## EE 108: Digital System Design

Digital circuit, logic, and system design. Digital representation of information. CMOS logic circuits. Combinational logic design. Logic building blocks, idioms, and structured design. Sequential logic design and timing analysis. Clocks and synchronization. Finite state machines. Microcode control. Digital system design. Control and datapath partitioning. Lab. Undergraduates must enroll for 4 units. *In Autumn, enrollment preference is given to EE majors. Formerly
EE 108A.

Terms: Aut, Win
| Units: 4
| UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-SMA

Instructors:
Mitra, S. (PI)
;
Prabala, R. (PI)
;
Bertrand, A. (TA)
...
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Instructors:
Mitra, S. (PI)
;
Prabala, R. (PI)
;
Bertrand, A. (TA)
;
Duncan, B. (TA)
;
Li, W. (TA)
;
Prabala, R. (TA)
;
Wang, V. (TA)

## EE 122A: Analog Circuits Laboratory

The course covers practical applications of mixed-signal circuits, including simple amplifiers, filters (passive, op-amp, switched-capacitor and digital-signal-processor-based), oscillators, power supplies, sensors and interface (input/output) circuits. Practical design skills, computer-aided design, and circuit fabrication and debugging are core topics. The design process is learned through proposing, designing, simulating, building, debugging, and demonstrating a substantial and novel team project. Radio frequency and largely digital projects not suitable for
EE 122. Prerequisite: basic electronics laboratory experience with solid working knowledge of circuit analysis, Fourier and Laplace methods.

Terms: Aut
| Units: 3
| UG Reqs: GER:DB-EngrAppSci, WAY-SMA

Instructors:
Kovacs, G. (PI)
;
Esposito, B. (TA)

## EE 122B: Introduction to Biomedical Electronics

EE122B is a laboratory course covering the design and realization of key components and architectures of modern biomedical electronics systems, their application in clinical and research measurements, and practical matters in their safe reduction to practice. Material in each topic area begins with an overview of the underlying physiology. Details are presented beginning with the molecular, cellular, organ-level origins of the biosignals, followed by the relevant transduction principles, nature of the signals (amplitude, frequency spectrum, etc.), and their processing and clinical use. Specific engineering topics include safety in biomedical instruments, fundamentals of analog/digital conversion and filtering techniques for biosignals, typical transducers (biopotential, electrochemical, temperature, pressure, acoustic, movement), applications (cardiovascular medicine, neurology, pulmonology, etc.) and interfacing circuits. Prerequisite: EE122A or equivalent hands-on mixed-signal design experience and solid working knowledge of EE122A topics (see course description).

Last offered: Spring 2016
| UG Reqs: WAY-AQR, WAY-SMA

## EE 142: Engineering Electromagnetics

Introduction to electromagnetism and Maxwell's equations in static and dynamic regimes. Electrostatics and magnetostatics: Gauss's, Coulomb's, Faraday's, Ampere's, Biot-Savart's laws. Electric and magnetic potentials. Boundary conditions. Electric and magnetic field energy. Electrodynamics: Wave equation; Electromagnetic waves; Phasor form of Maxwell's equations.nSolution of the wave equation in 1D free space: Wavelength, wave-vector, forward and backward propagating plane waves.Poynting's theorem. Propagation in lossy media, skin depth. Reflection and refraction at planar boundaries, total internal reflection. Solutions of wave equation for various 1D-3D problems: Electromagnetic resonators, waveguides periodic media, transmission lines. Formerly
EE 141. Pre-requisites: Phys 43 or
EE 42,
CME 100,
CME 102 (recommended)

Terms: Aut
| Units: 3
| UG Reqs: GER:DB-EngrAppSci, WAY-FR, WAY-SMA

Instructors:
Fan, J. (PI)
;
Qiu, B. (TA)

## EE 180: Digital Systems Architecture

The design of processor-based digital systems. Instruction sets, addressing modes, data types. Assembly language programming, low-level data structures, introduction to operating systems and compilers. Processor microarchitecture, microprogramming, pipelining. Memory systems and caches. Input/output, interrupts, buses and DMA. System design implementation alternatives, software/hardware tradeoffs. Labs involve the design of processor subsystems and processor-based embedded systems. Formerly
EE 108B. Prerequisite:
CS107 (required) and
EE108 (recommended but not required).

