 Programs:
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COURSE DESCRIPTIONSA total of 192 quarter hours of course credit is required for the B.E.T degree, and normally 96 quarter credit hours of the program may be transferred from a community and/or technical college. (Additional transfer credit for approved upper division courses and courses that satisfy the university core curriculum may be applied over the 96 credit limit.) The overall minimum distributional requirements for the B.E.T. degree are (quarter hours):
The balance of credits is made up of approved technical courses in the major and technical electives.
Mail questions and inquiries to mniamat@uoft02.utoledo.edu
ENGINEERING TECHNOLOGY COREBET 301 APPLIED STATISTICS AND PROBABILITY. 4 hours. Prerequistite: associate degree in engineering technology. Introduction to applied probability and statistical inference. Topics include population parameters, sampling, estimating population means and proportions testing hypothesis, and linear regression. The MINITAB computer program is also utilized. Four hours lecture. (Fall, D/N; Spring and Summer, N) ETC:301BET 302 APPLIED ANALYSIS. 4 hours. Prerequisite: TSTM 246. Introduction to partial derivatives, series expansions, differential equations and Laplace transform analysis. Emphasis on interpretation of basic concepts and their application to the solution of simplified problems in electrical and mechanical technologies. Application of computers for numerical solution techniques. Four hours lecture. (Fall, D/N; Spring and Summer, N) ETC:302 BET 304 MATERIALS SCIENCE. 5 hours. Prerequisite: CHEM 104. Relationships between structure and properties of common engineering materials including metals, polymers, cermaics, and composites. Mechanical behavior, temperature effects, heat treatment and corrosion will be covered. No credit unless both the lecture and laboratory sections are completed satisfactorily. Four hours lecture and two hours lab. (Winter, D/N; Spring, N; Summer, N) ETC:304 BET 305 THERMODYNAMICS. 4 hours. Prerequisite: TSTM 246. Fundamentals of classical thermodynamics. Basic principles and definitions, energy concepts, the first and second law of thermodynamics, entropy, availability, processes and cycles for ideal and non ideal substances. Emphasis on application of basic principles to solution of simplified problems in mechanical technology. Four hours lecture. (Winter, D/N; Spring, N) ETC:305 BET 310 APPLIED ENGINEERING MECHANICS I: STATICS. 4 hours. Prerequisites: TSPS 101, TSTM 246. A review and extension of static force analysis: freebody diagrams, forces, moments, dry friction, and static equilibrium applied to machines, mechanisms, trusses and frames. Utilization of computers for instruction and problem solving. Four hours lecture. (Fall, D/N; Spring, D/N; Summer, N) ETC:310 BET 403 DESIGN AND ANALYSIS OF EXPERIMENTS. 4 hours. Prerequisites: ETC 301, ETC 302. Introduction to theories of experimentation including experimental error and uncertainty propagation, instrument response, test sequence and experemental plans, data checking and rejection, and graphical and mathematical data analyses. Emphasis on fundamental concepts of experimental planning, techniques and computer data analysis, as opposed to detailed descriptions of instruments and experiments. Four hours le�cture (Fall, D/N; Spring, N) ETC:403 BET 480 SENIOR CAPSTONE PROJECT. 4 hours. Prerequisites: Senior standing and consent of instructor. The senior capstone course is a course that represents the student's academic capstone. A comprehensive problem in engineering technology is assigned to a group of students that work together as a team to present a solution in a written and oral report. The course is conducted over two consecutive quarters. During the first quarter, the class meets as a group to study the process of creative proble�m solving and design. Speakers from industry present real-world topics and procedures. Each team is assigned a problem during the first quarter and continue to work independently to arrive at a solution during the second quarter. (Fall, N; Winter, N) ETC:480 BET 490 SPECIAL TOPICS IN ENGINEERING TECHNOLOGY. 2, 3, and 4 hours. Selected subjects in engineering technology with intensive investigation of recent literature in a few areas of special interest. May be repeated for credit. (Spring, D/N) ETC:490
