory work includes destructive and non destructive testing and image analysis of microscopic structure of industrial materials.

MENG 380. THERMODYNAMICS. 5 Credits.

Pre-requisites: PHYS 152; MATH 162; MENG 300, may be taken concurrently; and a declared Mechanical Engineering major.
This course explores properties of materials, work, heat, conversion of energy, conservation of mass and energy transformation processes. Emphasis is on application of the first and second laws to engineering systems.

MENG 381. LABORATORY ANALYSIS AND REPORTS. 5 Credits.

Pre-requisites: PHYS 153 or PHYS 133, MATH 162.
This course examines the different aspects of laboratory analysis and report writing. This includes description of engineering problems, analysis of data including error analysis and data interpretation, instrumentation and measurements. In addition, the application of spreadsheets for solving and analyzing engineering problems, creating technical graphs, trending and curve fitting and project management will be addressed.

MENG 382. FLUID MECHANICS. 5 Credits.

Notes: laboratory work is included.
Pre-requisites: grades ≥2.0 in all of the following, PHYS 152; MATH 162; MENG 300 (may be taken concurrently); and a declared Mechanical Engineering major.
This course introduces the student to theory, concepts and applications of fluid mechanics. Topics include static and dynamic forces; conservation of mass, energy and momentum; flow in pipes and ducts; and fan and pump performance.

MENG 385. ROBOTICS AND AUTOMATION. 5 Credits.

Notes: three hours lecture, four hours laboratory per week.
Pre-requisites: grades ≥2.0 in all of the following, MENG 207 or MNTC 208; MENG 201 or CSCD 255; and a declared in Mechanical Engineering or Mechanical Engineering Technology major or permission of instructor.
This course covers various electrical and mechanical systems used in robotics and other automated industrial systems. It includes automated equipment programming and industrial planning as applied to automated systems.

MENG 386. ENGINEERING NUMERICAL ANALYSIS. 5 Credits.

Pre-requisites: PHYS 153; MATH 163; and either MENG 201 or CSCD 255; and a declared Mechanical Engineering major.
This course covers a multitude of numerical approximation methods used to solve specific structural engineering problems and highlights the algorithms used in many common scientific software packages.

MENG 398. SEMINAR. 1-5 Credits.

Seminar

MENG 399. DIRECTED STUDY. 1-5 Credits.

Pre-requisites: junior standing; declared Mechanical Engineering major and permission of the instructor, department chair and college dean.
Independent Study.

MENG 405. DESIGN OF MACHINE ELEMENTS. 5 Credits.

Pre-requisites: MATH 162, MENG 241, MENG 353, and a declared Mechanical Engineering major.
This course covers the design of machine components and mechanisms and utilizes the concepts of engineering mechanics and strength of materials.

MENG 407. HEATING, VENTILATING AND AIR CONDITIONING. 5 Credits.

Pre-requisites: PHYS 132 or PHYS 152; and a declared Mechanical Engineering or Mechanical Engineering Technology major.
The study of the principles of Heating, Ventilating and Air Conditioning (HVAC) including the investigation of the basic calculations to determine heating and cooling loads and the study of the basic equipment design for HVAC.

MENG 412. FUNDAMENTALS OF ENGINEERING. 2 Credits.

Pre-requisites: senior standing; and declared into one of the following: Mechanical Engineering, Mechanical Engineering Technology, Electrical Engineering; or permission of instructor.
This course reviews the fundamentals of engineering. It provides an overview of principles of the practice of engineering and assists students in preparation for the first steps in professional licensure.

MENG 444. HEAT TRANSFER. 5 Credits.

Pre-requisites: grades ≥2.0 in all of the following, MATH 241, MATH 347, MENG 300, MENG 382, MENG 386; and a declared Mechanical Engineering major.
This course provides a detailed calculus-based analysis of the heat transfer through solids, fluids and vacuums. Concepts include conduction, convection, and radiation heat transfer in one and two dimensions for steady and unsteady states.

MENG 452. ENGINEERING ECONOMICS. 2 Credits.

