Wireless Systems Lab

This page lists the classes that are currently being taught by Professor Nathan M. Neihart.

EE 414/514 - Microwave Engineering
This class focuses on the principles, analysis, and instrumentation used in designing circuits that operate in the microwave portion of the electromagnetic spectrum. We discuss component modeling, S-parameters, microwave amplifiers, oscillators, and filters including optimum noise figure and maximum power designs.

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EE 201 - Electronic Circuits
This class is an introduction to electrical engineering. It focuses on basic circuit and systems concepts such as Kirchhoff's Laws, Ohm's Law, and basic circuit elements such as the resistor, inductor, and capacitor. This class also covers circuit analysis techniques including DC, sinusoidal steady-state, and transient analysis. Additionally, students learn AC power concepts, frequency response of basic circuits, and how to use PSpice in circuit design. There is also an associated laboratory section.

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EE 507 - VLSI Circuits for Wireless Communication
The primary goal of this class is to analyze and design radio frequency integrated circuits (RFICs) for wireless and wired communication. The course begins with an overview of wireless technology and a discussion of fundamental concepts in RF design, such as nonlinearity, sensitivity, and dynamic range. The discussion will then move towards matching and impedance transformation networks as well as noise in integrated circuits. In addition to transceiver architectures, the remainder of the course concentrates on the detailed analysis and design of common RF building blocks including: low-noise amplifiers, mixers, oscillators, and power amplifiers.

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EE 506 - CMOS Phase Locked Loops
Phase-locked loops (PLLs) are an integral part of many systems from television to high-speed wireless and wired communication systems. This class incorporates both the analysis and design of PLLs and upon completion of this course students will be able to identify and analyze PLLs of different types and orders. Students will be able to understand the design trade-offs between different performance metrics including settling time, tuning range, and noise and using this information to analyze and design the various PLL sub-components such as phase/frequency detectors, charge pumps, loop-filters, and voltage controlled oscillators. Finally, students will have a thorough understanding of the various integration issues and their impacts upon PLL performance.

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