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ECE 299: Advanced Topics in Electrical and Computer Engineering

3.00 Credits

Duke University

Opportunity for study of advanced subjects related to programs within the electrical and computer engineering department tailored to fit the requirements of a small group. Instructor: Staff

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ECE 310: Foundations of Nanoscale Science and Technology

3.00 Credits

Duke University

This course is the introductory course for the Graduate Certificate Program in Nanoscience (GPNANO) and is designed to introduce students to the interdisciplinary aspects of nanoscience by integrating important components of the broad research field together. This integrated approach will cross the traditional disciplines of biology, chemistry, electrical & computer engineering, computer science, and physics. Fundamental properties of materials at the nanoscale, synthesis of nanoparticles, characterization tools, and self-assembly. Prerequisites: Physics 62L and Chem 21L or instructor approval. C-L: NANO 200 pending in COMPSCI, CHEM, and PHYS. Instructor: Dwyer

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ECE 311: Quantum Electronics

3.00 Credits

Duke University

Instructor: Staff

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ECE 316: Advanced Physics of Semiconductor Devices

3.00 Credits

Duke University

Semiconductor materials: band structure and carrier statistics. Advanced treatments of metal-semiconductor contacts, Schottky barriers, p-n junctions, bipolar transistors (charge-control and Gummel-Poon models), and field-effect transistors (short channel effects, scaling theory, subthreshold conduction, nonuniformly doped substrates, surface and buried-channel devices, hot-electron effects). Device modeling in two dimensions using PISCES. Prerequisite: Electrical Engineering 216. Instructor: Massoud

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ECE 318: Integrated Circuit Fabrication Laboratory

3.00 Credits

Duke University

Introduction to IC fabrication processes. Device layout. Mask design and technology. Wafer cleaning, etching, thermal oxidation, thermal diffusion, lithography, and metallization. Laboratory fabrication and characterization of basic IC elements (p-n junctions, resistors, MOS capacitors, gated diodes, and MOSFETs). Use of four-point probe, ellipsometer, spreading resistance probe, scanning electron microscope, and evaporation system. Testing of basic inverters and gates. Prerequisite: Electrical Engineering 218 and consent of instructor. Instructor: Massoud

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ECE 322: Quantum Electronics

3.00 Credits

Duke University

Quantum theory of light-matter interaction. Laser physics (electron oscillator model, rate equations, gain, lasing condition, oscillation dynamics, modulation) and nonlinear optics (electro-optic effect, second harmonic generation, phase matching, optical parametric oscillation and amplification, third-order nonlinearity, optical bistability.) Prerequisite ECE 211, Physics 211, or equivalent. Instructors: Stiff-Roberts or Yoshie. One course

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ECE 334: Nonlinear Oscillations in Physical Systems

3.00 Credits

Duke University

Instructor: Staff

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ECE 342: Optimal Control Theory

3.00 Credits

Duke University

Instructor: Staff

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ECE 352: Advanced Topics in Digital Systems

3.00 Credits

Duke University

A selection of advanced topics from the areas of digital computer architectures and fault-tolerant computer design. Prerequisite: Electrical Engineering 252 or equivalent. Instructor: Staff

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ECE 361: Advanced VLSI Design

3.00 Credits

Duke University

Theory of advanced VLSI design. Specifications development, methodology, issues, circuit-level trade-offs. Full custom design, standard cell design, gate array design, silicon compilation. Semiconductor technologies and logic families for semi-custom design. Clocking schemes and distribution, race conditions. Design of a variety of circuits (adders, I/O drivers, RAM, FIFO, etc.) Testing of all phases in the life cycle of an integrated circuit. Top-down design and bottom-up implementation. Student projects. Not open to students who have taken Computer Science 310 before Fall 1994. Prerequisite: Electrical Engineering 261 or equivalent. Instructor: Kedem

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