Online courses directory (10358)

This course introduces principles and mathematical models of electrochemical energy conversion and storage. Students study equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. In addition, this course includes applications to batteries, fuel cells, supercapacitors, and electrokinetics.

This course introduces principles and mathematical models of electrochemical energy conversion and storage. Students study equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. In addition, this course includes applications to batteries, fuel cells, supercapacitors, and electrokinetics.

This course covers a variety of topics concerning superconducting magnets, including thermodynamic and transport properties of aqueous and nonaqueous electrolytes, the electrode/electrolyte interface, and the kinetics of electrode processes. It also covers electrochemical characterization with regards to d.c. techniques (controlled potential, controlled current) and a.c. techniques (voltametry and impedance spectroscopy). Applications of the following will also be discussed: electrowinning, electrorefining, electroplating, and electrosynthesis, as well as electrochemical power sources (batteries and fuel cells).

This course discusses applications of electromagnetic and equivalent quantum mechanical principles to classical and modern devices. It covers energy conversion and power flow in both macroscopic and quantum-scale electrical and electromechanical systems, including electric motors and generators, electric circuit elements, quantum tunneling structures and instruments. It studies photons as waves and particles and their interaction with matter in optoelectronic devices, including solar cells, displays, and lasers.

The instructors would like to thank Scott Bradley, David Friend, Ta-Ming Shih, and Yasuhiro Shirasaki for helping to develop the course, and Kyle Hounsell, Ethan Koether, and Dmitri Megretski for their work preparing the lecture notes for OCW publication.

This course examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena.

Acknowledgments

The instructor would like to thank Thomas Larsen and Matthew Pegler for transcribing into LaTeX the homework problems, homework solutions, and exam solutions.

This course is a graduate level subject on electromagnetic theory with particular emphasis on basics and applications to Nuclear Science and Engineering. The basic topics covered include electrostatics, magnetostatics, and electromagnetic radiation. The applications include transmission lines, waveguides, antennas, scattering, shielding, charged particle collisions, Bremsstrahlung radiation, and Cerenkov radiation.

Acknowledgments

Professor Freidberg would like to acknowledge the immense contributions made to this course by its previous instructors, Ian Hutchinson and Ron Parker.

Electromagnetic Theory covers the basic principles of electromagnetism: experimental basis, electrostatics, magnetic fields of steady currents, motional e.m.f. and electromagnetic induction, Maxwell's equations, propagation and radiation of electromagnetic waves, electric and magnetic properties of matter, and conservation laws. This is a graduate level subject which uses appropriate mathematics but whose emphasis is on physical phenomena and principles.

6.632 is a graduate subject on electromagnetic wave theory, emphasizing mathematical approaches, problem solving, and physical interpretation. Topics covered include: waves in media, equivalence principle, duality and complementarity, Huygens' principle, Fresnel and Fraunhofer diffraction, dyadic Green's functions, Lorentz transformation, and Maxwell-Minkowski theory. Examples deal with limiting cases of Maxwell's theory and diffraction and scattering of electromagnetic waves.

6.630 is an introductory subject on electromagnetics, emphasizing fundamental concepts and applications of Maxwell equations. Topics covered include: polarization, dipole antennas, wireless communications, forces and energy, phase matching, dielectric waveguides and optical fibers, transmission line theory and circuit concepts, antennas, and equivalent principle. Examples deal with electrodynamics, propagation, guidance, and radiation of electromagnetic waves.

This course explores electromagnetic phenomena in modern applications, including wireless and optical communications, circuits, computer interconnects and peripherals, microwave communications and radar, antennas, sensors, micro-electromechanical systems, and power generation and transmission. Fundamentals include quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided waves; resonance; acoustic analogs; and forces, power, and energy.

This course explores electromagnetic phenomena in modern applications, including wireless communications, circuits, computer interconnects and peripherals, optical fiber links and components, microwave communications and radar, antennas, sensors, micro-electromechanical systems, motors, and power generation and transmission. Fundamentals covered include: quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided and unguided waves; resonance; and forces, power, and energy.

Acknowledgments

The instructors would like to thank Robert Haussman for transcribing into LaTeX the problem set and Quiz 2 solutions.

