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Course Criteria
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3.00 Credits
No course description available.
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4.00 Credits
Introduction to semiconductor devices including diodes, bipolar junction transistors, and field-effect transistors. Analysis and design of rectifiers, switches, and amplifiers. Small-signal characteristics of discrete transistor amplifiers including gain and frequency response. Introduction to power devices and power amplifiers. Laboratory includes experiments and computer simulations. Prerequisite: EET 103 (Alternating Current Circuits). Co-requisite: MATH 190 (Calculus I) Course Objectives (1) Describe the behavior of semiconductor materials and p-n junctions in electronic devices (2) Identify the characteristics of junction diodes, bipolar junction transistors, and field-effect transistors (3) Analyze and design rectifier-filter circuits (4) Design simple voltage regulators using Zener diodes (5) Analyze and design bias networks for bipolar junction and field-effect transistors in order to achieve specified operating conditions (6) Analyze and design linear small-signal transistor amplifiers (7) Compute and plot the frequency response of linear small-signal transistor amplifiers (8) Choose bipolar junction and field-effect transistors for high-power applications (9) Identify common types of power amplifiers (10) Use laboratory equipment including signal generators, digital multimeters, oscilloscopes, and prototyping boards to construct, troubleshoot, and test electronic circuits (11) Simulate electronic circuits using industry-standard software (12) Create accurate, attractive, and readable laboratory reports
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4.00 Credits
Continuation of EET 200. Analysis and design of operational amplifier circuits including amplifiers, filters, and oscillators. Applications of analog integrated circuits in communication, instrumentation, and data conversion. Study of thyristors and regulators for power conversion and control. Introduction to photovoltaic devices. Laboratory includes experiments and computer simulations. Prerequisite: EET 200 (Basic Electronics) Course Objectives (1) Analyze and design basic operational amplifier circuits including amplifiers, filters, oscillators, integrators, and differentiators (2) Analyze and design communication, instrumentation, and data conversion circuits that employ operational amplifiers and other analog integrated circuits (3) Consider the practical characteristics and limitations of electronic devices during the design process (4) Choose thyristors for power conversion and control applications (5) Identify circuits that employ series, shunt, and switching voltage regulators and design circuits using integrated circuit regulators (6) Understand the characteristics and applications of photovoltaic devices (7) Use laboratory equipment including signal generators, digital multimeters, oscilloscopes, and prototyping boards to construct, troubleshoot, and test electronic circuits (8) Simulate electronic circuits using industry-standard software (9) Create accurate, attractive, and readable laboratory reports
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3.00 Credits
Electrical characteristics of digital logic devices. Number systems and Boolean algebra. Combinational and sequential logic design using standard techniques such as Karnaugh maps. Study of common logic circuits including multiplexers, decoders, adders, flip-flops, counters, and shift registers. Implementation of digital systems using standard logic families and programmable devices. Prerequisites: EET 201 (Electronic Circuits), ET 204 (Programming for Engineering Technology) Course Objectives (1) Consider the electrical characteristics of digital signals and logic devices as part of the hardware design process (2) Work with numbers in binary, octal, and hexadecimal representations and convert numbers from one radix to another (3) Apply elementary Boolean algebra to the analysis and design of digital systems (4) Employ canonical techniques such as truth tables, Karnaugh maps, and state diagrams in the analysis and design of digital systems (5) Analyze and design digital systems for common tasks such as computation, bit sequence detection, and counting (6) Construct digital circuits using standard logic families and interface components (7) Use computer-aided engineering software to simulate combinational and sequential logic and to implement logic in programmable devices (8) Create accurate, attractive, and readable laboratory reports
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3.00 Credits
Introduction to modern microprocessor architecture, characteristics, and applications. Programming in assembly language. Hardware and software development to perform common tasks in data acquisition, control, and computation. Implementation of designs using industry-standard components and practices. Prerequisite: EET 215 (Digital Electronics I) Course Objectives (1) Identify key features of the PIC microcontroller architecture (2) Write assembly language code with the PIC instruction set (3) Use the MPLAB assembler and a hardware programmer to implement assembly language programs (4) Interface the input/output ports of the PIC to switches, LEDs, and LCDs (5) Build simple measuring instruments using analog-to-digital conversion hardware (6) Interface the PIC to multiplexed devices such as keypads and displays (7) Make use of the timing and interrupt capability of the PIC (8) Employ good practices for writing efficient assembly language programs (9) Create accurate, attractive, and readable laboratory reports
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3.00 Credits
No course description available.
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3.00 Credits
Selected Topics in EET
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4.00 Credits
Analysis and design of communication circuits including tuned matching networks, small-signal amplifiers, large-signal amplifiers and oscillators, mixers, modulators, and demodulators. Introduction to Fourier transform analysis. Theory of amplitude, frequency, and phase modulation. Transmitter and receiver topologies. Effects of noise in communication systems. Prerequisites: EET 201 (Electronic Circuits), MATH 210 (Calculus II) Course Objectives (1) Represent periodic functions using Fourier series (2) Design tuned matching networks for proper bandwidth and impedance transformation (3) Design small-signal amplifiers using Y parameter techniques and recognize the limitations of this approach (4) Design large-signal amplifiers and oscillators using a simple large-signal model for the bipolar junction transistor (5) Calculate the Fourier transform of a signal and interpret the result (6) Analyze mixers, modulators, and demodulators using Fourier and time-domain techniques (7) Identify the characteristics and relative merits of different transmitter and receiver topologies (8) Characterize the effects of noise in communication systems using an elementary noise model (9) Perform accurate radio frequency measurements of components and circuits using the equipment available in a modern radio laboratory (10) Consider non-ideal effects in radio-frequency components and circuits during the design process (11) Keep an accurate and complete laboratory notebook according to accepted industry practices
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3.00 Credits
Electromagnetic principles of rotating machines. Characteristics and applications of dc generators, dc motors, and ac generators. Electronic control of dc motors. Methods of power generation including economics and environmental effects. Study of modern topics in generation, motor control, and energy using the current literature. Prerequisites: EET 103 (Alternating Current Circuits), ET 204 (Programming for Engineering Technology) Course Objectives (1) Specify, install, and test dc motors and generators (2) Select electronic controls for dc machines (3) Specify, install, and test ac generators (alternators) (4) Analyze single- and three-phase ac power systems (5) Employ safe laboratory practices for working with potentially hazardous electrical equipment (6) Create accurate, attractive, and readable laboratory reports
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3.00 Credits
Continuation of EET 327. Transformers, three-phase induction and synchronous motors, and single-phase motors. Electronic control of ac motors. Basics of electrical power transmission and an introduction to the smart grid, micro grids, and dc transmission. Study of modern topics in power transmission and motor controls using the current literature. Prerequisite: EET 327 (Electrical Power Technology I) Course Objectives (1) Analyze and design single- and three-phase transformer circuits (2) Calculate the performance of three-phase motors using simple circuit models (3) Identify the benefits of using electronic controls for three-phase motors (4) Perform basic power-line calculations in three-phase systems (5) Employ safe laboratory practices for working with potentially hazardous electrical equipment (6) Wire single- and three-phase circuits involving transformers, motors, and generators and make measurements on these circuits (7) Work as a team member in performing tests, collecting data, and writing technical reports (8) Create accurate, attractive, and readable laboratory reports
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