CS 290 INTRODUCTION TO FORTRAN PROGRAMMING (2)
MATH 206. Elementary computer programming using FORTRAN language. Lecture 1 hour, laboratory 3 hours. no credit toward Computer Science major.
CHEM 101 GENERAL CHEMISTRY I (5)
High school chemistry and physics; two years of high school algebra; satisfactory performance on mathematics placement examination given during registration period. Physical concepts, stoichiometry, structure of atom, periodic table, chemical bonding.
Lecture 3 hours, recitation 1 hour, laboratory 3 hours.
ENGR 100 INTRODUCTION TO ENGINEERING (1)
Introduction to profession of engineering; ethical and legal aspects of engineering profession; engineering design process; communication and computer skills in engineering. Laboratory 3 hours. Graded CR/NC.
ENGR 103 DESIGN GRAPHICS
MATH 103; one year high school mechanical drawing or TECH 110. Role of engineering, work of engineering, design process; problem identification, analysis of design data, pictorial presentation, design problems; spatial relationships, empirical equations, nomography. Lecture 2 hours, laboratory 3 hours.
ENGR 201 STATICS (4)
MATH 207, PHYS 201. Fundamental principles of statics, resolution and composition of forces, algebraic and graphic solution, friction, center of gravity, moment of inertia.
ENGR 204 CIRCUIT ANALYSIS I (4)
MATH 208, PHYS 203. Electric circuit analysis, transient and steady state; and introduction to frequency response.
ENGR 205 STRENGTH OF MATERIAL I (4)
ENGR 201. Stresses and strains under axial, sharing, and torsional forces; flexural stresses and deflections of simple beams; columns; and combined stresses.
ENGR 207 MATERIAL SCIENCE AND ENGINEERING (4)
CHEM 101, MATH 206, PHYS 201. Understanding structure and fundamentals of atomic and molecular mechanisms of engineering materials, atom and electron movement, physical and mechanical properties; overview of engineering materials, semiconductors, metals, ceramics, polymers, and composites.
ENGR 210 MATRIX ALGEBRA FOR ENGINEERS (2)
MATH 208, PHYS 201. Introduction to calculations using vectors; matrix operation, solution of linear simultaneous equations; coordinate transformation; application to engineering problems.
ENGR 211 STATISTICS AND PROBABILITY FOR ENGINEERS (2)
MATH 208, PHYS 201. Introduction to calculations using probability distributions and densities; concepts in statistics; application to engineering problems.
MATH 207 Calculus II: Integration (4)
MATH 206 with minimum C grade. The definite integral, fundamental Theorem of the Calculus, transcendental functions, methods of integration, applications to physics and biology.
MATH 208 Calculus III: Sequences, Series, and Coordinate Systems (4)
MATH 207 with minimum C grade. Limits of sequences and series, indeterminate forms, Taylor Series, plane coordinate systems, and change of coordinates.
MATH 209 Calculus IV: Several Variables (4)
MATH 208 with minimum C grade. Three-dimensional analytic geometry, partial differentiation, multiple integration, spherical and cylindrical coordinate systems, improper integrals.
MATH 215 DIFFERENTIAL EQUATIONS (4)
MATH 209. Ordinary differential equations with concentration on methods of finding solutions; applications in science and engineering.
CAN MATH 24
PHYS 201
High schools physics or permission of partment; MATH 206 (may be taken concurrently). Vectors, mechanics of particles and rigid bodies, basic conservation laws of mechanics.<
PHYS 202
MATH 207. Mechanical vibrations and sounds, elementary thermodynamics.
PHYS 203
MATH 208. Elementary field theory, basic electricity and magnetism, DC and AC circuits.
PHYS 204
MATH 209. Continuation of electricity and magnetism including oscillations and waves; geometrical and physical optics.
TECH 160 INTRODUCTION TO METAL WORKING (3)
Basic metal properties, metalworking processes, and hand and machine tool applications.
Lecture 1 1/2 hours, laboratory 4 1/2 hour.
CE/ME 312 STRENGTH OF MATERIALS LABORATORY (1)
ME 310, ENGR 103; 205 (may be taken concurrently). Tests of engineering materials in tension, compression, bending and torsion; verification by experiment; basic theories learned in strength of materials. Laboratory 3 hours.