Pre-requisites: junior standing; and a declared Mechanical Engineering or Mechanical Engineering Technology major or permission of instructor.
This course focuses on the systematic evaluation of the economic benefits and costs of projects involving engineering design and analysis. Engineering economics quantifies the benefits and costs associated with engineering projects to determine whether they make (or save) enough money to warrant their capital investment.

MENG 453. MATERIALS AND DESIGN. 5 Credits.

Pre-requisites: MENG 241, MENG 353; and a declared Mechanical Engineering major.
This course expands upon the concepts covered in the Industrial Materials class. Focus is on how materials and the design of products and the processes to make them are interrelated. Students explore processing and properties of materials such as glass, ceramics, polymers and metals other than steel.

MENG 455. COMPOSITE MATERIALS. 5 Credits.

Pre-requisites: MENG 201, MENG 353; and a declared Mechanical Engineering major or permission of instructor.
This course covers basics of composite materials including manufacturing, design and applications. Students learn anisotropic and heterogeneous material systems; types of composite constituents; physical and mechanical properties; micro, macro and ply mechanics; composite design related to strength and different failure modes; and applications of composite beams, plates and stiffened panels.

MENG 482. ADVANCED FLUID DYNAMICS. 5 Credits.

Pre-requisites: grades ≥2.0 in all of the following, MATH 347, MENG 217, MENG 382; and a declared Mechanical Engineering major.
Students apply fluid principles to various technical situations and utilize advanced methods to derive a solution. Topics covered may include Computational Fluid Dynamics (CFD), turbo machinery, compressible fluid flow, turbulence, thermo-fluid system design, and fan and pump performance.

MENG 485. ADVANCED ROBOTICS AND AUTOMATION. 5 Credits.

Pre-requisites: a grade ≥3.0 in MENG 385; and a declared Mechanical Engineering or Mechanical Engineering Technology major.
A study of the various electrical and mechanical systems used in advanced robotics and other automated systems. Topics include automated equipment, programming and industrial planning as applied to automated systems, robotic vision, cooperative robotics and service robots.

MENG 486. PROGRAMMABLE LOGIC CONTROLLERS IN AUTOMATION. 5 Credits.

Pre-requisites: a grade ≥3.0 in MENG 385; and a declared major in Mechanical Engineering or Mechanical Engineering Technology.
A study of Programmable Logic Controllers used in industrial automation and advanced robotics. Course explores automated equipment, ladder logic programming and industrial planning as applied to automated systems.

MENG 487. SENSORS THEORY FOR AUTOMATION. 5 Credits.

Pre-requisites: a grade ≥3.0 in MENG 385; and a declared major in Mechanical Engineering.
This course introduces the common sensors used in robotics and automation, including the theory of how sensors work, the circuitry involved and the programming logic for input/output.

MENG 490A. SENIOR CAPSTONE: DESIGN LABORATORY I. 2 Credits.

Pre-requisites: MENG 217, MENG 241 with a grade ≥2.0, MNTC 301; and a declared Mechanical Engineering major; and senior standing.
Satisfies: senior capstone university graduation requirement.
This course simulates the industrial environment, where students work in teams to solve a real world problem from design to implementation. Team dynamics and project constraints are strictly monitored and each student’s unique skills are utilized in different stages of the design process.

MENG 490B. SENIOR CAPSTONE: DESIGN LABORATORY II. 3 Credits.

Pre-requisites: MENG 490A.
Satisfies: senior capstone university graduation requirement.
See description for MENG 490A.

MENG 491. SENIOR THESIS. 1-6 Credits.

Pre-requisites: permission of instructor.
Independent and/or group study and implementation of a design and development project. (variable time)

MENG 492. FINITE ELEMENT ANALYSIS. 5 Credits.

Pre-requisites: grades ≥2.0 in all of the following, MATH 347, MENG 217, MENG 241; and a declared Mechanical Engineering major or permission of the instructor.
This course introduces the computational methods to solve engineering problems using the finite element approach. Modeling techniques for different engineering structures such as truss, beams, frames, two and three dimensional solids, and thin-walled structures are introduced in this course. Students solve a wide variety of engineering problems dealing with statics, dynamics, fluid mechanics, heat transfer and design and material selections using the state of art FEA software.

MENG 493. SENIOR SEMINAR. 1 Credit.