CONSTRUCTION ENGINEERING TECHNOLOGY (CON)CET 312 ADVANCED CONSTRUCTION MATERIALS FOR CONSTRUCTION TECHNOLOGISTS. 4 hours. Prerequisites: CVLT 211, CHEM 104. Verification, through testing, of principles learned in strength of materials and basic structural design. Including stress strain relationship, axial stresses, bending stresses, column behavior and combined stresses. Also preparation and testing of several different types of mix designs in concrete and asphalt concrete. Other masonry materials will be introduced. Three hours lectur�e and two hours lab. (Fall, N) CON:312CET 322 CONSTRUCTION METHODS AND OPERATIONS FOR CONSTRUCTION TECHNOLOGISTS. 3 hours. Prerequisite: Associate degree in civil engineering technology or equivalent. Topics include equipment selection and use, concrete and asphalt placing and handling, formwork, scaffolding, falsework, special construction techniques, dewatering cofferdams, tunneling, and related architectural materials. Three hours lecture. (Fall, N) CON:322 CET 412 COST AND QUANTITY ESTIMATING FOR TECHNOLOGY. 5 hours. Prerequisites: ACCT 290, CON 322. Preparation and analysis of a material, equipment, labor warranty and cost estimate from working drawings. Completed estimates will include exterior and interior work, heavy construction, mechanical and electrical work, special trades, indirect and direct cost, and profit. Use of nationally accepted computerized cost data bank. Five hours lecture. (Winter, N) CON:412 CET 422 - CONTRACTS AND SPECIFICATIONS. 3 hours. Prerequisites: Senior standing and approval of instructor. Engineering relations, ethics, contract documents; specifications and their composition; elements necessary to a valid contract. Three hours lecture. (Winter, N) CON:422 CET 432 CONSTRUCTION CONTROL FOR TECHNOLOGY. 4 hours. Prerequisite: MET 412. Topics include job start up, scheduling (pre construction operations, CPM and PERT), inspection and supervision (methods, responsibilities and risk), disputes and claims, job closeout, liens and job relationships. Four hours lecture. (Spring, N) CON:432
ELECTRONICS ENGINEERING TECHNOLOGY (EET)EET 355 DIGITAL CIRCUIT DESIGN I. 4 hours. Prerequisites: ELET 221, ETC 302. Analysis and design of combinational logic circuits. Topics include top down design process for gate level implementation, obtaining realizable logic diagrams using SSI devices, and implementing logic functions using MSI and programmable devices including PROM, PAL, PLA, and FPGA. Three hours lecture and two hours lab. (Winter, N; Spring, N) EET:355EET 365 ADVANCED NETWORK ANALYSIS I. 4 hours. Prerequisites: ELET 113, ETC 302. Basic circuit analysis techniques, waveform analysis, first order time domain circuits, Laplace transform techniques and a circuit analysis by Laplace transforms. Four hours lecture. (Fall, N; Winter, N) EET:365 EET 375 DIGITAL CIRCUIT DESIGN II. 4 hours. Prerequisite: EET 355. A course covering the desing, analysis, and applications of synchronous and asynchronous sequential logic circuits. Topics include bistable memory devices. Moore, Mealy, and mixed type synchronous state machines, synchronous counter design, design of synchronous state machines using programmable devices, asynchronous design fundamentals, and asynchronous sequential design of fundamental and pulse mode circuits. Three hours lecture �and two hours laboratory. (Fall and Spring, N) EET:375 EET 385 ADVANCED NETWORK ANALYSIS II. 3 hours. Prerequisite: EET 365. Transfer functions, frequency response plots. Fourier analysis, discrete time systems and Z transforms. Three hours lecture. (Winter, N; Spring, N) EET:385 EET 405 AUTOMATIC CONTROL AND INSTRUMENTATION. 