Terms: Win
| Units: 4
| UG Reqs: GER:DB-EngrAppSci, WAY-SMA

## ENERGY 101: Energy and the Environment (EARTHSYS 101)

Energy use in modern society and the consequences of current and future energy use patterns. Case studies illustrate resource estimation, engineering analysis of energy systems, and options for managing carbon emissions. Focus is on energy definitions, use patterns, resource estimation, pollution. Recommended:
MATH 21 or 42.

Terms: Win
| Units: 3
| UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-SMA

Instructors:
Durlofsky, L. (PI)
;
Kovscek, A. (PI)
;
Beutler, H. (TA)
...
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Instructors:
Durlofsky, L. (PI)
;
Kovscek, A. (PI)
;
Beutler, H. (TA)
;
Jaeger, M. (TA)
;
Makalinao, A. (TA)

## ENERGY 102: Fundamentals of Renewable Power (EARTHSYS 102)

Do you want a much better understanding of renewable power technologies? Did you know that wind and solar are the fastest growing forms of electricity generation? Are you interested in hearing about the most recent, and future, designs for green power? Do you want to understand what limits power extraction from renewable resources and how current designs could be improved? This course dives deep into these and related issues for wind, solar, biomass, geothermal, tidal and wave power technologies. We welcome all student, from non-majors to MBAs and grad students. If you are potentially interested in an energy or environmental related major, this course is particularly useful. Recommended:
Math 21 or 42.

Terms: Spr
| Units: 3
| UG Reqs: GER:DB-EngrAppSci, WAY-SMA

Instructors:
Gerritsen, M. (PI)
;
Kovscek, A. (PI)

## ENERGY 120: Fundamentals of Petroleum Engineering (ENGR 120)

Lectures, problems, field trip. Engineering topics in petroleum recovery; origin, discovery, and development of oil and gas. Chemical, physical, and thermodynamic properties of oil and natural gas. Material balance equations and reserve estimates using volumetric calculations. Gas laws. Single phase and multiphase flow through porous media.

Terms: Aut
| Units: 3
| UG Reqs: GER:DB-EngrAppSci, WAY-FR, WAY-SMA

## ENGR 15: Dynamics

The application of Newton's Laws to solve 2-D and 3-D static and dynamic problems, particle and rigid body dynamics, freebody diagrams, and equations of motion, with application to mechanical, biomechanical, and aerospace systems. Computer numerical solution and dynamic response. Prerequisites: Calculus (differentiation and integration) such as
MATH 41; and
ENGR 14 (statics and strength) or a mechanics course in physics such as
PHYSICS 41.

Terms: Aut, Spr
| Units: 4
| UG Reqs: GER:DB-EngrAppSci, WAY-SMA

Instructors:
Lew, A. (PI)
;
Mitiguy, P. (PI)
;
Alter, A. (TA)
;
Comenencia Ortiz, L. (TA)
;
Grossman-Ponemon, B. (TA)
;
Kim, K. (TA)
;
Lemongo, I. (TA)
;
Moss, J. (TA)
;
Shu, Y. (TA)

## ENGR 20: Introduction to Chemical Engineering (CHEMENG 20)

Overview of chemical engineering through discussion and engineering analysis of physical and chemical processes. Topics: overall staged separations, material and energy balances, concepts of rate processes, energy and mass transport, and kinetics of chemical reactions. Applications of these concepts to areas of current technological importance: biotechnology, energy, production of chemicals, materials processing, and purification. Prerequisite:
CHEM 31.

Terms: Spr
| Units: 4
| UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-SMA

Instructors:
Khosla, C. (PI)
;
Gauthier, J. (SI)

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