ME/EE 310 ENGINEERING MEASUREMENTS LABORATORY (1)
PHYS 203. Techniques and procedures used in making typical measurements in engineering laboratories. Laboratory 3 hours.
ME 310 ENGINEERING MEASUREMENTS LABORATORY (1)
PHYS 203. Techniques and procedures used in making typical measurements in engineering laboratories. Laboratory 3 hours.
ENGR 300 ECONOMICS FOR ENGINEERING (4)
Basic economic concepts, relationships between economic and engineering problems, role of interest and capital in cost minimization, analysis of financial statements, original and alternative investments, capital depreciation and replacement problems.
ENGR 301 ETHICS AND PROFESSIONALISM IN ENGINEERING (1)
Senior standing in engineering; ethical and professional standards in engineering profession; impact of engineering profession on society; professional registration and liability; government regulations and legal responsibilities.
ENGR 311 ELECTRIC CIRCUITS LABORATORY (also under EE 211)
ENGR 204. Experimental verification of the laws of electric circuits. Laboratory 3 hours.
TECH 400 WRITTEN COMMUNICATION SKILLS FOR INDUSTRIAL STUDIES (4)
ENGL 102. Written communication skills for the professional needs of Industrial Studies students with emphasis on education, public, industrial, and business requirements.
Students subject to earlier catalogs satisfy this prerequisite with ENGL 101 or 190.
ENGL 306 TECHNICAL WRITING (4)
Passing WPE Score. Fundamentals of technical writing; development and writing of mechanism descriptions, proposals, feasibility studies, progress reports, and long technical reports.
CE/ME 303 FLUID MECHANICS I (4)
CE/ME 320, PHYS 202. Fundamental principles and methods of fluid mechanics; thermodynamics of fluid flow; Newtonian fluids; equations of fluid flow; laminar and turbulent flow; applications.
CE/ME 320 DYNAMICS I (4)
ENGR 201. Kinematics and kinetics of rigid bodies; work, kinetic energy, impulse, momentum in two and three dimensions; applications to space mechanics.
EE 304 ELECTRIC MACHINES (4)
ENGR 204 with C or higher grade. Electromechanical principles and applications to electric machines.
ME 306 HEAT TRANSFER I (4)
CE/ME 303 or ME 326A; MATH 215. Fundamental principles of heat transfer; conduction; convection, and radiation; applications.
ME 323 MACHINE DESIGN I (4)
ENGR 205. Application of principles of mechanics, properties of materials, and fabrication processes to design of simple machines and structural elements.
ME 327 MANUFACTURING PROCESSES (4)
ENGR 207. Manufacturing properties of metals, alloys, and nonmetallic materials; solidification processes; material forming; material removal; joining processes; unconventional processes; numerical control; and automated process.
ME 328 INTRODUCTION TO METALLURGY (4)
ENGR 207, ME 326A. Theory, composition, and properties of pure metals and alloys. Alloying, fabrication, and heat treatment of metals, with emphasis on nature of metals and their alloys.
ME 329 METALLOGRAPHY LABORATORY (1)
ME 328. Preparation of metallic samples and study of their internal structure by microscopic techniques.
ME 410 CONTROL OF MECHANICAL SYSTEMS
CE/ME 320, ME 306, CS 290, MATH 215. Mathematical models of dynamic systems, fundamental of feedback control, basic control actions and devices, applications to mechanical systems.
EE 438A CONTROL SYSTEMS THEORY I (4) ( under EE 360 )
EE 334. Analysis and design of feedback control systems by classical methods; introduction to state-variable methods.
ME 428 AUTOMATION AND COMPUTER-AIDED MANUFACTURING
ME 327. Automation of manufacturing processes, numerical control, computer-aided manufacturing, group technology, flexible manufacturing, applications of robots in industry.
TECH 484 AUTOMATED MANUFACTURING SYSTEMS (4)
Applications and theories of advanced production systems in automated manufacturing environments; emphases include direct and computer numerical control, computer integrated manufacturing CAD/CAM; flexible manufacturing; group technology. Lecture 2 1/2 hours, laboratory 4 1/2 hours.
