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  • 1.00 Credits

    This lab accompanies ME 3300. Emphasis is on analysis and reporting of results. (Spring, Summer) [Graded (Standard Letter)] Co-requisite(s): ME 3300 Registration Restriction(s): None Corequisite:    ME 3300
  • 3.00 Credits

    An interdisciplinary systems approach to dynamics and control involving the integration of mechanical, electrical, and electronics engineering using microprocessor control. Involves computer modeling and designing of mechanical, electrical, fluid, and thermal systems. (Spring) [Graded (Standard Letter)] Co-requisite(s): ME 3325 Prerequisite(s): ME 2030 - Prerequisite Min. Grade: D- Registration Restriction(s): None Prerequisite:    ME 2030 O ENGR 2030 Corequisite:    ME 3325
  • 1.00 Credits

    This lab accompanies ME 3320. Lab activities include the analysis, computer simulation, design, implementation, and measurement of electromechanical systems. (Spring) [Graded (Standard Letter)] Co-requisite(s): ME 3320 Registration Restriction(s): None Corequisite:    ME 3320
  • 3.00 Credits

    Application of engineering design principles to a team-based capstone project in the student?s specialty area. Emphasis on creative and critical thinking, planning, design, execution and statistical evaluation of experiments, as well as teamwork, project management, and communication. Students will use engineering, systems engineering and project-management principles and concepts learned to-date to execute the project, complete a design report, and present results. Should be taken in the last semester before graduation. (Fall, Spring) [Graded (Standard Letter)] Prerequisite(s): ME 3055 - Prerequisite Min. Grade: D- Registration Restriction(s): Senior standing required Equivalent Course(s): CE 4055, EE 4055 Prerequisite:    ME 3055
  • 3.00 Credits

    An introduction to various instruments used in engineering measurements and methods for obtaining quality experimental data. The course includes lectures where theoretical background and best practices are examined and utilizes hands-on experience with electronics and measurement equipment in a laboratory setting. Statistical analysis is used to analyze, manipulate, plot, and interpret acquired data. (Spring) [Graded (Standard Letter)] Co-requisite(s): ME 4105 Prerequisite(s): EE 2250 and EE 2255 and ENGR 2140 and ENGR 2145 and ME 2030 and ME 3200 - Prerequisite Min. Grade: D- Registration Restriction(s): None Prerequisite:    ( EE 2250 O ENGR 2250 ) ( A EE 2255 O ENGR 2255 ) A ENGR 2140 A ENGR 2145 ( A ME 2030 O ENGR 2030 ) ( A ME 3200 O ENGR 3000 ) Corequisite:    ME 4105
  • 1.00 Credits

    This lab accompanies ME 4100. The lab focuses on hands-on use of instrumentation in engineering applications and proper analysis and reporting methods. (Spring) [Graded (Standard Letter)] Co-requisite(s): ME 4100 Registration Restriction(s): None Corequisite:    ME 4100
  • 3.00 Credits

    This course is an introduction to conduction, convection, and radiation modes of heat transfer. Both steady state and unsteady state cases are covered. Other topics include analytical and numerical solution of practical problems in heat transfer. (Fall) [Graded (Standard Letter)] Co-requisite(s): ME 4205 Prerequisite(s): MATH 2250 and ME 3300 and ME 3305 - Prerequisite Min. Grade: D- Registration Restriction(s): None Prerequisite:    MATH 2250 ( A ME 3300 O ENGR 3050 ) ( A ME 3305 O ENGR 3055 ) Corequisite:    ME 4205
  • 1.00 Credits

    This course provides hands-on laboratory experience to complement and add depth of comprehension to concepts gained in ME 4200 - Heat Transfer. Laboratory assignments explore these concepts in greater depth and provide experiences in conduction, convection, and thermal radiation heat transfer. (Fall) [Graded (Standard Letter)] Co-requisite(s): ME 4200 Registration Restriction(s): None Corequisite:    ME 4200
  • 3.00 Credits

    Vibration of single and multiple degrees of freedom and discrete mass systems. Natural frequencies and mode shapes for free, damped, and undamped systems. Forced vibrations; forcing functions; steady state and transient response. Application of matrix methods and numerical solutions. Analogies between unsteady behavior of mechanical, electrical and fluid systems. Introduction to vibration measurements and instrumentation. Applications; avoidance of vibration problems at the design stage of a new system. (Fall) [Graded (Standard Letter)] Prerequisite(s): ENGR 2140 and ENGR 2170 and ME 2030 and (MATH 2250 or MATH 2280) - Prerequisite Min. Grade: D- Registration Restriction(s): None Prerequisite:    ENGR 2140 A ENGR 2170 ( A ME 2030 O ENGR 2030 ) ( A MATH 2250 O MATH 2280 )
  • 3.00 Credits

    This class will introduce the theory and practice of feedback control systems to students. The topics will include the Laplace transform, control system block diagrams and the transient and steady state response of the control systems. Also, students will learn how feedback systems affect to the transient and steady state response of the control systems. Other topics include dynamic systems, modelling, linearization techniques, and PID controllers. (Spring - Even Years [As Needed]) [Graded (Standard Letter)] Prerequisite(s): ME 3030 - Prerequisite Min. Grade: D- Registration Restriction(s): None Equivalent Course(s): EE 4310 Prerequisite:    ME 3030
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