This course is the second in a series on Electromagnetism beginning with Electromagnetism I (8.02 or 8.022). It is a survey of basic electromagnetic phenomena: electrostatics; magnetostatics; electromagnetic properties of matter; time-dependent electromagnetic fields; Maxwell's equations; electromagnetic waves; emission, absorption, and scattering of radiation; and relativistic electrodynamics and mechanics.

The electron microprobe provides a complete micrometer-scale quantitative chemical analysis of inorganic solids. The method is nondestructive and utilizes characteristic X-rays excited by an electron beam incident on a flat surface of the sample. This course provides an introduction to the theory of X-ray microanalysis through wavelength and energy dispersive spectrometry (WDS and EDS), ZAF matrix correction procedures and scanning electron imaging with back-scattered electron (BSE), secondary electron (SE), X-ray using WDS or EDS (elemental mapping), and cathodoluminescence (CL). Lab sessions involve hands-on use of the JEOL JXA-8200 Superprobe.

This course covers the fundamental concepts that determine the electrical, optical, magnetic and mechanical properties of metals, semiconductors, ceramics and polymers. The roles of bonding, structure (crystalline, defect, energy band and microstructure) and composition in influencing and controlling physical properties are discussed. Also included are case studies drawn from a variety of applications: semiconductor diodes and optical detectors, sensors, thin films, biomaterials, composites and cellular materials, and others.

EE40LX teaches the fundamentals of engineering electronic interfaces between the physical world and digital devices. Students can expect to cover the material of a traditional first circuits course with a project-based approach. We start with essential theory and develop an understanding of the building blocks of electronics as we analyze, design, and build different parts of a robot from scratch around a microcontroller. This course uses the Texas Instruments MSP430G2 LaunchPad, but you are welcome to bring whichever development board or microcontroller you like!

Useful mathematics will be discussed where appropriate, but only a working knowledge of high school algebra is required to follow along for most of the course. The philosophy of the course is to learn by doing, so every lecture features a substantial lab component. Students are invited to work together in small groups to build their own robots along with the instructors. There will also be individual circuit analysis and design exercises to reinforce the theories presented in the course. Those who successfully complete each theory assignment and earn a passing grade will get an Honor Code certificate from BerkeleyX.

Additionally, a kit of electronic components will be available from Newark element14 starting June 12. The kit is not necessary to obtain a certificate for this run of the course, but it will greatly enhance your learning experience. Some mechanical components are required to complete the robot as presented in the course. Also, the lab experience will be most effective if you have access to a digital multimeter.

Creativity is encouraged! Students who are willing to work outside the bounds of the class to develop their own inventions will get the most out of this guided learning experience.

MyDAQ Information
Those who do not have access to an oscilloscope or a digital multimeter might consider purchasing a MyDAQ to enable measurements. The video modules use the MyDAQ and the MyProtoBoard as measurement equipment to debug circuits. National Instruments has made available the MyDAQ for students in this course. If you are interested, take a look at the MyDAQ ordering page: http://www.studica.com/us/en/BerkeleyMOOC.html

Parts Kit Information
The parts included in the construction of the robot can be purchased at Newark's landing page, which can be found here: http://www.element14.com/community/community/learning-center/online-learning/moocs/edxucb-bridging

A detailed bill of materials with more information can be found here: courses.edx.org/asset-v1:BerkeleyX+EE40LX+2T2015+type@asset+block@EE40LX_PartsList_Summer15.pdf

What is the format of the class?
The class consists of eight modules. Every module consists of a combination of theory-based lectures and lab-based discussions where we apply that module’s theory to building a part of a robot. Quiz exercises are sprinkled throughout the videos to reinforce your knowledge and every module ends with a problem set that reinforces the design and analysis aspects of the class.

Is this class taught at UC Berkeley?
This class is part of the laboratory component of "EE40: Introduction to Microelectronic Systems," the first circuit analysis course at UC Berkeley. It was specifically designed for the online course format.

What will the robot do?
The bare-bones robot that we build will be capable of bouncing around, responding to light or touch inputs, and responding to a loud audio signal.

What supplies and equipment will I need to get the most out of this course?
In order to download programs to the MSP430 microcontroller, you will need access to a modern operating system (Apple, Windows, or Linux) with the Energia environment (http://energia.nu/download) installed. Additionally, access to some wire cutters and pliers would be useful. Also, the lab experience will be most effective if you have access to a digital multimeter. An oscilloscope would be useful, but not necessary.