Notes: graded Pass/Fail.
Pre-requisites: senior standing or permission of instructor; and a declared Mechanical Engineering or Mechanical Engineering Technology major.
This course provides the students firsthand exposure to the latest technological advances directly from the manufacturer or researcher. This helps students in their lifelong learning and provides an opportunity to inquire about particular topics or fields of interest.

MENG 495. INTERNSHIP. 1-6 Credits.

Notes: Graded Pass/Fail. A minimum of 180 hours of work is required for students to complete the internship experience. Students working part-time over multiple quarters will have the credit hours divided across quarters to match the hours worked in each quarter.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean; and declared Mechanical Engineering major.
This course gives students applied field experience working in industry. Students will apply engineering principles to solve problems under the supervision of a practicing engineer.

MENG 496. EXPERIMENTAL COURSE. 1-10 Credits.

MENG 499. DIRECTED STUDY. 1-10 Credits.

Pre-requisites: permission of the instructor, department chair and college dean; senior standing; and a declared Mechanical Engineering major.
Designed for students wanting to pursue a subject beyond the scope of regular courses.


Mechanical Engineering Technology Courses


METC 102. INTRODUCTION TO ENGINEERING GRAPHICS. 4 Credits.

Notes: graded Pass/Fail.
This course offers an introduction to the fundamentals of technical drawing. It emphasizes the technical methods used to describe the size and shape of objects. This course will not satisfy elective requirements for a major or minor in Technology.

METC 110. ENGINEERING GRAPHICS. 5 Credits.

Pre-requisites: METC 102, two years of high school drafting or equivalent.
A study of the technical portion of the graphics language. This language, technical drawing, is used by engineers to communicate proposed designs and new ideas. Includes the theory and practice of descriptive geometry and the graphic representation of data.

METC 340. STATICS. 5 Credits.

Pre-requisites: PHYS 131 and MATH 142 or equivalent.
A study of applied mechanics and the principles of statics dealing with forces and with the effects of forces acting upon rigid bodies at rest. (four hours lecture per week)

METC 341. STRENGTH OF MATERIALS. 4 Credits.

Pre-requisites: METC 340.
A study of the relationship that exists between externally applied forces and internally induced stresses in members and parts, including the relationship existing between these same externally applied forces and the resulting deformations. (four hours lecture per week)

METC 342. DYNAMICS. 4 Credits.

Pre-requisites: METC 340 and MATH 162.
This course is a study of the motion of rigid bodies and forces affecting their motion. Topics include kinematics and kinetic of motion, curvilinear motion, plane motion, work, energy and power, impulse and momentum. (four hours lecture per week)

METC 384. ENERGY MANAGEMENT AND UTILIZATION. 5 Credits.

Pre-requisites: MENG 380.
The study of energy usage and energy management within industrial facilities. The development of Energy audit procedures including the energy saving calculations for industrial settings. Students will develop and explore the creation of industrial energy audits through the extensive use of case studies.

METC 387. FLUID MECHANICS. 5 Credits.

Notes: laboratory work is included.
Pre-requisites: grades ≥2.0 in all of the following, PHYS 132 or PHYS 152, MATH 162; TCOM 205 or MENG 300 (may be taken concurrently); and a declared Mechanical Engineering Technology major.
This course introduces the student to theory, concepts and applications of fluid mechanics. Topics include static and dynamic forces; conservation of mass, energy and momentum; flow in pipes and ducts; and fan and pump performance.

METC 388. THERMODYNAMICS AND HEAT TRANSFER. 5 Credits.

Pre-requisites: PHYS 132 or PHYS 152; MATH 162; TCOM 205 or MENG 300 (may be taken concurrently); and a declared Mechanical Engineering Technology major.
This course introduces the student to theory, concepts and applications of thermodynamics and heat transfer. Topics include properties of materials, work, heat, conservation of mass and energy, energy transformation processes, and heat transfer via conduction, convection and radiation.

METC 415. DESIGN OF MACHINE ELEMENTS. 5 Credits.

Pre-requisites: METC 341, MENG 353, MATH 162 or permission of instructor, and a declared Mechanical Engineering Technology major.
This course covers the design of machine components and mechanisms and utilizes the concepts of engineering mechanics and strength of materials.

