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Course Criteria
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3.00 Credits
Credits: 3 Prerequisites: None Corequisites: None Type: LEC/REC An application-oriented course to introduce students to the basic principles and concepts employed in analysis and synthesis of modern-day analog and microcomputer control systems. Topics include: review of vectors, matrices, and Laplace transforms, followed by introduction to block diagram, signal flow graph, and state-variable representation of physical systems, network and linear graph techniques of system modeling; time-domain, frequency domain, and state-space analysis of linear control systems, control concepts in multivariable systems, hierarchy of control structures, design of analog and digital controllers.
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3.00 Credits
Credits: 3 Prerequisites: EE 310 Corequisites: None Type: LEC Reviews semiconductor materials properties that are important for device operation. Also, discusses semiconductor devices along with important materials properties for each device. Reviews the device models employed in SPICE circuit simulations. Uses several SPICE simulation projects to learn about the SPICE device models and about the effect of materials properties on the device performance and circuit operation. Devices covered are: pn junction diode; SPICE pn junction diode models and model parameters; MOS field effect transistor, SPICE MOSFET models and model parameters; CMOS integrated circuits; bipolar transistor fundamentals; SPICE BJT models and model parameters; MS junction; mesfet; jfet; SPICE models; PSPICE or HSPICE simulations of semiconductor devices.
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3.00 Credits
Credits: 3 Prerequisites: None Corequisites: None Type: LEC The recent emergence of fabrication tools and techniques capable of constructing nanometer-sized structures has opened up numerous possibilities for the development of new devices with size domains ranging from 0.1 - 50 nm. The course introduces basic single-charged electronics, including quantum dots and wires, single-electron transistors (SETs), nanoscale tunnel junctions, and so forth. Giant magnetoresistance (GMR) in multilayered structures are presented with their applications in hard disk heads, random access memory (RAM) and sensors. Discusses optical devices including semiconductor lasers incorporating active regions of quantum wells and self assembled formation of quantum-dot-structures for new generation of semiconductor layers. Finally, devices based on single- and multi-walled carbon nanotubes are presented with emphasis on their unique electronic and mechanical properties that are expected to lead to ground breaking industrial nanodevices. The course also includes discussions on such fabrication techniques as laser-ablation, magnetron and ion beam sputter deposition, epitaxy for layer structures, rubber stamping for nanoscale wire-like patterns, and electroplating into nanoscale porous membranes.
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3.00 Credits
Credits: 3 Prerequisites: None Corequisites: None Type: LEC Covers -D electron systems, quantum wires and dots, ballistic transport, quantum interference, and single-electron tunneling.
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4.00 Credits
Credits: 4 Prerequisites: EE 03 or EE 34 Corequisites: None Type: LEC/LAB Principles of electromagnetic energy conversion with applications to motors and generators. Topics include magnetic circuits, transformers, hysteresis, field energy, dc and ac motors. Students learn the basic fundamentals of electro-mechanical energy conversion. Design project with laboratory validation accounts for 50 % of grade.
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3.00 Credits
Credits: 3 Prerequisites: None Corequisites: None Type: LEC Covers various commonly used micro/nanofabrication techniques, microfluidics, various chemical and biochemical applications such as separation, implantable devices, drug delivery, and microsystems for cellular studies and tissue engineering. Discusses recent and future trends in BioMEMS and nanobiosensors. Students will gain a broad perspective in the area of micro/nano systems for biomedical and chemical applications.
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3.00 Credits
Credits: 3 Prerequisites: None Corequisites: EE 324 Type: LEC EMC deals with interference in electronic systems. For senior and first-year graduate students and industrial professionals who have an interest in designing electronic systems that comply with current commercial and military standards on EMC such as the FCC Part 15 and CISPR 22. Both specify limits on radiated and conducted emissions for digital devices which are defined as any electronic device that has digital circuitry and uses a clock signal in excess of 9 kHz. Student projects designed in electronic instrumentation classes without consideration of the limits imposed by these standards would fail to meet the current standards and as a result could not be marketed in the United States or Europe.
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3.00 Credits
Credits: 3 Prerequisites: EE 421 Corequisites: None Type: LEC Develops an understanding of the operation of different semiconductor devices, starting from a quantitative knowledge of semiconductor properties.
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3.00 Credits
Credits: 3 Prerequisites: Experience in programming with a high-level language (e.g., C) Corequisites: None Type: LEC Object-oriented analysis, design and programming. Introduces Java syntax, application programmers interface (API), object-oriented programming concepts including encapsulation, inheritance, and polymorphism, and multi-threaded programming including thread synchronization and control. Also introduces graphical programming API and effective graphical programming techniques. Applies all these concepts and techniques to the student-chosen, engineering simulation projects. Emphasizes software engineering processes such as architectural design, unit refinement cycles and code reuse throughout the semester. For the project, requires students to develop a reusable class library consisting of at least three packages: a graphical drawing package, a problem simulation package, and a visual presentation package.
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3.00 Credits
Credits: 3 Semester: SP Prerequisites: CHE 101, CHE 105, or CHE 107 and PHY 107 or equivalent Corequisites: None Type: LEC An introduction to the fundamentals of electrochemistry. Batteries as electromechanical power sources including: battery related terminology, quantitative assessment and comparison methodologies, design considerations for batteries, the chemistry and function of several classes of primary (single use) and secondary (rechargeable) battery types, and appropriate selection of power sources for applications. Students participate in design projects including the development of power systems for specific applications.
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