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Course Criteria
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3.00 Credits
Study of the principles and application of Programmable Logic Controllers including ladder logic, program control, data manipulation, math instructions, sequencers, shift registers, networking, PLC-mechanism interfacing and human-machine interfacing. Prerequisite: ENT 291. 2 Lec. 1 Lab.
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3.00 Credits
Advanced study of microprocessor application for commercial and industrial use. Emphasis on understanding how microprocessors are interfaced to a variety of peripheral devices such as printers, modems, D to A and A to D converters, and programmable controllers. Specific devices examined such as UARTs, PPIs, and programmable interval timers. Prerequisite: ENT 293, 295. 2 Lec. 1 Lab. Offered infrequently. (Electrical technology)
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3.00 Credits
Introduction to data communications, computer networks, and media. Includes transmission basics, digital representations, data link concepts, and other networking issues. Networking data telecommunications project assigned as a significant part of the course requirement. Prerequisite: CSA 153 or 174.
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3.00 Credits
The basic concepts of force, mass, and acceleration; work and energy; and impulse and momentum are introduced and applied to problems involving particles and rigid bodies. Topics include displacement, velocity, and acceleration of a particle; relations between forces acting on a particle or rigid body; and the changes in motion produced. Prerequisite: ENT 271 and MTH 151. 2 Lec. 1 Lab.
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3.00 Credits
The application of fluid statics and fluid dynamics to the solution of fundamental engineering fluid problems. The one dimensional energy and momentum equations are introduced and applied to the solution of fluid flow problems. Prerequisite: ENT 271 and MTH 151. 2 Lec. 1 Lab.
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3.00 Credits
Introduction to data acquisition and control with a graphical user interface (GUI). Topics include parallel, serial, and network access. Data transfer technology such as Object Linking and Embedding and Dynamic Data Exchange also covered. Prerequisite: CSA 153, ENT 192 or equivalent and completion of an engineering technology associate's degree or permission of instructor. 2 Lec. 1 Lab.
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3.00 Credits
Fundamental concepts of energy transformation and transport are introduced. The First and Second Laws of thermodynamics are applied to process and cycle analysis. Heat conduction, convection, and radiation modes are introduced and applied to simple heat balance problems. Prerequisite: PHY 172, MTH 151, and completion of an engineering technology associate's degree or permission of instructor.
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3.00 Credits
Rigid body kinematics is applied to the analysis and design of mechanisms used in machines. The course includes motion and force transference from power source, motion characteristics of real-world machinery, and analysis and design concepts to facilitate optimization of the machine arrangement. Prerequisite: ENT 301.
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3.00 Credits
A course for upper-level students in engineering technology. This course covers background, techniques, and case studies in project management particularly focused on engineering technology applications. The student will develop a fundamental understanding of the concepts for managing both small and large projects. Discussion, evaluation, and presentation skills will be enhanced. Some of the specific topics to be covered include: Gantt charts, PERT charts, project life-cycle, budgeting, cost analysis, break-even analysis, conflict resolution, organization tools, project planning, statistical process control, and other selected quality improvement tools. Microsoft Project? and Microsoft Excel? will be used as software tools throughout the course. Prerequisite: ECO 201 or 202 or permission of instructor. Corequisite: STA 301, 368, or equivalent.
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4.00 Credits
An in-depth study of engineering analysis techniques with emphasis on mathematical analysis of mechanical and electrical subsystems. Detailed study of a variety of situations using techniques based on state-variable analysis and state transition matrix; convolution and circuit response in the time domain; system function and response in the frequency domain; and time shift and periodic functions. Co-requisite: MTH 251. 3 Lec. 1 Lab.
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