METC 417. ADVANCED PARAMETRIC DESIGN. 5 Credits.

Pre-requisites: MENG 217; MATH 162; METC 341 or MENG 241; and a declared Mechanical Engineering or Mechanical Engineering Technology major.
Advanced techniques and best practices for parametric design of parts and assemblies. These advanced methodologies include design simulation and analysis including stress analysis, thermal analysis, flow analysis, vibration and motion studies, and design optimization.

METC 456. ENGINEERING ETHICS, CONTRACTS AND PATENTS. 2 Credits.

Pre-requisites: junior standing and a declared Mechanical Engineering or Mechanical Engineering Technology major or permission of instructor.
This course investigates the elements of professional engineering practice including their relationship to the law, to the public and the ethics of the profession. Topics covered range from ethics, contracts, patents, copyrights, sales agreements and engineering specifications to professionalism, licensing, intellectual property, liability, risk, reliability and safety. Further discussion areas involve interdisciplinary teams, team tools, codes, standards, professional organizations, careers, entrepreneurship, human factors and industrial design.

METC 468. QUALITY ASSURANCE AND INTRO TO LEAN. 5 Credits.

Pre-requisites: PHYS 132 or PHYS 152; MATH 162; MENG 300, may be taken concurrently; and a declared Mechanical Engineering or Mechanical Engineering Technology major.
Application and theory of quality control and continuous improvement systems. This includes statistical analysis, design of experiments, development and use of process control charts, sampling processes, time and motion studies, and introduction to other Lean tools.

METC 490A. SENIOR CAPSTONE: DESIGN LABORATORY I. 2 Credits.

Pre-requisites: MENG 217, MATH 162, METC 341 (may be taken concurrently), TECH 301 and senior standing. Must be a declared Mechanical Engineering Technology major.
Satisfies: senior capstone university graduation requirement.
This course simulates the industrial environment, where students work in teams to solve a real world problem from design to implementation. Team dynamics and project constraints are strictly monitored and each student’s unique skills are utilized in different stages of the design process.

METC 490B. SENIOR CAPSTONE: DESIGN LABORATORY II. 3 Credits.

Pre-requisites: METC 490A. Must be a declared Mechanical Engineering Technology major.
Satisfies: senior capstone university graduation requirement.
See description for METC 490A.

METC 491. SENIOR PROJECT. 1-10 Credits.

Pre-requisites: senior standing, a declared Mechanical Engineering Technology majorand permission of the instructor and chair.
Independent and/or group study and implementation of a design and development project. (variable time).

METC 495. INTERNSHIP. 1-15 Credits.

Notes: Graded Pass/Fail.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean and a declared Mechanical Engineering Technology major.
A maximum of 5 credits may be earned toward electives for a Technology major. Students considering electives for a Technology minor should consult with their departmental advisor. This course gives students applied field experience working in industry. Students will apply engineering principles to solve problems under the supervision of a practicing engineer. A minimum of 180 hours of work is required for students to complete the internship experience. Students working part-time over multiple quarters will have the credit hours divided across quarters to match the hours worked in each quarter.

METC 499. DIRECTED STUDY. 1-5 Credits.

Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.


Manufacturing Technology Courses  


MNTC 208. SURVEY OF ELECTRICITY. 4 Credits.

Pre-requisites: pre-university basic skills in mathematics.
Introduces the student to direct current, alternating current (including residential wiring), and amplifying devices. (3 hours lecture, 2 hours laboratory per week)

MNTC 301. METALLIC PROCESSES. 5 Credits.

Pre-requisites: junior standing or permission of instructor.
Metallic Processes is a comprehensive basic course in technical metals which is designed to survey metalworking materials and processes which have been developed by modern industry. The course provides opportunity to learn the theories and scientific principles basic to the application of metalworking tools and procedures.

MNTC 320. NON-METALLIC PROCESSES. 5 Credits.

Pre-requisites: METC 110; junior/senior status or permission of instructor.
Survey of non-metallic materials (such as woods, plastics, and ceramics) and the industrial processes utilized to convert raw materials into finished products. Course includes characteristics and properties of non-metallic materials and utilization of industrial tools and processing equipment.