ME 481 INTRODUCTION TO ROBOTICS
EE 438A or ME 410. General considerations of robotic manipulator; spatial description, homogeneous transformations; manipulator kinematics; inverse manipulator kinematics; motion trajectories; static forces.
ME 491 ROBOTICS LABORATORY (1)
EE/ME 481. Robot system installation; programming and languages; link kinematics and motion planning; control of the arm; automated manufacturing and computer-integrated manufacturing (CIM).
MGMT 306 PRODUCTION AND OPERATIONS MANAGEMENT (4)
ECON 209, MATH 242. Analysis and applications of concepts and techniques of the quantitative approach, systems analysis, and operations analysis to managerial functions, with emphasis on production.
MGMT 460 CASE STUDIES IN PRODUCTION AND OPERATIONS MANAGEMENT (4)
MGMT 306. Undergraduate seminar that analyzes factory management, including such topics as industrial standards, schematic and quantitative models, production management and control, programming aggregate rates of production, inventory control, and production scheduling.
MGMT 463 MOTION AND TIME STUDY (4)
ECON 309, MGMT 460. Quantitative aspects of scientific management including elements of motion economics, operation analysis, flow process charts, and time study with an introduction to methods-time measurements (written reports in this areas).
MGMT 464 PRODUCTION AND INVENTORY MANAGEMENT (4)
MGMT 306. Design of information and decision system for allocating resources and scheduling activities; development of conceptual structures guiding integrated production and inventory systems in manufacturing environments; introduction of computerized MRP systems.
MGMT 467 QUALITY CONTROL (4)
ECON 309. Control of quality of manufactured products by statistical methods; control charts for variables, fraction defective, defects per unit; acceptance sampling; single, double and multiple sampling methods; sampling tables.
MGMT 496 OPERATIONS RESEARCH (4)
MGMT 306. Evaluation and application of operations research methods as a tool for management decision-making.
EE 336 ELECTRONICS (4)
PHYS 333. Analysis and design of small-signal and large-signal electronic amplifiers; frequency response; feedback.
EE 345 MICROCOMPUTER PROGRAMMING
EE 244. Organization and structure of microcomputer systems; machine and assembly language programming; system software for microcomputer.
EE 372 DIGITAL ELECTRONICS (4)
EE 244, EE 336. Switching mode circuits; diode circuits applications; opto-electronic devices; TTL, CMOS, ECL families; logic gates; SSI, MSI, LSI circuit functions.
EE 445 MICROPROCESSOR INTERFACE DESIGN (4)
EE 345, EE 372; EE 347 (may be taken concurrently). Microprocessor architecture and timing; bus structure; memory system design; parallel and serial input/output; interrupts and timers; analog-digital and digital-analog conversion.
ME 414 MACHINE DESIGN II (4)
ME 319, ME 323. Design of unit assemblies and machines; materials, safety, lubrication, and construction.
ME 422 OPTIMIZATION OF MECHANICAL ENGINEERING SYSTEMS (4)
ME 319, prerequisite or corequisite: ME 323. Design considerations of mechanical engineering systems; optimization techniques; application of existing computer programs and analytical methods to optimization of mechanical engineering systems.
TECH 327 MICROPROCESSOR (3)
TECH 326. Architecture, programming, interface, and applications of microprocessors; hand-on programming and interfacing applications. Lecture 1 1/2 hours, laboratory 4 1/2 hours.
TECH 325 INDUSTRIAL CONTROLS
TECH 321. Sensors and their control applications; process control and data acquisition; motor controls; practical control applications; trouble-shooting. Lecture 1 1/2 hours, laboratory 4 1/2 hours.
TECH 411 TOOL DESIGN
TECH 110. Application of principles of precision dimensioning, mechanics, and drafting to design of machines, tools, gears, and cams; selection and design of tools for mass production. Lecture 1 1/2 hours, laboratory 4 1/2 hours.
TECH 425 PROGRAMMABLE CONTROLS
TECH 325. Applications, programming, and troubleshooting of programmable logic controllers (PLC) and motion controls with servo and stepper motors; hands-on applications. Lecture 1 1/2 hours, laboratory 4 1/2 hours.