5 hours. Prerequisite: EET 385, EET:415 (Corequisite). Continuous control which includes: implications of controlling first and second order systems, proportional- integral derivative (PID) control schemes, system stability and time response, and compensating methods, discrete sampling, discrete PID control schemes, Z plane discrete system stability, digital filters and frequency response of discrete functions. Four hours lecture and two hours lab. (Fall, N; Spring, N) EET:405 EET 415 ADVANCED ELECTRONIC CIRCUITS I. 4 hours. Prerequisites: ELET 213, EET 385, EET 405 (Corequisite). The design and analyses of small signal and power amplifiers using computer aided engineering techniques. Three hours lecture and two hours lab. (Fall, N; Winter, N) EET:415 EET 425 ELECTRIC POWER SYSTEMS. 4 hours. Prerequisites: ELET 113 or MET 320. An applied study of AC DC machines including transformers, power transmission, and the regulations governing them as specified by industry and the National Electrical Code. Three hours lecture and two hours laboratory. (Fall, N; Winter, N) EET:425 EET 435 ADVANCED ELECTRONIC CIRCUITS II. 4 hours. Prerequisite: EET 415. Topics include: differential amplifiers, practical operational amplifiers, feedback and stability in amplifier design in both discrete and operational amplifiers, and the design of Butterworth and Chebyshev active filters using op amps. Three hours lecture and two hours lab. (Winter, N; Spring, N) EET:435 EET 455 ELECTRICAL TRANSMISSION LINES. 5 hours. Prerequisite: EET 365. An introduction to traveling waves on guided structures. Topics include transmission lines, Smith charts, impedance matching, waveguides and antennas. Five hours lecture. (Fall, N) EET:455 EET 465 ADVANCED MICROPROCESSORS. 4 hours. Prerequisite: EET 375. Design of microprocessor systems and peripheral interfacing. Topics include microprocessor architecture and operation, system buses, CPU inteface and memory system design, interrupts, DMA, memory management mechanisms, serial I/O transmission, display and keyboard interfacing, and recent developments. Three hours lecture and two hours lab. (Spring, N) EET:465 EET 475 ADVANCED PROGRAMMABLE LOGIC CONTROLS. 4 hours. Prerequisite: EET 385. A study of programmable controller programming and applications with an emphasis on manufacturing. Sequential control of devices is covered along with process control using PID control loops. Three hours lecture and two hours lab. (Winter, N). EET:475
MECHANICAL ENGINEERING TECHNOLOGY (MET)MET 320 CIRCUIT ANALYSIS FOR MECHANICAL TECHNOLOGISTS. 5 hours. Prerequisite: TSTM:246. The study of AC and DC circuits, and circuit analysis. No credit unless both the lecture and laboratory sections are completed satisfactorily. Four hours lecture and two hours lab. (Fall, D/N; Winter, N) MET:320MET 330 APPLIED ENGINEERING MECHANICS II: DYNAMICS. 4 hours. Prerequisites: ETC 302, ETC 310. Dynamic force analysis: kinematics, force and acceleration, work and energy, and impulse and momentum methods applied to particles and rigid bodies. Emphasis on application of basic principles to solution of simplified problems in mechanical technology. Utilization of computers for instruction and problem solving. Four hours lecture. (Winter D/N; Spring, N) MET 340 ELECTRONICS FOR MECHANICAL TECHNOLOGISTS. 5 hours. Prerequisite: MET 320. Characteristics and applications of electronic devices including amplifiers and digital circuits. No credit unless both the lecture and laboratory sections are completed satisfactorily. Four hours lecture and three hours laboratory. (Winter, D/N; Spring, N) MET:340 MET 350 MECHANICAL DESIGN I FOR TECHNOLOGY. 4 hours. Prerequisites: ETC 304, MET 330. Applied stress and deflection analysis in mechanical design considering the factors of combined stresses and strains, stress concentrations, failure theories and fatigue. Design catagories include beams, columns, springs, and shafts. Computer programs will be employed for numerical solution techniques. Four hours lecture (Spring, D/N) MET:350 MET 360 ENGINEERING SAFETY. 