MNTC 402. MACHINE TOOL I. 5 Credits.

Pre-requisites: METC 110 and MNTC 301.
A comprehensive course in machine tool operations, both conventional and CNC. Course includes cutting operations, precision measurement, set up, and CNC programming. (3 hours lecture, 4 hours laboratory per week).

MNTC 404. COMPUTER NUMERICAL CONTROL. 5 Credits.

Pre-requisites: MNTC 301 and MNTC 402.
This course provides the learner with experience utilizing CNC processes. Programming methods will include manual, CAM software and conversational languages.

MNTC 406. WELDING TECHNOLOGY. 4 Credits.

Pre-requisites: MNTC 301 or permission of the instructor.
Theory and practice of welding ferrous and non-ferrous metals. Practice in oxyacetylene, shielded metal arc and inert gas processes. (4 hours lecture, 4 hours laboratory per week).

MNTC 430. MACHINE TOOL II. 5 Credits.

Pre-requisites: MNTC 301 and MNTC 402.
Application and theory in the design, development and function of tooling, dies, molds, jigs, and fixtures. Laboratory experiences provide a problem solving approach to development of prototypes in both unit and mass production applications. (5 hours lecture, 4 hours laboratory per week).

MNTC 439. TOPICS IN MANUFACTURING. 5 Credits.

Notes: an authorized elective substitution for MNTC 495.
Pre-requisites: senior standing or permission of instructor.
This course explores topics in manufacturing that are beyond the scope of the regular program course curriculum. It allows for a more in-depth coverage through lecture, discussion, and explorations of the manufacturing world as students prepare to enter the work force.

MNTC 490. SENIOR CAPSTONE: PRODUCTION LAB. 4 Credits.

Cross-listed: APTC 490, CMTC 490, DNTC 490, TECH 490.
Pre-requisites: senior standing.
Satisfies: senior capstone university graduation requirement.
The course simulates the real world situation that many of the graduates from the department will face. The students will work in teams to apply techniques of production management, product design/development, plant layout, scheduling, cost accounting, assembly, inspection and quality control to produce a product. The course will simulate a real world design team concept by utilizing a design group that contains members of different program majors. The team, to accomplish its goals, is required to draw on each other's unique skills learned in stated goal. In industry often a design team is formed to develop a new product. The team is made up of members from different departments in the company. Learning to deal with the team dynamics while learning to take advantage of the synergy that can be gained by a diverse team is a valuable learning process for our business as well as civic life. Each student team is to produce a new product (to be massed produced and demonstrated by producing a minimum quantity of 25 units built with unskilled labor utilizing jigs, fixtures and/or CNC controlled machines) and create a final written report to demonstrate how the process and goals of the course have been realized.

MNTC 491. SENIOR PROJECT. 3-10 Credits.

Cross-listed: APTC 491, CMTC 491, DNTC 491, TECH 491.
Pre-requisites: permission of the instructor.
Independent and/or group study and implementation of a design and development project. (variable time).

MNTC 495. INTERNSHIP. 1-15 Credits.

Cross-listed: APTC 495, CMTC 495, DNTC 495, TECH 495.
Notes: Graded Pass/Fail. This course may be repeated.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean.
A maximum of 5 credits may be earned toward electives for a Technology major. Students considering electives for a Technology minor should consult with their departmental advisor.

MNTC 496. EXPERIMENTAL COURSE. 1-6 Credits.

Cross-listed: APTC 496, CMTC 496, DNTC 496, TECH 496.
Experimental Course.

MNTC 497. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-6 Credits.

Cross-listed: APTC 497, CMTC 497, DNTC 497, TECH 497.
Workshop, short course, conference, or seminar.

MNTC 498. SEMINAR. 1-6 Credits.

Cross-listed: APTC 498, CMTC 498, DNTC 498, TECH 498.
Seminar.

MNTC 499. DIRECTED STUDY. 1-5 Credits.

Cross-listed: APTC 499, CMTC 499, DNTC 499, TECH 499.
Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.


Technology Courses


TECH 102. INTRODUCTION TO ENGINEERING GRAPHICS. 4 Credits.

