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Course Criteria
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3.00 Credits
At this level, the students will improve their ability to actively lead and participate in group discussions. They will also practice speaking in front of the class by giving group and individual short presentations. They will gain experience in how to be active audiencemembers. (prereq: "CD" or better in ES-022; coreq: ES-013)
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4.00 Credits
This course is an introduction to the fundamental concepts and laws of electric circuits and their application to DC and AC circuit analysis. Topics covered include Ohm's law, Kirchhoff'slaws, capacitance,magnetism, inductance, series-parallel circuits, single- and three-phase AC circuits, transformers, and electric power. Phasors and complex numbers are utilized in AC analysis. The laboratory is used to illustrate electric circuit concepts and electric circuit measurement techniques. Note: this course is not intended for the electrical engineering technologymajor. (prereq:MA-126,MA-127, PH-123 or PT-220)
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3.00 Credits
This course is a survey of semiconductor principles, discrete semiconductor devices, linear and digital integrated circuits, and transducers. These devices are applied to the concepts and properties of electronic circuits such as power supplies, linear amplifiers, active filters, oscillators, nonlinear circuits, and interfacing. The laboratory is used to illustrate electronic devices, applications, andmeasurement techniques. Note: this course is not intended for the electrical engineering technologymajor. (prereq: ET-1520,MA-128)
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4.00 Credits
The analysis of electric circuits in both the time domain and the Laplace transformdomain is covered in this course. The circuit responses to a variety of waveforms, including step, ramp, sinusoid, switched, exponential, and impulse functions, are analyzed. Time domain differential equations and Laplace transforms are emphasized as circuit analysis techniques. The student will also learn to design circuits and experiments that will illustrate the concepts introduced in this course. (prereq: ET-3051,MA-227)
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4.00 Credits
The theory and circuit applications of periodic signals are covered in this course. The power in a circuit withmultiple frequencies is investigated initially. This discussion leads to the determination of the rectangular and polar forms of the Fourier series for periodic signals and the analysis of circuits with periodic signal inputs. The spectra of periodic signals are constructed fromthe Fourier series. Periodic signals are analyzed in circuits, filters and systems. Applications such as signal distortion and harmonic generation are covered. Laboratory experiments will reinforce the concepts presented. (prereq: full admission into the BS-EET programor permission of an EET programadvisor; coreq: OR-307S)
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4.00 Credits
Electronic signals and noise, especially in the frequency domain, and the corresponding circuit and systemresponses are examined in this course.Major topics include the exponential Fourier series, the Fourier transform, electronic noise, and circuit/systemspecifications and performance. The course provides an examination of digital signals, sampling, A/D and D/A converters, and an introduction to digital signal processing using the Z-transform. Practical applications are discussed throughout the course. (prereq: ET- 3000 or ET-3001)
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4.00 Credits
This course provides an introduction to electronic circuit design. The student applies fundamental electronic circuit concepts to laboratory design projects utilizing discrete semiconductor devices and analog integrated circuits. Design activity focuses on linear power supplies, switchingmode power supplies, sinusoidal oscillators and active filters. Circuit simulation software is utilized as an integral part of the design process. (prereq: ET-3000 or ET-3001)
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4.00 Credits
The fundamental concepts of electrostatics andmagnetostatics are presented in this course. Vector tools are developed and used to strengthen the understanding of the physical properties of static electric andmagnetic fields. Vector algebra in rectangular, cylindrical and spherical coordinate systems is initially covered. Subsequently, electrostatic andmagnetostatic field topics, such as Coulomb's law, Biot-Savart law, Gauss's law, and electric andmagnetic flux areexamined and also related to circuit concepts. (prereq:MA-226 or equivalent, full admission into the BS-EET programor permission of an EET programadvisor, EG-1260)
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3.00 Credits
Data communications is very significant in today's world. It is used inmost aspects of everyday life. Business, industry, education and homes all rely on the communication of information. This course is focused on fundamental concepts and practical applications, and prepares students tomake intelligent decisions on the appropriate design, purchase, integration, and use of data communications equipment and systems. Required aspects of data communications are discussed, including relevant terminology, concepts, hardware, software, protocols, architectures, and current and future products. This course is not intended for the electrical engineering technologymajor.
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4.00 Credits
The student develops a working knowledge of designing and implementing computer programs to solve problems encountered in engineering technology practice. Structured programming techniques and object-oriented programming techniques will be introduced in this course. Fundamental topics include programdesign life cycle, data types, assignment statements, I/O statements, I/O files, strings, control constructs, looping techniques, arrays, user-defined functions, library functions, andmodules. Object-oriented programming topics include describing, declaring and developing user-defined classes and objects, function overloading, constructors and destructors, inheritance, polymorphism, encapsulation, operator overloading, pointers and dynamicmemory. The Standard Template Library (STL) will also be discussed. Programming for real-time control systems and applications in engineering technology and numericalmethods will be emphasized. Data visualization will be presented. Laboratory sessions will be used to enhance lecture topics. (prereq: full admission into the BS-EET program or permission of an EET programadvisor)
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