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Course Criteria
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1.00 Credits
1 credit This laboratory course is to be taken concurrently with ECE231. The laboratory provides hands-on experience with DC and AC circuits that includes the applications of Kirchhoff's laws, superposition and Thevenin equivalent circuits. Topics also include operational amplifier circuits, phasor diagrams and electric machines. Co-requisite: ECE 231
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3.00 Credits
3 credits This course introduces AC circuits and three-phase circuit analysis. Power concepts are introduced as pertaining to single and three-phase circuit applications. Frequency response characteristics of RLC circuits are studied, including the Fourier Series representation of a periodic signal. Frequency domain tools such as Laplace Transforms and Fourier Transforms are presented and employed in circuit analysis. Modern computer-aided design tools are used for solving homework assignments. Prerequisite: ECE 228 and 229
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1.00 Credits
1 credit This laboratory course is to be taken concurrently with Circuits II ECE 240. The laboratory provides hands-on experience with AC circuits that includes the transient analysis and frequency response applications of first- and second-order circuits. Topics also include Butterworth filter design for frequency response applications. The use of a contemporary computer-aided design tool in support of circuit design is an integral part of the laboratory. Co-requisite: ECE 240
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3.00 Credits
3 credits This course introduces tools from the industry-approved National Instruments (NI) software and hardware products. The students will design and build virtual instruments (VIs) using the graphical programming language LabVIEW to acquire, analyze, and present data. They will develop measurement techniques and understand the limitations of measurement and instrumentation. In addition, sensor and transducer characteristics and their applications will be presented.
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2.00 Credits
2 credits This course is designed to give students a basic background in hardware and software aspects of microprocessors. Contents of the course include: a microprocessor architecture, addressing modes, instruction set, assembly language, timers, I/O interrupt handling, mixed C/Assembly programming, finite state machine design, basic peripheral interfaces, UART, ADC and DAC. Microcontroller configuration. Schematic entry and basic PCB design. Prerequisites: ECE 140 or ECE 337 Co-requisite: ECE247
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1.00 Credits
1 credit This course is designed to give students a basic background in hardware and software aspects of microprocessors. Contents of the course include: a microprocessor architecture, addressing modes, instruction set, assembly language, timers, I/O interrupt handling, mixed C/Assembly programming, finite state machine design, basic peripheral interfaces, UART, ADC and DAC. Microcontroller configuration. Schematic entry and basic PCB design Co-requisite: ECE 246
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3.00 Credits
3 credits This course covers basic understanding of embedded kernel and real-time operating system paradigms. Topics include process management, process synchronization, and memory management. Embedded kernel topics will be implemented on an embedded-system platform. RTOS topics will be implemented on commercial real-time operating systems. Pre-requisite: ECE 217
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3.00 Credits
3 credits This course focuses on the analysis and design of electronic sub-systems/systems. General design aspects are considered from a top down approach and thus sub-system design and analysis naturally follow. Main topics include electronic systems and design considerations, diode circuits emphasizing rectification, operational amplifiers and applications, and transistors (BJT and FET). All devices are considered as system components. The use of a contemporary software tool in aid of circuit design is an integral part of the course and used for design/analysis. Prerequisites: ECE 228
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1.00 Credits
1 credits This lab is to accompany and complement Electronics I and is taken concurrently with it. Hands-on work with op-amps, diodes, BJTs and FETs in different circuit configurations are conducted. Theoretical and a computer-aided design tool for analysis is used to complement the lab activity. Co-requisite: ECE 321
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3.00 Credits
3 credits This course introduces the fundamental principles of transformers, energy conversion and the operational principles of electric machines. Induction machines, Synchronous machines, and DC machines are discussed including their steady-state characteristics and operations Prerequisites: ECE 335
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