Notes: graded Pass/Fail.
This course offers an introduction to the fundamentals of technical drawing. It emphasizes the technical methods used to describe the size and shape of objects. This course will not satisfy elective requirements for a major or minor in Technology.

TECH 110. ENGINEERING GRAPHICS. 5 Credits.

Pre-requisites: METC 102 or TECH 102, two years of high school drafting, or equivalent.
A study of the technical portion of the graphics language. This language, technical drawing, is used by engineers to communicate proposed designs and new ideas. Includes the theory and practice of descriptive geometry and the graphic representation of data.

TECH 197. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-5 Credits.

TECH 199. DIRECTED STUDY. 1-5 Credits.

TECH 217. 3D PARAMETRIC COMPUTER AIDED DESIGN. 4 Credits.

Pre-requisites: METC 110 or TECH 110, or High School AUTOCAD, or permission of instructor.
This course uses the computer to draft parametric models in three dimensions. File management methods, rapid prototyping and 2D drawing development techniques are discussed. (Four hours per week.)

TECH 297. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-5 Credits.

TECH 298. SEMINAR. 1-5 Credits.

TECH 330. TECHNOLOGY PROBLEM ANALYSIS AND DESIGN I. 4 Credits.

Pre-requisites: junior standing or permission of the instructor.
Development of advanced skills in technical problem analysis, planning, research, solution strategies, critical thinking and presentation. Computer-aided design tools such as CAD, project-planning software, spreadsheets, as well as imaging and publishing software are used. Emphasis is on consideration of interconnected systems.

TECH 331. TECHNOLOGY PROBLEM ANALYSIS AND DESIGN II. 4 Credits.

Pre-requisites: TECH 330.
Development of student's synthesis, design, organizational, and learning skills through examination of current research and/or design topics in Technology.

TECH 393. TECHNOLOGY WORLD CIVILIZATION. 4 Credits.

Cross-listed: HONS 393.
Pre-requisites: ENGL 101.
Satisfies: international studies university graduation requirement.
Students will investigate the issues surrounding technological change in discrete cultural settings with a historical perspective of the evolution of technology in a global context.

TECH 395. CO-OP FIELDWORK. 1-5 Credits.

TECH 396. EXPERIMENTAL COURSE. 1-6 Credits.

TECH 397. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-5 Credits.

TECH 398. SEMINAR. 4 Credits.

TECH 403. COMPUTER-AIDED DESIGN AND PROJECT MANAGEMENT. 4 Credits.

Pre-requisites: MATH 107 or permission of the instructor.
The application of spreadsheets to solve engineering problems, technical graphs, trending and curve fitting. The introduction to the use of computer-aided scheduling of projects, critical path planning, project tracking and cost collection.

TECH 452. ENGINEERING ECONOMICS. 4 Credits.

Pre-requisites: junior standing or permission of instructor.
This course focuses on the systematic evaluation of the economic benefits and costs of projects involving engineering design and analysis. Engineering economics quantifies the benefits and costs associated with engineering projects to determine whether they make (or save) enough money to warrant their capital investment.

TECH 454. ENVIRONMENTAL ENGINEERING. 4 Credits.

Pre-requisites: junior standing or permission of the instructor.
This course explores ways to promote the design and manufacturing of environmentally sound products and processes. Benefits include environmentally-friendly products, more efficient operations and the good will of an informed public that expects a clean, healthy environment.

TECH 456. ENGINEERING ETHICS, CONTRACTS AND PATENTS. 4 Credits.

Pre-requisites: junior standing or permission of instructor.
This course investigates the elements of professional engineering practice including their relationship to the law, to the public and the ethics of the profession. Topics covered range from ethics, contracts, patents, copyrights, sales agreements and engineering specifications to professionalism, licensing, intellectual property, liability, risk, reliability and safety.

TECH 458. QUALITY ASSURANCE. 4 Credits.

Pre-requisites: junior standing.
Application and theory of quality control systems including development and use of process control charts, sampling, time and motion studies, and statistical analysis. (4 hours lecture, 1 hour laboratory per week)

TECH 462. INDUSTRIAL SAFETY ENGINEERING. 4 Credits.

