Difference between revisions of "User:Ap210"
Line 14: | Line 14: | ||
'''Name Pronunciation-''' | '''Name Pronunciation-''' | ||
æləks fɪ́fnər | æləks fɪ́fnər | ||
+ | |||
+ | |||
+ | == Matlab Demo: 3-D Drawing == | ||
+ | The 3-D Drawing Program seemed most interesting to me because it epitomizes the ease with which computer programs can accomplish tasks humans would have extreme difficulty with. Even with a relatively simple program, MATLAB can generate the surface of revolution for any combination of straight lines the user could present. It perfectly represents the graphics both before and after generating the surface, which any person would have extreme difficulty drawing in a few seconds. This not only seems useful, but is also interesting to experiment with and see what shapes can be made. | ||
+ | |||
+ | |||
== External Links == | == External Links == |
Revision as of 03:02, 21 September 2011
About Me
My name is Alex Pfiffner
From Portland, Oregon
Class of 2015
Studying Mechanical Engineering (also interested in BME and Neuroscience)
This should sum things up: http://nyan.cat/
Name Pronunciation- æləks fɪ́fnər
Matlab Demo: 3-D Drawing
The 3-D Drawing Program seemed most interesting to me because it epitomizes the ease with which computer programs can accomplish tasks humans would have extreme difficulty with. Even with a relatively simple program, MATLAB can generate the surface of revolution for any combination of straight lines the user could present. It perfectly represents the graphics both before and after generating the surface, which any person would have extreme difficulty drawing in a few seconds. This not only seems useful, but is also interesting to experiment with and see what shapes can be made.
External Links
External Links NANOWIRES MAY BOOST SOLAR CELL EFFICIENCY, UCSD Jacobs, May 13, 2008, September 20, 2011 (Grand Challenge)
Summary- University of California, San Diego has developed Nanowires that may boost the efficiency of ultra-thin solar panels. Indium phosphide Nanowires increase the number of electrons that are successfully knocked into the solar panel's electrode and therefore increase the productivity of thinner panels. The Nanowires allow electrons a direct pathway to the electrode not found in most current, thin solar panels which are built from normal polymer mixtures. If these Nanowires could be grown on untreated metal electrodes, many possibilities and applications (such as more efficient and curved panels) would be made available. Scientists predict this technology will not be publicly available until at least the year 2018.