The NI MyDAQ has been made available for students who would like to follow along with the course. The robot project as presented also requires a few wooden craft sticks and two springs which can be found at a local hardware store.

How much does the kit cost?
The parts kit will cost around $50 USD for most parts. You are welcome to purchase a kit with another student and to work together on labs to split costs. We will also demonstrate other parts not in the kit for those interested in extending their projects.

Will I need to know how to program?
Sample programs are provided in each module that will allow you to test your own circuits with an MSP430 LaunchPad controller. These programs will be explained in optional videos for interested students. If you already know how to code, you can tweak these programs to add additional functionality to your project.

Will this course cover microcontroller programming?
No. Sample programs written in Energia, a high-level language, will be provided, but programming will not be explicitly covered. Students interested in learning microcontroller programming should refer to UT Austinx’s Embedded Systems course.

What if I already have a microcontroller?
Since analog electronics are the emphasis of the course, you should feel free to use any microcontroller you feel comfortable with. However, the use of any other microcontrollers would require you to write your own programs.

Is there a required textbook?
No textbook is required for this course. Handouts are provided for the concepts presented in the class; material for some of these handouts is taken from the 2nd edition of the book Circuits by Fawwaz Ulaby and Michel Maharbiz and we recommend the book as way to delve deeper into basic circuit concepts. We also occasionally provide links to web content that we find useful or informative.

Love letters generated by a computer. An online poem two hundred trillion stanzas long. A mystery novel in the form of a wiki. The story of Inanimate Alice, told through videos and instant messages. An ocean buoy tweeting remixes of Moby Dick. Welcome to the weird world of electronic literature—digitally born poetic, narrative, and aesthetic works read on computers, tablets, and phones. Experimental, evocative, and sometimes simply puzzling, electronic literature challenges our assumptions about reading, writing, authorship, and meaning.

Yet e-lit, as it is often called, has also profoundly influenced mainstream culture. Literature, film, comics, apps, and video games have all learned lessons from electronic literature. This course will trace the rise of electronic literature and explore both historic and contemporary works of e-lit. We’ll begin with electronic literature’s roots in avant-garde art and Cold War technology, and follow e-lit through the birth of the personal computer into the era of the Web and smartphone. At every step along the way the expressive power of new media—the way digital media enables and shapes different modes of creative and cultural expression—will be of particular interest to us.

Courses offered via edX.org are not eligible for academic credit from Davidson College. A passing score in a DavidsonX course(s) will only be eligible for a verified certificate generated by edX.org.

In this engineering course, you will learn about diodes, bipolar junction transistors, MOSFETs and semiconductor properties.

This course is part 1 of a series that explain the basis of the electrical, optical, and magnetic properties of materials including semiconductors, metals, organics, and insulators. You will learn how devices are built to take advantage of these properties. This is illustrated with a wide range of devices, placing a strong emphasis on new and emerging technologies.

Part 2 - 3.15.2x: Optical Materials and Devices
Part 3 - 3.15.3x: Magnetic Materials and Devices

Taught by instructors with decades of experience on Wall Street, Electronic Trading in Financial Markets is a comprehensive study of the impact of technology on financial market systems.

This economics and finance course provides students with a foundation in market structure (what is ‘liquidity?’) before building to introduce electronic trading fundamentals (order books) and advanced electronic trading techniques (algorithmic trading). Learners will study the history of technology in markets, the details of electronic trading protocols and the impact of innovation on market structure.

This course is broken down into 6 modules:

• Module 1: Fundamentals of Market Structure
• Module 2: Fundamentals of Electronic Trading
• Module 3: Mechanics of an Order Book
• Module 4: Advanced Electronic Trading
• Module 5: Electronic Trading in Fixed Income
• Module 6: Innovation Guidelines

Upon completion of this course, participants will receive a certificate bearing the New York Institute of Finance (NYIF) name. A NYIF certificate, highly valued in the financial industry, will bolster a resume or LinkedIn profile and prove the skills you’ve gained to potential employers.

This course describes how electronic, optical and magnetic properties of materials originate from their electronic and molecular structure and how these properties can be designed for particular applications. It offers experimental exploration of the electronic, optical and magnetic properties of materials through hands-on experimentation and practical materials examples.

Lecture Series on Adaptive Signal Processing by Prof.M.Chakraborty, Department of E and ECE, IIT Kharagpur.