4 hours. Prerequisite: Junior standing. The application of engineering skills to meet the Occupational Safety and Health requirements, including accident investigation, the handling of dangerous materials and job safety analysis procedures. Four hours lecture. (Fall and Spring, N) 490:307 MET 380 COMPUTER AIDED DESIGN I. 4 hours. Prerequisites: DRTD 102, DRTD 201. An introduction to the fundamentals of the AutoCAD computer aided design system, with the UNIX operating system. Will use commands leading to geometric construction of 2D drawings. Two hours lecture and two hours supervised lab. (Winter, N) MET:380 MET 390 COMPUTER AIDED DESIGN II. 4 hours. Prerequisites: MET 380 and consent of instructor. The advanced study of AutoCAD computer aided design systems with the Unix operating system environment. 3D wire frame models leading to part design and model preparations for finite element analysis, surfacing libraries, attributes, associative dimensioning, script, macro programs, w slide, v slide, elevation, hatch, v point, hide and custom menus. Two hours lecture and two hours supervised laboratory. (Sp�ring, N) MET:390 MET 400 APPLIED FLUID MECHANICS. 4 hours. Prerequisites: ETC 302, ETC 305. Fundamentals of fluid statics and dynamics. Basic fluid flow equations. Viscous flow in pipes and channels. Elements of compressible flow. Applications to flow measurements, flow in conduits, and turbomachinery. Use of CFD software for problem solving. Four hours lecture. (Winter D/N) MET:400 MET 410 PRODUCTION DESIGN & PROCESSING. 4 hours. Prerequisites: ETC 304, INDT 111 or equivalent. Design considerations for parts or products related to production feasibility, methods, volume, tooling and cost. Determination of production steps, including the preparation of route sheets for various parts. Four hours lecture. (Winter, N) MET:410 MET 420 TOOLING CONCEPTS & METHODOLOGY. 4 hours. Prerequisite: MET 410. An advanced course in the principles and design of special tooling, jigs, fixtures, dies and molds based upon considerations of methods, materials volume and cost. Projects in tooling design, production and inspection. Four hours lecture. (Spring, N) MET:420 MET 430 QUALITY CONTROL. 4 hours. Prerequisites: ETC 301, ETC302. An introduction to statistical quality control. Topics include sampling, statistical inference, control charts, specifications and tolerances and acceptance sampling by attributes and variables. Four hours lecture. (Spring, N) MET:430 MET 440 CONTROL SYSTEMS FOR MECHANICAL TECHNOLOGISTS. 5 hours. Prerequisite: MET 340. An introduction to fundamental control system language, with emphasis on sensors, signal conditioning and instrument characteristics. Includes an entry level for design, selection and specification of continuous process control systems. Also first and second order lag time, dead time and integrals will be studied. No credit unless both the lecture and laboratory sections are completed satisfactorily. Four hours �lecture and two hours laboratory. (Fall, D/N; Spring, N) MET:360. MET 450 MECHANICAL DESIGN II FOR TECHNOLOGY. 4 hours. Prerequisite: MET 350. Design and application of mechanical components and machine elements including bearings, gears, fasteners, clutches and brakes, and belt drives. Application of standard components and conventional designs will be studied. Computer programs will be employed for numerical solution techniques. Four hours lecture. (Fall, D/N) MET:450 MET 460 APPLIED ENERGY CONVERSION FOR TECHNOLOGY. 4 hours. Prerequisite: MET 305. Fundamentals of applied thermodynamics: gas compressors, adiabatic efficiencies of steady flow devices, gas and vapor power cycles, refrigeration and heat pump cycles, air conditioning processes, and nozzles. Emphasis on application of basic principles to simplified problems in mechanical technology. Four hours lecture. (Winter, D/N; Spring, N) MET:460 MET 470 HEAT TRANSFER FOR TECHNOLOGY. 4 hours. Prerequisites: ETC 302, ETC 305, MET 400. Fundamentals of applied heat transfer by steady and transient conduction, laminar and turbulent convection, and radiation exchange between surfaces. Emphasis on physical interpretation of problems and engineering solutions from analytical, empirical and numerical approaches. Three hours lecture and two hours laboratory. (Spring, N) MET:470
Mail questions and inquiries to mniamet@uoft02.utoledo.edu |
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