Fundamentals of safety, classification of hazards, accident statistics, organization problems, safety codes, machine guarding, mechanical, electrical and chemical hazards, ventilation, respiratory and safety devices. (4 hours lecture per week)

TECH 490. SENIOR CAPSTONE: PRODUCTION LAB. 4 Credits.

Cross-listed: APTC 490, CMTC 490, DNTC 490, MNTC 490.
Pre-requisites: senior standing.
Satisfies: senior capstone university graduation requirement.
The course simulates the real world situation that many of the graduates from the department will face. The students will work in teams to apply techniques of production management, product design/development, plant layout, scheduling, cost accounting, assembly, inspection and quality control to produce a product. The course will simulate a real world design team concept by utilizing a design group that contains members of different program majors. The team, to accomplish its goals, is required to draw on each other's unique skills learned in stated goal. In industry often a design team is formed to develop a new product. The team is made up of members from different departments in the company. Learning to deal with the team dynamics while learning to take advantage of the synergy that can be gained by a diverse team is a valuable learning process for our business as well as civic life. Each student team is to produce a new product (to be massed produced and demonstrated by producing a minimum quantity of 25 units built with unskilled labor utilizing jigs, fixtures and/or CNC controlled machines) and create a final written report to demonstrate how the process and goals of the course have been realized.

TECH 491. SENIOR PROJECT. 3-10 Credits.

Cross-listed: APTC 491, CMTC 491, DNTC 491, MNTC 491.
Pre-requisites: permission of the instructor.
Independent and/or group study and implementation of a design and development project. (variable time).

TECH 495. INTERNSHIP. 1-15 Credits.

Cross-listed: APTC 495, CMTC 495, DNTC 495, MNTC 495.
Notes: Graded Pass/Fail. This course may be repeated.
Pre-requisites: junior or senior status and permission of the instructor, department chair and dean.
A maximum of 5 credits may be earned toward electives for a Technology major. Students considering electives for a Technology minor should consult with their departmental advisor.

TECH 496. EXPERIMENTAL COURSE. 1-6 Credits.

Cross-listed: APTC 496, CMTC 496, DNTC 496, MNTC 496.
Experimental Course.

TECH 497. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-6 Credits.

Cross-listed: APTC 497, CMTC 497, DNTC 497, MNTC 497.
Workshop, short course, conference, or seminar.

TECH 498. SEMINAR. 1-6 Credits.

Cross-listed: APTC 498, CMTC 498, DNTC 498, MNTC 498.
Seminar.

TECH 499. DIRECTED STUDY. 1-5 Credits.

Cross-listed: APTC 499, CMTC 499, DNTC 499, MNTC 499.
Pre-requisites: permission of the instructor, department chair and college dean.
Designed for students wanting to pursue a subject beyond the scope of regular courses.

TECH 539. SPECIAL STUDIES TECHNOLOGY. 1-5 Credits.

TECH 595. INTERNSHIP. 1-5 Credits.

TECH 596. EXPERIMENTAL COURSE. 1-6 Credits.

TECH 597. WORKSHOP, SHORT COURSE, CONFERENCE, SEMINAR. 1-6 Credits.

Notes: only one workshop course for up to 3 credits may be used to fulfill graduate degree requirements.

TECH 598. SEMINAR. 1-6 Credits.

TECH 599. INDEPENDENT STUDY. 1-6 Credits.

Notes: may be repeated within the 6 credits allowed to fulfill the student’s goals and needs in specific areas.
Pre-requisites: permission of the instructor, department chair and college dean.

TECH 600. THESIS. 2-6 Credits.

Pre-requisites: permission of the instructor, department chair and college dean.
Independent research study under the direction of a graduate adviser committee.

TECH 601. RESEARCH REPORT. 2-6 Credits.

TECH 695. INTERNSHIP. 1-6 Credits.

Pre-requisites: permission of the instructor, department chair and college dean.

TECH 696. COLLEGE TEACHING INTERNSHIP. 1-5 Credits.

Pre-requisites: permission of the instructor, department chair and college dean.
Teaching a lower-division college course under supervision of a regular faculty member. Includes course planning, arranging bibliographical and instructional aids, conferences with students, experience in classroom instruction and student course evaluation.