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Course Criteria
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3.00 Credits
Digital Logic introduces a student to two-state logic. Logic analysis will use the binary number system and Boolean algebra. Both combinational (AND-OR) logic and sequential (flip-flop) logic are studied. Logic designs are implemented using relay ladder logic, Programmable Logic Controllers, Transistor-Transistor Logic and Field Programmable Gate Arrays.
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3.00 Credits
The fundamentals of prototype design, fabrication, and documentation will be covered. Major topics include: safety, sheet metal fabrication, printed circuit board design & fabrication, schematic & wiring diagram drafting & analysis, computer applications for schematic drawing and printed circuit board layout, circuit construction, trouble- shooting fundamentals, soldering techniques and project parts procurement and cost analysis.
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3.00 Credits
Laboratory experiments parallel material presented in ELET 1103. The theories and laws governing dc circuits are applied and verified. Hands-on building of electrical circuits reinforces the interpretation of schematic diagrams. Verification includes detailed analysis of the circuit under test by calculation, measurement, and simulation. Outside preparation and laboratory report writing are required.
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3.00 Credits
This course provides an introduction to computer networks. It serves as a foundation for the computer/electronic technician to build on. The knowledge and skills obtained in this course will prepare the student for the CompTIA Network + exam.
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3.00 Credits
A study of solid state devices, including diodes, bipolar transistors, and field effect transistors. Includes the theory of operation, biasing, stabilization, frequency response, distortion, and gain using mathematical analysis, equivalent circuits, and computer models.
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3.00 Credits
A continuation of Circuit Theory I. The emphasis is on the electrical principles, laws, and theorems applicable to sinusoidal ac circuits. Complex number notation is used to evaluate ac circuits. Topics include ac power, resonance, polyphase circuits and transformers.
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3.00 Credits
A microcontroller is a microcomputer on a silicon chip. When a microcontroller is in a device that is not a computer, it is called an embedded controller. Examples of typical devices would be telephones, televisions, copy machines, microwave ovens and in automobiles. Automobiles incorporate more than ten microcontrollers used for such applications as controlling air/fuel mixtures in the engine to antilock brakes at the wheels. This course focuses on the fundamentals of both the hardware and software aspects of the microcontroller. Typical devices that are connected to the microcontroller are; switches, light emitting diodes, seven segment displays, pneumatic solenoids and a matrix keypad. An engineering evaluation board is used as the development system for the embedded controller. Structured programming, using flow charts, is emphasized. Code is written in assembly language, assembled and then downloaded to the Engineering Evaluation Board.
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3.00 Credits
The material in this course parallels and supplements the subject matter in ELET 2103. The use of appropriate electronic test equipment is emphasied, along with computer simulation, and computer aided test equipment.
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3.00 Credits
This course will provide an overview of the fabrication and operation of silicon-based integrated circuits including resistors, diodes, transistors and their current-voltage (I-V) characteristics. Laboratory exercises teach the basics of IC fabrication and I-V measurements. Oxidation/diffusion, photolithography (spin/bake/expose/develop), etch, and vapor deposition equipment allow students the opportunity to design, build, and test simple solid-state devices.
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3.00 Credits
This course involves the study and application of operational amplifiers. Inverting, non-inverting and follower amplifiers are presented in detail with consideration of gain, bandwidth, and impedance. Different feedback circuits are studied to realize basic mathematical operations. Op-amps topologies are then used to make filters, oscillators, and regulated power supplies.
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